Xantrex Technology Portable Generator 120 VAC 60 User Manual

SW Series Inverter/Chargers  
With Revision 4.01 Software  
Owner’s Manual  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
PRODUCT MATERIALS PACKAGE  
Thank you for choosing Xantrex products to meet your powering needs. We make every effort to ensure  
that your inverter/charger is properly packaged for shipping including the following:  
q Owners Manual;  
q Battery Temperature Sensor (BTS);  
q Red and black battery terminal covers with attaching hardware;  
q Hardware package (AC access panels with screws, crimp-on terminals);  
q Tracebumper sticker;  
If any of the above listed materials are missing from your package, or if it is unsatisfactory in any manner,  
please contact our Service department at 360-435-8826; or, fax this page explaining the discrepancy to  
360-474-0616. Please provide:  
Model Number: ________________________________  
Serial Number: ________________________________  
Comments:  
Visit our web site at www.traceengineering.com for more information and answers to frequently asked  
questions.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
www.traceengineering.com  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
TABLE OF CONTENTS  
TABLE OF CONTENTS  
IMPORTANT SAFETY INSTRUCTIONS ..................................................................................................... 1  
GENERAL PRECAUTIONS....................................................................................................................................1  
SPECIAL NOTICES................................................................................................................................................2  
PERSONAL PRECAUTIONS..................................................................................................................................3  
INTRODUCTION .......................................................................................................................................... 5  
UNIT IDENTIFICATION................................................................................................................................ 7  
MODEL NUMBER...................................................................................................................................................7  
CONTROLS, INDICATORS AND COMPONENTS...................................................................................... 9  
CONTROL PANEL..................................................................................................................................................9  
AC SIDE ...............................................................................................................................................................12  
DC SIDE ...............................................................................................................................................................14  
INSTALLATION.......................................................................................................................................... 15  
QUICK INSTALL...................................................................................................................................................16  
COMPLETE INSTALL...........................................................................................................................................17  
FUNCTIONAL TEST .................................................................................................................................. 31  
MENU SYSTEM.......................................................................................................................................... 33  
OVERVIEW ..........................................................................................................................................................33  
USER MENU MAP................................................................................................................................................34  
SETUP MENU MAP..............................................................................................................................................35  
USER MENU ........................................................................................................................................................36  
SETUP MENU ......................................................................................................................................................44  
OPERATION............................................................................................................................................... 57  
THEORY OF OPERATION...................................................................................................................................57  
POWER VS. EFFICIENCY...................................................................................................................................59  
INVERTER CAPACITY VS TEMPERATURE .......................................................................................................60  
OPERATING MODES...........................................................................................................................................61  
INVERTER MODE ................................................................................................................................................62  
CHARGER MODE ................................................................................................................................................64  
INVERTER/CHARGER MODE .............................................................................................................................69  
GENERATOR SUPPORT MODE .........................................................................................................................71  
AUTOMATIC GENERATOR CONTROL MODE ...................................................................................................73  
UTILITY BACKUP MODE .....................................................................................................................................81  
UTILITY INTERACTIVE MODE ............................................................................................................................83  
ENERGY MANAGEMENT MODE.........................................................................................................................90  
PEAK LOAD SHAVING MODE.............................................................................................................................92  
IN BRIEF...............................................................................................................................................................92  
LOW BATTERY TRANSFER (LBX) MODE ..........................................................................................................93  
USING MULTIPLE INVERTERS...........................................................................................................................95  
TECHNICAL INFORMATION..................................................................................................................... 99  
BATTERY TYPE ...................................................................................................................................................99  
BATTERY SIZING...............................................................................................................................................101  
BATTERY BANK SIZING....................................................................................................................................102  
BATTERY CARE AND MAINTENANCE .............................................................................................................104  
BATTERY INSTALLATION.................................................................................................................................106  
BATTERY HOOK-UP CONFIGURATIONS.........................................................................................................107  
BATTERY CABLE INDUCTANCE ......................................................................................................................110  
APPLICATIONS..................................................................................................................................................111  
TROUBLESHOOTING GUIDE............................................................................................................................112  
INVERTER/CHARGER TERMINOLOGY............................................................................................................115  
SPECIFICATIONS AND FEATURES (60 Hz Models) ........................................................................................118  
SPECIFICATIONS AND FEATURES (50 Hz Models) ........................................................................................119  
DIMENSIONS .....................................................................................................................................................121  
INSTALLATION DIAGRAMS ..............................................................................................................................121  
USER SETTINGS WORKSHEETS.....................................................................................................................123  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
TABLE OF CONTENTS  
APPENDIX................................................................................................................................................ 128  
OPTIONS ........................................................................................................................................................... 128  
OTHER PRODUCTS.......................................................................................................................................... 129  
REFERENCE TABLES AND GRAPHS.............................................................................................................. 130  
STORAGE CHECKLIST..................................................................................................................................... 133  
WARRANTY/REPAIR INFORMATION .................................................................................................... 135  
LIMITED WARRANTY........................................................................................................................................ 135  
WARRANTY REGISTRATION ........................................................................................................................... 135  
LIFE SUPPORT POLICY.................................................................................................................................... 135  
WARRANTY OR REPAIR SERVICE REQUIRED.............................................................................................. 136  
INDEX ....................................................................................................................................................... 137  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
TABLE OF CONTENTS  
INDEX OF FIGURES  
Figure 1, Identification Label .................................................................................................................. 7  
Figure 2, SW Series Inverter/Charger.................................................................................................... 9  
Figure 3, Control Panel........................................................................................................................... 9  
Figure 4, AC Side ................................................................................................................................. 12  
Figure 5, Internal Components and Indicators ..................................................................................... 13  
Figure 6, Aux and Gen Control Relays................................................................................................. 14  
Figure 7, DC Side................................................................................................................................. 14  
Figure 8, Air Flow Intake Location........................................................................................................ 18  
Figure 9, AC Input/Output Power Connection ...................................................................................... 19  
Figure 10, Warning Label..................................................................................................................... 21  
Figure 11, Battery to Inverter Cable Connection .................................................................................. 24  
Figure 12, Neutral-To-Ground Bond Switching: No External AC Source Connected........................... 27  
Figure 13, Neutral-To-Ground Bond Switching: External AC Source Connected ................................ 28  
Figure 14, Neutral-To-Ground Bond Switching: Neutral Bonded To Ground....................................... 28  
Figure 15, Multiple Point Ground System............................................................................................. 29  
Figure 16, Single Point Ground System ............................................................................................... 29  
Figure 17, TraceSW Series Inverter Simple Block Diagram ........................................................... 57  
Figure 18, TraceSW Series Inverter Output Waveform................................................................... 58  
Figure 19, TraceSW Series Efficiency Curves.................................................................................. 59  
Figure 20, Inverter Capacity vs. Temperature...................................................................................... 60  
Figure 21, Three-Stage Battery Charging ............................................................................................ 64  
Figure 22, BTS (Battery Temperature Sensor) .................................................................................... 65  
Figure 23, Two Wire Start Wiring Diagram .......................................................................................... 76  
Figure 24, Three Wire Start Wiring Diagram (HONDA Type) .............................................................. 77  
Figure 25, Three Wire Start Wiring Diagram (ONAN Type)................................................................. 77  
Figure 26, Relay RY7 and RY8 Sequence ........................................................................................... 78  
Figure 27, Selling Power From A DC Charging Source; Hypothetical Time Of Day Oper. History...... 85  
Figure 28, Selling Power Stored In The Batteries; Hypothetical Time Of Day Operational History...... 86  
Figure 29, Utility Interactive Line-Tie System With Battery Backup Flow Diagram .............................. 88  
Figure 30, Overvoltage Protection for Battery ...................................................................................... 89  
Figure 31, Series Configuration: 6-Volt Battery Wiring....................................................................... 107  
Figure 32, Series Configuration: 12-Volt Battery Wiring..................................................................... 107  
Figure 33, Parallel Configuration: 12-Volt Battery Wiring................................................................... 108  
Figure 34, Series-Parallel Configuration: 6-Volt Battery Wiring.......................................................... 109  
Figure 35, Series-Parallel Configuration: 12-Volt Battery Wiring........................................................ 109  
Figure 36, AC Waveforms.................................................................................................................. 116  
Figure 37, SW Series Dimensions: With AC Access Covers Showing Knockout Sizes ................. 120  
Figure 38, Installation Diagram, 120 VAC, 1 Phase, Grid Connected, Generator Backup ................ 121  
Figure 39, Installation Diagram, 240 VAC, 3 Wire, Grid Connected, Generator Backup................... 122  
Figure 40, AWG Wire Size................................................................................................................. 131  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
TABLE OF CONTENTS  
INDEX OF TABLES  
Table 1, AC Input and Output Wiring Connections .............................................................................. 19  
Table 2, Minimum Recommended Battery Cable Size vs. Cable Length............................................. 22  
Table 3, Battery Cable To Maximum Breaker/Fuse Size ..................................................................... 23  
Table 4, Charging Setpoints For Common Battery Types.................................................................... 67  
Table 5, Typical Wattage Of Common Appliances ............................................................................ 101  
Table 6, Battery Charging: Charging Setpoints .................................................................................. 104  
Table 7, Battery State of Charge Voltage........................................................................................... 105  
Table 8, Battery Cable Inductance ..................................................................................................... 110  
Table 9, Power Consumption Of Common Appliances...................................................................... 130  
Table 10, AWG to Metric Wire Conversion Chart .............................................................................. 130  
Table 11, Minimum Recommended Battery Cable Size vs. Cable Length......................................... 131  
Table 12, Battery Cable to Maximum Breaker/Fuse Size................................................................... 131  
Table 13, Recommended Minimum AC Wire Sizes (75° C)............................................................... 132  
Table 14, Knockout/Hole Size To Conduit Size Required .................................................................. 132  
Table 15, Safety Ground Wire Sizes .................................................................................................. 132  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
IMPORTANT SAFETY INSTRUCTIONS  
IMPORTANT SAFETY INSTRUCTIONS  
SAVE THESE INSTRUCTIONS!  
This manual contains important safety and operating instructions as prescribed by UL Standards for the  
TraceSW Series Inverter/Chargers for use in residential and commercial applications. This manual  
specifically covers products with the revision 4.01 software.  
The 120 VAC/60 Hertz models of the SW Series Inverter/Chargers are ETL listed to UL Standard 1741  
(Draft), Static Inverters and Charge Controllers for use in Photovoltaic Systems. The 12 and 24 VDC,  
120 VAC/60 Hertz models of the SW Series Inverter/Chargers are ETL listed to UL standard 458, Power  
Converters/Inverters and Power Converter/Inverter Systems for Land Vehicles and Marine Craft.  
The 120 VAC/60 Hertz models of the SW Series Inverter/Chargers are also ETL listed to Canadian  
Standard CSA - C 22.2 No. 107.1 - M1, Commercial and Industrial Power Supplies.  
The following Model Numbers of the SW Series Inverter/Chargers listed above comply with the following  
EU directives:  
89/336/EEC, “Council Directive of 3 May 1989 on the approximation of the laws of Member States  
relating to Electromagnetic compatibility(EMC)  
73/23/EEC, Council Directive of 19 February 1973 on the harmonization of the laws of Member  
States relating to electrical equipment for use within certain voltage limits(LVD)  
SW2612E  
SW4548AHC  
SW4548EPV  
SW2612AHC  
SW3024E  
SW2612A  
SW3048E  
SW2612EHC SW4548EHC  
SW3048AHC  
SW3048EPV  
SW3048APV  
SW4548E  
SW4548E3PH  
SW3048E3PH  
SW4548APV  
SW4548A  
SW3048EHC  
SW3024AHC  
SW3024EHC  
SW3024E  
SW3048E  
SW3048A  
SW3024A  
SW3048E  
The compliance of the above mentioned products with the Directives is confirmed through the  
application of the following essential requirements:  
Emissions and Immunity  
EN 50091-1  
Safety  
EN 50091-2 and  
EN 60950  
NOTE: To achieve compliance to EN50091-1, Conducted RF emissions, product must not be  
connected to AC mains. Compliance is assured for off-grid applications only.  
As the manufacturer we declare under our sole responsibility that the above mentioned products comply  
with the above named directives.  
GENERAL PRECAUTIONS  
1. Before using the SW Series Inverter/Charger, read all instructions and cautionary markings on:  
(a) the inverter/charger; (b) the batteries and; (c) all appropriate sections of this manual.  
WARNING - To reduce risk of injury, charge only deep-cycle lead acid, lead antimony, lead calcium,  
gel cell, absorbed glass mat, or NiCad/NiFe type rechargeable batteries. Other types of batteries  
may burst, causing personal injury and damage.  
2. Do not expose inverter/charger to rain, snow or liquids of any type. The inverter is designed for indoor  
mounting only. Protect the inverter from splashing if used in vehicle applications.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
1
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
IMPORTANT SAFETY INSTRUCTIONS  
3. Use of battery cable or custom attachment not recommended or sold by Xantrex Technology Inc. for  
the SW Series Inverter/Charger may result in a risk of fire, electric shock, or injury to persons.  
4. Do not disassemble the inverter/charger. Take it to a qualified service center when service or repair is  
required. Incorrect re-assembly may result in a risk of electric shock or fire.  
5. To reduce risk of electric shock, disconnect all wiring before attempting any maintenance or cleaning.  
Turning off the inverter will not reduce this risk. Solar modules produce power when exposed to light.  
Cover them with opaque material before servicing any connected equipment.  
WARNING RISK OF EXPLOSIVE GASSES  
(a) WORKING IN VICINITY OF A LEAD ACID BATTERY IS DANGEROUS. BATTERIES  
GENERATE EXPLOSIVE GASES DURING NORMAL BATTERY OPERATION. FOR THIS  
REASON, IT IS OF UTMOST IMPORTANCE THAT EACH TIME BEFORE SERVICING  
EQUIPMENT IN THE VICINITY OF THE BATTERY, YOU READ THIS MANUAL AND  
FOLLOW THE INSTRUCTIONS EXACTLY.  
(b) To reduce risk of battery explosion, follow the instructions in this manual and those published  
by the battery manufacturer as well as manufacturer of any additional equipment used in the  
vicinity of the battery. Review all cautionary markings on these products.  
SPECIAL NOTICES  
1. Tools required to make AC and DC wiring connections: Wire strippers; 1/2" (13MM) open-end or  
socket wrench; Phillips #2 screwdriver; flat blade 1/4" (6MM) screwdriver.  
2. No terminals or lugs are required for hook-up of the AC wiring. AC wiring must be copper wire and  
rated for 75°C or higher. The maximum wire size for the AC terminals is #6 AWG (4.11 mm diameter).  
Battery cables must be rated for 75°C or higher. Crimped and sealed copper ring terminal lugs with a  
5/16 hole should be used to connect the battery cables to the DC terminals of the inverter/charger.  
Soldered cable lugs are also acceptable.  
3. Torque all AC wiring connections to 20 inch-pounds. Torque all DC cable connections to 10-15 foot-  
pounds. Avoid dropping metal tools onto the batteries. A short-circuit could result in a spark, fire or  
possible explosion.  
4. This inverter/charger is designed for use with a battery supply with a nominal voltage that matches the  
last two digits of the model number (e.g., 12 Volt with an SW2512).  
5. For instructions on mounting, see the MOUNTING section on page 17 of this manual.  
NOTE: Do not use the keyhole mounting slots for permanent installations. For battery installation  
and maintenance refer to the battery manufacturer’s instructions.  
6. No AC or DC disconnects are provided as an integral part of this inverter. Both AC and DC  
disconnects must be provided as part of the system installation. Refer to the INSTALLATION section  
beginning on page 15 for more information.  
7. No overcurrent protection for the battery supply is provided as an integral part of this inverter.  
Overcurrent protection of the battery cables must be provided as part of the system installation. Refer  
to the INSTALLATION section beginning on page 15 and the DC DISCONNECT AND  
OVERCURRENT PROTECTION section on page 23 for more information.  
8. No over current protection for the AC output wiring is provided as an integral part of this inverter.  
Overcurrent protection of the AC output wiring must be provided as part of the system installation. Refer to  
the INSTALLATION section on page 15 and the AC WIRING section on page 18 for more information.  
9. The AC output neutral conductor and DC negative conductors are not connected (bonded) to the  
inverter chassis. Both the input and output conductors are isolated from the enclosure and each other.  
System grounding, if required by sections 690-40, and 690-42 of the National Electric Code,  
ANSI/NFPA 70-1996, is the responsibility of the system installer. All installations must comply with  
local and national electrical codes and standards.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
2
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
IMPORTANT SAFETY INSTRUCTIONS  
10. GROUNDING INSTRUCTIONS - This inverter/battery charger should be connected to a grounded,  
permanent wiring system. For most installations, the negative battery conductor should be bonded to  
the grounding system at one (and only one point) in the system. All installations should comply with  
national and local codes and ordinances. Refer to the SYSTEM GROUNDING section on page 26 for  
more information.  
PERSONAL PRECAUTIONS  
1. Someone should be within range of your voice or close enough to come to your aid when you work  
near batteries.  
2. Have plenty of fresh water and soap nearby in case battery acid contacts skin, clothing, or eyes.  
3. Wear complete eye protection and clothing protection. Avoid touching eyes while working near  
batteries. Wash your hands when done.  
4. If battery acid contacts skin or clothing, wash immediately with soap and water. If acid enters eye,  
immediately flood eye with running cool water for at least 15 minutes and get medical attention immediately.  
(a) Baking soda neutralizes lead acid battery electrolyte.  
(b) Vinegar neutralizes spilled NiCad and NiFe battery electrolyte.  
(c) Keep a supply on hand in the area of the batteries.  
5. NEVER smoke or allow a spark or flame in vicinity of a battery or generator.  
6. Be extra cautious to reduce the risk of dropping a metal tool onto batteries. It could short-circuit the  
batteries or other electrical parts that may result in a spark which could cause an explosion.  
7. Remove personal metal items such as rings, bracelets, necklaces, and watches when working with a  
battery. A battery can produce a short-circuit current high enough to weld a ring or the like to metal,  
causing severe burns.  
8. NEVER charge a frozen battery.  
9. If necessary to remove the battery, make sure all accessories are off. Then, remove the grounded  
terminal from the battery first.  
10. If a remote or automatic generator control system is used, disable the automatic starting circuit and/or  
disconnect the generator from its starting battery while performing maintenance to prevent accidental  
starting.  
11. Provide ventilation to outdoors from the battery compartment. The battery enclosure should be  
designed to prevent accumulation and concentration of hydrogen gas in pocketsat the top of the  
compartment. Vent the battery compartment from the highest point. A sloped lid can also be used to  
direct the flow to the vent opening location.  
12. Clean battery terminals. Be careful to keep corrosion from coming in contact with eyes.  
13. Study all the battery manufacturers specific precautions, such as removing or not removing cell caps  
while charging and recommended rates of charge.  
14. For flooded lead acid batteries, add distilled water in each cell until the battery acid reaches the level  
specified by the battery manufacturer. This helps purge excessive gas fumes from the cells. Do not  
overfill. For a battery without cell caps, carefully follow the manufacturers recharging instructions.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
3
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
IMPORTANT SAFETY INSTRUCTIONS  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
4
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
INTRODUCTION  
INTRODUCTION  
Congratulations! You are the proud owner of the finest inverter on the market today - and one very  
complex piece of equipment. The TraceSine wave (SW Series) Inverter/Charger has many features  
and capabilities previously either non-existent, or found only in separate products.  
With proper installation, the inverter will operate satisfactorily for many applications straight out of the box,  
using the factory default settings. To fully utilize the inverter's generator interactive, or utility interactive  
capabilities, it is necessary to understand the way the inverter operates and then tailor its operation via the  
Control Panel and the USER and SETUP menu systems. This manual will provide the necessary  
information. However, it is recommended that you consult with your authorized dealer to ensure correct  
installation and maximum utilization of the numerous features of this product. If you do not understand any  
aspect of installation, contact your authorized Xantrex dealer/installer for assistance.  
If you intend to operate the inverter in a utility interactive mode, in which power will be sold to the utility,  
you must contact the local utility office and get their approval. The utility may require additional information  
that may not be included in this manual. Please contact your authorized Xantrex dealer/installer for  
assistance.  
As a minimum, you should read the sections of the manual that relate to your type of installation. The  
MENU SYSTEM section, beginning on page 33, explains how to make changes to the inverters  
user/setup menus. The OPERATION section, beginning on page 57, explains how the inverter works in  
each of its different operating modes. Focus on the operating modes that relate best to your type of  
installation and make the appropriate selections and adjustments. Installation diagrams are provided for  
many of the various applications. This menu system provides control of the inverter, allows features to be  
enabled, and allows setting of operating parameters.  
This is a long manual and much of it is fairly technical. Throughout this manual terms may be used that  
are unfamiliar, see the INVERTER/CHARGER TERMINOLOGY glossary on page 115 for clarification. If  
you are an insomniac, properly used, this manual is guaranteed to provide several good nights of sleep.  
Note: This manual is specific to the REVISION 4.01 software. Some features discussed may not  
be included in previous software revisions provided in inverters manufactured before March  
1996.  
You can verify that the inverter is using REVISION 4.01 software by checking under the TRACE  
ENGINEERING (3) menu heading. The second menu item should read REVISION 4.01. If your inverter  
includes a previous software version, please contact your authorized Xantrex dealer regarding upgrade  
options.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
5
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
INTRODUCTION  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
6
Rev. C: February 2001  
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UNIT IDENTIFICATION  
UNIT IDENTIFICATION  
This section describes the marking and location of the model and serial numbers for SW Series  
Inverter/Chargers. Use this section to determine the type and model of your inverter/charger. The unit  
identification label on the left side panel of the inverter/charger will show the serial number, model  
number, listings, ratings, and date of manufacture.  
Model Number  
DC Input Voltage  
Operating Range  
AC Input/Output  
Phase,  
Quarter and Year of  
Manufacture  
Waveform,  
Frequency and  
Voltage  
Product Code and Serial  
Number  
Figure 1, Identification Label  
MODEL NUMBER  
The Model Number of your inverter determines the different features your unit may have. Consider the  
following unit with a SW4024 model number:  
SW  
40  
24  
*
Model  
Power  
Nominal DC  
Voltage  
AC Voltage/Options  
Model: The first letter(s) (SW) indicate the model, in this case the SW Series.  
Power: The first and second positions in the model number indicate the continuous AC power output in  
hundreds of VA (Volt-Amps). Power levels available start at 2500 up to 5500 Volt-Amps with different DC  
voltages. In the example above, 40 would stand for a 4000 VA (4 kVA), continuous-output inverter.  
Input/Output DC Voltage: The number (24) following the power rating indicates an inverter/charger that  
is designed to convert 24 VDC input to an AC voltage output, and charge 24 VDC batteries when  
powered by the same AC voltage. Available DC voltages are 12, 24 and 48 volt models.  
Input/Output AC Voltage/Options: The letter following the power rating indicates what AC voltage and  
frequency or particular option this inverter/charger is specifically designed to provide. No letter after the  
DC voltage number indicates an AC voltage of 120 VAC/60 Hz and requires the same AC voltage and  
frequency (120 VAC/60 Hz) to charge the inverter batteries. Available voltages range from 105 to 240  
VAC at 50 or 60 Hz.  
See the SPECIFICATIONS AND FEATURES section, on page 121, for the different models available.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
7
Rev. C: February 2001  
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UNIT IDENTIFICATION  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
Page  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Rev. C: February 2001  
8
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CONTROLS, INDICATORS AND COMPONENTS  
CONTROLS, INDICATORS AND COMPONENTS  
The SW Series Inverter/Chargers have an integral, full function Control Panel with LED status indicators.  
The following components are also included: inverter/charger circuit breaker; battery temperature sensor  
(BTS) port, remote port, and a stacking port.  
Stacking Interface  
Remote Interface  
Control Panel  
AC Side  
DC Side  
BTS Sensor Input  
Circuit Breaker  
Figure 2, SW Series Inverter/Charger  
CONTROL PANEL  
The Control Panel, on the front of the SW Series Inverter/Charger, provides the controls and displays  
needed to adjust, control and monitor the operation of the unit. The control panel is operational whenever  
DC power is applied to the inverter DC input terminals.  
Figure 3, Control Panel  
Eight pushbuttons are used to select the various menus, menu items and operating setpoint values for the  
unit, including the ability to turn the inverter on and off. A Liquid Crystal Display (LCD) presents the various  
system settings and data as selected by the operation of the MENU BUTTONS on the control panel. Eight  
LED indicators are provided to show the operating condition of the inverter, battery charger, AC inputs and  
self-protection systems.  
DISPLAY  
The Liquid Crystal Display (LCD) displays data as selected by the menu buttons. Refer to the USER  
MENU, beginning on page 36, and the SETUP MENU, beginning on page 44, for specific information on  
the Menu Items, functions and display information.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
9
Rev. C: February 2001  
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CONTROLS, INDICATORS AND COMPONENTS  
CONTRAST CONTROL  
The CONTRAST adjustment enables you to adjust the contrast of the LCD display screen to accommodate  
changing lighting conditions. Less contrast is usually preferable in brighter lighting conditions.  
RESET TO FACTORY DEFAULTS BUTTON  
The RESET TO FACTORY DEFAULTS button returns all of the inverter settings (except for the TIME OF  
DAY settings) to the factory default values. The default values will be re-entered only when this button is  
pushed from a specific menu item in the USER MENU. You must first select the TRACE ENGINEERING  
(3) menu heading and then go to the first menu item, which will display PRESS RESET NOW FOR  
DEFAULTS. Once this reset button is pressed from this menu item, you must reprogram all settings  
required by your installation into the inverter.  
Removing DC power from the inverter will also return the inverter to the factory default values  
(including the TIME OF DAY settings). You must then reprogram the inverter with the required settings  
for proper operation of your system. Recording your settings on the USER SETTINGS WORKSHEET, in  
the TECHNICAL INFORMATION section of this manual, will make the reprogramming of the inverter  
much easier.  
The reset button is also used to re-synchronize the remote control (SWRC) display if the characters become  
jumbled. Pressing the reset button anywhere in the menu system (except the PRESS RESET NOW FOR  
DEFAULTS menu item) will re-synchronize the display, but the default values will not be reset.  
MENU BUTTONS  
ON/OFF MENU BUTTON (Red)  
Pressing the red ON/OFF MENU button at any time will take you directly to the SET INVERTER menu  
item of the INVERTER MODE (1) menu heading. There are four options available from this menu item.  
The first letter of the selected item will be underlined. Pressing the red ON/OFF MENU button will move  
the cursor one position to the right, selecting the next item. You can also use the SET POINTS buttons to  
move either right or left.  
GEN MENU BUTTON (Green)  
Pressing the green GEN MENU button at any time will display the SET GENERATOR menu item of the  
GENERATOR MODE (2) menu heading. There are four options available from this menu. The first letter  
of the selected item will be underlined. Pressing the green GEN MENU button will move the cursor one  
position to the right, selecting the next item. You can also use the SET POINTS buttons to move either  
right or left.  
MENU ACCESS/ADJUSTMENT BUTTONS (Black)  
The MENU HEADING buttons are used to move either up or down through the selection of menu  
headings. Once a menu heading is selected, the MENU ITEM buttons are used to move up or down  
through the list of related menu items. The SET POINTS buttons change the value of a parameter or  
select a mode, for the selected menu item.  
LED STATUS INDICATORS  
The Control Panel features eight colored LED indicators that identify the various operating conditions of  
the inverter. Unless otherwise indicated, the LEDs will be "solid" in appearance, when illuminated.  
LINE TIE (Yellow)  
Selecting SELL from the GRID USAGE menu item under the INVERTER SETUP (9) menu heading will  
enable sell mode. This should only be done with utility connected systems and after you have received the  
approval of the local utility. This mode allows excess power to be sent into the utility grid.  
INVERTING (Yellow)  
The inverter is operational and AC output is available. If this LED is blinking, the inverter is in the search  
mode and is looking for an AC load greater than the SET SEARCH WATTS setting.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
10  
Rev. C: February 2001  
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CONTROLS, INDICATORS AND COMPONENTS  
AC1 IN GOOD (Green)  
Indicates that AC power is present at the AC HOT IN 1 and NEUTRAL IN 1 input terminals. This input is  
intended for utility power. When an AC source is connected to the input terminals, it will start to blink slowly  
(once a second) to show the AC voltage has been detected. After the inverter has connected to the AC  
source, the LED will be solid. If the LED starts to blink during operation, utility power has been dropped.  
AC2 IN GOOD (Green)  
Indicates that AC power is present at the AC HOT IN 2 and NEUTRAL IN 2 input terminals. This input is  
intended for generator power. When an AC source is connected to the input terminals, it will start to blink  
slowly (once a second) to show the AC voltage has been detected. After the inverter has connected to the  
AC source, the LED will be solid. If the LED starts to blink during operation, generator power may have been  
dropped.  
This LED will also blink slowly (once a second) when the automatic generator control system is enabled.  
When the generator has started, it will continue to blink slowly until the generator has been connected. If the  
generator does not successfully start, the AC 2 IN GOOD LED will stop blinking and the red ERROR LED will  
turn on. The ERROR CAUSES (5) menu heading will indicate a GENERATOR SYNC ERROR condition.  
BULK (Yellow)  
This indicator will be on to indicate the inverter is in the Bulk or Absorption charge stage. This indicator will  
go off and the FLOAT indicator will illuminate when the battery voltage has been held near the SET BULK  
VOLTS DC setting for the time period determined by the SET ABSORPTION TIME setting from the  
BATTERY CHARGING (10) menu heading.  
If the EQ mode is selected from the SET GENERATOR menu item under the GENERATOR MODE (2)  
menu heading, the BULK LED will slowly blink while the charger completes the equalization process.  
FLOAT (Green)  
This indicator will be on when the battery voltage has reached the Float Stage of the charging process. It  
will now regulate the charging process to the SET FLOAT VOLTS DC setting from the BATTERY  
CHARGING (10) menu heading. The SET FLOAT VOLTS DC setting provides a maintenance charge to  
the battery until another Bulk Charge Cycle is initiated or the AC source is disconnected. If a generator is  
manually controlled and powering the battery charger, the FLOAT indicator will come on to indicate that  
the generator should be turned off, since the battery is now fully charged.  
This indicator is also used to indicate the regulation setpoint when the inverter is operating as an Utility  
Interactive Inverter (SELL mode). The indicator will blink slowly to indicate the battery is regulated to the  
SET BATTERY SELL VOLTS DC setting from the BATTERY SELLING (17) menu heading, and the  
indicator will be solidto indicate the battery is regulated to the SET FLOAT VOLTS DC setting from the  
BATTERY CHARGING (10) menu heading.  
ERROR (Red)  
Indicates that an operating error has occurred (refer to the ERROR CAUSES (5) menu heading for a list  
of possible causes). To reset the inverter, press the red ON/OFF MENU button and then select OFF and  
then ON with the SET POINTS buttons or by pressing the red button several times.  
This indicator will blink slowly to indicate that the AC source frequency is not well-adjusted (3 to 7 hertz  
from nominal). You can use the LED blink to help adjust the AC source frequency. Once the frequency is  
within 3 hertz of your nominal frequency, the LED will turn off.  
OVERCURRENT (Red)  
The load requirement has exceeded the inverters maximum output AC amps. A sustained overcurrent  
condition will require a manual reset by pressing the red ON/OFF MENU button and then selecting OFF  
and then ON with the SET POINTS buttons or by pressing the red button several times. Momentary  
flashing of the red OVERCURRENT indicator means that the inverter has reached it maximum output AC  
amps and has automatically reset itself. This may occur during motor startups and is acceptable.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
11  
Rev. C: February 2001  
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CONTROLS, INDICATORS AND COMPONENTS  
AC SIDE  
Figure 4 shows the components located on the AC side of the inverter. The removable AC Access Panels  
cover and protect the Internal Components and Indicators, such as the AC Terminal Block, BTS  
Connection, LED status indicators (for the AC1 and Gen Control relays) and the Aux and Gen Control  
relay terminals. Refer to the INSTALLATION section beginning on page 15, for all wiring connections.  
Inverter/  
Charger  
Circuit Breaker  
Identification  
Label  
Knockouts  
(Also On Side}  
Remote  
Port  
Three  
Removable  
Access Panel  
(One Panel on  
Side)  
Stacking  
Port  
Figure 4, AC Side  
REMOTE PORT  
The SW Series Inverter/Charger can be controlled remotely from the unit by plugging in a Sine wave  
Remote Control (SWRC) or Sine wave Communications Adapter (SWCA).  
The SWRC remote control is a full function, programmable remote control with backlit LCD which  
duplicates the functions of the integral Control Panel.  
The SWCA serial communications interface adapter allows for remote setup, adjustment, monitoring and  
troubleshooting of SW Series Inverter/Chargers from a personal computer and allows modem access  
monitoring over long distances.  
See the APPENDIX, OPTIONS section, starting on page 128, for a complete description of the SWRC  
Remote Control and SWCA Serial Communications Adapter.  
STACKING PORT  
The stacking port allows multiple SW Series Inverter/Chargers to be used in the same system. The  
inverters can be used in a SERIESconfiguration to operate 240 Vac loads and to connect to  
120/240 Vac power systems. A series stacking interface cable (SWI) is required to connect the series  
stacking ports of the inverters. This port is also used to connect two units in a PARALLELconfiguration.  
The parallel stacking interface cable (SWI/PAR) allows two inverters to be connected to provide twice the  
continuous and surge capability at the same AC voltage. See the USING MULTIPLE INVERTERS section  
on page 95 for more information.  
INVERTER/CHARGER CIRCUIT BREAKER  
This circuit breaker protects the units internal wiring while the unit is inverting or charging. It is not used  
for the pass-through current. This is not a branch-circuit rated breaker, separate output breakers are  
required. Press the breaker to reset (to reset on 48-volt units, move the breaker handle to the ON  
position).  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
12  
Rev. C: February 2001  
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CONTROLS, INDICATORS AND COMPONENTS  
INTERNAL COMPONENTS AND INDICATORS  
Additional components and indicators are located behind three removable AC Access Panels located on  
the AC Side of the unit. They include the AC Terminal Block, BTS Connector, three LED indicators and  
the Aux and Gen Control Relay Connectors.  
RY7 (Yellow)  
LED  
RY8 (Green)  
LED  
AC1 Relay  
(Red) LED  
AC  
Terminal Block  
BTS  
Connector  
Aux and Gen Control  
Relay Connectors  
AC  
Safety Ground  
Figure 5, Internal Components and Indicators  
LED INDICATORS  
Three LED indicators allow visual indication of operation of the RY7, RY8 and AC1 relays.  
RY7 (Yellow) LED  
Allows visual indication of relay RY7 operation. During the automatic generator control sequence, the  
LED will be on to show that RY7 is closed (engaged) from the N.O. to the COM contacts, and will be  
off when RY7 is opened (disengaged).  
RY8 (Green) LED  
Allows visual indication of relay RY8 operation. During the automatic generator control sequence, the  
LED will be on to show that RY8 is closed (engaged) from the N.O. to the COM contacts, and will be  
off when RY8 is opened (disengaged).  
AC1 RELAY (Red) LED  
Allows visual indication of AC1 relay operation. The LED will be on when the AC1 relay is closed  
(engaged). This LED along with the test-jumper adjacent to the LED is used by utilities to perform  
voltage and frequency tests to qualify the SW Series Inverter/Charger for line-tie applications.  
BTS PORT  
The battery temperature sensor (BTS) can be connected (plugged in) at the RJ-11 four-conductor  
connector, located on the AC Circuit Board. The BTS provides information that enables the three-stage  
standby battery charger to fine tunethe battery charge voltages for better charging performance, greater  
efficiency and longer battery life.  
AC TERMINAL BLOCK  
A six position terminal block is provided to make the AC connections. The terminal block is located on the  
AC Circuit Board. The terminal block is used to hardwire all AC input and output connections.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
13  
Rev. C: February 2001  
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CONTROLS, INDICATORS AND COMPONENTS  
AC SAFETY GROUND  
The AC Safety Ground is used to connect the inverter chassis to the AC Grounding System.  
AUXILIARY AND GENERATOR CONTROL RELAY CONNECTORS  
Generator Control  
Relay Connectors  
Auxiliary Control  
Relay Connectors  
Figure 6, Auxiliary and Generator Control Relay Connectors  
DC SIDE  
Figure 5 shows the components located on the DC side of the inverter. Refer to the INSTALLATION  
section for the battery wiring connections to the Battery Terminals and the DC Ground.  
DC  
(Equipment)  
Ground  
Battery  
Terminal  
(-)  
Battery  
Terminal  
(+)  
Figure 7, DC Side  
BATTERY TERMINALS  
Caution: Before connecting the battery cables to the inverter, verify the correct battery voltage  
and cable polarity using a voltmeter. The inverter is not reverse polarity protected. If the  
positive terminal of the battery is connected to the negative terminal of the inverter and  
vice versa, severe damage will result. If necessary, color-code the cables with colored tape or  
heat shrink tubing: RED for positive (+); BLACK for negative (-) to avoid polarity problems.  
DC (EQUIPMENT) GROUND  
This connection is used to connect the exposed chassis of the inverter to the DC grounding system. The  
terminal accepts wires from #14 AWG to #2 AWG.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
14  
Rev. C: February 2001  
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INSTALLATION  
INSTALLATION  
This section is very important, since it tells you how to properly install your SW Series Inverter/Charger.  
It becomes very frustrating when your inverter system does not perform properly, simply because care  
was not taken during installation. Please read this entire section carefully. You will save time and avoid  
common mistakes.  
This section also describes the requirements and recommendations for installing the SW Series  
Inverter/Charger. In the U.S., the National Electrical Code (NEC) defines the standards for both the AC  
and DC wiring in residential, commercial and RV applications. It will list the requirement for wire sizes,  
overcurrent protection and installation methods and requirements. There are still many other variables not  
covered by the NEC. Most are determined by the level of automatic operation, the amount of external AC  
and DC power to be controlled and the loads to be operated.  
The NEC standards and regulations are described here in general for your convenience, and are not  
represented as comprehensive or complete. For comprehensive and complete official standards and  
regulations, write the address listed below:  
NFPA - National Fire Protection Association  
National Electrical Code Handbook  
1 Batterymarch Park,  
PO Box 9101  
Quincy, MA 02269-9101  
617-770-3000.  
Before beginning the installation of the SW Series Inverter/Charger, read all instructions. Disconnect all  
sources of AC and DC power to prevent accidental shock. Disable and secure all AC and DC disconnect  
devices and automatic generator starting devices.  
All installations should meet all local codes and standards and be performed by qualified  
personnel such as a licensed electrician. Although the DC electrical system may be low voltage,  
significant hazards may be present, particularly from short circuits of the battery system. Inverter systems  
by their nature involve power from multiple sources (inverter, generator, utility, batteries, solar arrays etc.)  
that add hazards and complexity that can be very challenging.  
After you have finished installing your unit, continue with the FUNCTIONAL TEST section on page 31.  
This Functional Test should be completed prior to configuring your units Menu System for your specific  
operation.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
15  
Rev. C: February 2001  
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INSTALLATION  
QUICK INSTALL  
This section provides installers, licensed electrical contractors, and knowledgeable laymen the essential  
steps to quickly install the TraceSW Series Inverter/Charger. If you havent had experience with the SW  
Series Inverter/Charger, you are urged to skip this section and read the entire INSTALLATION section  
before installing the inverter/charger.  
MOUNTING  
Mount the unit securely in a clean, dry, properly ventilated enclosure. Do not mount the unit in the same  
enclosure as vented or maintenance-free type vented batteries. Bolt the unit securely. Allow adequate  
clearance to allow access to the indicators or controls.  
DC CABLING  
1. Connect an appropriate sized cable from the positive batter terminal (or battery bank) to the inverters  
positive (red) terminal. See Table 12 in the Appendix to determine the proper size cable and length of  
run needed to use with your inverter model and for your specific application. The National Electric  
Code (NEC) requires the use of a DC fuse or disconnect with this cable. See Table 12 in the Appendix  
to determine the correct fuse or breaker to use.  
2. Connect an appropriate sized cable from the negative battery terminal to the negative (black) inverter  
terminal. Torque all terminals to 10-15 foot-pounds. NOTE: A 'snap' caused by charging the internal  
capacitors may occur when first connecting the cable. This can be avoided by first removing the DC  
fuse or opening the disconnect in the positive battery cable.  
3. Connect a cable from the inverters DC Chassis Ground to the system ground.  
AC IN CABLING  
1. See Table 13 in the Appendix to determine the appropriate AC wire size.  
2. Remove the knockout from the inverter chassis and install a strain relief or conduit in which to route  
the AC cabling in and out.  
3. Connect the black wire from the hot side of the AC power to the terminal labeled AC HOT IN 1 (AC  
HOT IN 2 if a generator is the AC source) on the inverter.  
4. Connect the white wire from the neutral side of the AC power source to the terminal labeled  
NEUTRAL IN 1 (NEUTRAL IN 2 if a generator is the AC source) on the inverter.  
5. Connect the green wire from the ground of the AC power source to the AC Ground Terminal of the  
inverter/charger.  
AC OUT CABLING  
1. Connect the black wire between the terminal marked AC HOT OUT to the hot bus of your AC load  
center or AC sub-panel.  
2. Connect the white wire from the terminal marked NEUTRAL OUT to the neutral bus of your AC load  
center or sub-panel.  
3. Connect the AC Ground Terminal of the inverter to the safety ground bus of the AC load center or  
sub-panel.  
WRAP UP  
1. Secure all wiring with wire ties or other non-conductive fasteners to prevent chafing or damage. Use  
strain-reliefs, grommets, or conduits to prevent damage to the wiring where it passes through any  
apertures. Tighten all connections to the correct torque (AC Connections at 20 inch-pounds; DC  
Connections at 10-15 foot-pounds).  
2. Make a final check of all wiring, then reconnect to the AC power source.  
3. Turn the inverter ON and check inverter operation (See the FUNCTIONAL TEST section on page 31).  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
16  
Rev. C: February 2001  
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INSTALLATION  
COMPLETE INSTALL  
UNPACKING  
Before beginning, unpack the inverter/charger; record the  
serial number on the inside cover of this booklet and on the  
warranty card. Right now, please do the following:  
Verify that you have everything listed on the Packaging  
Materials sheet. If any items are missing, please call  
Customer Service at (360) 435-8826.  
Save your proof-of-purchase, You will need the proof-of-  
purchaseto obtain warranty service.  
Keep the original carton and packing materials. If you  
need to return your inverter for service, you should ship it  
in the original carton. It is also the best way to keep the  
inverter safe if it needs to be moved.  
LOCATION  
Inverters are sophisticated electronic devices and should be treated accordingly. Treat the inverter as you  
would any fine piece of electronic equipment. When selecting the location for the inverter, don't think of it  
in the same terms as the other interfacing equipment, e.g. batteries, diesel generators, motor generators,  
washing machines etc. It is a highly complex microprocessor controlled device. There are nearly 500,000  
silicon junctions in its output devices and integrated circuits. The crystal oscillator runs at 4 megahertz.  
The drive circuitry timing is accurate to a thousandth of a second. Genetically speaking, it is a cousin to  
stereo equipment, television sets or computers. The use of conformal-coated circuit boards, plated copper  
bus bars, powder coated metal components, and stainless steel fasteners improves tolerance to hostile  
environments. However, in a corrosive or condensing environment (one in which humidity and/or  
temperature change cause water to form on components) all the ingredients for electrolysis are present -  
water, electricity and metals. In a corrosive or condensing environment, the life expectancy of the  
inverter is indeterminate and the warranty is voided.  
Caution: Install the inverter in a dry, protected location away from sources of high temperature  
and moisture. Exposure to saltwater is particularly destructive and potentially hazardous.  
Locate the inverter as close to the batteries as possible in order to keep the battery cable length short.  
Do not locate the inverter directly above the batteries or in the same compartment as vented batteries.  
Batteries generate hydrogen sulfide gas, which is very corrosive to electronic equipment and everything  
else. They also generate hydrogen and oxygen. If these gases accumulate, an arc caused by the  
connecting of battery cables or the switching of a relay could ignite the mixture. Mounting the inverter in a  
ventilated enclosure with sealed batteries is acceptable.  
Ensure the inverter is located in an area that prevents insects and rodents from entering the inverter, as  
the inverter can provide a warm habitat in a cold environment. This may involve installing the inverter in an  
enclosure and include mesh screens or nets over any openings to ensure the unit is kept well ventilated.  
This inverter can create RFI (Radio Frequency Interference). Keep this in mind when determining the  
placement of the inverter. You should locate the inverter as far away as possible from any electronic  
devices that may be susceptible to RFI.  
MOUNTING  
UL Standard 1741 (draft) requires that the inverter be mounted on a vertical surface (on a wall) and that  
the keyhole slots not be used as the only method of mounting. The purpose of the wall mounting  
requirement is to orient the inverter so that its bottom cover, which has no holes, will not allow burning  
material to be ejected in case of an internal fire.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
17  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
INSTALLATION  
Use 1/4" minimum diameter bolts for mounting. The mounting must be capable of supporting twice the  
weight of the inverter in order to comply with UL 1741. If this unit is used in a mobile application (i.e. RV,  
Boat) secure the inverter to a shelf or deck to prevent movement. Place flexible washers on the mounting  
screws or bolts between the shelf or deck and the inverter chassis to reduce vibration.  
VENTILATION  
Installation of the inverter in a properly ventilated enclosure is necessary for efficient operation of the unit.  
The inverters thermal shutdown point will be reached sooner than normal in a poorly ventilated  
environment and will result in a lower peak power output, reduced surge capability, and potentially shorter  
inverter life.  
Note: Do not operate the inverter in a closed-in area or restrict ventilation in any way.  
Testing has shown that the volume of the enclosure is not as important as the overall ventilation. A  
minimum airspace clearance of 1½ inches around the top and bottom and 3 inches of clearance at the left  
and right sides of the inverter will provide adequate ventilation. Because the top and bottom of the SW  
Series chassis is not vented, clearance between the enclosure and the top of the inverter is not critical. A  
fresh air intake port should be provided directly to the left side and an exhaust port on the right side will  
allow cool outside air to flow through the inverter and back out of the enclosure.  
Top  
Left  
Right  
(AC Side)  
(DC Side)  
AIR  
FLOW  
Bottom  
Figure 8, Air Flow Intake Location  
AC WIRING  
This section describes AC wiring requirements and recommendations; including AC connections; wire  
sizing; overcurrent devices; GFCIs; external relays; hookup procedure; and neutral-to-ground switching.  
Your local electrical code and the National Electrical Code (NEC) define the standards for AC installation  
wiring, but there are still many installation variables to be considered. Consult the local code and the NEC  
for the proper wire sizes, connectors and conduit. All installations should meet all local codes and  
standards and be performed by qualified personnel such as a licensed electrician.  
AC INPUT AND OUTPUT CONNECTIONS  
A six position terminal block is provided to make the AC connections. The terminal block is located on the  
left-hand side of the inverter, enclosed under a cover plate (See INTERNAL COMPONENTS AND  
INDICATORS on page 13 for location.). The terminal block can accept up to # 6 AWG stranded wire and  
is used to hardwire all AC connections. For 120 VAC inverters, we recommend 6 AWG (THHN) wire for  
full utilization of the inverters 60 amp AC pass through capability. The code requires that disconnect  
switches be provided in the AC input and output wiring circuits. AC circuit breakers in an AC load center  
can be used to meet this requirement. The wiring both in and out of the inverter must also be protected  
from short circuits and overloads by a fuse or circuit breaker. Typically, a 60 amp circuit breaker will  
protect #6 AWG wiring. Consult your local code for more information and for other wire sizes.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
18  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
INSTALLATION  
Note: The three neutral terminals are common to each other and can be used in any combination or  
order. In a residential application, it is often easier to only connect one AC neutral wire to the inverter and  
make the other neutral connections at a central point such as in the AC load center, etc. In mobile  
installations, the AC system must have the neutral physically isolated from the ground throughout the load  
distribution powered by the inverter. The SW Series Inverter/Charger does not include neutral to ground  
switching for the AC electrical system. This must be done externally from the inverter. See the NEUTRAL-  
TO-GROUND BOND SWITCHING (RV AND MARINE APPLICATIONS) section on page 27 for more  
information.  
AC Terminal Block  
(TB1)  
1b  
2b  
3b  
4b  
5b  
6b  
1a  
2a  
3a  
4a  
5a  
6a  
AC IN 1  
From  
Utility Power  
AC IN 2  
From  
Generator Power  
AC OUT  
To  
AC Loads  
Figure 9, AC Input/Output Power Connection  
Before making any AC connections, make sure that the inverter is disconnected from the battery (or  
battery bank). Feed the wires through conduit fittings located on the left side or left bottom side of the  
inverter. (Note: Conduit fittings must be purchased separately and are required by code to comply with  
residential and commercial installations).  
The AC wiring both in and out of the inverter must also be protected from short circuits and overloads by a fuse  
or circuit breaker. Consult the NEC or your local code for more information and for other wire sizes. Table 13 on  
page 132 gives suggestions for wire sizing. Follow the wiring guide on the circuit board inside the cover plate  
(see Figure 9, above). Connect the AC wiring as follows (from front to back when wall mounted):  
Table 1, AC Input and Output Wiring Connections  
AC CONNECTIONS  
AC HOT IN 1  
AC TERMINAL BLOCK #  
WIRE COLOR  
Black (Hot)  
PURPOSE  
Utility Power  
Utility Power  
Generator  
Generator  
AC Loads  
1b  
3b  
2b  
4b  
6b  
5b  
NEUTRAL IN 1  
AC HOT IN 2  
White (Neutral)  
Black (Hot)  
NEUTRAL IN 2  
AC HOT OUT  
White (Neutral)  
Black or Red (Hot)  
White (Neutral)  
NEUTRAL OUT  
AC Loads  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
19  
Part No. 2031-5  
Rev. C: February 2001  
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INSTALLATION  
AC INSTALLATION GUIDELINES  
The following steps are a basic guideline for installation and connection of the AC wiring into and out of  
the inverter.  
1. Disconnect the inverter from the battery bank (if already connected), by either removing the DC side  
fuse, or opening the DC disconnect. Then remove the AC wiring compartment cover from the front of  
the inverter by removing the two screws on the cover.  
2. If conduit will be utilized (consult code, it may be required in your installation), determine which  
knockout(s) will be utilized and remove them from the inverter. Using appropriate conduit connectors,  
fasten the conduit to the inverter. Feed all AC wiring through the conduit and into the inverter AC  
terminal block. Be sure to leave yourself several extra inches of wire to work with. Remember that you  
need at least two sets of three conductor wiring, one for AC Hot, Neutral, and Ground into the inverter,  
and another for AC Hot, Neutral and Ground out of the inverter to the loads. Torque all AC terminals  
to 10 to 15 inch-pounds.  
3. Connect the Hot (black) and Neutral (white) wires from the AC source(s) to the appropriately labeled  
terminals in the AC terminal block. The Safety Ground (green) should be connected to the terminal  
stud labeled AC Groundbolted to the chassis. Repeat the procedure for the AC wiring going to the  
AC sub-panel which will power the loads, except connect these wires to the terminals labeled AC HOT  
OUT.  
4. Inspect all wiring for proper installation and then replace the access cover using the two screws to  
secure it.  
IMPORTANT PRECAUTION  
The AC output of the inverter must at no time be connected directly to utility power or a generator.  
This condition can be far worse than a short circuit. If the inverter survives this condition, it will shut down  
until corrections are made. Connection to a utility or generator must be only done internally by the  
inverters built-in relays. This allows the inverter to first synchronize to the other AC sources waveform,  
preventing damage. Connect the utility or generator to the provided input terminals AC HOT IN 1 or AC  
HOT IN 2 respectively.  
When the inverter output is connected directly to an external source, the inverter will shut down and  
indicate an error on the control panel. Checking the ERROR CAUSES menu heading will show a YES for  
the AC SOURCE WIRED TO OUTPUT menu item. Either determine the source of the AC or call a  
qualified electrician to correct the situation.  
EXTERNAL TRANSFER RELAYS  
It is not acceptable to switch the AC input from one AC source to another while the inverter is  
connected. This applies whether the inverter is in battery charging mode or inverter mode. Switching the  
AC input from one source to another can result in a loss of synchronization that can cause a severe  
overcurrent condition that is far worse than short circuiting the inverter. Two separate AC inputs are  
provided to eliminate the need for use of external transfer relays. If a transfer relay is used, it must provide  
a center OFFposition (break before make) that causes a loss of input power to the inverter for a period  
of at least 100 milliseconds. This will allow the inverter to disconnect from the original AC input and then  
re-synchronize to the new AC source although the same AC input terminal is being used. During the  
transition period, the inverter will have to operate the load while it re-synchronizes to the new AC source  
(about a thirty-second period at the minimum). Most transfer relays will switch too fast for the inverter to  
detect - and will cause the inverter to lose synchronization with the AC source. This is indicated by the  
inverter shutting down upon transfer and the red overcurrent LED indicator flashing or turning on.  
Manually, hand operated transfer switches may be acceptable since the transfer time can be slow enough  
for the inverter to detect. The switch must go through a center offposition. They are often used to switch  
from one generator to another. Since the inverter has a separate AC input for a utility grid, a transfer  
switch is not required to switch from the utility grid to a back-up generator. The inverter will not allow the  
generator to be connected to the utility - if both are available, the generator will be disconnected and the  
inverter will connect to the utility on AC HOT IN 1.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
20  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
INSTALLATION  
120 VAC GROUND FAULT INTERRUPT OUTLETS (GFIS)  
Xantrex has tested the following 120 VAC GFIs and found them to work satisfactorily with our inverters:  
LEVITON  
6599  
PASS & SEYMOR  
ACE Hardware  
1591 4A957  
ACE 33238  
WARNING LABEL  
A warning label is provided to inform all personnel that an inverter is installed in your electrical system.  
This label should be installed at the electrical panel that is being powered by the inverter. Be cautious until  
the inverter is disconnected from your electrical system.  
!
Figure 10, Warning Label  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
21  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
INSTALLATION  
DC WIRING  
CAUTION: The inverter’s maximum peak current requirements are high. If battery cables are too  
small and/or connections are loose, efficiency and maximum output power are degraded. Small  
cables or loose connections may cause dangerous overheating and a fire.  
BATTERY CABLE SIZING  
The larger the battery cables the better. Undersized cables result in additional stress on the inverter, lower  
efficiency, reduced surge power and lower peak output voltage. Dont use cables that are too small and  
degrade the efficiency that we have worked so hard to achieve and you have paid so much to own.  
Also, dont use cables that are too long - the shorter the better. The lower the DC system voltage, the  
shorter the cables need to be. If long cables are required, either oversize them substantially, or switch to a  
higher voltage system, such as 24 Vdc or 48 Vdc. On 12-Vdc system, cables may need to be doubled up  
(paralleled) to get maximum performance from the inverter.  
NOTE: Do not separate the positive and negative cables - taping them together in parallel is  
best. This reduces the inductance of the wire resulting in a better waveform and reduces the  
current in the inverter’s filter capacitors. Make the battery cables as short as possible.  
Although large cables may seem expensive, spending an additional $100 or more to ensure the  
performance of your inverter is a wise investment. Using cables that are too small is like putting cheap  
tires on a high performance sports car - the results will be disappointing.  
If the system is expected to operate at the inverters continuous power level rating for long periods of time  
(over an hour), larger disconnects and cables may be required. Most systems do not operate at full  
capacity for periods exceeding an hour and can operate satisfactorily with the following cable and  
disconnects shown. If your system includes enormous batteries or has a very large DC source able to  
continuously power the inverter (such as a hydroelectric plant, etc.) then increasing the disconnect and  
cable sizes may be required to prevent nuisance tripping of a breaker or blowing of fuses.  
The following table gives recommended minimum cable sizes for various cable run lengths and inverter  
voltages. Use only all copper cables. These recommendations may not meet all local code or NEC  
requirements.  
Table 2, Minimum Recommended Battery Cable Size vs. Cable Length  
TYPICAL  
INVERTER  
MODEL  
NEC  
1 TO 3 FEET  
ONE WAY  
3 TO 5 FT  
ONE WAY  
5 TO 10 FT  
ONE WAY  
DC  
AMPS2  
AMPS1  
SW2512  
SW2612E  
267 Amps  
278 Amps  
160 Amps  
334 Amps  
348 Amps  
201 Amps  
267 Amps  
#4/0 AWG/107 mm2 #4/0 AWG/107 mm2 Not Recommended  
#4/0 AWG/107 mm2 #4/0 AWG/107 mm2 Not Recommended  
#4/0 AWG/107 mm2 #4/0 AWG/107 mm2 #4/0 AWG/107 mm2  
#4/0 AWG/107 mm2 #4/0 AWG/107 mm2 #4/0 AWG/107 mm2  
SW3024E or J  
SW4024 or W, K 214 Amps  
SW3048E or J  
SW4048 or K  
SW4548E or A  
SW5548  
80 Amps  
107 Amps  
120 Amps  
147 Amps  
100 Amps #2/0 AWG/67.4 mm2 #2/0 AWG/67.4 mm2 #4/0 AWG/107 mm2  
134 Amps #2/0 AWG/67.4 mm2 #2/0 AWG/67.4 mm2 #4/0 AWG/107 mm2  
150 Amps #2/0 AWG/67.4 mm2 #2/0 AWG/67.4 mm2 #4/0 AWG/107 mm2  
184 Amps  
#4/0 AWG/107 mm2 #4/0 AWG/107 mm2 #4/0 AWG/107 mm2  
1TYPICAL DC AMPS is based on Low Battery Voltage with an efficiency of 85%.  
2NEC AMPS is based on Low Battery Voltage, an efficiency of 85%, and a 125% NEC de-rating.  
WARNING! Battery cables that are too small will melt and burn the first time the inverter is  
operated at high power levels.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
22  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
INSTALLATION  
DC DISCONNECT AND OVERCURRENT PROTECTION  
For safety and to comply with regulations, battery over-current protection is required. Fuses and  
disconnects must be sized to protect the wiring in the system. The fuse or disconnect is required to open  
before the wire reaches its maximum current carrying capability.  
For residential and commercial electrical systems, the National Electrical Code requires both overcurrent  
protection and a disconnect switch. These installation parts are not supplied as part of the inverter.  
However, Xantrex offers a DC rated, UL listed, circuit breaker disconnect specifically designed for use  
with Traceinverters for applications requiring NEC compliance. Two amperage ratings are available - a  
DC250 (250 amps) and a DC175 (175 amps). These disconnects are available in a single or double pole  
configuration to handle either one or two inverters. The DC disconnect enclosure will accommodate up to  
four smaller breakers for use as DC load disconnects, PV array disconnects, etc. and the top is designed  
to allow direct connection of up to two Xantrex charge controllers. The TraceDC disconnect is not  
designed to accept doubled (paralleled) cables which may be required for long cable runs. Also, the plastic  
red and black covers on the end of the inverter is not designed to accommodate dual cables. If dual  
cables are used, the optional conduit box (SWCB) should be used.  
When sizing the DC disconnect, the expected continuous load on the inverter is used to determine the DC  
current involved. You must account for the efficiency loss through the inverter (see the POWER VS.  
EFFICIENCY section on page 59 in this manual) which increases the DC current draw. Divide the  
maximum continuous current draw by the lowest efficiency to determine the DC current, a 25% safety  
margin should be included to comply with the code requirements. When a breaker has been selected as  
the overcurrent device, tighter sizing may be acceptable since the breaker is more easily reset when  
compared to a high current, bolt-in type fuse.  
Marine and RV installations typically do not require conduit or a means of disconnection, although  
overcurrent protection (fuse) is required. Xantrex offers a fuseblock (TFB) that provides the code required  
inverter overcurrent protection for residential, commercial, RV and Marine applications.  
TFBs include a fast acting, current limiting class-T fuse to protect your battery, inverter and high  
amperage cables from damage by short circuits and overloads. This fuse provides extremely fast  
protection when a short circuit occurs. When properly selected, it also has a time delay that allows the  
inverter to surge to full power without blowing the fuse. A slide off cover prevents accidental contact with  
the fuses live terminals. For maximum protection, install the fuseblock within 18 inches (45 cm) of the  
battery. The fuses are available in 110, 200, 300, and 400 amp sizes.  
Use Table 3 below, to determine the proper size disconnect (breaker) or fuse for the battery cables you  
are using. These recommendations may not meet all local code or the NEC requirements, consult your  
applicable electrical code for more information regarding acceptable fuse and cable sizes.  
Table 3, Battery Cable To Maximum Breaker/Fuse Size  
CABLE SIZE  
REQUIRED  
RATING IN  
CONDUIT  
MAXIMUM  
BREAKER SIZE  
RATING IN  
FREE AIR”  
MAXIMUM  
FUSE SIZE  
# 2 AWG  
00 AWG  
115 amps  
175 amps  
250 amps  
125 amps*  
175 amps  
250 amps  
170 amps  
265 amps  
360 amps  
175 amps*  
300 amps*  
400 amps*  
0000 AWG  
*The NEC allows rounding up to the next standard fuse size from the cable rating, i.e. 150-amp cable size  
rounds up to a standard 175-amp fuse or breaker size. The term "free air" is defined by the NEC as cabling that  
is not enclosed in conduit or a raceway. Cables enclosed in raceways or conduits have substantially lower  
continuous current carrying ability due to heating factors.  
Contact your Xantrex dealer to order the inverter disconnects/fuses or see the OTHER PRODUCTS  
section in this manual on page 129 for more information.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
23  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
INSTALLATION  
BATTERY CABLE CONNECTIONS  
Cables must have crimped (or preferably, soldered and crimped) copper compression lugs unless  
aluminum mechanical lugs are used. Soldered connections alone are not acceptable. We suggest using  
high quality, UL-listed Xantrex battery cables. These cables are available in a specific assortment of sizes  
from 1-½ to 10 feet, and in 2/0 or 4/0 AWG. They are color-coded and have pressure-crimped, sealed-ring  
terminals. Contact your Xantrex dealer to order. Figure 11, illustrates proper method to connect the battery  
cables to the SW Series Inverter/Charger.  
Do not place anything  
between battery cable lug  
and terminal surface.  
Assemble exactly as shown.  
2/0 Copper Compression Lug  
Figure 11, Battery to Inverter Cable Connection  
INSTALLATION PROCEDURE - BATTERY CABLES  
2/0 Aluminum Mechanical Lug  
CAUTION: THIS INVERTER IS NOT REVERSE POLARITY PROTECTED. If the positive  
terminal of the battery is connected to the negative terminal of the inverter and vice versa, the  
result will be instantaneous failure of nearly every power transistor. This type of damage is  
obvious and requires an extensive rebuilding of the inverter at your own cost. It is not covered by  
the warranty.  
Ensure that the inverter is off before connecting or disconnecting the battery cables and that all  
AC power is disconnected from the inverters inputs.  
Determine the correct size battery cable to use for your installation from Table 2, on page 22 and the  
proper size disconnect/fuse from Table 3, Battery Cable To Maximum Breaker/Fuse Size on page 23.  
Color-code the cables with colored tape or heat shrink tubing [the standard colors are red for positive (+)  
and black for negative (-)]. Always double-check the polarity with a voltmeter before making the battery  
connections  
Install the over-current device (fuse or circuit breaker) between the inverter and battery - as close as  
possible to the battery - in the ungrounded conductor [typically the positive (red) cable]. Connect a cable  
from the battery negative terminal to the negative (black) terminal on the inverter.  
Observe Battery Polarity! Place the battery cable ring terminals over the stud and directly against the inverters  
battery terminals. Red is positive (+), Black is negative (-). Use a 1/2-inch wrench or socket to tighten the 5/16  
SAE nut to 10-15 foot/pounds. Do not place anything between the cable ring terminal and the flat metal  
part of the terminal or overheating of the terminal may occur. DO NOT APPLY ANY TYPE OF ANTI-  
OXIDANT PASTE until after the battery cable wiring is tightened to 1015 foot-pounds!  
Note: Connecting the battery cables to the inverter battery terminals may cause a brief spark or arc  
- usually accompanied by a "snapping" sound. This is normal - don’t let it scare you. It is simply the  
internal capacitors of the inverter being charged.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
24  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
INSTALLATION  
CONTROL WIRING  
More advanced installations will require additional wiring to interface the inverter to other components of  
the system. Proper installation is important to ensure the reliability of the system.  
Although the circuits may carry little or even no actual power, the use of quality wire in conduit is  
recommended to provide good results. All circuits should also be fused at the source of the power in the  
circuit to provide both protection and indication of problems with the control circuit. Consult local code and  
the NEC for minimum wire size and type required based on the length that you want to run.  
The AC circuit board provides male type push on connectors and you are provided crimp-on terminals in  
your hardwire package to connect to these Aux and Gen Control relays. These terminals allow easier  
connection of a variety of wire sizes and allow faster installation and troubleshooting. This circuit board  
also includes two LED indicators to allow visual indication of the generator control sequence provided by  
relays RY7 and RY8. These relays are not intended to directly control the starter motor or operate the  
ignition system - rather they can be used to send a signal or operate the coil of another higher amperage  
device which does the actual switching of the power.  
CAUTION: A fuse rated at 5 amps or less must be included to protect each of the relays.  
Damage to these relays is not covered by the Warranty and requires the inverter to be returned to  
a service center for repair.  
GEN CONTROL WIRING  
The configuration of the starting relays on all SW Series inverters allows starting of both Honda and Onan  
type generators. The COM terminals of relay RY7 and RY8 are separated and both the normally open and  
normally closed contacts are provided.  
It is much easier to make the connections to the generator if a remote control terminal or connector is  
available on the generator. This sometimes requires that the generator optional remote control panel be  
purchased. This allows examination of how the generator remote control panel works - which is what the  
inverters generator control system in the inverter must duplicate.  
Connection of the inverters generator control relays in the inverter to the generators remote control panel  
also eliminates the need to make modifications and thus violate the generators warranty.  
You should also ensure that there is a switch to allow disabling of the automatic generator control system  
at the generator. This will allow local control of the generator, preventing starting while servicing, etc.  
AUX RELAY WIRING  
The auxiliary relays are RY9, RY10, and RY11 and can be used to control external power sources or  
loads. The voltage settings that determine when the relays are activated are individually adjustable. The  
relays are connected to a terminal block located in the wiring compartment at the left end of the inverter  
and must be fused to prevent damage if they are miswired or a short-circuit occurs . The maximum fuse  
size must not exceed 5 amps and the fuses should be located as close as possible to the source of power  
e.g. generator battery.  
REMOTE CONTROL WIRING  
An optional remote control panel for the SW Series Inverter/Charger is available (Tracepart number  
SWRC or SWRC/50FT) which provides complete duplication of the control panel on the front of the  
inverter. It is connected to the REMOTE PORT on the left side (AC side) of the inverter (see page 12 for  
the location of the REMOTE PORT) through a provided cable. Two cable lengths are available - 25 feet (8  
meters) or 50 feet (16 meters). Distances longer than 50 feet (16 meters) are not recommended. The  
remote control cable should be kept away from sources of radio frequency interference such as motors  
and antennas. The cable must be protected from abrasion and hot surfaces.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
25  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
INSTALLATION  
SYSTEM GROUNDING  
GROUNDING INSTRUCTIONS - This inverter/charger should be connected to a grounded, permanent  
wiring system. For most installations, the negative battery conductor should be bonded to the grounding  
system at one (and only one point) in the system. The subject is more easily discussed if it is divided into  
three separate subjects; Chassis Ground, Ground Rods and Bonding. The grounding requirements vary  
by country and application. All installations should comply with national and local codes and ordinances.  
Even system designers and electricians often misunderstand system grounding. Consult local codes and  
the NEC for specific requirements. Refer to Table 15, page 133 for safety ground wire sizes.  
EQUIPMENT OR CHASSIS GROUNDS  
This is the simplest part of grounding. The idea is to connect the metallic chassis of the various  
enclosures together to have them at the same voltage potential, which reduces the possibility for electric  
shock. It also provides a path for fault currents to flow through to blow fuses or trip circuit breakers. The  
size of the connecting conductors should be coordinated with the size of the overcurrent devices involved.  
Under some circumstances, the conduit and enclosures themselves will provide the current paths.  
GROUNDING ELECTRODES/GROUND RODS  
The purpose of the grounding electrode (often called a ground rod) is to bleedoff any electrical charge  
that may accumulate in the electrical system and to provide a path for induced electromagnetic energyor  
lightning to be dissipated. The size for the conductor to the grounding electrode or grounding system is  
usually based on the size of the largest conductor in the system. Most systems use a 5/8(16 mm) copper  
plated rod 6 feet (2 meters) long driven into the earth as grounding electrode. It is also common to use  
copper wire placed in the concrete foundation of the building as a grounding system. Either method may  
be acceptable, but the local code will prevail. Connection to the ground electrode should be done with  
special clamps located above ground where they can be periodically inspected.  
Many large systems use multiple ground rods. The most common example is providing a direct path from  
the solar array to earth near the location of the solar array. Most electrical codes want to see the multiple  
ground rods connected by a separate wire with its own set of clamps. If this is done, it is a good idea to  
make the connection with a bare wire located outside of the conduit (if used) in a trench. The run of buried  
wire may be a better grounding electrode than the ground rods! Well casings and water pipes can also be  
used as grounding electrodes. Under no circumstance should a gas pipe or line be used. Consult local  
codes and the NEC for more information.  
BONDING THE GROUNDING SYSTEM  
This is the most confusing part of grounding. The idea is to connect one of the current carrying conductors  
(usually the AC neutral and DC negative) to the grounding system. This connection is why we call one of  
the wires neutralin the North American type electrical systems. You can touch this wire and the  
grounding system and not be shocked. When the other ungrounded conductor (the hot or positive)  
touches the grounding system, current will flow through it to the point of connection to the grounded  
conductor and back to the source. This will cause the overcurrent protection to stop the flow of current,  
protecting the system. This point of connection between the grounding system (ground rod, vehicle  
frame, boat hull, etc.), the current carrying grounded conductor (AC neutral and DC negative), and the  
equipment grounding conductor (green ground wire, equipment ground) is often called a bond. It is  
usually located in the overcurrent protection device enclosures (both AC and DC). Although it can be done  
at the inverter, codes do not generally allow it since the inverter is considered a serviceableitem that  
may be removed from the system. In residential systems, it is located at the service entrance panel, after  
the power has gone through the kilowatt-hour meter of the utility. In mobile applications (RV and marine)  
this bondis provided by the different AC sources on board, see NEUTRAL-TO-GROUND BOND  
SWITCHING (RV AND MARINE APPLICATIONS) on page 27.  
Bonding must be done at only one point in an electrical system. Our systems inherently have two separate  
electric systems - a DC system and an AC system. This means that two bonding points will occur in all  
inverter applications. The bonding point will also be connected to the equipment (chassis) grounding  
conductors. It is common to have two separate conductors connect the ground electrode and the two  
bonding points. Each conductor should use a separate clamp.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
26  
Rev. C: February 2001  
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INSTALLATION  
In some countries, the neutral is not bonded to the grounding system. This means you may not know  
when a fault has occurred since the overcurrent device will not trip unless a doublefault occurs. In some  
marine electrical codes, this type of system is used.  
NEUTRAL-TO-GROUND BOND SWITCHING (RV AND MARINE APPLICATIONS)  
As required by NEC code and UL specification 458, inverter/charger installations in the U.S. that are used  
in RV or Marine applications employ ground-to-neutral switching. The purpose for this requirement is to  
ensure that all the neutral conductors are connected (bonded) to a single ground point in a three-wire  
(hot, neutral and ground) AC system. This prevents a voltage difference from developing between the  
vehicle/boats AC neutral and the external AC sources (generator or shore power) neutral, which may  
cause an electric shock or cause nuisance tripping of GFIs. The SW Series Inverter/Charger does not  
include Neutral-to-Ground switching and must be provided in the AC installation.  
When the unit is operating as an inverter, the AC output neutral should be connected or bondedto the  
frame/hull (chassis ground). When an external AC source (AC shore cord) is provided, the inverters AC  
output neutral should be disconnected from the frame/hull (chassis ground) and allow the bondto be  
provided by the external AC source. The requirement to switch the neutral can be met by your inverter  
internally or can be easily met by using an external relay to connect and disconnect the external AC  
sources neutral. If another AC source (on-board generator) is included in the RV or boat, this AC source  
neutral is required to be connected to ground when it is being used, and to disconnect all other neutrals  
from ground. An AC transfer switch can be used if it switches both the shore cords and generators neutral.  
In some marine applications, neutral-to-ground switching is not required or acceptable. The potential for  
galvanic corrosion caused by small leakage currents between boats with dissimilar metals is present. The  
proper and safe ways to prevent this is by using galvanic isolators or include an isolation transformer for  
the AC input. Disconnecting the common ground between the AC and DC system could contribute  
to a hazardous and potentially fatal situation.  
The figures below graphically describes the neutral-to-ground switching system for the two cases in  
question: the unit operating as an inverter feeding the AC subpanel, and the unit connected to an external  
AC source (generator, shore power, etc.).  
NEUTRAL-TO-GROUND  
BONDis provided by this relay  
for the entire AC system  
NEUTRAL-TO-GROUND SWITCHING  
RELAY (provided in the AC installation):  
Connects the output neutral to chassis or  
vehicle ground when AC is not present at  
inverter input. This assures all equipment in  
the vehicle is referenced to the same  
ground.  
No external AC  
source is present  
INVERTER  
(AC Terminal Block)  
AC PANEL  
(RV/Marine)  
AC HOT IN  
AC NEUTRAL IN  
EARTH GROUND  
CHASSIS GROUND  
HOT  
RY1  
AC HOT OUT  
AC NEUTRAL OUT  
GROUND  
The neutral conductor should  
not be connected to the  
equipment grounding  
conductors or enclosures.  
Figure 12, Neutral-To-Ground Bond Switching: No External AC Source Connected  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
27  
Rev. C: February 2001  
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INSTALLATION  
NEUTRAL-TO-GROUND SWITCHING RELAY  
(Provided in the AC installation): Connects the  
neutral from external AC source, and neutral of  
the AC panel loads together when AC is applied  
to the inverter input.  
NEUTRAL-TO-GROUND BONDis  
provided by an external AC source for  
the entire AC system  
AC SOURCE  
INVERTER  
(AC Terminal Block)  
AC PANEL  
(RV/Marine)  
AC HOT IN  
AC NEUTRAL IN  
EARTH GROUND  
HOT  
The neutral conductor  
should not be  
connected to the  
equipment grounding  
conductors or  
CHASSIS GROUND  
RY1  
enclosures.  
GROUND  
AC HOT OUT  
AC NEUTRAL OUT  
Figure 13, Neutral-To-Ground Bond Switching: External AC Source Connected  
Figure 14, graphically shows the current path if no ground switching was employed in a multiple AC  
source system. If one neutral was tied to the AC subpanel ground buss and another neutral tied to the  
vehicle or chassis ground, the two different ground points would now form a current carrying conductor  
with the frame/hull (chassis ground) acting as the wirebetween the two different ground points. This  
means any ground point in the vehicle or boat becomes a potential current carrying conductor, which  
could result in an electric shock. Any form of Ground Fault Circuit Interrupter (GFCI) such as those found  
in bathroom outlets, will pop if a ground loop (a situation where a voltage difference exist between multiple  
ground points) is created.  
If, however, the ground switching system were in place, it would ensure that there is only one ground point  
in the system at all times. This would be either the vehicle/boat ground or the external AC source ground,  
but never both at once.  
NEUTRAL-TO-GROUND  
BONDis provided by  
the external AC source  
NEUTRAL-TO-GROUND SWITCHING RELAY  
(Provided in the AC installation): Connects the  
neutral from external AC source, and neutral of  
the inverter output (AC panel loads) together  
when AC is applied to inverter input.  
AC SOURCE  
INVERTER  
(AC Terminal Block)  
Another NEUTRAL-  
TO-GROUND  
BONDis  
incorrectly provided  
in the AC panel.  
The neutral  
AC PANEL  
(RV/Marine)  
AC HOT IN  
GFI  
AC NEUTRAL IN  
EARTH GROUND  
CHASSIS GROUND  
HOT  
GFIs will  
nuisance trip  
with multiple  
Neutral-to-  
conductor should  
not be connected to  
the equipment  
grounding  
Ground bonds  
RY1  
GROUND  
AC HOT OUT  
conductors or  
enclosures.  
AC NEUTRAL OUT  
Figure 14, Neutral-To-Ground Bond Switching: Neutral Bonded To Ground  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
28  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
INSTALLATION  
GROUNDING VS. LIGHTNING  
This information is intended to provide basic grounding techniques that will help prevent inverter damage  
due to lightning. It is not intended to be a complete course on grounding or a guarantee against protection  
during a lightning strike situation. The NEC is the ultimate authority as to legitimate grounding techniques  
for your electrical system.  
If an electrical system has components grounded at different points in the earth, large voltage differences  
will exist between these points during a lightning strike (See Figure 15). If this voltage appears between  
the AC and DC side of the inverter, it will fail. All Traceinverters are designed to withstand a minimum  
of 1750 volts between AC and ground, and 500 volts between DC and ground.  
ONE GROUND FOR ALL EQUIPMENT  
The first step in inverter protection is to make sure that all equipment in the system is physically  
grounded at the same location. This assures that there is no voltage potential between grounds in the  
system (See Figure 15 and Figure 16). No voltage means no current flow through the system.  
Practically speaking, this would mean connecting the generator and battery grounds together, as well  
as the case or safetygrounds in the system, and then attaching all to the same earth grounding rod  
(See the NEC for specific information on grounding requirements, and hardware).  
In severe conditions, the generator frame should physically be isolated from the earth by a wood  
frame or some other insulating means. This assures that the single point ground system is  
maintained.  
KEEP EQUIPMENT CLOSE TOGETHER  
All equipment involved in a system should physically be located as close as possible to one another.  
This reduces the potential that is developed between the ground site and the individual components of  
the system during a lightning strike. This single point grounding greatly reduces the potential for  
lightning damage to electrical equipment.  
If you are unable to achieve single-point grounding due to large distances between equipment or other  
variables, other means of lightning protection must be considered. Consult a reputable lightning  
protection company.  
Equipment acts as a  
Equipment all grounded at  
conductor due to  
same point. No voltage  
voltage between the  
across system, and no  
grounds. Bad!  
current flow through  
Lightning  
Strike  
Lightning  
Strike  
equipment and wiring.  
GENERATOR  
INVERTER  
BATTERY  
BANK  
GENERATOR  
INVERTER  
BATTERY  
BANK  
Generator  
Ground  
Inverter  
Ground  
Battery  
Ground  
Generator  
Ground  
Inverter  
Ground  
Battery  
Ground  
Voltage  
Difference  
Voltage  
Difference  
Zero Voltage Difference  
across Component Grounds  
Figure 15, Multiple Point Ground System  
Figure 16, Single Point Ground System  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
29  
Rev. C: February 2001  
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INSTALLATION  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
30  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
FUNCTIONAL TEST  
FUNCTIONAL TEST  
Once the AC and DC wiring have been installed and connected, take a moment to go back over all  
connections and make sure they are secure and have been installed properly. Ensure that there is no AC  
or DC power provided to the inverter/charger and that all AC loads are disconnected from the output of the  
inverter.  
The below steps will complete a functional test of the inverter. If any area fails, figure out why before  
proceeding. The TROUBLESHOOTING GUIDE section, starting on page 112, will hopefully help solve  
problems you may encounter.  
1. After ensuring the correct polarity, apply battery (DC) power to the inverter by turning on the battery  
bank DC disconnect or connecting the proper fuse inline to the battery to complete the battery circuit.  
The inverter will power up, the LCD display will be on, but the inverter will remain in the OFF mode.  
2. Press the red ON/OFF MENU switch twice (SEARCH then ON) to turn the inverter on.  
Monitor your INVERTING LED (Yellow) to ensure what mode you are in:  
Off The Inverter/Charger is off. This is the default position of the inverter upon power-up. No  
inverter or pass-thru power will be applied to the AC loads.  
One blink/sec The Inverter/Charger is in the Search mode and is looking for an AC load greater  
than the SEARCH WATTS setting (default = 16 watts).  
On Indicates the Inverter/Charger is on. The inverter will produce a low audible buzzis able to  
provide power to the AC loads.  
If the inverter does not produce an low audible buzzor come on, check all connections. Check the  
inverters DC voltage on the positive (+) and negative () terminals. If the DC voltage is low, the  
battery bank needs to be charged externally. Charge the battery bank and restart the functional test.  
3. With the inverter ON, check the AC voltage on the AC output terminal of the inverter and ensure you  
get the correct AC voltage for your particular unit. After confirming the correct AC voltage, connect  
your AC output breaker and place a load on the inverter (plug in a light or other load to an outlet the  
inverter is powering), and make sure it works.  
4. Check your battery charger. To charge your batteries, provide AC power - by plugging in a power  
cord or turning on the AC input breaker - to the AC HOT IN 1 and NEUTRAL IN 1 terminals on the  
inverter. The AC1 IN GOOD (Green) light will initially blink until AC power has synchronized and then  
turn solid to indicate the AC power is getting to the inverter. After a minimum 20 second delay, the  
Battery BULK LED (Yellow) or FLOAT LED (Green) on the inverter should be on. This indicates the  
charger is working properly. The Control Panel lights should indicate which charge stage (bulk or float)  
the inverter is currently in. Any AC loads powered by the inverter should also work at this point since a  
portion of the AC input power (Utility or Generator) is passed through the inverter to power the loads.  
5. Disconnect AC power. Take away the AC input power by turning the AC power breaker off, or  
unplugging the AC power cord. The inverter should transfer to inverter mode immediately. The  
INVERT (yellow) LED coming on will indicate this. The inverter will begin to produce an low audible  
buzzas it takes power from the batteries and uses it to power the loads. The loads should continue  
to operate uninterrupted.  
6. This completes the functional test, if all areas pass, the inverter is ready for use. If any of the inverters  
internal setpoints are to be adjusted, consult the MENU SYSTEM section starting on page 33.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
31  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
FUNCTIONAL TEST  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
Page  
32  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
MENU SYSTEM  
MENU SYSTEM  
OVERVIEW  
The operation of the inverter is determined by the settings in the menu system. The menu system is  
divided into a USER MENU and a SETUP MENU. Each of the menu systems is divided into MENU  
HEADINGS and MENU ITEMS. The menu headings break the menu into groups of related menu items.  
At the Menu Item level a setting can be adjusted, a mode can be selected or information can be displayed.  
When a number is included with the graphic of the menu heading or menu item in this manual, the values  
shown are the default value and are for a 12-volt domestic (120VAC/60Hz) model SW Series  
Inverter/Charger. For 24 volt systems multiply the DC settings shown by 2, for 48 volt systems multiply the  
DC settings shown by 4.  
The USER MENU provides the controls and settings needed on a daily basis. It allows you to turn on  
the inverter and generator, read the AC and DC meters, check on an error cause and even adjusts  
the inverters time clock.  
The SETUP MENU provides all of the settings required to configure the inverter to operate in the  
necessary modes for your installation. They are separated from the USER MENU to reduce tampering  
and simplify the daily operation of the inverter.  
The SW Series Inverter/Charger MENU SYSTEM is accessed through the CONTROL PANEL on the front  
of the unit. To access the SETUP MENU, press both the red ON/OFF MENU and green GEN MENU  
buttons at the same time once. The display will show INVERTER SETUP (9). This is simply the  
continuation of the same menu system of the USER MENU. If you select a menu heading less than nine,  
or press either the red or green buttons, you will have to re-enter the setup menu by pressing the red and  
green buttons at the same time again.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
33  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
MENU SYSTEM  
USER MENU MAP  
The values shown are the factory default values for  
Menu Heading  
Model SW2512.  
See the USER and SETUP menu item descriptions  
for default values for other models.  
Menu Item  
Setpoint  
Information  
Push buttons on  
Control Panel  
MENU HEADINGS  
Inverter Mode  
Set Inverter  
Generator Mode  
Set Generator  
Trace  
Engineering  
Meters  
Error Causes  
Time of Day  
1
2
3
4
5
00:00:00  
6
Press reset now  
for defaults  
Inverter/charger  
Amps AC  
Over Current  
Set Clock hour  
00:00:00  
OFF SRCH ON CHG  
OFF AUTO ON EQ  
00  
NO  
NO  
NO  
NO  
NO  
CHG avail. Only  
in FLT mode.  
Gen under/over  
speed  
Revision 4.01  
Input amps AC  
Transformer  
overtemp  
Set Clock minute  
00:00:00  
NO  
00  
00  
Press red or  
setpoint button  
Generator start  
error  
5916 195th St NE  
Arlington, WA  
Load  
amps AC  
Heatsink  
overtemp  
Set Clock second  
NO  
00  
to move.  
Move cursor to  
Generator sync  
error  
98223 USA  
Battery actual  
volts DC  
High Battery  
voltage  
NO  
12.6  
Inverter OFF to  
resetOverCurrent  
Gen max run time  
error  
Ph 360-435-8826  
Fax 360-435-2229  
Battery TempComp  
volts DC  
Low Battery  
voltage  
NO  
12.6  
00  
Generator Timer  
Start Quiet  
Load Amp Start  
Ready  
Inverter  
volts AC  
Inverter breaker  
tripped  
7
NO  
NO  
Voltage Start  
Ready  
Grid (AC1)  
volts AC  
AC source wired  
to output  
NO  
NO  
00  
NO  
NO  
NO  
NO  
Time h:m  
08:00  
Exercise Start  
Ready  
Generator (AC2)  
volts AC  
External error  
(stacked)  
End Quiet  
Time h:m  
00  
60  
08:00  
Move cursor to  
GEN OFF to reset  
Read Frequency  
Hertz  
Generator start  
error  
Gen doesn’t run  
During quiet  
Generator error.  
AC1 & AC2 volts  
valid only when  
Generator sync  
error  
time unless batt  
volts is less.  
If no start in 5  
trys then error.  
inverter synced  
to that input.  
Gen max run time  
than LBCO volts  
for 30 seconds.  
error  
NO  
If Gen starts &  
runs for 5 min  
Batt volt actual  
is used for  
Gen under/over  
speed  
To defeat timers  
set start = end.  
NO  
then stops the  
inverter will  
LBCO,HBCO,LBX,  
LBCI,sell volts,  
Inverter breaker  
tripped NO  
If exercise day  
set to 1 then  
not attempt  
restart until  
and gen starting  
gen will always  
start @ endquiet  
gen auto start  
conditions are  
Batt volt temp  
comp is used,  
again satisfied.  
for float, bulk, eq  
& aux relays  
If Gen runs for  
More than max  
Run time then  
Error.  
Under/Over speed  
Will cause a  
End User Menu  
Sync error in 10  
minutes  
8
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
34  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
MENU SYSTEM  
SETUP MENU MAP  
The SETUP MENU provides all the controls and settings needed when installing or adjusting the  
system. To access the SETUP MENU, press both the red ON/OFF MENU and green GEN MENU buttons  
on the Control Panel at the same time. To exit the SETUP MENU, press the red ON/OFF MENU button or  
press the down MENU HEADING button until you reach the USER MENU (menu headings 1-8).  
MENU HEADINGS  
Inverter Setup  
Set Grid Usage  
Battery Charging  
10  
AC Inputs  
Gen Auto Start  
setup  
Gen starting  
details  
Auxiliary Relays  
9
11  
12  
13  
R9 R10 R11  
14  
Set Bulk  
volts DC  
Set Grid (AC1)  
amps AC  
Set Load Start  
amp AC  
Set RY7 Function  
GlowStop Run  
Set Relay 9  
volts DC  
FLT SELL SLT LBX  
14.4  
60  
30  
20  
5.0  
5.0  
14.5  
01.0  
14.8  
Set Low battery  
cut out VDC 11.0  
Set Absorption  
Set Gen (AC2)  
amps AC  
Set Load Start  
delay min  
Set Gen warmup  
seconds  
R9 Hysteresis  
volts DC  
time h:m  
02:00  
60  
Set LBCO delay  
minutes  
Set Float  
volts DC  
Set Input lower  
limit VAC  
Set Load Stop  
delay min  
Set Pre Crank  
seconds  
Set Relay 10  
volts DC  
10  
13.4  
14.4  
108  
10  
Set Low battery  
Set Equalize  
volts DC  
Set Input upper  
limit VAC  
Set 24 hr start  
Set Max Cranking  
seconds  
R10 Hysteresis  
cut in VDC  
13.0  
132  
volts DC  
12.3  
10  
volts DC  
01.0  
Set High battery  
cut out VDC 16.0  
Set Equalize  
time h:m  
Set 2 hr start  
Set Post Crank  
seconds  
Set Relay 11  
volts DC 15.0  
02:00  
volts DC  
11.8  
30  
Set search  
watts  
Set Max Charge  
amps AC  
Set 15 min start  
R11 Hysteresis  
48  
59  
20  
volts DC  
11.3  
volts DC  
01.0  
Set search  
spacing  
Set Temp Comp  
Read LBCO 30 sec  
Close on batt >  
setpoint.  
LeadAcid  
NiCad  
start VDC  
11.0  
Set Exercise  
period days  
Open on batt <  
setpoint - Hys  
30  
Set Maximum run  
Relays have 2  
time h:m  
08:00  
second delay on  
Set Max Run time  
to 0 to defeat.  
Close, 0.1 sec  
delay on open  
Set Exercise to 0  
to defeat.  
See menu 9 to  
to set LBCO.  
Bulk Charge  
Trigger Timer 15  
Low Battery  
Transfer (LBX) 16  
Battery Selling  
Grid Usage Timer  
Information file  
End Setup Menu  
17  
18  
battery  
19  
20  
Set Start Bulk  
Set Low Battery  
TransferVDC 11.3  
Set Battery Sell  
Start Charge  
time  
Batt temp comp  
changes battery  
time  
00:00  
volts DC  
13.4  
30  
21:00  
21:00  
To disable timer  
set to 00:00  
Set Low battery  
cut in VDC 13.0  
Set Max Sell  
amps AC  
End Charge  
time  
voltage reading  
away from actual  
If grid timer  
active set bulk  
See menu 9 to  
enable LBX mode.  
See menu 9 to  
enable SELL mode.  
After Start  
Charge time:  
HBCO resets at:  
6v/48, 3v/24 and  
time after start  
charge time.  
Make sure LBX is  
above LBCO volts.  
Make sure LBX is  
above LBCO volts.  
SELL mode  
charges battery.  
1.5v/12v under  
HBCO.  
In SLT mode dont  
disable this  
FLT mode  
charges battery  
LowBattTransfer  
used in LBX, FLT  
timer. It is the  
daily chg time.  
After End Charge  
time:  
Modes only. Goes  
back to battery  
SELL mode sells  
battery to AC1.  
at LowBattCutIn  
(aka LBCI).  
FLT mode drops  
AC1 and inverts  
For LBX mode set  
below LBCI so  
Timer on when  
start < > end;  
charger wont  
cycle batteries  
timer off when  
start = end  
up and down and  
set LBCO below.  
Sell and float  
modes use timer  
SLT and LBX mode  
ignore timer  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
35  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
MENU SYSTEM  
USER MENU  
The USER MENU provides all the controls and settings needed on a daily basis. It allows you to turn on  
the inverter and generator, read the AC and DC meters, check on an error cause and even adjust the  
inverters time clock.  
MENU HEADINGS  
Inverter Mode  
Allows control of the inverter and enables the search and charger only  
modes.  
1
2
Generator Mode  
Allows control of the generator, enables automatic operation or triggers an  
equalization charge cycle. This menu heading is used only if a generator is  
included and controlled by the inverter.  
Trace  
Engineering  
Provides information for accessing Xantrex. Also provides the software  
revision number and allows resetting to the factory default values.  
3
4
5
6
7
Meters  
Allows monitoring of the DC battery voltage, AC voltages and AC current of  
the inverter and other AC sources.  
Error Causes  
Time of Day  
Generator Timer  
Provides an indication of the cause of an error condition. Check this menu  
heading if the red ERROR LED indicator is illuminated on the control panel.  
Sets the internal 24-hour clock. This is used for time sensitive operating  
modes and to determine the quiet timeperiod for generator run lockout.  
Used to set a run lockout period called quiet time. During quiet time, the  
generator starts only if the battery voltage reaches the LBCO 30 sec start  
VDC setting.  
End User Menu  
Used to display that you have reached the end of the USER MENU.  
8
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
36  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
MENU SYSTEM  
INVERTER MODE (1) MENU HEADING  
Set Inverter  
OFF SRCH ON CHG  
Allows turning the inverter ON and OFF, enabling the SEARCH mode or selecting the charger only mode  
CHG. The inverter always starts in the OFF position when powered up. Pressing the red ON/OFF MENU  
button on the control panel can also access this display. Use the SET POINTS button to move the single  
space cursor under the desired selection or you can continue to push the red button to move the cursor to  
the right.  
OFF - Disables the inverter. When the OFF position is selected, no power will be provided to the AC  
loads even if an AC source is available. This is the default position of the inverter upon power-up.  
SRCH - Enables the automatic load search mode control system. This system will turn on the  
inverter if a large enough load is connected. If not enough AC loads are detected, the INVERTING  
LED will blink slowly. The required AC load level is adjustable in the INVERTER SETUP (9) menu  
heading of the SETUP MENU.  
ON - Allows the inverter to provide AC voltage to the output and energize the AC loads either  
from the battery or any synchronizedAC source available on the input. This position must be  
manually selected.  
CHG - Allows the inverter to operate only as a battery charger. AC power will be available to the  
AC loads only if an AC source is available and synchronized. This mode is used to prevent  
discharge of the batteries by the AC loads when a utility outage occurs. This mode is only operational  
on the AC1 input and when the SET GRID USAGE menu item under the INVERTER SETUP (9)  
menu heading is in the FLT mode. When a different mode under the INVERTER SETUP (9) menu  
heading is selected, this position will be locked out. Selecting the CHGmode will disable the  
Automatic Generator control features.  
INFORMATION DISPLAY  
The following information is displayed as additional Menu Items.  
CHG Avail. Only in FLT mode. Press red or setpoint button to move.  
Move cursor to Inverter OFF to reset Overcurrent  
GENERATOR MODE (2) MENU HEADING  
Set Generator  
OFF AUTO ON EQ  
Allows the generator to be turned ON and OFF or enables AUTO-matic and EQualization operation. This  
menu display always starts in the OFF position when the inverter is powered up. Pressing the green GEN  
MENU button on the control panel can access this display. Use the SET POINTS button to move the  
single space cursor under the desired selection. You can also push the green button again to move the  
cursor to the right.  
OFF - Disables the auto startsystem or turns off a generator that has been started by the  
inverter. Also resets the automatic generator control system after an ERROR condition has occurred.  
AUTO - Enables the automatic generator control features. When the battery voltage or load amps  
reach the auto start settings for the required time period, the generator will be started unless the timer is  
in the quiet timeperiod. The generator will only start if the SET LOW BATTERY CUT OUT VDC setting  
under the INVERTER SETUP (9) menu heading is reached for over 30 seconds continuously. If the  
generator is started automatically based on battery voltage, the generator will shut off automatically once  
the battery has completed the BULK and ABSORPTION stages of the battery charging process. If the  
generator is started automatically based on load amps, as set in under the GEN AUTO START SETUP  
(12) menu heading, the generator will turn off once the load current has decreased below the LOAD  
START AMPS continuously for the LOAD STOP DELAY MIN period. The AUTO-matic generator control  
operation is disabled if the CHGmode under INVERTER MODE (1) menu heading is selected.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
37  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
MENU SYSTEM  
ON - Starts the generator that is controlled by the inverter. If this position is selected, it will  
manually turn on the generator that is connected to the GEN CONTROL relays. The OFF position  
must be selected to manually turn the generator off.  
EQ - Triggers the battery charger to complete the equalization process. If an AC source is  
connected to the AC HOT IN 1 terminals, then the equalization process will begin. If no AC source is  
connected to the AC HOT IN 1 terminals, then the generator will start the equalization process the  
next time the generator is automatically started. Once the equalization process has been completed,  
the cursor will return to the AUTO position. If you are battery charging - in FLOAT charge - from the  
Utility or a manually controlled generator, you may initiate another BULK charge by moving the cursor  
through EQ.  
Gen under/over  
speed  
NO  
If YES is displayed, it indicates that the automatic generator control system has detected that the  
generator frequency is with in acceptable tolerance, but is not well adjusted. This error condition will cause  
the red ERROR LED to blink, but will not cause the automatic generator control system to shut down the  
generator.  
The ERROR LED can be used to indicate when the generator frequency is well adjusted. When the  
frequency is within is within 3 hertz of the nominal value (57 to 63 for 60 Hz units, 47 to 53 for 50 Hz units),  
the LED will be off. Once outside this window, the LED will blink slowly. A frequency meter is also provided  
in the METERS (4) menu heading to allow a more precise adjustment of the generator. It is able to  
indicate the frequency of the generator only after the inverter has been able to synchronize to the  
generator. The acceptable frequency range for the SW Series is 53 to 67 Hertz for 60-Hertz models and  
44 to 56 Hertz for 50-Hertz models.  
Generator start  
error  
NO  
If YES is displayed, it indicates that the automatic generator control system was not able to successfully  
start the generator. The system completes five start cycles and requires that the generator operate for a  
minimum of 5 minutes before the starting attempts counter is cleared. To manually clear this error, select  
OFF and then AUTO or ON from the SET GENERATOR menu item, which can also be accessed by  
pressing the green GEN MENU button on the control panel.  
Generator sync  
error  
NO  
If YES is displayed, it indicates that the automatic generator control system was not able to successfully  
connect to the generator after it was running. If the generator runs for 10 minutes without operating in the  
AC voltage and frequency tolerance windows, then the automatic control system stops the generator and  
indicates an error condition. To manually clear this error, select OFF and then AUTO or ON from the SET  
GENERATOR menu item, which can also be accessed by pressing the green GEN MENU button on the  
control panel.  
Gen max run time  
error  
NO  
If YES is displayed, it indicates that the generator ran for a period of time that exceeded the SET MAX  
RUN TIME menu item setting under the GEN AUTO START SETUP (12) menu heading. This error  
indication will only light to let the user know that the generator ran longer than originally expected. This  
may be caused by many variables such as; excessive AC or DC loads operating while the generator is  
trying to charge the battery; the generator operating near the INPUT LOWER LIMIT VAC setting; or the  
batteries no longer holding a charge. This error LED is an advisory indication only and will not allow the  
inverter to stop the generator. To disable the MAX RUN TIME, set the time to zero. To manually clear this  
error, select OFF and then AUTO or ON from the SET GENERATOR menu item, which can also be  
accessed by pressing the green GEN MENU button on the control panel.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
38  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
MENU SYSTEM  
Load Start Amps  
Ready  
NO  
If YES is displayed, it indicates that the automatic control system has started or is about to start the  
generator because the AC load current has reached the LOAD START AMPS setting. The automatic start  
is delayed by the time period set by the LOAD START DELAY MIN setting in the GEN AUTO START  
SETUP (12). This allows checking why the generator was automatically started.  
Voltage Start  
Ready  
NO  
If YES is displayed, it indicates that the automatic control system has started or is about to start the  
generator because the DC battery voltage reached one of the START VOLTS settings. The automatic  
start is delayed by the time period of the START VOLTS setting involved in the GEN AUTO START  
SETUP (12). This allows checking why the generator was automatically started.  
Exercise Start  
Ready  
NO  
If YES is displayed, it indicates that the automatic control system has started or is about to start the  
generator because the EXERCISE PERIOD DAYS setting has been reached. This allows checking of why  
the generator was automatically started.  
INFORMATION DISPLAY  
The following information is displayed as additional Menu Items.  
Move cursor to GEN OFF to reset Generator error. If no start in 5 trys then error.  
If Gen starts & runs for 5 min then stops the inverter will not attempt restart until gen auto  
start conditions are again satisfied. If Gen runs for more than max run time then error.  
Under/Over speed will cause a Sync error in 10 minutes.  
TRACE ENGINEERING (3) MENU HEADING  
Press reset now  
for defaults  
Allows resetting of all menu item settings to the factory default values. This also occurs when the battery is  
disconnected from the inverter. The RESET TO FACTORY DEFAULTS button on the control panel will  
only reset the default values if it is pressed while this menu item is displayed. All factory default settings  
will be reset except for the TIME OF DAY (6) clock.  
If the RESET TO FACTORY DEFAULTS button is pressed while in any other menu item or menu  
heading, only the control panel display (and remote control display) is reset, no settings will be reset. This  
is useful for clearing any garbled display information. This may be encountered when a remote display is  
initially connected or when a remote is used in a high electrical noise environment such as a vehicle  
application.  
Revision  
4.01  
Displays the software revision. Used to ensure compatibility with other units when stacked, etc.  
INFORMATION DISPLAY  
The following information is displayed as additional Menu Items.  
5916 195th St NE Arlington, WA 98223 USA  
Ph 360-435-8826  
Fax 360-435-2229  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
39  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
MENU SYSTEM  
METERS (4) MENU HEADING  
The current meters provided measure only the real, in phase component of the current. This is the portion  
of the power that actually uses power from the battery. This allows better estimation of the DC power  
drawn by the load or the battery charger. This may cause the reading to vary from other AC meters.  
NOTE: The meters do not display a (+) symbol for positive values.  
Inverter/charger  
Amps AC  
00  
All models  
Range: -64 to +64 Amps  
Reads AC amperage. Positive (+) amps indicates inverter is charging the batteries. Negative (-) amps  
indicate the inverter is powering the AC loads and the batteries are being discharged.  
Input  
Amps AC  
00  
All models  
Range: -64 to +64 Amps  
Reads total AC input current from the grid (AC1) or generator (AC 2). The reading is positive (+) if the  
inverter is drawing power from the utility grid to charge the battery or power AC loads and negative (-) if  
the inverter is selling power into the utility grid (only available if SELL mode is enabled).  
Load  
Amps AC  
00  
All models  
Range: 00 to 64 Amps  
Reads the current that is going to the AC loads. This reading is always positive (+).  
Battery actual  
volts DC  
Battery actual  
12.6 volts DC  
Battery actual  
25.2 volts DC  
50.4  
12 VDC models  
24 VDC models  
48 VDC models  
Range: 5.0 to 17.5 VDC  
Range: 10.0 to 35.5 VDC  
Range: 20.0 to 71.0 VDC  
Reads the battery voltage. Similar to the voltage reading of a standard DC voltmeter. The actual battery  
voltage value is used for the LOW BATTERY CUT OUT; HIGH BATTERY CUT OUT, LOW BATTERY  
TRANSFER, LOW BATTERY CUT IN and BATTERY SELL VOLTS settings.  
Battery TempComp  
Battery TempComp  
Battery TempComp  
50.4  
volts DC  
12.6 volts DC 25.2 volts DC  
12 VDC models  
24 VDC models  
48 VDC models  
Range: 5.0 to 17.5 VDC  
Range: 10.0 to 35.5 VDC  
Range: 20.0 to 71.0 VDC  
Note: The BTS must be installed for temperature compensation to be operational.  
Reads the battery voltage after it has been adjusted based on the batterys temperature. This value is  
used by the battery charger for its regulation settings. The value will decrease from the actual battery  
voltage if the battery is cold and will increase if the battery is hot, which may give the appearance that the  
batteries are being overcharged during winter and undercharged in the summertime. This improves the  
performance of the batteries in cold weather and reduces gassing in hot weather. If you are using a NiCad  
or other alkaline type battery, be sure to adjust the SET TEMP COMP menu item under the BATTERY  
CHARGING (10) menu heading of the SETUP MENU to NiCad.  
Inverter  
volts AC  
Inverter  
120 volts AC  
Inverter  
230 volts AC  
Inverter  
105 volts AC  
220  
Standard models  
Range: 00 to 255 VAC  
Emodels  
Range: 00 to 510 VAC  
J & Kmodels  
Range: 00 to 255 VAC  
Wmodels  
Range: 00 to 510 VAC  
Reads the RMS value of the inverters AC output voltage. When synchronized to an AC source, the  
inverter AC output voltage would match the AC inputs value.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
40  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
MENU SYSTEM  
Grid (AC1)  
volts AC  
Grid (AC1)  
120 volts AC  
Grid (AC1)  
230 volts AC  
Grid (AC1)  
105 volts  
220  
Standard models  
Range: 00 to 255 VAC  
Emodels  
Range: 00 to 510 VAC  
J & Kmodels  
Range: 00 to 255 VAC  
Wmodels  
Range: 00 to 510 VAC  
Reads the RMS value of the AC voltage at the inverters AC HOT 1 input and NEUTRAL IN 1 terminals.  
This is usually the connection for the utility grid. Value will drift around before inverter has synchronized.  
Generator (AC2)  
volts AC  
Generator (AC2)  
120 volts AC  
Generator (AC2)  
230 volts AC  
Generator (AC2)  
105 volts AC  
220  
Standard models  
Range: 00 to 255 VAC  
Emodels  
Range: 00 to 510 VAC  
J & Kmodels  
Range: 00 to 255 VAC  
Wmodels  
Range: 00 to 510 VAC  
Reads the RMS value of the AC voltage at the inverters AC HOT 2 input and NEUTRAL IN 2 terminals.  
This is usually the connection for a back-up, fuel-powered generator. Value will drift around before inverter  
has synchronized.  
Read Frequency  
Hertz  
Read Frequency  
60 Hertz  
50  
60 Hz models  
50 Hz models  
Range: 53 to 67 Hz  
Range: 44 to 56 Hz  
Reads the frequency of the AC source that the inverter is synchronized to. This value may drift around  
until the inverter has synchronized to the source. Once synchronized, the inverter follows the frequency of  
the AC source it is connected to.  
INFORMATION DISPLAY  
The following information is displayed as additional Menu Items.  
AC1 & AC2 volts valid only when inverter synced to that input.  
Batt volt actual is used for LBCO, HBCO, LBX, LBCI, sell volts and gen starting.  
Batt volt temp comp is used for float, bulk, eq & aux relays  
ERROR CAUSES (5) MENU HEADING  
When an error has occurred, the red ERROR LED on the control panel will be illuminated. If a generator  
error has occurred, the ERROR LED will blink slowly. This menu is provided to assist with the investigation  
into the error cause. If an error condition has occurred, the word NO will be changed to YES. To reset the  
error, turn the inverter OFF and then ON.  
Over Current  
NO  
Too large of a load was connected or the AC output wiring was short-circuited. This can occur in inverter  
or charger mode. To clear this fault, disconnect the loads and restart the inverter. To restart, push the red  
ON/OFF MENU button on the control panel and then select OFF and then ON or SRCH. Reconnect the  
loads one at a time to find the load or combination of loads that cause the problem. If the inverter will not  
restart with all loads and inputs disconnected remove all AC wiring from the terminal block and try to  
restart again. If it restarts, the problem is with the wiring. If it does not restart, refer to the  
TROUBLESHOOTING GUIDE on page 112.  
Transformer  
overtemp  
Heatsink  
NO overtemp  
NO  
The transformer or power transistors have exceeded their safe operating temperature and the inverter has  
turned off. When operating as a battery charger, the inverter will reduce its charging rate to prevent  
overheating. As an inverter, overheating can be caused by attempting to operate too large of a load for too  
long, a failure of the inverter cooling fans, or that the air flow into or out of the inverter is being blocked.  
The inverter will automatically reset once it has cooled. While the inverter has shut down, AC power from  
any AC source will not pass through the inverter to power AC loads. Any power management provided by  
the inverter will not be able to occur while the inverter is off.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
41  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
MENU SYSTEM  
High Battery  
voltage  
NO  
Battery voltage was above the HIGH BATTERY CUT OUT VDC setting. This can be caused by the solar  
array or other charging source not being regulated. Check the controller for proper operation. Some  
controllers have a equalizesetting which over-rides the normal operation, allowing the battery voltage to  
be unregulated. Return the controller to the normalsetting and check for proper operation. If you are  
using NiCad type batteries, you will need to increase the HIGH BATTERY CUT OUT VDC setting. The  
inverter will automatically reset once the battery voltage has dropped 1.5 volts below the HBCO setting for  
a 12 VDC system, 3 volts for a 24 VDC system and 6 volts for a 48 VDC system.  
Low Battery  
voltage  
NO  
Battery voltage is below the LOW BATTERY CUT OUT VDC setting. The inverter has shut off to prevent  
over-discharge of the battery. Allow the battery to recharge or connect to an AC source such as a back-up  
generator. The inverter will reset when the battery exceeds the LOW BATTERY CUT IN VDC setting.  
AC source wired  
to output  
NO  
Reports that an AC voltage source was connected directly to the AC output. This can be caused by  
improper wiring or incorrect installation of the inverter. Check the AC input and output wiring. This  
condition is much worse than a short circuit and may cause damage to the inverter. Find the cause and  
correct the problem before restarting the inverter. A defective utility or generator AC input relay could  
cause this condition. To test, disconnect all input wiring from AC inputs 1 and 2 and restart the inverter. If  
the AC IN GOOD LED indicator on the control panel glows, then the inverters internal relay is defective.  
External error  
(stacked)  
NO  
A problem has occurred with the series interface cable or one of the inverters operated in series. Check the  
cable for damage and replace it to see if the problem is corrected. Also, check the connecting AC wiring.  
Generator start  
error  
NO  
Indicates that the automatic generator control system was not able to successfully start the generator. The  
system completes five start cycles and requires that the generator operate for a minimum of 5 minutes  
before the starting attempts counter is cleared. To manually clear this error, select OFF and then AUTO or  
ON from the SET GENERATOR menu item, which pressing the green GEN MENU button on the control  
panel can access.  
Generator sync  
error  
NO  
Indicates that the automatic generator control system was not able to successfully connect to the  
generator after it was running. If the generator runs for 10 minutes without operating in the AC voltage and  
frequency tolerance windows, then the automatic control system stops the generator and indicates an  
error condition. To manually clear this error, select OFF and then AUTO or ON from the SET  
GENERATOR menu item, or press the green GEN MENU button on the control panel can access.  
Gen under/over  
speed  
NO  
Indicates that the automatic generator control system has detected that the generator frequency is not well  
adjusted. This error condition will cause the red ERROR LED to illuminate, but will not cause the  
automatic generator control system to shut down the generator. If the inverter can not synchronize to the  
generator after a 10-minute period, then the GENERATOR SYNC ERROR condition will be reached.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
42  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
MENU SYSTEM  
The ERROR LED can be used to indicate when the generator frequency is well adjusted. When the  
frequency is within ± 5% of the nominal value, the LED will be off. Once outside this window, the LED will  
be on. A frequency meter is also provided in the METERS (4) menu heading to allow a more precise  
adjustment of the generator. It is able to indicate the frequency of the generator only after the inverter has  
been able to synchronize to the generator. The acceptable frequency range for the SW Series is 53 to 67  
Hertz for 60-Hertz models and 44 to 56 Hertz for 50-Hertz models.  
Inverter breaker  
tripped  
NO  
The inverters output AC circuit breaker on the left end of the chassis has tripped or is open. Operating  
too large of an AC load may cause this. Reduce the loads connected and reset the circuit breaker by  
pressing it in or moving the handle depending upon the type of breaker included.  
TIME OF DAY (6) MENU HEADING  
Provides the reference for any time functions enabled. Does not reset when the PRESS FOR FACTORY  
DEFAULTSbutton is pressed. Will reset only if DC power to the inverter is lost.  
Set Clock hour  
00:00:00  
Indicates and allows setting of the hours for the internal clock. This setting is based on a 24-hour clock  
and adjusts in 10-minute increments.  
Set Clock minute  
00:00:00  
Indicates and allows setting of the minutes for the internal clock.  
Set Clock second  
00  
Indicates and allows setting of the seconds for the internal clock.  
GENERATOR TIMER (7) MENU HEADING  
Start Quiet  
Time h:m  
08:00  
Generator will not be started during this period unless the actual battery voltage reaches the LOW  
BATTERY CUT OUT VDC setting for a continuous period of 30 seconds. Causes the automatic generator  
control system to ignore the AC load and battery voltage start settings. The quiet time period is usually set  
for the sleeping hours.  
End Quiet  
Time h:m  
08:00  
This setting finishes the quiet time period, allowing the generator to start as required by the settings of the  
GEN AUTO START SETUP (12) menu heading in the SETUP MENU. To disable the quiet time, set the  
start and end times equal. The generator exercise system will start at this time setting and will run for 15  
minutes if the generator exercise timer has reached the SET EXERCISE DAYS menu item setting. For  
example, if the SET EXERCISE DAYS menu item is set for 1, then the generator will start every day at  
this time. To disable the generator exercise system, set the SET EXERCISE DAYS menu item to zero.  
INFORMATION DISPLAY  
The following information is displayed as additional Menu Items.  
Gen doesnt run during quiet time unless batt volts is less than  
LBCO volts for 30 seconds, or load > load start amps.  
To defeat timers set start = end.  
If exercise day set to 1 then gen will always start @ end quiet.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
43  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
MENU SYSTEM  
SETUP MENU  
The SETUP MENU provides all the controls and settings needed when installing or adjusting the system.  
To access the SETUP MENU, press both the red ON/OFF MENU and green GEN MENU buttons at the  
same time on the control panel of the inverter or remote control. To exit, simply go to one of the USER  
MENU headings numbers 1 through 8, or press the red ON/OFF MENU or green GEN MENU button  
once.  
MENU HEADINGS  
Inverter Setup  
Battery Charging  
AC Inputs  
Use to program and adjust the operation of the inverter. Also allows  
adjustment of how the inverter/ charger mode uses the utility grid.  
9
10  
11  
12  
13  
14  
15  
16  
17  
18  
19  
20  
Use to adjust the operation of the battery charger.  
Use to adjust the operating characteristics of the utility grid (AC1) and the  
generator (AC2) inputs.  
Gen Auto Start  
setup  
Use to setup the when the automatic generator control system and the  
maximum run time allowed  
Gen starting  
details  
Use to adjust the starting sequence of the automatic generator control  
system.  
Auxiliary Relays  
R9 R10 R11  
Use to adjust the operation of the auxiliary signal relays for controlling  
external power sources or system loads.  
Bulk Charge  
Trigger Timer  
Use to set a time when the battery will be given a bulk charge cycle from the  
utility grid (AC1) input. Usually only used when SLT mode is enabled.  
Low Battery  
Transfer (LBX)  
Use to set up the transfer voltage setting for the LBX mode.  
Battery Selling  
Grid Usage Timer  
Use to control the SELL mode when it is used to discharge a battery into the  
utility grid. Also allows setting of the maximum sell amps.  
Use to control when the inverter/charger mode uses the utility grid for the  
FLT and SELL modes.  
Information File  
battery  
Provides information about the operation of some settings and meters.  
End Setup Menu  
Used to display that you have reached the end of the SETUP MENU.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
44  
Rev. C: February 2001  
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MENU SYSTEM  
INVERTER SETUP (9) MENU HEADING  
Set Grid Usage  
FLT SELL SLT LBX  
FLT - Float will try to maintain the batteries at the float voltage level. This can be used when the  
source of power is a utility grid or a generator. When AC power is available, the inverter will complete  
a full three stage charge cycle and then hold the battery at the float level until the source of utility  
power is no longer available. This is the default setting and is appropriate for use with stand-alone  
systems with back-up generators or utility back-up systems. FLT mode does not sell excess power  
into the utility grid. If a DC power source is available and the battery is full, its power will be used to  
directly power the AC loads connected to the inverter output even though the AC power is also  
connected to the loads. If more power is available from the DC source than is required to power the  
AC loads, the battery voltage will increase above the float level. An external charge control device –  
such as the TraceC40 Load/Charge controller - is therefore required to prevent over charging of the  
battery.  
SELL SELL mode enables the inverter to sellthe excess power to the grid (AC HOT IN 1  
only). This mode must have the approval of the local power utility prior to its use. In the US,  
utility companies are required by law to purchase any excess power generated by their customers;  
however, they decide what can be connected and what safety requirements must be met. Be advised:  
some utilities will be more receptive than others will. The most advantageous configuration is called  
NETmetering where only one meter is installed and spins either direction. The purchase and sell  
prices are equal. Dualmetering requires two meters and is less desirable since the power you sell is  
usually worth only a fraction of the price for the power you purchase. Power from any DC source, such  
as a solar array, and a battery can be sold. When power from a DC source is available, it will be used  
to power any AC loads connected to the AC output first. Any excess power available from the system  
will be sold intothe utility gird through the AC HOT IN 1 terminals.  
SLT - The silent mode does not maintain the battery at float voltage all the time. The battery  
charger only operates for part of each day. AC power from the utility grid is passed through the  
inverter to the loads 24 hours a day. Once a day, at the time prescribed by the BULK CHARGE  
TRIGGER TIMER, the batteries are given a bulk and absorption charge cycle. The inverter will  
perform a bulk charge once per day from the grid, charging the battery to near the SET BULK VOLTS  
DC setting until the battery charger has held the battery near the SET BULK VOLTS DC setting for  
the ABSORPTION TIME period setting. The inverter will then go totally silent and will wait for the utility  
power to fail, or until the next day when it performs another bulk charge. After each power outage, the  
inverter will perform another bulk charge cycle once the AC source has returned. This is typically used  
only in utility back-up applications.  
LBX - The low battery transfer mode allows a system to automatically switch between utility  
connected and stand alone battery operation. In this mode, the inverter will power the loads from  
the battery and solar array (or other energy source) until the battery voltage drops to the LOW  
BATTERY TRANSFER VDC setting. It will then connect to the utility grid and charge the battery. The  
loads will be powered by the utility until the battery voltage reaches the LOW BATTERY CUT IN VDC  
setting. The inverter will then disconnect the utility and power the loads from the battery and any other  
source of DC power connected. This mode is often used instead of the SELL mode because approval  
from the utility is not required - no power will be sent into the utility distribution system when LBX is  
selected. To use the LBX mode, the AC source (utility power) must be connected to AC1 input only,  
transfer to the inverter will not occur if the AC source is connected to the AC2 input. If AC is present  
on the AC1 input in the LBX mode, the AUTO GENERATOR CONTROL MODE will be disabled.  
CAUTION: If the system is not properly sized, the LBX mode can result in frequent transfers  
from the battery to the utility and result in poor performance of the system and excessive  
energy consumption from the utility. The daily output of the alternative power source (solar,  
wind etc.) should be able to meet the daily power requirements of the loads being operated  
under typical conditions. See the low battery transfer mode section for more information.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
45  
Rev. C: February 2001  
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MENU SYSTEM  
Set Low Battery  
cut out VDC  
Set Low Battery  
11.0 cut out VDC  
Set Low Battery  
22.0 cut out VDC 44.0  
12 VDC models  
24 VDC models  
48 VDC models  
Range: 08.0 to 16.0  
Range: 16.0 to 32.0  
Range: 32.0 to 64.0  
This setting controls when the inverter turns off due to a low battery voltage condition. The inverter will turn  
off only after this level has been reached for the period of time set by the following item. When the  
automatic generator control system is used, the generator will be started when the battery voltage has  
dropped below this value for 30 seconds continuously. This will occur even during the quiet time period.  
This setting is not temperature compensated.  
Set LBCO delay  
minutes  
15  
All models  
Range: 00 to 255  
This setting controls how long the inverter delays before turning off due to a low battery voltage condition.  
The inverter will turn off only after the LOW BATTERY CUT OUT VDC level has been reached for this  
period of time continuously. If you are using the automatic generator control system, dont set this delay  
period shorter than the amount of time it takes the generator to start and connect or the power will go off  
and then back on when the generator auto starts due to a LBCO condition.  
Set Low battery  
cut in VDC  
Set Low battery  
13.0 cut in VDC  
Set Low battery  
26.0 cut in VDC  
52.0  
12 VDC models  
24 VDC models  
48 VDC models  
Range: 05.0 to 17.5  
Range: 10.0 to 35.0  
Range: 20.0 to 70.0  
This setting controls when the inverter turns back on once it has shut off after the battery reached the  
LOW BATTERY CUT OUT VDC setting. It is also used to control when the system resumes powering the  
AC loads from the inverter when LBX mode is being used. In LBX mode, the best performance will often  
be achieved if this setting is higher than the BULK and FLOAT VOLTS DC setting in order to reduce  
cycling of the system. The DC charging sources (wind, solar etc.) must then cause the battery voltage to  
rise above the charger settings before the system resumes inverter mode operation. This setting is not  
temperature compensated.  
Set High battery  
Set High battery  
Set High battery  
64.0  
cut out VDC  
16.0 cut out VDC 32.0 cut out VDC  
12 VDC models  
24 VDC models  
48 VDC models  
Range: 00.0 to 16.5  
Range: 00.0 to 33.0  
Range: 00.0 to 66.0  
This is the battery voltage at which the inverter turns off. The inverter will automatically restart once the  
battery voltage has dropped 1.5 VDC below the HBCO setting for 12 VDC systems, 3 VDC for 24 VDC  
systems, and 6 VDC for 48 VDC systems. This setting is not temperature compensated.  
Set search  
watts  
48  
All models  
Range: 00 to 240  
The sensitivity threshold of the search mode circuit is adjustable. If set to zero, it is effectively disabled.  
The sensitivity is only adjustable in increments of 16 watts.  
Set search  
spacing  
59  
All Models  
Range: 10 to 255*  
The length of time between each search pulse is also adjustable. The setting is in cycles. Therefore, a  
setting of 60 would generate search pulses that are 1 second apart. The range of settings is from 10 to  
255 cycles, which equals a search pulse from 6 times a second to once every 4.25 seconds. This  
adjustment can be used to speed up the response of the search circuit, which will reduce the delay when  
starting a load. Reducing the spacing increases the power consumption of the inverter when it is in the  
search mode, reducing the benefit of it. Typically, the default value is acceptable.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
46  
Rev. C: February 2001  
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MENU SYSTEM  
BATTERY CHARGING (10) MENU HEADING  
Note: See the battery section of this manual for recommended setting for different battery types.  
Set Bulk  
volts DC  
Set Bulk  
14.4 volts DC  
Set Bulk  
28.8 volts DC  
57.6  
12 VDC models  
Range: 10.0 to 16.0  
24 VDC models  
Range: 20.0 to 32.0  
48 VDC models  
Range: 40.0 to 64.0  
Sets the voltage level that will be maintained during the first and second stage of the charging process.  
This will be the maximum voltage at which the batteries will be charged. This setting will be  
compensated for the battery temperature if the BTS sensor is installed.  
Set Absorption  
time h:m  
02:00  
All models  
Range: 00:00 to 23:50  
Sets the time period that the batteries will be held near the SET BULK VOLTS DC level for the second  
stage of the battery charging process, this ensures that the battery is well charged. If the automatic  
generator control system is used, the generator will turn off when the batteries have been held near the  
SET BULK VOLTS DC setting until the ABSORPTION TIME period has elapsed. This time is an  
accumulating or up/down type timer - it counts up while the voltage is near the BULK setting and counts  
back down if the voltage drops. This makes the process more reliable and predictable. If the system  
designer wants to minimize generator operation, a shorter time may be used. If the system designer wants  
to ensure that the batteries are fully charged before stopping the charging process, then a longer setting  
may be used. If the ABSORPTION TIME is set to zero (00:00) the unit will not provide any absorption  
charge time and go straight to the float charge stage after reaching near the BULK voltage setting.  
Set Float  
volts DC  
Set Float  
13.4 volts DC  
Set Float  
26.8 volts DC  
53.6  
12 VDC models  
Range: 10.0 to 16.0  
24 VDC models  
Range: 20.0 to 32.0  
48 VDC models  
Range: 40.0 to 64.0  
Sets the voltage level that will be maintained at the final stage of the charging process. This is important for  
systems which are connected to utility power since the battery charger will often be in this stage most of the  
time. This setting will be compensated for the battery temperature if the BTS sensor is installed.  
Set Equalize  
volts DC  
Set Equalize  
14.4 volts DC  
Set Equalize  
28.8 volts DC  
57.6  
12 VDC models  
Range: 10.0 to 16.0  
24 VDC models  
Range: 20.0 to 32.0  
48 VDC models  
Range: 40.0 to 64.0  
Sets the voltage level that the batteries will be limited to during the equalization process. This will be the  
maximum voltage at which the batteries will be charged. This setting will be compensated for the  
battery temperature if the BTS sensor is installed.  
Set Equalize  
time h:m  
02:00  
All models  
Range: 00:00 to 23:50  
Sets the amount of time battery voltage must exceed the BULK VOLTS DC setting before the equalization  
process is considered to be completed. If the automatic generator control system is used; it will turn off the  
generator when this timer has reached its setting, and return the cursor from the EQ to the AUTO position.  
This time is an accumulating or up/down type timer - it counts up while the voltage is above the BULK  
setting and counts back down if the voltage drops below the BULK setting for a period of time.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
47  
Rev. C: February 2001  
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MENU SYSTEM  
Set Max Charge  
amps AC  
Set Max Charge  
20 amps AC  
Set Max Charge  
30 amps AC  
Set Max Charge  
15 amps AC  
35  
12 VDC models  
Range: 01 to 25  
24 VDC & 48 VDC models  
Range: 01 to 35  
E & Wmodels  
Range: 01 to 18  
J & Kmodels  
Range: 02 to 40  
Sets the maximum amount of AC input current that the battery charger will use to charge the battery. This  
can be used to limit the charger output as well. The charger will back-offif the combination of AC loads  
and the charger reaches the AMPS AC setting of the AC INPUT connected to prevent overloading the  
source or tripping breakers. This process occurs automatically.  
Set Temp Comp  
LEADACID  
NICAD  
All models  
Allows selection of the battery type for the battery temperature compensation system. This effectively  
reduces the battery charging set points when the battery is hot and increases them when the battery is  
cold. The battery charging set points change ±0.005 volts per degree Celsius for the LEADACID setting  
and ±0.003 volts per degree Celsius per battery cell for the NICAD setting. These battery setpoint  
changes occur if the battery temperature is higher or lower than 25° C (77°F), and will only occur if the  
battery temperature sensor (BTS) is installed. The setting should be changed from the default setting only  
if NiCad or Nickel Iron batteries are used.  
AC INPUTS (11) MENU HEADINGS  
Set Grid (AC1)  
amps AC  
Set Grid (AC1)  
60 amps AC  
Set Grid (AC1)  
30.0 amps AC  
60  
Standard models  
Range: 00 to 63  
E & Wmodels  
Range: 00 to 31.5  
J & Kmodels  
Range: 00 to 63  
This setting determines the level in AC amps at which the inverter begins to back-off the battery charger  
or operates in parallel to reduce the load on the utility grid. Typically, this is set to the size of the AC circuit  
breaker that feeds the AC HOT IN 1.  
Set Gen (AC2)  
amps AC  
Set Gen (AC2)  
30 amps AC  
Set Gen (AC2)  
15.0 amps AC  
30  
Standard models  
Range: 00 to 63  
E & Wmodels  
Range: 00.0 to 31.5  
J & Kmodels  
Range: 00 to 63  
This setting determines the level in AC amps at which the inverter begins to back-off the battery charger or  
operates in parallel to reduce the load on the generator. Typically, this is set to the size of the generators  
circuit breaker feeding the inverter (AC HOT IN 2) or the maximum output amperage ability of the generator.  
Set Input Lower  
limit VAC  
Set Input Lower  
108 limit VAC  
Set Input Lower  
206 limit VAC  
Set Input Lower  
88 limit VAC  
196  
Standard models  
Range: 80 to 111  
Emodels  
Range: 170 to 220  
J & Kmodels  
Range: 70 to 90  
Wmodels  
Range: 160 to 210  
Sets the lowest voltage at which the inverter is allowed to be connected to the utility grid (AC INPUT 1) or  
the generator (AC INPUT 2). When the AC input voltage reaches this level, the inverter will stop battery  
charging and begin to invert in parallel with the AC source to reduce the load. If the voltage continues to  
drop, the inverter will disconnect and will power the loads from the battery. NOTE: Typically the INPUT  
LOWER LIMIT VAC setting will be based upon the minimum AC voltage tolerable by the AC loads.  
Set Input Upper  
limit VAC  
Set Input Upper  
132 limit VAC  
Set Input Upper  
254 limit VAC  
Set Input Upper  
112 limit VAC  
244  
Standard models  
Range: 128 to 149  
Emodels  
Range: 250 to 298  
J & Kmodels  
Range: 105 to 129  
Wmodels  
Range: 240 to 288  
Sets the highest voltage at which the inverter is allowed to be connected to the utility grid (AC INPUT 1) or  
generator (AC INPUT 2). This is also the maximum voltage at which the inverter will sell power into the line if  
SELL is enabled. When this voltage is reached the inverter will disconnect and power the AC loads from the  
battery. If this voltage drops below this setting, the inverter will reconnect the loads to the AC source.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
48  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
MENU SYSTEM  
GEN AUTO START SETUP (12) MENU HEADING  
Set Load Start  
amps AC  
33  
All models  
Range: 00 to 63  
Sets the AC load current that will initiate the automatic generator control system when the current remains  
above this setting continuously for the LOAD START DELAY MIN period.  
Set Load Start  
delay min  
05.0  
All models  
Range: 00.0 to 25.5  
Sets the time delay period that will initiate automatic generator control system when the current remains  
above the LOAD START AMPS AC setting continuously for this time period.  
Set Load Stop  
delays min  
05.0  
All models  
Range: 00.0 to 25.5  
Sets the amount of time that the automatic generator will continue to run after the load current  
(determined by the LOAD AMPS AC meter) decreases below the LOAD START AMPS AC setting.  
Set 24 hr start  
volts DC  
Set 24 hr start  
12.3 volts DC  
Set 24 hr start  
24.6 volts DC  
49.2  
12 VDC models  
24 VDC models  
48 VDC models  
Range: 05.0 to 16.5  
Range: 10.0 to 35.5  
Range: 20.0 to 71.0  
Sets the battery voltage that will initiate the automatic generator control system if the voltage remains  
below this setting continuously for 24 hours. This setting is not temperature compensated. This 24-hour  
start is defeated if the QUIET TIME under GENERATOR TIMER (7) is enabled.  
Set 2 hr start  
volts DC  
Set 2 hr start  
11.8 volts DC  
Set 2 hr start  
23.6 volts DC  
47.2  
12 VDC models  
24 VDC models  
48 VDC models  
Range: 05.0 to 16.5  
Range: 10.0 to 35.5  
Range: 20.0 to 71.0  
Sets the battery voltage that will initiate the automatic generator control system if the voltage remains  
below this setting continuously for 2 hours. This setting is not temperature compensated. This 2-hour start  
is defeated if the QUIET TIME under GENERATOR TIMER (7) is enabled.  
Set 15 min start  
Set 15 min start  
Set 15 min start  
45.2  
volts DC  
11.3 volts DC 22.6 volts DC  
12 VDC models  
24 VDC models  
48 VDC models  
Range: 05.0 to 16.5  
Range: 10.0 to 35.5  
Range: 20.0 to 71.0  
Sets the battery voltage that will initiate the automatic generator control system if the voltage remains  
below this setting continuously for 15 minutes. This setting is not temperature compensated. This 15-  
minute start is defeated if the QUIET TIME under GENERATOR TIMER (7) is enabled.  
Read 30 sec LBCO  
Read 30 sec LBCO  
Read 30 sec LBCO  
44.0  
start VDC  
11.0 start VDC 22.0 start VDC  
12 VDC models  
24 VDC models  
48 VDC models  
Range: 05.0 to 16.5  
Range: 10.0 to 35.5  
Range: 20.0 to 71.0  
Displays the battery voltage setting that will initiate the automatic generator control system if the voltage  
remains below the setting continuously for 30 seconds. This setting is not temperature compensated. This  
display is linked and is adjusted by the SET LOW BATTERY CUT OUT VDC menu item setting under the  
INVERTER SETUP (9) menu heading. This 30-second start will attempt to start the auto start generator  
even if the QUIET TIME under GENERATOR TIMER (7) is enabled.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
49  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
MENU SYSTEM  
Set Exercise  
period days  
30  
All models  
Range: 00 to 255  
Sets a maximum number of days allowed between operation of the generator. When an internal counter  
reaches the number of days set, the generator will be started at the END QUIET TIME menu item setting.  
The run time is fixed at 10 minutes. If the generator is manually or automatically operated for 5 minutes at  
any time during this period, then this counter will reset and the period will start again. If this menu item is  
set for 1 day, then the generator will start everyday at this time. If the period is set to zero, then the  
exercise system will be disabled. If power is present at the AC1 input, the generator will not be connected  
to during the exercising operating period.  
Set Maximum run  
time h:m  
08:00  
All Models  
Range: 00:00 to 23:50  
This setting provides an indication that the generator operated excessively after it was automatically or  
manually started. Once this time period is reached, the error LED will flash and a GEN MAX RUN TIME  
ERROR condition will be indicated in the GENERATOR MODE (2) menu heading. This error is an  
advisory only error and does not stop the generator and the inverter/charger will continue to operate  
normally. While the error condition exists, the generator can be started manually or automatically. To reset  
the error condition, press the green GEN MENU button to select OFF, then the AUTO or ON. Setting the  
time to 00:00 defeats this function.  
INFORMATION DISPLAY  
The following information is displayed as additional Menu Items.  
Set Max Run Time to 0 to defeat. Set exercise to 0 to defeat. See menu 9 to set LBCO.  
GEN STARTING DETAILS (13) MENU HEADING  
Set RY7 Function  
GlowStop Run  
All Models  
Allows Relay 7 (RY7) to provide two different generator start routines. The relay labeled RY7 is used to  
either provide a STOP signal or a RUN signal. It can also be used to provide a GLOW signal on diesel  
generators with glowplugs. Note that the right side choice, RUN, is the default.  
When RUN is selected as the function of the RY7 relay, the RY7 COM and RY7 N.O. contacts remain closed  
while the generator is running. The RY7 N.C. (normally closed) contact is open (not connected to the common  
terminal) while the generator is running. When the generator is off, the RY7 N.C. terminal is connected to the  
RY7 COM terminal. This configuration is useful for starting a two wire (auto crank) type generator.  
When GLOWSTOP is selected as the function of the RY7 relay, the RY7 COM and RY7 N.O. contacts  
remain open while the generator is running. The contacts close only when it is time for the generator to be  
stopped, then re-open. This is useful for generators that require a stop signal to shut down the generator.  
The GLOWSTOP setting can also be used for diesel generators. This relay can be used to provide both  
the GLOW and STOP signals. When this is done the generator will be given both GLOW and STOP  
signals before cranking and when stopping.  
Set Gen warmup  
seconds  
60  
All Models  
Range: 16 to 255  
Sets the number of seconds the generator is allowed to warm up before the load is connected and the  
battery charger started. If the generator is located in a cold location (below freezing), a longer setting may  
be required.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
50  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
MENU SYSTEM  
Set Pre Crank  
seconds  
10  
All Models  
Range: 00 to 255  
Sets the number of seconds the system delays closing of relay RY8 - the star signal relay - once relay  
RY7 is closed. See the AUTOMATIC GENERATOR CONTROL MODE for more information. This period  
may also be the amount of time that the glow plugs will be on if they are connected to the automatic  
control system.  
Set Max Cranking  
seconds  
10  
All Models  
Range: 00 to 15  
Sets the maximum number of seconds the starter will be cranked during the starting sequence by closing  
relay RY8. See the AUTOMATIC GENERATOR CONTROL MODE for more information.  
Set Post Crank  
seconds  
30  
All Models  
Range: 00 to 255  
Sets the number of seconds the system will delay after completing the start sequence. If the generator has not  
started, this sequence will be repeated up to 5 times. See the AUTOMATIC GENERATOR CONTROL MODE  
for more information. This period is provided to allow the starter motor to cool off. It can also allow generators  
with built in warm-up delay contactors to provide AC output before the inverter attempts a re-crank cycle.  
AUXILIARY RELAYS (14) MENU HEADING  
Three voltage-controlled relays are provided to simplify installations that have battery voltage related tasks  
to perform. They are single pole double throw, five amp relays. Both the normally closed and normally  
open contacts are available for each relay. The operation of the relays is individually controlled and  
adjustable. The three auxiliary relays operate independently of the inverter/charger status (being on or off).  
Both the normally open (N.O.) and normally closed (N.C.) contacts are available for each of these auxiliary  
relays. Use the crimp-on terminals provided in the hardware package to connect to these contacts.  
CAUTION: These relays are not intended to directly control a load or charging source - rather  
they can be used to send a signal or operate the coil of another higher amperage device which  
does the actual switching of the power. A fuse rated at 5 amps or less should be included to  
protect each of the relays. Damage to these relays from overloading is not covered by warranty  
and requires the inverter to be returned to a repair center. This also applies to the relays that are  
provided to start a generator.  
The SET RELAY VOLTS DC setting sets the voltage trip point for each of the auxiliary relays (9, 10, and  
11). When the battery voltage exceeds this setting, the relay energizes and closes the N.O. and COM  
terminals on the relay. This setting is compensated for the battery temperature when the BTS is used.  
There is no intentional time delay (0.1 sec) on the reaction for this setting; this allows fast response to  
rapid voltage changes in the system  
The HYSTERESIS VOLTS DC setting determines the voltage difference between when the relay  
becomes energized and when it is de-energized. This is an active hightype of control. The N.O. and  
COM terminals of the relay close (relay is energized) when the battery voltage exceeds the AUX RELAY 9  
VOLTS DC setting and opens (relay is de-energized) at this setting minus the R9 HYSTERESIS VOLTS  
DC setting. The N.O. and COM terminals of the relay remain open (de-energized) until it again reaches  
the AUX RELAY 9 VOLTS DC setting. (For example, the default setting energizes the relay when the  
voltage exceeds 14.5 VDC and de-energizes when it drops below 13.5 VDC for 12-volt systems). There is  
an intentional 2-second time delay to reduce cycling.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
51  
Rev. C: February 2001  
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MENU SYSTEM  
Set Relay 9  
volts DC  
Set Relay 9  
14.5 volts DC  
Set Relay 9  
29.0 volts DC  
58.0  
12 VDC Models  
Range: 05.0 to 17.6 Range: 10.0 to 35.5  
24 VDC Models  
48 VDC Models  
Range: 20.0 to 71.0  
Sets the voltage trip point for the auxiliary relay number 9. This setting is compensated for the battery  
temperature when using the BTS. There is no intentional time delay on the reaction for this setting. This  
allows fast response to rapid voltage changes in the system.  
R9 Hysteresis  
volts DC  
R9 Hysteresis  
01.0 volts DC  
R9 Hysteresis  
02.0 volts DC  
04.0  
12 VDC Models  
24 VDC Models  
48 VDC Models  
Range: 00.1 to 12.8  
Range: 00.1 to 12.8  
Range: 00.2 to 25.6  
The hysteresis setting for relay number 9. There is an intentional 2-second time delay to reduce cycling.  
Set Relay 10  
volts DC  
Set Relay 10  
14.8 volts DC  
Set Relay 10  
29.5 volts DC  
59.0  
12 VDC Models  
Range: 05.0 to 17.6  
24 VDC Models  
Range: 10.0 to 35.5  
48 VDC Models  
Range: 20.0 to 71.0  
Sets the voltage trip point for the auxiliary relay number 10. This setting is compensated for the battery  
temperature when using the BTS. There is no intentional time delay on the reaction for this setting. This  
allows fast response to rapid voltage changes in the system.  
R10 Hysteresis  
volts DC  
R10 Hysteresis  
01.0 volts DC  
R10 Hysteresis  
02.0 volts DC  
04.0  
12 VDC Models  
24 VDC Models  
48 VDC Models  
Range: 00.1 to 12.8  
Range: 00.1 to 12.8  
Range: 00.2 to 25.6  
The hysteresis setting for relay number 10. There is an intentional 2-second time delay to reduce cycling.  
Set Relay 11  
volts DC  
Set Relay 11  
15.0 volts DC  
Set Relay 11  
30.0 volts DC  
60.0  
12 VDC Models  
Range: 05.0 to 17.6  
24 VDC Models  
Range: 10.0 to 35.5  
48 VDC Models  
Range: 20.0 to 71.0  
Sets the voltage trip point for the auxiliary relay number 11. This setting is compensated for the battery  
temperature when using the BTS. There is no intentional time delay on the reaction for this setting. This  
allows fast response to rapid voltage changes in the system.  
R11 Hysteresis  
volts DC  
R11 Hysteresis  
01.0 volts DC  
R11 Hysteresis  
02.0 volts DC  
04.0  
12 VDC Models  
24 VDC Models  
48 VDC Models  
Range: 00.1 to 12.8  
Range: 00.1 to 12.8  
Range: 00.2 to 25.6  
The hysteresis setting for relay number 11. There is an intentional 2-second time delay to reduce cycling.  
INFORMATION DISPLAY  
The following information is displayed as additional Menu Items.  
Close on batt > setpoint. Open on batt < setpoint hys.  
Relays have 2 seconds delay on close, 0.1 sec delay on open.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
52  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
MENU SYSTEM  
BULK CHARGE TRIGGER TIMER (15) MENU HEADING  
Set Start Bulk  
time  
00:00  
All Models  
Range: 00:00 to 23:50  
Starts the bulk charge process at the time shown. Setting to 00:00 defeats this function. This setting  
should be enabled when using the SLT mode so that the batteries are charged once each day. With the  
GRID USAGE TIMER enabled, the START BULK TIME setting should be set near the beginning of the  
charging time window for best operation. Since the battery will usually be fully charged when this timer  
setting is reached, the battery charger will usually reach the ABSORPTION stage of the charging process  
quickly and will then hold the battery near the SET BULK VOLTS DC setting for the ABSORPTION TIME  
setting (default time period is 2 hours). This setting does not need to be adjusted if you are using FLT  
mode with a generator. This setting works with the AC1 HOT IN 1 input only.  
INFORMATION DISPLAY  
The following information is displayed as additional Menu Items.  
To disable timer set to 00:00. If grid timer active set bulk time after start charge time.  
In SLT mode dont disable this timer. It is daily chg time.  
LOW BATTERY TRANSFER (16) MENU HEADING  
Set Low Battery  
Transfer VDC  
Set Low Battery  
11.3 Transfer VDC  
Set Low Battery  
22.6 Transfer VDC  
45.2  
12 VDC models  
24 VDC models  
48 VDC models  
Range: 05.0 to 16.5  
Range: 10.0 to 33.0  
Range: 20.0 to 66.0  
This is the voltage at which the inverter transfers the loads from the battery to the utility grid. It is used only  
with the LBX and FLT modes. This setting is not temperature compensated. The transfer will occur only if  
the battery voltage remains below this setting for 20 seconds. The system returns to powering the AC  
loads from the battery once the battery voltage has reached the LOW BATTERY CUT IN setting. This  
setting works with the AC1 HOT IN 1 input only.  
Set Low battery  
cut in VDC  
Set Low battery  
13.0 cut in VDC  
Set Low battery  
26.0 cut in VDC  
52.0  
12 VDC models  
24 VDC models  
48 VDC models  
Range: 05.0 to 16.5  
Range: 10.0 to 33.0  
Range: 20.0 to 66.0  
This setting controls when the inverter turns back on once it has shut off when the battery reached the  
LOW BATTERY CUT OUT VDC setting. It is also used to control when the system resumes powering the  
AC loads from the inverter when LBX mode is being used. In LBX mode, the best performance will often  
be achieved if this setting is higher than the BULK and FLOAT VOLTS DC setting in order to reduce  
cycling of the system. The DC charging sources (wind, solar etc.) must then cause the battery voltage to  
rise above the charger settings before the system resumes inverter mode operation. This setting is not  
temperature compensated  
INFORMATION DISPLAY  
The following information is displayed as additional Menu Items.  
See menu 9 to enable LBX mode.  
Make sure LBX is above LBCO volts.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
53  
Rev. C: February 2001  
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MENU SYSTEM  
BATTERY SELLING (17) MENU HEADING  
Note: See the battery section of this manual for recommended settings for different battery types.  
Set Battery Sell  
Set Battery Sell  
Set Battery Sell  
53.6  
volts DC  
13.4 volts DC 26.8 volts DC  
12 VDC models  
24 VDC models  
48 VDC models  
Range: 5.0 to 16.0  
Range: 10.0 to 32.0  
Range: 20.0 to 64.0  
Sets the level to which the batteries will be discharged when power is being sold from the batteries to the  
grid. This is only used if the SELL mode is enabled and the GRID USAGE TIMER (18) is programmed.  
This setting will not be adjusted for the battery temperature if the temperature sensor is installed.  
Set Max Sell  
amps AC  
Set Max Sell  
30 amps AC  
Set Max Sell  
15.0 amps AC  
Set Max Sell  
35 amps AC  
16.5  
Standard models  
Range: 01 to 35  
Emodels  
Range: 01 to 18  
J & Kmodels  
Range: 01 to 40  
Wmodels  
Range: 01 to 18  
Sets the maximum AC amps allowed to be delivered to the utility grid from a solar array and/or the  
batteries during utility interactive operation. This is only used if the SELL mode is enabled. If batteries are  
being soldinto the utility grid, this setting together with the SET BATTERY SELL VOLTS DC setting  
determines the depth of discharge the batteries will experience. Note: The default setting will vary  
between models with different continuous output power ratings.  
INFORMATION DISPLAY  
The following information is displayed as additional Menu Items.  
See menu 9 to enable SELL mode. Make sure LBX is above LBCO volts.  
GRID USAGE TIMER (18) MENU HEADING  
The Grid Usage Timer selects when power may be drawn from the utility grid for battery charging. It is  
used only when either the FLT or SELL modes are selected in the SET GRID USAGE menu item under  
the INVERTER SETUP (9) menu heading. Utility Power must be connected to the AC1 for this timer to be  
operational.  
Start Charge  
time  
End Charge  
21:00 time  
21:00  
All Models  
Range: 00:00 to 23:50  
All Models  
Range: 00:00 to 23:50  
FLT mode: After the START CHARGE TIME, the inverter turns on the battery charger, connects the  
utility grid and powers the AC loads from the utility grid and charges the battery to the FLOAT VOLTS DC  
setting. At the END CHARGE TIME, the inverter disconnects from the utility grid and powers the loads  
from the battery.  
SELL mode:  
With the GRID USAGE TIMER enabled (the START CHARGE TIME is different from the END  
CHARGE TIME), the inverter will charge the battery to the FLOAT VOLTS DC setting at the START  
CHARGE TIME. After the END CHARGE TIME, the inverter turns off the battery charger and begins  
to sellpower into the utility grid from the battery (or any other DC sources available and connected to  
the batteries) to the SELL VOLTS DC setting. The current will be limited to a maximum level  
controlled by the MAX SELL AMPS AC menu item setting under the BATTERY SELLING (17) menu  
heading.  
With the GRID USAGE TIMER disabled (the START CHARGE TIME beginning time is equal to the  
END CHARGE TIME), the inverter will use the utility grid (or any other DC sources available and  
connected to the batteries) to maintain the batteries to the FLOAT VOLTS DC setting.  
In the SELL mode, battery voltage will be held near the SET BULK VOLTS DC setting for the adjustable  
ABSORPTION TIME period setting after an AC failure or upon encountering a BULK CHARGE TRIGGER  
TIMER event.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
54  
Rev. C: February 2001  
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MENU SYSTEM  
In either mode, the SET START BULK TIME menu item setting under the BULK CHARGE TRIGGER  
TIMER (15) menu heading can be used to increase the battery charging regulation voltage to the BULK  
VOLTS DC setting.  
Note: By setting the beginning time equal to the ending time, the grid usage timer feature is defeated.  
INFORMATION DISPLAY  
The following information is displayed as additional Menu Items.  
After Start Charge time: SELL mode charges battery. FLT mode charges battery.  
After End Charge time: SELL mode sells battery to AC1. FLT mode drops AC1 and inverts.  
Timer on when start <> end. Timer off when start = end;  
Sell and float modes use timer. SLT and LBX mode ignore timer.  
INFORMATION FILE BATTERY (19) MENU HEADING  
This Menu Heading provides additional information about the battery charging system. It has no user  
adjustable settings.  
INFORMATION DISPLAY  
The following information is displayed as Menu Items.  
Batt temp comp changes battery voltage reading away from actual.  
HBCO resets at: 6v/48, 3v/24 and 1.5v12 under HBCO.  
LowBatt Transfer used in LBX, FLT modes only.  
Goes back to battery at LowBattCutIn (aka LBCI).  
For LBX mode set below LBCI so charger wont cycle batteries up and down set LBCO below.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
55  
Rev. C: February 2001  
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MENU SYSTEM  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
56  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
OPERATION  
OPERATION  
The SW Series Inverter/Charger can be configured as a simple stand-alone unit, working in conjunction  
with your generator to handle loads too large for the generator alone, allowing two-wire or three-wire  
generators to be turned on and off based on battery voltage or loads amp size, or functioning as a utility  
interactive inverter which will allow you to send excess power back to the utility grid. Often, the inverter will  
be set-up to operate in several modes at the same or different times - such as operating as an  
inverter/charger in utility back-up mode with automatic generator control mode and generator support  
mode during extended utility outage periods. The extensive configurations available are described in this  
section will allow you to enhance and customize your inverters particular operation.  
Before operating the SW Series Inverter/Charger, ensure that the unit is installed in accordance with the  
instructions in the INSTALLATION section beginning on page 15.  
THEORY OF OPERATION  
The SW Series inverters employ a new patented inverter design. This design uses a combination of three  
transformers, each with its own low frequency switcher, coupled in series and driven by separate  
interconnected micro-controllers. In essence, it is three inverters linked together by their transformers.  
Micro-  
Controllers  
Bridges are mixedby  
Micro-Controllers  
Controlling the H-Bridges.  
Low  
Frequency  
H-Bridge  
Transformer  
Low  
Frequency  
H-Bridge  
AC  
Loads  
Battery  
Transformer  
Transformer  
Low  
Frequency  
H-Bridge  
Figure 17, TraceSW Series Inverter Simple Block Diagram  
By mixing the outputs from the different transformers, a sine wave is produced. Shown in Figure 18, is the  
output waveform from a TraceSW Series Inverter/Charger. Notice the stepsform a staircase that is  
shaped like a sine wave. The total harmonic distortion in this sine wave approach is typically 3-5%. The  
multi-stepped output is formed by modulation of the voltage through mixing of the transformers in a  
specific order. Anywhere from 34-52 stepsper AC cycle are present in the waveform. The heavier the  
load or lower DC input voltage the more steps there are in the waveform.  
This type of inverter solves many of the problems associated with high frequency or ferroresonant sine  
wave inverters. The low frequency method described has excellent surge ability, high efficiency (typically  
85 to 90%), good voltage and frequency regulation, and low total harmonic distortion.  
The inverter runs in two basic formats: as a stand-alone inverter (converting DC to AC), or as a parallel  
inverter (with its output synchronized to another AC source). In inverter mode, only 60 Hz (50 Hz for export  
units) waveforms are created. As the battery voltage rises, waveforms with progressively fewer steps are  
generated. More steps are used when battery voltage decreases. Since the battery voltage tends to drop  
with increased load, the waveform has increased number of steps with heavier AC loads.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
57  
Rev. C: February 2001  
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OPERATION  
Figure 18, TraceSW Series Inverter Output Waveform  
The inverter is able to synchronize with other AC sources before connecting it to the AC load. The  
frequency of the AC source is tracked and the inverter constantly adjusts its frequency to maintain a lock.  
A normally open contactor is used to parallel the inverters output and the AC source.  
The inverters power topology is bi-directional. If the waveform created by the inverter has a higher voltage  
than the paralleled AC source, then power flows from the batteries to the load. If the waveform generated  
has a lower voltage than the AC source, power flows from the source to the battery. The various modes of  
operation use different algorithms for determining the size of the waveform to be created by the inverter. In  
battery charger mode, for example, waveforms smaller than the AC source are created to cause current to  
flow into the batteries. This process is fully regulated to provide a three-stage charge cycle. If the level of  
AC current exceeds the user programmed generator or grid size, and then the inverter will switch to a  
generator support mode and create waveforms that are larger than the AC source. This causes power to  
flow from the batteries to the AC loads to prevent overloading of the AC source.  
In utility-interactive mode, the inverter can operate as a battery charger or paralleled AC source to the  
utility grid. If an external source such as solar panels attempts to raise the batteries above the float voltage  
setting, the inverter will try to hold the battery voltage at the float voltage level by sellingthe excess  
power into the utility grid. This is done by increasing the inverters output voltage level. This moves the  
excess DC power from the solar array to the AC utility grid, preventing the battery from being overcharged.  
If the utility grid connected to the inverter is de-energized, the inverter can not regulate the battery voltage.  
Some external control device, such as TraceC40 Load/Charge controller, must be provided to prevent  
damage to the battery.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
58  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
OPERATION  
POWER VS. EFFICIENCY  
There are two primary losses that combine to create the efficiency curve of the SW Series inverter. The  
first is the energy that is required to operate the inverter at full output voltage while delivering no current.  
This is the no load or idle power. At low power levels, the idle power is the largest contributor to efficiency  
losses. At high power, the largest source of loss is a result of the resistance in the transformer and power  
transistors. The power lost here is proportional to the square of the output power. For example, losses at  
2000 watts will be four times higher than losses at 1000 watts. This graph represents a typical inverters  
efficiency while operating resistive loads. Inductive loads such as motors are run less efficiently due to the  
impact of power factor losses.  
100%  
90%  
80%  
70%  
60%  
50%  
40%  
30%  
20%  
10%  
0%  
Power (VA)  
Figure 19, TraceSW Series Efficiency Curves  
The SW Series offers an extremely good efficiency curve. The inverter reaches high efficiency at very low  
AC load levels, which is important because the inverter often spends the majority of the time at the lower  
power range. The high efficiency is maintained over a wide power range. Only when operating at high  
power levels at or above the continuous power levels does the efficiency begin to drop off. Since this  
usually only occurs for short periods of time, the impact may be negligible.  
If your application involves the inverter powering heavy loads for significant periods of time, selecting a  
model with a higher continuous power rating and a higher DC input voltage would improve the operation of  
the system. Since the low power efficiency of all the SW Series is extremely good, oversizing the inverter  
does not reduce system performance.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
59  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
OPERATION  
INVERTER CAPACITY VS TEMPERATURE  
The current protection circuit in the SW Series Inverter/Charger is temperature compensated, therefore  
the maximum sized load that the inverter can run changes with temperature. As the temperature of the  
power devices (FETs) increase, the allowable current is reduced. When the available current is reduced,  
the capacity of the inverter to run loads is reduced.  
The graph below shows the effect temperature has on the inverters capacity to run loads, notice that the  
inverter reduces its capacity at temperature above 25 °C. The temperature derating graph assumes that  
the inverter is at sea level and the airflow to the inverter is unrestricted.  
Temperature Derating for SW Series Inverters  
120  
100  
Percent  
of  
total  
rated  
power  
capacity  
80  
60  
40  
20  
0
25  
32.5  
40  
47.5  
55  
62.5  
70  
77.5  
85  
92.5  
100  
Temperature °C  
Figure 20, Inverter Capacity vs. Temperature  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
Page  
60  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
OPERATION  
OPERATING MODES  
The SW Series Inverter/Charger can be used in a wide variety and combination of operating modes:  
Inverter Mode - DC to AC inverter with sine wave output, high starting surge, power saving search  
mode, low idle current, and very high efficiency DC to AC conversion.  
Charger Mode - Low AC current distortion, three stage, temperature compensated, high amperage  
battery charger.  
Inverter/Charger Mode - Automatic transfer from inverter to battery charging upon presence of utility  
or generator AC power source.  
Generator Support Mode - Automatic no glitchswitching from charger mode to inverter mode  
allowing the inverter to assist the generator in starting and powering large loads. Adjustable generator  
support current and voltage thresholds.  
Automatic Generator Control Mode - Automatic generator starting, based on the battery voltage  
reaching an adjustable voltage setting or the AC loads exceeding an amperage setting. Both start  
conditions include adjustable time delays. Once started, the inverter operates in battery charger mode  
until battery is charged to the float stage or until the AC load is reduced. The generator is then shut off  
and the loads are powered from the battery through the inverter. Automatic generator exercising of the  
generator and adjustable quiet time period to reduce generator operation may be programmed in the  
setup menu.  
Utility Backup Mode - Phase synchronized fast AC transfer switching for utility backup power supply  
applications. Includes adjustable AC transfer voltage and line conditioning ability.  
Utility Interactive Mode - Excess power from charging sources or stored power from the battery can  
be soldback into a utility grid. Also allows selling of the stored energy in the battery during a specific  
time period.  
Energy Management Mode - Onboard clock to set inverter and charger operating time periods. This  
mode can be used with time of daymetering to shift energy consumption to off-peak periods.  
Peak Load Shaving Mode - Used to limit the draw of AC loads from a utility grid by powering it from  
the batteries. The batteries are recharged when the AC loads are reduced. This can levelthe load  
on a utility.  
Low Battery Transfer Mode - Automatic transfer of the AC loads from the batteries to the utility when  
the system reaches an adjustable low battery voltage setting. Independent settings allow control of  
when the AC loads return to battery once it is recharged.  
Often, the inverter will be set-up to operate in several modes at the same or different times - such as  
operating as an inverter/charger in utility back-up mode with automatic generator control mode and  
generator support mode during extended utility outage periods.  
ADDITIONAL FEATURES  
Numerous additional features are provided to enhance and customize the inverter's operation for the  
various operational modes:  
Automatic generator control system with adjustable quiet time period to reduce generator operation.  
Three-stage battery charging with fully adjustable charge settings and battery temperature sensing.  
AC and DC voltmeters and AC ammeters to allow monitoring of inverter, generator, and utility grid.  
On-board 24-hour clock for programming of generator quiet time and utility interactive modes.  
Adjustable sellback current level for utility interactive mode.  
Two separate AC inputs for utility and generator sources with utility priority.  
Three independently adjustable auxiliary signal relays for controlling charging sources, loads etc.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
61  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
OPERATION  
INVERTER MODE  
BATTERY  
INVERTER  
AC LOADS  
DC  
AC  
IN BRIEF  
The inverter makes a stepped approximation to a sine wave. The number of steps typically varies from 34  
to 52 per cycle. Lower battery voltage and/or higher output power level increases the number of steps.  
Higher battery voltage decreases the number of steps. Distortion varies from 3% to 5%. The inverter is  
able to control the AC output voltage, allowing the inverter to also sell power into a utility grid or assist  
during the operation of heavy loads by operating in parallel with another AC power source such as a  
engine powered generator.  
SEARCH MODE CONTROL  
An automatic search mode circuit is available to minimize the power draw of the inverter when no loads  
are being operated. This reduces the power consumption from 16 watts with no load to less than 1 watt  
(when using the default settings). To do this, the output is reduced to pulses of a single AC cycle with an  
adjustable delay between pulses. These pulses are used to detect the presence of a load. When a load is  
detected, the inverters output goes to full 120 VAC output. The sensitivity of the detection circuit and the  
spacing of the pulses are user adjustable using the Control Panel.  
This feature can save a considerable amount of power, particularly in smaller systems that do not have  
loads operating all of the time. In larger systems, this feature may not result in as much savings. If  
continuous operation of an AC load is required (such as when powering a microwave clock, VCR timer,  
computer, or fax machine), then using the search mode is not recommended.  
To enable the search mode: Select SRCH mode from the SET INVERTER menu item, accessible by  
pushing the red ON/OFF MENU button. Pressing the red ON/OFF MENU button can also access the  
SRCH mode. It is also located as the first menu item under the INVERTER MODE (1) menu heading.  
Pressing the red ON/OFF MENU button again will move the cursor one position to the right. The SET  
POINT buttons can also be used to move the cursor right or left. To disable the search mode, select ON  
from the SET INVERTER menu item.  
Successful operation of the system utilizing the search mode requires some initial tuning of the search  
mode settings to match the loads connected in the system. If the loads change significantly, re-tuning of  
the settings may be required. The benefit of the search mode circuit only is realized if the inverter is able  
to enter the energy saving search mode for substantial periods of the day. Occasional checking of the  
yellow INVERT LED operation should be done to ensure that the search mode is being used when all of  
the loads are turned off (it should blink slowly if it is searching for a load).  
SETTING SEARCH MODE WATTS  
The search mode is user adjustable to allow fine-tuning of its operation. The settings are located under  
the INVERTER SETUP (9) menu heading in the SETUP MENU. The following example explains the  
operation:  
Example: With the SEARCH WATTS setting at 32, a 50-watt load will bring the inverter to full output  
voltage. However, a 30-watt load will leave the inverter in its energy saving search mode. If the sensitivity  
is increased by lowering the setting to 16, a 20-watt load will bring the inverter out of the search mode,  
while a 5-watt load will not.  
When in the search mode, the yellow INVERT LED will blink slowly and the inverter will make a ticking  
sound. At full output voltage, the yellow INVERT LED will stay on and the inverter will make a steady  
humming sound. When the inverter is used as an uninterruptible power supply, the search mode should  
be defeated.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
62  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
OPERATION  
Example A: If the SEARCH WATTS is set at 32 and a 30-watt incandescent light is turned on, the inverter  
will detect the light. The initial load of the bulb is much greater than 32 watts when its filament is cold.  
When the light gets bright, the filament heats up and the light becomes a 30-watt load. Since this is below  
the setting of 32, the inverter will not detect it and the light will turn off. This can cause cycling of the  
inverter between on and off.  
Example B: If the SEARCH WATTS setting is 32 and a 40-watt florescent light is turned on, the inverter  
will not detect the light. The light presents a smaller load than 32 watts until the gas in the florescent tube  
ionizes and begins to glow. This problem is more common with the non-electronic type fluorescent bulbs.  
Example C: There are some appliances that draw power even though they are turned off. TVs with instant  
on circuits, microwave ovens with digital displays and VCRs with clocks are examples. These loads can  
present a dilemma. If the SEARCH WATTS is set higher than the combination of these loads, then an  
additional load must be used to bring the inverter out of the search mode before the appliances can be  
turned on. If the SEARCH WATTS is set lower than this combination of loads, then the inverter and the  
loads will be left on. This will put an additional drain on the batteries (three such 15-watt loads would  
amount to an additional 45 amp/hours per 24 hours in a 24 VDC system). One solution is to turn these  
items off by using an extension cord with a rocker switch, a switched outlet, or a circuit breaker for the  
circuit. Unfortunately, this solution does not allow a clock to retain its setting and may cause it to blink  
constantly while operating.  
SETTING SEARCH MODE SPACING  
The SET SEARCH SPACING menu item is calibrated in cycles. To test for loads once each second,  
adjust this setting to 59 (for 60 Hz models); to test for loads about twice a second, adjust the setting to 30.  
NOTE: The lower the search spacing value the less time it takes for the inverter to bring up a load. The  
lower the setting), the greater the power consumption while in the search mode, thus reducing power. The  
factory default value (59) is acceptable for most applications. The range is from 4 to 255.  
LOW BATTERY PROTECTION  
When the actual battery voltage reaches the LOW BATTERY CUT OUT menu item setting for the LBCO  
DELAY period, the inverter shuts off to prevent the battery from being over-discharged. If the inverter is  
setup to automatically start a backup generator (Gen Auto Start Menu), then it will start once the battery  
reaches the LBCO setting for the selected time (30 seconds, etc).  
Any of the following three conditions will return the inverter to normal operation, after a LBCO condition:  
1. Power is applied to the AC HOT IN 1 or AC HOT IN 2 input terminals, allowing the inverter to operate  
as a battery charger.  
2. The inverter is manually restarted by pushing the red ON/OFF button and selecting OFF and then  
SRCH or ON.  
3. Battery voltage rises above the SET LOW BATTERY CUT IN menu item setting.  
While the inverter is shut off due to the battery reaching the LOW BATTERY CUT OUT settings, the red  
ERROR LED will be illuminated. When the battery voltage increases to the LOW BATTERY CUT IN  
setting, the inverter will automatically turn back on and the ERROR LED will turn off.  
ADJUSTING THE LOW BATTERY PROTECTION  
There are three settings used to prevent over-discharge of the battery. These settings are located under  
the INVERTER SETUP (9) menu heading. See the SETUP MENU section for instructions on accessing  
these settings.  
The SET LOW BATTERY CUT OUT menu item determines the voltage level that the battery must reach for  
it to be considered low. The inverter will continue to operate until the voltage has continuously remained  
below this setting for the time period from the SET LBCO DELAY menu item. Once the inverter has shut off,  
the battery voltage must rise above the value from the SET LOW BATTERY CUT IN menu item.  
The default LOW BATTERY CUT OUT setting may be lower than what is often recommended for many  
applications by battery manufacturers. It is set to allow maximum performance from the inverter, not to  
maximize the life of the battery. If the system is properly designed, the inverter should not reach the LBCO  
setting very often. If the system is expected to utilize the LBCO control on a regular basis, then increasing  
this setting is recommended.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
63  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
OPERATION  
CHARGER MODE  
AC SOURCE  
CHARGER  
BATTERY  
AC  
DC  
IN BRIEF  
When AC power is available, the inverter can operate as a very powerful battery charger with low current  
distortion. Power is drawn over the full AC cycle. This improves the performance with low AC input voltage  
or with small generators.  
The SW Series Inverter/Charger includes the ability to automatically back-offthe battery charger to  
prevent overloading a generator or tripping a circuit breaker when other AC loads are being operated  
through the inverter. This improves system reliability and allows greater use of the power available. The  
charger will also be turned off if the AC voltage drops to an adjustable lower limit VAC setting.  
THREE STAGE CHARGING PROCESS  
The charging cycle uses three stages. During the initial "Bulk Charge" stage, the inverter charges at  
maximum rate allowed by the SET MAX CHARGE AMPS AC setting. This causes the battery voltage to  
rise over time. After the battery voltage nears the SET BULK VOLTS DC setting, the charger starts the  
second or Absorptionstage. During this phase, the charge rate is gradually reduced while the battery  
voltage is held near the bulk voltage setting. This ensures that the battery is fully charged. The final "Float"  
stage is initiated when the battery has been held near the SET BULK VOLTS DC setting for the  
adjustable ABSORPTION TIME period setting. At this point, the battery voltage is allowed to fall to the  
FLOAT VOLTS DC voltage setting, where it is maintained until another bulk charge cycle is initiated. This  
reduces gassing of the battery and keeps it fully charged. A new three-stage charge cycle is initiated after  
an AC source is reapplied to the AC HOT input terminals, or daily if the BULK CHARGER TRIGGER  
TIMER (15) is enabled and if AC power is available continuously.  
Bulk Stage  
Absorption Stage  
Float Stage  
Charging  
Bulk Volts Setting  
Started  
Float Volts Setting  
Reduced Voltage  
Absorption Time  
Constant Voltage  
DC Voltage  
Increased Voltage  
Max Charge Amps  
Setting  
If a generator was started automatically by the  
inverter to charge the battery, it will be shut off when  
the charger reaches the float stage after the  
bulk/absorption period. (GENERATOR must be in  
AUTO mode)  
Constant Current  
Reduced Current  
Reduced Current  
AC Current  
Time  
Figure 21, Three-Stage Battery Charging  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
Page  
64  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
OPERATION  
BATTERY TEMPERATURE SENSOR (BTS)  
A plug-in external Battery Temperature Sensor (BTS), which is provided,  
automatically fine-tunes the charging process of the battery charger in  
relation to temperature. When the temperature sensor is installed, the  
charge voltage is adjusted either higher or lower than the BULK and  
FLOAT setpoints based on temperature. The BATTERY TEMP COMP  
VOLTS DC menu item under the METERS (4) menu heading shows this  
adjusted charge voltage.  
If the temperature sensor is NOT installed and if the battery is subjected to  
large temperature variations, a shorter battery life cycle may be expected.  
Install the BTS on the side of the battery below the electrolyte level. It is best  
if the sensor is placed between batteries and if the batteries are placed in  
an insulated box to reduce the influence of the ambient temperature outside  
the battery enclosure. Ventilate the battery box at the highest point to  
prevent hydrogen accumulation.  
The BTS provided may be extended beyond the standard 15 feet by an  
additional 20 feet using standard telephone cables with RJ-11 plugs.  
Figure 22, BTS (Battery  
Temperature Sensor)  
CHARGER ONLY OPERATION  
When the CHG mode is selected, the inverter will operate only as a charger. This is useful for unattended  
operation where a power failure might allow the inverter to drain the batteries by powering an AC load  
unnecessarily. To allow the Charger Only mode, FLT must be selected from the SET GRID USAGE menu  
item under the INVERTER SETUP (9) menu heading in the SETUP MENU (FLT is the factory default  
setting).  
This feature is commonly used in marine applications where the inverter operates a refrigeration system  
from the batteries. Normally, the engines alternators keep the batteries charged. When docked, a shore  
cord is connected to the inverter to power the battery charger and run the refrigerator.  
AC INPUT REQUIREMENTS  
When an AC source is applied to the AC input, the AC1 IN GOOD or AC2 IN GOOD LED indicator will  
blink slowly once the AC voltage has been detected. If the AC source is acceptable, the inverter will  
synchronize to it after a delay period has passed. Once synchronized, the inverter will close an internal  
relay, connecting the AC source to the AC loads, indicated by the green AC IN GOOD LED (ON solid),  
and begin charging the batteries, indicated by the orange BULK LED (ON solid).  
The AC source, connected to the inverters AC HOT IN 1 and AC HOT IN 2 terminals, is used to power  
both the battery charger and the AC loads while the inverter is in the battery charger mode. There are  
several settings, listed below, that involve the AC INPUT. See the USER SETTINGS WORKSHEET on  
page 123 for factory default settings.  
INPUT AC VOLTAGE  
The AC HOT IN 1 and AC HOT IN 2 inputs share the same upper and lower limits for restricting  
connection to an acceptable AC voltage operating window.  
The AC input voltage window is typically set to the minimum / maximum range that the AC loads can  
tolerate - the inverter itself can operate over an extremely wide voltage range. The upper and lower  
settings are adjustable with the Control Panel and are located under the AC INPUTS (11) menu heading  
in the SETUP MENU.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
65  
Rev. C: February 2001  
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OPERATION  
AC CURRENT LEVEL  
The maximum current draw into the AC HOT IN 1 terminal can be adjusted by the SET GRID (AC1)  
AMPS AC menu item. The maximum current draw into the AC HOT IN 2 terminal can be adjusted by the  
SET GEN (AC2) AMPS AC menu item. These adjustments are used to back offthe battery chargers  
AC current draw while other AC loads are being powered through the inverter. This prevents the  
overloading of the AC source and prevents nuisance tripping of the AC source circuit breakers.  
FREQUENCY  
AC HOT IN 1 is the Utility Power connection point. The frequency tolerance is 53 to 67 Hz for 60 Hz  
models (44 to 56 for 50 Hz models). The typical transfer delay is approximately 30 seconds once the AC  
HOT IN 1 terminals are energized. When the SELL mode is enabled from the SET GRID USAGE menu  
item, the transfer delay period is typically 90 seconds and the frequency tolerance is restricted to 58 to 62  
Hz for 60 Hz models (48 to 52 Hz for 50 Hz models).  
AC HOT IN 2 is used as a fuel-powered generator connection point. There is a default 60-second delay  
before transfer occurs. This gives the generator time to stabilize before being loaded. Frequency tolerance  
is 53 to 67 Hz for 60 Hz models (44 to 56 for 50 Hz models). The fuel-powered generator must be stable  
for the inverter to synchronize and connect.  
DELAY PERIOD  
The delay period, approximately 30 seconds, occurs after the AC source has been applied to the AC HOT  
IN 1 terminal. If SELL mode is enabled (from the SET GRID USAGE menu item under the INVERTER  
SETUP (9) menu heading) and a power outage occurs, reconnection back to the utility power will be  
delayed for a period of at least 90 seconds. This delay allows the utility distribution system to stabilize  
before the inverter resumes selling power back to the utility. It is not adjustable.  
The delay period for the AC HOT IN 2 terminal is adjustable through the SET GEN WARMUP SECONDS  
menu item under the GEN STARTING DETAILS (13) menu heading. This allows the generator to reach a  
stable operating condition before being loaded. The default generator warm-up period is 60 seconds.  
Once warmed up, the inverter synchronizes to the generator. If the AC source is not stable, the inverter  
may not be able to synchronize and will not connect. If the generator runs for 5 minutes without the  
inverter being able to connect, then the generator will be shut off and the ERROR LED indicator will be  
illuminated. A GENERATOR SYNC, YES error condition will be displayed in the ERROR CAUSES (5)  
menu heading on the Control Panel.  
RECOMMENDED BATTERY CHARGER SETTINGS  
The settings for the battery charger primarily depend upon the battery chemistry and construction. Other  
factors such as usage, age and battery bank size need to be considered as well. The battery charger  
settings will automatically adjust if the temperature compensation sensor is installed. If it is not installed,  
the settings should be adjusted manually to allow for the typical battery temperature. This may require  
seasonal readjustment for optimum performance.  
The default settings are typical values for liquid, lead acid battery applications. They will work satisfactorily  
for many systems.  
CAUTION: To prevent battery damage and achieve maximum performance, adjust the battery  
charger settings to the manufacturers recommendations. NiCad (or alkaline) battery users must  
also adjust the SET TEMP COMP menu item setting. The battery charger settings are located  
under the BATTERY CHARGER (10) menu heading in the SETUP MENU.  
The SET MAX CHARGE AMPS AC menu item will need to be reduced if you are using a small battery  
bank. High charge rates can cause a small battery to overheat. This may cause damage and is not an  
efficient way to recharge the battery. With the Control Panel, adjust the charger for a maximum rate that is  
less than 1/5 of the battery capacity for efficient recharging. For example, if the battery is rated at 500  
amp-hours, set the maximum charge rate for 100 amps DC. Since the setting is adjusted in amps AC  
drawn by the battery charger, divide the DC charge rate by 8 for 12 volt systems, 4 for 24 volt systems and  
2 for 48 volt systems (these factors are for 120 VAC systems and include the power lost in the battery  
charger). If the example battery bank of 500 amp hours was a 24 volt system, the maximum AC amps  
setting should be around 25 amps AC (500 x 1/5 = 100 amps DC, 100 / 4 = 25 amps AC.)  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
66  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
OPERATION  
Once the battery voltage nears the BULK VOLTS DC setting, the voltage will be held at this level while the  
current into the battery tapers off. The time allowed for this tapering period is called the ABSORPTION  
TIME period. This setting is very important for systems which use generators since it determines how long  
a generator will run and when the generator shuts off. Using a generator to tricklecharge a battery is not  
efficient and should be avoided. Some users may want to decrease the ABSORPTION TIME to keep  
generator-running time to a minimum. This may result in the batteries not being fully charged. The higher  
the BULK VOLTS DC setting and the longer the ABSORPTION TIME period, the more fully charged the  
battery would be when the charger is shut off. Often, the generator is used only to BULK CHARGEthe  
battery and the solar array is allowed to trickle charge the battery to a full charge condition.  
The following chart provides a guideline in setting the battery charger settings for several different types of  
batteries. The battery manufacturer is the best source of information and should be consulted if your  
battery type is not shown. Since the settings also depend on the system design, other factors may apply.  
Table 4, Charging Setpoints For Common Battery Types  
TYPICAL BULK AND FLOAT SETPOINTS FOR COMMON BATTERY TYPES  
Battery Type  
Bulk Volts  
14.1 VDC BULK  
14.4 VDC BULK  
14.4 VDC BULK  
14.6 VDC BULK  
16.0 VDC BULK  
Float Volts  
13.6 VDC FLOAT  
13.4 VDC FLOAT  
13.4 VDC FLOAT  
13.4 VDC FLOAT  
14.5 VDC FLOAT  
Equalizing Charge Process  
Not Recommended - Consult manufacturer  
Charge to 15.5 VDC or as per manufacturer  
Not Recommended - Consult manufacturer  
Charge to 15.5 VDC or as per manufacturer  
Consult manufacturer  
Sealed Gel  
Lead Acid battery  
A.G.M.  
Lead Acid battery  
Maintenance-Free RV/Marine  
Lead Calcium Battery  
Deep-Cycle, Liquid Electrolyte  
Lead Antimony Battery  
NiCad or NiFe Alkaline Battery*  
(using 10 cells in series)  
Note: Values shown are for 12 volt systems. For 24 volt systems multiply the settings shown by 2.  
For 48 volt systems multiply the settings shown by 4. These settings are guidelines, refer to your  
battery manufacturer for specific settings.  
EQUALIZING BATTERIES (UNSEALED OR VENTED BATTERIES ONLY)  
In many of the inverter/charger applications, batteries are subjected to less than ideal operating  
conditions. This can result in significant differences in the state-of-charge level between the individual  
battery cells. Furthermore, the low charge rates and extended periods at partial charge levels can result in  
both stratified battery electrolyte and inactive areas of battery plate material. If the condition is allowed to  
remain for extended periods of time, the battery can sulfateand become unusable.  
To correct this condition, many manufacturers recommend a periodic equalizationcharge to mix up the  
electrolyte, re-activate unused battery plate material, and bring up all of the individual cells to a full state of  
charge. This requires that the battery be given a controlled overchargeby increasing the charge voltage  
for a limited period of time. The voltage and time required are both dependent upon the amount of  
correction required. The more frequently the batteries are equalized, the lower the equalize voltage and  
shorter the time period.  
Equalizing a battery is only recommended on unsealed or vented batteries. The process will cause the  
electrolyte to gas and will release hydrogen and oxygen in the process. The chance of explosion due to  
the accumulation of these gasses is therefore a realistic hazard. The batteries must be provided with good  
ventilation with no ignition sources present. Some users have found that the battery cell caps are subject  
to clogging during an equalization charge and therefore remove them during this process. Since the  
batteries may rapidly bubble while being charged, it is advised that the battery be refilled only after the  
equalization process is finished (if the battery electrolyte level is low, add enough to cover the plates  
before charging).  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
67  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
OPERATION  
The battery manufacturer or supplier should be consulted before equalizing to provide the recommended  
process and settings. During the equalization process, check the temperature of each battery every hour  
by momentarily feeling the battery case. If the batteries are excessively warm (too hot to keep your hand  
on), terminate the charging immediately. Let the batteries cool before checking the need for further  
equalization charging.  
A manual or automatically controlled equalization charge process is available in the SW Series  
Inverter/Charger. This equalization process can be powered by any AC source. The SET EQUALIZE  
TIME H: M menu item under the BATTERY CHARGING (10) menu heading sets the amount of time that  
the battery voltage must exceed the SET BULK VOLTS DC setting before the equalization process is  
completed. This timer is an accumulating type and does not reset if the voltage momentarily drops below  
the bulk voltage setting. During the equalization process, the voltage is limited to the level of the SET  
EQUALIZE VOLTS DC menu item under the BATTERY CHARGING (10) menu heading.  
To start the equalization process (either manually or automatically):  
Select EQ from the SET GENERATOR menu item, by pressing the green GEN MENU button on the  
Control Panel. During the equalization process, the BULK LED will flash slowly to indicate that the EQ  
position has been selected from the SET GENERATOR menu item.  
To manually equalize the batteries, AC power must be available at the AC HOT IN 1 (utility power) or AC  
HOT IN 2 (generator) terminals. If utility power is not available, the generator must be manually started.  
The inverter uses this power to start the battery charger and begin the equalization process. Equalization  
will continue to run for the amount of time programmed. When the equalization process finishes, the  
FLOAT LED will come on (as long as utility or generator power is still available).  
NOTE: If the generator was manually started to equalize the batteries, it must be manually shut off  
once equalization has completed. Return the cursor to the OFF position in the SET GENERATOR  
menu item (accessible by pressing the green GEN MENU button on the Control Panel).  
If the automatic generator control system is selected, the inverter will complete an equalization charge  
process during the next - automatically started - generator run period.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
68  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
OPERATION  
INVERTER/CHARGER MODE  
UTILITY GRID  
AC  
INVERTER/  
CHARGER  
AC  
AC LOADS  
AC  
DC  
GENERATOR  
BATTERY  
IN BRIEF  
The SW Series Inverter/Charger is capable of automatically transferring AC loads from the inverter to a  
utility grid or generator. Once transferred, the inverter can recharge the battery. The inverter/charger can  
transfer upon the availability of AC power (FLT mode), either at a specific time each day (using the GRID  
USAGE TIMER (18) menu heading), or upon a low battery condition (LBX mode).  
TRANSFERRING UPON AVAILABILITY OF AC POWER  
When AC power is supplied to the AC HOT IN 1 or AC HOT IN 2 input, the inverter automatically transfers  
from inverter mode to battery charger mode. Before transferring, the inverter verifies that both the AC  
input voltage and frequency are within tolerance. It then synchronizes waveforms and connects to the  
inverters AC output without interruption of power.  
The FLT mode is the default mode (see the GRID USAGE menu item under the INVERTER SETUP (9)  
menu heading) and may be used with AC power supplied to either the AC HOT IN 1 or AC HOT IN 2  
input. This is the proper mode for most utility connected applications or for use with a back-up generator  
that is being manually or automatically started.  
The SLT mode is used only with AC power supplied to the AC HOT IN 1 input. The SLT mode is selected  
from the GRID USAGE menu item under the INVERTER SETUP (9) menu heading. In this mode, the only  
operational difference is that the battery charger will only be engaged for a single period of time each day,  
set by the BULK CHARGE TRIGGER TIMER (15) menu heading setting. This reduces the power  
consumption of the inverter over the period of a day. It is also used in applications where the slight noise  
of the inverter might be undesirable, such as at night. AC power continues to be passed through the  
inverters transfer relay while the charger is not engaged. If the AC source fails, the inverter will turn on  
automatically and power the connected AC loads. When utility power returns, the AC loads will be  
reconnected to the utility and the battery charger will complete a bulk charge cycle. Once this has been  
completed the battery charger will turn off, but the loads will remain connected to the utility.  
TRANSFERRING BASED ON BATTERY VOLTAGE  
The LBX mode is used only with AC power supplied to the AC HOT IN 1 input. The LBX mode is selected  
from the GRID USAGE menu item under the INVERTER SETUP (9) menu heading. In this mode, the  
decision to transfer to and from charger mode will be based upon the battery voltage. With LBX enabled,  
the SET LOW BATTERY CUT IN VDC setting and the SET LOW BATTERY TRANSFER VDC setting  
determine the DC transfer voltages. When the battery voltage reaches the LOW BATTERY TRANSFER  
VDC setting for more then 20 seconds, the AC loads are transferred from the inverter to the utility. If the  
battery voltage reaches the LOW BATTERY CUT IN VDC setting, the AC loads are transferred from the  
utility to the inverter. The low battery transfer system includes a 20 second delay so that large loads are  
less likely to cause a transfer to the utility grid during motor startup, etc.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
69  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
OPERATION  
While connected to the utility, the battery charger will be engaged. Some applications may want to allow  
the alternate power source (solar, wind or hydro) to recharge the battery instead of allowing the utility to  
provide the power. The only option is to program the SET MAX CHARGE AMPS AC menu item under the  
BATTERY CHARGING (10) menu heading to the minimum value, 1 amp AC, and set the BULK VOLTS  
and FLOAT VOLTS settings, also under the BATTERY CHARGING (10) menu heading, to a low value.  
TRANSFER TIME  
Normally there is no transfer time from the inverter to utility power or generator. The inverter operates in  
parallel with the AC source at all times - even when battery charging. This allows the transfer from inverter  
to the utility grid or generator to be interruption-free and virtually unnoticeable.  
However, in SELL mode, when the utility grid fails, the inverter will reach the overcurrent protection  
system setting (since it is will try to power everything that is connected to the grid). The inverter will  
momentarily shut off while it opens the internal AC input relay. Once the relay has opened, the inverter will  
begin to operate within a single cycle. This results in a 20 millisecond transfer period. Most AC loads,  
including computers, will not be affected during the transfer.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
70  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
OPERATION  
GENERATOR SUPPORT MODE  
INVERTER/  
CHARGER  
GENERATOR  
AC LOADS  
AC  
AC  
DC  
BATTERY  
IN BRIEF  
The factory default settings are intended to operate the inverter as an inverter/charger connected to a  
generator. When the generator is off, the inverter will power the AC loads from the battery. Once the  
generator is started, the AC loads will be transferred to the generator and the inverter will become a  
battery charger and store the unused power in the batteries for later use. The inverter will automatically  
limit the draw of the battery charger to prevent overloading the generator. When the generator is turned off  
it will be disconnected and the inverter will instantly take over and power the AC loads from the batteries.  
Generator support does not require that the automatic generator control system be used.  
To operate in this mode the system must be set-up as follows:  
Connect the generator AC output to the inverters AC HOT IN 2 and NEUTRAL IN 2 terminals.  
Connect the AC loads to the inverters AC HOT OUT and NEUTRAL OUT terminals.  
Adjust the battery charger parameters to match the requirements of the batteries connected (if the  
factory defaults listed in the technical section are not satisfactory).  
Adjust the SET GEN (AC2) AMPS AC menu item located in the AC INPUTS (11) menu heading, to  
the continuous output ability of the generator. This allows the generator support feature to function  
correctly, preventing the generator from being overloaded. The generators output should be de-rated  
for altitude and if propane or natural gas is the power source. It is best to error on the low side for this  
setting, or to experiment with higher settings after the system has been operational.  
Adjust the SET INPUT LOWER LIMIT VAC located in the AC INPUTS (11) menu heading, to the  
lowest AC voltage that the AC loads can tolerate. If the generator is pulled down to this level while  
powering a load, the inverter will back-off its battery charging or even operate in parallel to reduce the  
load on the generator. Keep in mind that when the inverter supports the generator it uses energy from  
the batteries to power the AC loads. Therefore, when generator support occurs, the batteries can be  
discharging instead of recharging even though the generator is running.  
Adjust the SET INPUT UPPER LIMIT VAC located in the AC INPUT (11) menu heading, to the  
highest voltage that the generator will be allowed to operate without being considered out of tolerance.  
At this voltage the inverter will disconnect to protect the AC loads. When the voltage returns to the  
operating window, the inverter will require a minimum of 20 seconds to re-synchronize and connect  
the generator to the loads.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
71  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
OPERATION  
GENERATOR SUPPORT/OVERLOAD PROTECTION  
This battery charger is quite powerful and, without limits, could overload a generator. When the generator  
is running, it has to power both the battery charger and any connected AC loads. If the AC load current,  
combined with the charge current, exceeds the SET GEN (AC2) AMPS AC setting, the charge rate will  
automatically be reduced to avoid overloading the generator or tripping its circuit breaker.  
If the amount of current demanded by the AC load is greater than the GEN (AC2) AMPS AC setting, the  
inverter is capable of supplementing the generators power. The inverter attempts to hold the current  
drawn from the generator at the setting of the GEN (AC2) AMPS AC. This allows the generator to start  
larger loads than it could normally and reduces the load on the generator during motor start-ups.  
Generator support is also available if AC voltage falls to the SET INPUT LOWER LIMIT VAC. In this case,  
the inverter will assist the generator as long as there is power flowing from the generator to the load. This  
is typically used when a large AC load is being operated and the generators AC output voltage drops.  
For example, if you have a 20 amp generator and the GEN SIZE AMPS AC setting is at 15 amps, the  
inverter will start providing additional power from the batteries whenever the load reaches 15 amps or  
higher (even though it may not be required). When setting the GEN SIZE AMPS AC value, allow for  
headroom but do not set the value too low.  
While the inverter is supporting the generator, the BULK or FLOAT LED Indicator will remain on even  
though the inverter may not be battery charging. The INVERTER/CHARGER AMPS AC meter will indicate  
the support process by displaying negativecurrent flowing from the inverter to the loads. The INPUT  
AMPS AC will also drop during this process while the LOAD AMPS AC remains the same.  
120 VAC VS. 120/240 VAC GENERATORS  
In the US, generators are available with either 120/240 VAC split phaseor 120 VAC only output. Some  
generators can be rewired in the field, or have a switch, for changing from one output to the other. If a  
system uses only one inverter, having the generator put out all of its power at 120 VAC is advantageous. If  
two inverters are used, having the generator wired for 120/240 VAC output is better.  
If you are using one inverter and can not rewire your generator for 120 VAC, or have a combination of 120  
and 240 VAC loads which need to be operated, you may need to include a balancing transformer to allow  
full use of the generator output at 120 VAC. This allows the battery charger to use power from both  
halvesof the generator, instead of only half of it. Xantrex offers a balancing transformer (Part Number T-  
240) for this purpose. See OTHER PRODUCTS section on page 129 or contact your inverter supplier for  
more information.  
If your generator can be wired for 120 VAC output and you are using only one inverter, 240 VAC loads can  
be operated from the system by using a transformer in a step-up configuration. This is common for deep  
well submersible well pumps. If the step-up is done on the pump side of the pressure switch or manual  
switch for the pump (run 120 VAC through the switch then step it up to 240 VAC), the transformer will not  
interfere with using the search mode or increase idle current draw by the inverter when the pump is off.  
When two inverters are operating in a series stackedconfiguration (120/240 VAC); each inverter  
operates as a separate inverter. One inverter can be battery charging with the excess power from one half  
of the generator, while the other inverter is supporting the generator by operating in parallel to support a  
heavy 120 VAC load on that half of the system. This allows greater utilization of limited system capacity  
and is very useful when starting large 120 VAC loads such as water pumps or compressors.  
Two 120 VAC/60 HZ inverters can be used to provide 240 VAC. This provides both 120 and 240 VAC  
since a center neutralis provided between the two inverters. If a 240 VAC only AC source is connected  
to the AC input terminals of the inverter without this center neutral, unacceptable operation will result. To  
allow connection of a 240 VAC only source, a small (500 VA) autotransformer must be connected across  
the 240 VAC input and to the AC neutral terminals of the inverters. This will allow the inverter to operate  
properly. No transformer is required on the AC output side - the 240 VAC can be taken directly from the  
two AC hot output terminals (one from each inverter).  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
72  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
OPERATION  
AUTOMATIC GENERATOR CONTROL MODE  
AC  
INVERTER/  
CHARGER  
GENERATOR  
AC LOADS  
AC  
CONTROL  
DC  
BATTERY  
IN BRIEF  
Automatic start/stop control of a back-up generator can be used with any of the other operating modes. If  
used with an application that includes utility power, the generator will be started only if the utility power is  
not available. It is not possible to use both generator and utility power at the same time. If the generator is  
manually started while the inverter is connected to utility power, the inverter will ignore the generator and  
not connect to it. With utility power connected to the AC HOT IN 1 terminals, the automatic generator start  
and stop control is disabled.  
Extensive control of automatic generator operation is available through the items under the menu  
headings GEN AUTO START SETUP (12), GEN STARTING DETAILS (13) and GENERATOR TIMER  
(7). The generator can be set to start based on four different low battery voltage levels with different delay  
times for each. A quiet time period can be set that restricts the generator from starting during defined  
hours of the day. The generator will be started during the quiet time period only if the battery voltage  
reaches the setting of the SET LOW BATTERY CUT OUT VDC MENU ITEM for a continuous 30-second  
period of time.  
To operate in this mode the system must be set-up as follows:  
Connect the generator AC output to the inverters AC HOT IN 2 and NEUTRAL IN 2 terminals.  
Connect the AC loads to the inverters AC HOT OUT and NEUTRAL OUT terminals.  
Select AUTO from the SET GENERATOR menu item, accessed by pressing the green GEN MENU  
button. The AUTO mode is disabled if the CHG mode under INVERTER MODE (1) menu heading is  
selected.  
Adjust the battery charger parameters to match the requirements of the batteries connected (if the  
factory defaults listed in the technical section are not satisfactory).  
Adjust the SET GEN (AC2) AMPS AC menu item, located in the AC INPUTS (11) menu heading, to  
the continuous output ability of the generator. This allows the generator support feature to function  
correctly, preventing the generator from being overloaded. The generators output should be derated  
for altitude and if propane or natural gas is powering it. It is best to error on the low side for this  
setting, or to experiment with higher settings after the system has been operational.  
Adjust the SET INPUT LOWER LIMIT VAC menu item, located in the AC INPUTS (11) menu  
heading, to the lowest AC voltage that the AC loads can tolerate. If the generator is pulled down to this  
level while powering a load, the inverter will back-off its battery charging or even operate in parallel to  
reduce the load on the generator. Keep in mind that when the inverter supports the generator it uses  
energy from the batteries to power the AC loads. Therefore, when generator support occurs, the  
batteries can be discharging instead of recharging even though the generator is running.  
Adjust the SET INPUT UPPER LIMIT VAC menu item, located in the AC INPUT (11) menu heading,  
to the highest voltage that the generator will be allowed to operate without being considered out of  
tolerance. At this voltage the inverter will disconnect to protect the AC loads. When the voltage returns  
to the operating window, the inverter will require a minimum of 20 seconds to re-synchronize and  
connect the generator to the loads.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
73  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
OPERATION  
GEN CONTROL RELAYS  
CAUTION: All circuits connecting the auto generator control system MUST be protected  
with fuses rated at 5 amps or less. The warranty does not cover damage to these relays.  
Fuses should be located as close as possible to the point of connection to the larger conductors  
providing power from the battery. A fuse must be used, even if the circuit is providing only a dry  
contactor groundconnection - it will prevent damage if the connection is miswired or if the  
cable connecting the inverter to the generator is damaged.  
The generator control relays are not intended to directly control the starter motor or operate the ignition  
system - rather they are used to send a signal to operate the coil of another higher amperage device  
which does the actual switching of power. For location and wiring information on the GEN CONTROL  
RELAYS, see AUXILIARY AND GENERATOR CONTROL RELAY on page 14.  
The SW Series Inverter/Charger provides two relays, labeled RY7 and RY8, to allow starting of many  
types of generators. Two LED indicators provide status indications whether RY7 or RY8 have been  
energized.  
The relay labeled RY7 is used to provide either a STOP signal or a RUN signal. It can also be used to  
provide a GLOW signal on diesel generators with glow-plugs. The relay labeled RY8 is used to provide a  
crank signal for the starter of the generator engine. It is not used on two-wire type (auto cranking)  
generators. The COM (common) terminals of the relays are separated and both the N.O. (normally open)  
and N.C. (normally closed) contacts of the relays are provided.  
It is much easier to make the connections to the generator if a remote control terminal or connector is  
available on the generator. This sometimes requires that the generator optional remote control be  
purchased. This also allows examination of how the generator remote control works - which is what the  
inverters generator control system in the inverter must duplicate.  
Connection of the GEN CONTROL RELAYS to the generator remote control also eliminates the need to  
modify the generator and violate the warranty of the generator.  
You should also add a switch to allow disabling of the automatic generator control system at the generator  
to allow local control of the generator, preventing starting while servicing, etc. Many generators include this  
switch with the optional remote control.  
GENERATOR STARTING SCENARIOS  
The generator can be set to start based on the four following scenarios:  
AUTOMATICALLY  
(1) AC Current: The generator starts whenever the current travelling through the inverter to the AC  
loads remains above the LOAD START AMPS AC setting for the selected LOAD START DELAY  
MIN period. The current can be monitored by the LOAD AMPS AC menu item under the METERS  
menu. The generator will start, unless the timer is in the quiet timeperiod, at which time it will only  
start if the READ LBCO 30 SEC START VDC setting is reached. Whenever the generator starts  
automatically, based on load amps, it will shut off once the load current drops below the LOAD  
START AMPS value for the selected LOAD STOP DELAY MIN period.  
(2) Battery Voltage: The generator starts whenever the battery voltage reaches one of the four  
adjustable low battery voltage levels for the selected delay periods (24 hours, 2 hours, 15 minutes, or  
30 seconds). The low battery voltage levels are set under the GEN AUTO START SETUP. Actual  
battery voltage can be monitored from the BATTERY ACTUAL VOLTS DC menu item under the  
METERS menu. The generator will start, unless the timer is in the quiet timeperiod, at which time it  
will only start if the SET LOW BATTERY CUTOUT VDC or READ LBCO 30 SEC START VDC  
setting is reached. Whenever the generator starts automatically, based on low battery voltage it will  
shut off once the BULK and ABSORPTION stages of the battery charging have completed, thus  
fully recharging the batteries.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
74  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
OPERATION  
(3)  
Time (Exercise Period Days): The generator is automatically started at a pre-selected time  
whenever it exceeds a set number of days without running. Once the start command is initiated,  
the generator starts and runs for 15 minutes to ensure that it remains fully operational and that the  
generators starting battery is maintained at an optimal state of charge. To set generator start  
time, go to END QUIET TIME under the GENERATOR TIMER menu. To set the number of days  
between exercise periods, go to SET EXERCISE PERIOD DAYS under the GEN AUTO START  
SETUP menu. If the value is set to 10, the generator will start every tenth day of continuous non-  
operation. To disable this feature, set the value to zero.  
MANUALLY  
(4) Manual Start The generator can be manually started by selecting ON from SET GENERATOR  
directory under the GENERATOR MODE menu. In manual mode, the generator MUST be  
manually switched OFF by selecting OFF from the SET GENERATOR menu item.  
GENERATOR STARTING AND STOPPING CONFIGURATIONS  
Two different generator start routines are available to allow use with a wider variety of generator types.  
The sequence of closing and opening of the RY7 relay changes depending upon what position the  
underlining cursor is in from the SET RY7 FUNCTION menu item under the GEN STARTING DETAILS  
(13) menu item. The choices are GLOWSTOP or RUN.  
When RUN is selected as the function of the RY7 relay, the RY7 COM and RY7 N.O. contacts remain  
closed while the generator is running. This is usually wired to the ignition system of the generator engine  
and/or a fuel solenoid valve. The normally closed contacts of this relay are also available on the terminal  
block, marked RY7 N.C. The normally closed contact is open (not connected to the common terminal)  
while the generator is running. When the generator is off, the RY7 N.C. terminal is connected to the RY7  
COM terminal. This configuration is useful for starting many HONDA brand generators as well as some  
others. This should also be used to select when the RY7 COM and RY7 N.O. contacts are used to control  
a two wire (auto crank) type generator.  
When GLOWSTOP is selected as the function of the RY7 relay, the RY7 COM and RY7 N.O. contacts  
remain open while the generator is running. The contacts close only when it is time for the generator to be  
stopped. This is useful for generators that require a stop signal to shut down the generator. The  
GLOWSTOP configuration is useful for starting ONAN brand generators.  
The GLOWSTOP setting can also be used for diesel generators. The RY7 COM and RY7 N.O. contacts  
will be closed during the PRE CRANK SECONDS period. This relay can be used to provide both the  
GLOW and STOP signals. When this is done the generator will be given both GLOW and STOP signals  
before cranking and when stopping. This is done on many diesel generators by their own starting systems.  
You should also check that the control system also powers the glow plugs during the cranking signal - the  
generator manufacturer or dealer can provide more information.  
The terminals RY8 COM and RY8 N.O. provide contacts that remain closed only during the generator-  
cranking period. This is usually wired to the starter solenoid (relay) of the generator engine. This relay  
closes after an initial PRE CRANK delay period (the default MAX CRANKING SECONDS period is 10  
seconds). Relay RY8 will open after a half-second delay, once the inverter senses an AC voltage above  
80 VAC on the AC HOT IN 2 terminals. If the voltage remains for the POST CRANK period, relay RY8 will  
remain open. If the generator doesnt start, it will close again after a POST CRANK delay period. The  
inverter will attempt to start the generator up to 5 times (the number of times the inverter tries to start the  
generator is fixed at 5 attempts). If the required voltage level is not reached, relay RY7 opens (in RUN  
mode) to killthe generator before a restart is attempted. This reduces the chance that the starter motor  
will be engaged on a spinning generator engine. This protection is inherent in the GLOWSTOP mode.  
The generator will be stopped when the battery charger has kept the temperature compensated battery  
voltage near the BULK VOLTS DC setting for the ABSORPTION TIME period.  
When it is time to stop the generator, relay RY7 will open or close (depending on which RY7 FUNCTION  
is selected), stopping the generator. This will occur after a 40 second cool down period. If the generator  
does not stop, the inverter will continue to charge the battery at the FLOAT VOLTS DC.  
The transfer from generator to inverter will be less noticeable if you manually turn off the generator from  
the inverters Control Panel instead of from the generators off switch. This allows the inverter to first  
disconnect the generator before it is turned off, reducing problems with voltage sags during the transition.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
75  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
OPERATION  
GENERATOR AUTO START REQUIREMENTS AND TYPES  
In order for the generator to be automatically started, it must include electric start and an automatic choke.  
An automatic primer system may also be required on natural gas and propane powered generators. The  
generator should also include remote start ability with accessible remote start terminals or a connector.  
Protective systems for low oil pressure, over temperature, starter lockout and over crank control are  
valuable features that will prevent generator damage and increase system reliability. Two wirestart  
generator are recommended highly because of the greater simplicity for automatic starting and because  
they are intended for remote/automatic/unattended operation.  
Generators used can be fueled by gasoline, propane or diesel fuel. Propane is often the best choice for  
residential applications due to the ease of fuel storage and delivery, cost, safety, and ease of starting.  
Since propane is required for the cooking stove, water heater and space heating as well, most residential  
applications will already have a tank and propane service. Gasoline is also common, but can be difficult to  
transport and store on site safely. Most small generators do not hold much fuel in their built-in tanks -  
refitting the generator to use marine outboard motor type fuel tanks is often a good solution for limited fuel  
capacity. This eliminates the need to pour fuel into the tank of a hot generator - which can be very  
dangerous. Diesel is a much safer fuel to use and store. Diesel generators can operate with very little  
maintenance and have very long lives. The only problems with diesel are the higher initial cost, difficulty  
with starting in cold weather and possible need for the additional control of the glow plugs before starting.  
Generators can be either air or water-cooled. Water-cooled units are usually more quiet but can require  
more maintenance. Low speed (~1800 / 1500 rpm) generators are preferred by many system designers  
as they often provide longer life due to less mechanical wear and tear.  
TWO WIRE START GENERATORS  
Generator starting requirements can be divided into two categories two-wire start types and three-wire  
start types. The two-wire start type generator is more simple and the easiest to automate. To start, simply  
connect the two remote controlwires together and it starts. The generator provides its own cranking  
control circuit for start-up. To stop, simply disconnect the two wires. The wires can be connected by a  
switch or relay. To enable automatic start, connect the two wires from the generator to Relay RY7 COM  
and RY7 N.O. of the inverter and connect the generator output to AC HOT IN 2 input of the inverter. Two  
wire start generators are specifically designed for unattended operation and usually include all of the  
safety and protection devices from the factory. They are highly recommended due to the ease of hook-up  
and troubleshooting that they allow.  
GEN CONTROL RELAYS  
2 WIRE TYPE GENERATOR  
COM  
N.O.  
5 AMP  
FUSE  
REMOTE  
START/STOP  
TERMINALS  
RY7  
Figure 23, Two Wire Start Wiring Diagram  
When a two-wire start type generator is used, multiple loads can signal the generator to run. A good  
example is a float switch in a water storage tank. When the water level drops, the float switch closes a set  
of contacts, which signals the generator to run. When the tank is full, the float switch opens its contacts  
and the generator stops. The float switch can be used in parallel with the automatic control system of the  
inverter. Either switchcan start the generator. This allows easy automation of the entire system. For this  
type of generator, select RUN from the SET RY7 FUNCTION menu item under the GEN STARTING  
DETAILS (13) menu heading. This is the default setting of this menu item.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
76  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
OPERATION  
THREE-WIRE START GENERATORS  
Three-wire start generators do not include automatic engine cranking control system. Separate  
control of the starter motor requires additional interaction between the inverters auto-control system and  
the generator. This also adds complexity to the installation since more wires must be connected and  
more programming of the inverter is required. Troubleshooting can also be more difficult.  
The automatic control system controls the starter much like a person does when starting a car engine.  
The starter is turned on for short periods of time and then turned off. If the engine starts up while cranking,  
the starter is turned off after a 1/2-second delay. If the engine does not start, the starter is turned on again  
after a delay period. This is repeated until either the generator starts or the maximum number of start  
attempts is reached.  
The common term three-wire startmay be misleading - the actual number of wires used may be four or  
more. It simply means that control of the starter motor is done separately from the generator. Most three-  
wire start generators are not designed for automatic, unattended operation. The generator supplier should  
be consulted regarding additional safety components required for your installation. The automatic control  
system only provides the starting and stopping signals based on what the batteries need. It will not shut off  
the generator if a problem such as low oil pressure occurs.  
Three-wire start type generators can be divided into two basic types - Hondatypes and Onantypes.  
The Honda type uses an automotive type starting circuit as previously discussed. Operating a switch that  
is first turned to RUNand then momentarily held to a STARTposition starts it. Once the engine has  
started, the switch is released and it returns to the RUNposition. To shut down the generator, the switch  
is placed in the OFFposition. For this type of generator, relay RY7 duplicates the RUNposition and  
relay RY8 duplicates the STARTposition, cranking the starter motor. For this type of generator, select  
RUN from the SET RY7 FUNCTION menu item under the GEN STARTING DETAILS (13) menu heading.  
This is the default setting of this menu item.  
GEN CONTROL RELAYS  
HONDA TYPE GENERATOR  
COM  
5 AMP FUSE  
5 AMP FUSE  
STOP SWITCH  
CONTACTS  
RY7  
RY8  
N.O.  
COM  
N.O.  
START SWITCH  
CONTACTS  
Figure 24, Three Wire Start Wiring Diagram (HONDA Type)  
Onan type generators use a different starting sequence. Most Onan type generators use a three-position  
momentary type switch that controls their operation. To start the generator, the switch is held to the  
STARTposition. This energizes the ignition system and cranks the starter motor. Once the engine has  
started, the switch is released and it returns to a center off position. The starter motor then stops cranking  
but the ignition system remains energized. To shut down the generator, the switch is held to the STOP”  
position until the engine dies. Once the handle is released, it returns to the center position. For this type of  
generator, relay RY8 duplicates the STARTposition and relay RY7 is used to duplicate the STOP”  
position (using the common and normally open contacts). Some generators use a similar system with two  
push button switches - one to start and one to stop.  
GEN CONTROL RELAYS  
HONDA TYPE GENERATOR  
COM  
5 AMP FUSE  
STOP SWITCH  
CONTACTS  
RY7  
RY8  
N.O.  
COM  
N.O.  
START SWITCH  
CONTACTS  
Figure 25, Three-Wire Start Wiring Diagram (ONAN Type)  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
77  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
OPERATION  
Most diesel generators are controlled like the Onan type, except that they also require that glow plugs be  
operated before the generator start is attempted. The SW Series Inverter/Charger automatic generator  
control system can also provide glow plug control. The addition of an external relay may be required to  
operate the glow plugs due to the amperage required by the glow-plugs and to separate the stop signal  
circuit. For this type of generator, select GLOWSTOP from the SET RY7 FUNCTION menu item under the  
GEN STARTING DETAILS (13) menu heading.  
3-TO-2 WIRE CONVERTERS  
Another option for three-wire start-type generators is a 3-to-2-wire converter which vary from simple relays  
to advanced microprocessor types. Onan offers a simple 3-to-2-wire converter that works well for many  
installations. Universal 3-to-2 wire converters can be used with virtually any generator as well as control  
glow plugs for diesel generators. These also feature additional system components to signal the  
generator control system to start.  
GENERATOR CONTROL SEQUENCE  
The relays close in a specific sequence to start the generator. Some of the timing periods are adjustable  
through the GEN STARTING DETAILS (13) menu heading. GLOWSTOP has been added to the  
sequence for diesel generator applications. RY7 can be configured for either RUNor GLOWSTOP”  
operation. The two control relays complete the following sequence:  
The auto generator control sequenceis initiated if the battery voltage remains below the Set start volts DCsetting (unless  
Start/End Quiet time h:mis enabled) for the required period of time or the Read LBCO 30 sec start VDCsetting for 30 seconds;  
or if the load amps reaches the Load Start amp ACsetting longer than the Set Load Start delay minperiod. The manual  
generator control sequence is initiated if generator is manually turned on via Set Generatorto ON.  
First auto  
generator  
start  
The generator will stop  
immediately with an  
inverter fault or if Set  
Generatoris set to  
OFF. Also a "Kill Before  
Cranking" signal is  
enabled before the next  
'auto generator start  
attempt'  
Second  
auto  
generator  
start  
The auto generator stop sequence  
is initiated if: (1) The battery  
voltage has been held at the Set  
Bulk volts DCsetting for the Set  
Absorption time h:mperiod or (2)  
The load amps drops below the  
Load Start amps ACsetting for  
longer than the Set Load Stop  
delay minperiod.  
Next auto  
generator  
Start  
sequence  
has been  
initiated  
attempt’  
attempt’  
RY7  
OFF  
OFF  
ON (engages to the N.O. position)  
OFF (engages to the N.C. position)  
OFF  
ON  
ON  
RUN (or)  
GLOW-  
STOP  
ON  
ON  
OFF  
START  
DELAY  
PERIOD  
START  
DELAY  
PERIOD  
SET PRE  
CRANK  
SECONDS SECONDS  
SET MAX  
CRANKING  
SET GEN  
WARM-UP  
SECONDS  
LOCK ON  
GOOD  
DELAY  
GEN-RUN PERIOD  
COOL  
DOWN  
PERIOD  
Generator is  
off and  
waiting for  
next auto  
generator  
start  
SET PRE  
CRANK  
SECONDS  
(Determined by the  
voltage and time  
settings under the  
BATTERY  
CHARGINGheading  
or by the current and  
delay min settings  
under the GEN  
PERIOD  
8 SECS  
FIXED  
10 SECS. 10 SECS  
DEFAULT DEFAULT  
60 SECS  
DEFAULT  
40 SECS  
FIXED  
8 SECS  
FIXED  
10 SECS.  
DEFAULT  
12 SECS  
FIXED  
sequence  
(RY8 goes  
off with a  
1 sec delay  
when  
AC HOT IN  
>80 VAC)  
(Starts once  
voltage  
exceeds  
80 VAC)  
(Only used  
with Set  
Generatorto  
AUTO)  
(Starts when  
AC is within  
108 to 132  
VAC  
AUTO START  
SETUPheading)  
and  
53-67 Hz)  
ON  
OFF (engages to the N.C. position)  
RY8  
Time (Sec) 0  
8
18  
28  
88  
100  
+100 +140  
0
8
18  
GEN CONTROL RELAYS  
OFF = relay contact closed from N.C. to COM (relay disengaged)  
ON = relay contact closed from N.O. to COM (relay engaged)  
Figure 26, Relay RY7 and RY8 Sequence  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
Page  
78  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Rev. C: February 2001  
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OPERATION  
GENERATOR STOP COOL DOWN PERIOD  
When the automatic generator stop system is used to stop the generator, the generator is disconnected  
from the inverter first by opening the AC relay inside the inverter. This allows a very clean transition from  
the generator to the inverter. The STOP signal is provided immediately if the generator is manually shut  
off from the Control Panel. If the generator is shut off automatically the generator will be allowed to run for  
an additional 40 seconds before the STOP signal is provided. This allows the generator to cool down  
before it is turned off. This is very important for turbocharged generators as it allows cooler oil to reach the  
turbo. If the generator does not stop after the 40 second cool down period when the stop signal is sent,  
then the inverter will reconnect to the AC source and remain connected as long as it is available.  
If the generator is stopped manually from the Control Panel, the generator is stopped immediately with no  
cool down.  
GENERATOR ERROR CAUSES  
The red ERROR LED indicator will blink slowly if one of the following generator errors occurs:  
GEN UNDER/OVER SPEED: Indicates that the generator has synchronized with the inverter/charger  
but the frequency is not well adjusted (63 - 67 on the high-end or 53 - 57 on the low end).  
GENERATOR START ERROR: The automatic control system will attempt to start the generator 5  
times by closing the starting relay RY8 for up to the MAX CRANKING SECONDS setting, or the  
inverter senses an AC voltage above 80-volts AC on the AC HOT IN 2 terminal. Once the inverter  
senses 80 volts AC on the AC HOT IN 2 terminal, after a half-second delay, RY8 opens. After  
successfully running for 5 minutes, the start attempts counter resets to zero. If the generator dies  
within the 5-minute period of being started, the inverter will attempt to restart the generator. An  
unsuccessful run is considered a failed start attempt. After 5 start attempts, the ERROR LED  
illuminates and the generator control system shuts down. If the generator dies after successfully  
running for 5 minutes, the start attempt counter will be reset to zero and the inverter will only restart  
the generator if the auto start voltage setting or load amps AC setting is reached for the required time  
delay period.  
GENERATOR SYNC ERROR: Indicates that the generator was running but was not operating within  
the voltage and frequency tolerances and not able to connect (out of sync), or the unit can not  
maintain synchronization (AC voltage or frequency is out of tolerance).  
GEN MAX RUN TIME ERROR: Indicates that the generator ran for a period of time that exceeded the  
SET MAXIMUM RUN TIME setting. This setting is intended to indicate excessive generator operation  
if the system has not been able to fully charge the battery. Operating heavy loads while charging, an  
unstable generator or even low electrolyte levels in the battery can cause this. This may also occur  
with systems that have very large batteries, requiring long charge periods, or systems with small  
generators with limited battery-charging ability. If the default value results in repeated error conditions,  
increasing the SET MAXIMUM RUN TIME menu item setting may be necessary for your application.  
When using the automatic generator control system to complete a equalization cycle, the additional  
time required for the EQ cycle should be considered in order to prevent reaching the SET MAXIMUM  
RUN TIME menu item setting and causing a GEN MAX RUN TIME ERROR. This is an advisory error  
only and does not stop the generator.  
To clear a generator start error, access the SET GENERATOR menu item by pressing the green GEN  
MENU button and move the cursor from AUTO or ON to OFF in the SET GENERATOR menu item. This  
clears all the generator error conditions and resets the start attempts counter.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
79  
Rev. C: February 2001  
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OPERATION  
EQUALIZATION CHARGING, AUTOMATIC GENERATOR CONTROL SYSTEM  
An automatic equalization charge process is available in the SW Series Inverter/Charger. To start the  
equalization process, select EQ from the SET GENERATOR menu item, accessible by pressing the green  
GEN MENU button on the Control Panel.  
During the next automatic generator run period, the inverter can be set to complete an equalization charge  
process. You must first select EQ from the SET GENERATOR menu item. The generator will start the  
equalization process the next time the generator is automatically started and will automatically stop and  
return the cursor to the AUTO position in the SET GENERATOR menu item once the equalization period  
has been completed.  
The SET EQUALIZE TIME menu item under the BATTERY CHARGING (10) menu heading sets the  
amount of time that the battery voltage must exceed the BULK VOLTS DC setting before the equalization  
process is considered to be completed. This timer is an accumulating type timer that does not reset if the  
voltage drops momentarily below the bulk voltage setting. During the equalization process, the voltage will  
be limited to the level of the SET EQUALIZATION VOLTS DC menu item.  
During the equalization process, the BULK LED will flash slowly to indicate that the EQ position has been  
selected from the SET GENERATOR menu item. When the process has finished, the FLOAT LED will be  
on if the generator or utility power is still available.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
80  
Rev. C: February 2001  
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OPERATION  
UTILITY BACKUP MODE  
UTILITY GRID  
GENERATOR  
AC  
AC  
MAIN  
AC BREAKER  
PANEL  
ADDITIONAL  
AC BREAKER  
SUB-PANEL  
INVERTER/  
CHARGER  
AC  
AC  
AC  
AC  
DC  
NON-CRITICAL  
AC LOADS  
CRITICAL  
AC LOADS  
BATTERY  
IN BRIEF  
SW Series Inverter/Chargers provide an excellent utility system backup under the majority of powering  
applications. Whenever a shorted grid condition affects voltage or frequency, the inverter disconnects  
itself from the grid and continues to support the AC load using battery power. Typical transfer time under  
a shorted grid condition is instantaneous.  
Depending upon the type and amount of load, the transfer may, at times, be noticeable. This is due to the  
inverters output reaching the overcurrent trip level as it tries to maintain the load before the internal relay  
transfers to battery power.  
To operate the system in utility backup mode:  
Connect utility AC power to the inverter's AC HOT IN 1 and NEUTRAL IN 1 terminals.  
Connect the AC loads to the inverter's AC HOT OUT and NEUTRAL OUT terminals.  
Adjust the battery charger parameters if the factory default values are not satisfactory. For UPS  
applications with small battery banks, lower the battery-charging rate.  
Adjust the GRID (AC1) AMPS AC menu item to match the amperage of the circuit breaker supplying  
AC to the inverter input. This setting is located in the AC INPUTS (11) menu heading - (See UTILITY  
SUPPORT/OVERLOAD PROTECTION, on page 82).  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
81  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
OPERATION  
UTILITY SUPPORT/OVERLOAD PROTECTION  
This battery charger is very powerful and without limits could draw more current than is available from the  
AC input source. When the utility grid is available, the grid has to power both the battery charger and any  
AC loads connected. If AC charge current combined with any AC load current exceeds the GRID (AC1)  
AMPS AC menu item setting, the charge rate will be automatically reduced to keep from tripping the utility  
grid breaker.  
In addition, the inverter will support utility grid in the event that excessive loads threaten to trip the AC  
breaker. If the amount of power demanded by the AC loads is greater than the GRID (AC1) AMPS AC  
menu item setting, the inverter will contribute power to operate the AC loads. This will limit the AC current  
drawn from the utility system.  
This ability allows the utility line to be sized closer to the typical draw of the system, instead of being sized  
to the maximum load. This may save considerable cost if a utility extension or upgrade is being installed.  
The savings can even offset part or all of the inverter / battery system in some situations.  
While the inverter is supporting the AC loads, the battery will be discharging. Typically, utility line support is  
required for only short period of time during heavy power usage that will not cause the battery to be  
significantly drained.  
USING SLT MODE (SILENT MODE)  
In SLT mode the batteries are charged only once a day, at a time prescribed in the BULK CHARGE  
TRIGGER TIMER (15) menu heading. Selecting SLT in the SET GRID USAGE menu item, located under  
the INVERTER SETUP (9) menu heading enables it. During the rest of the day the battery charger is  
turned off and the utility grid powers the AC loads. If a utility outage occurs, the inverter turns on and runs  
the loads. When power returns, the inverter will return to the SLT mode after it has completed the Bulk  
and Absorption stages of the battery charging process. The advantage of SLT mode is silent operation  
and slightly less power consumption under most conditions and quieter operation since the battery charger  
is off most of the time. The disadvantage of SLT mode is the loss of the natural power conditioning ability  
of the inverter and the ability to back offthe AC input which prevents overloading or circuit breaker  
tripping (except during the time that the inverter is charging). The transition from utility to inverter when an  
outage occurs may also be more noticeable.  
When using this mode, a START BULK TIME must be entered from the BULK CHARGE TRIGGER  
TIMER (15) menu heading. If the timer is defeated by setting it to 00:00, no bulk charging will take place  
on a daily basis except immediately after a grid failure has occurred and the power has been restored.  
The default setting is 00:00 that defeats the BULK CHARGE TRIGGER TIMER.  
BATTERY REQUIREMENTS  
Utility backup applications usually are designed to discharge the battery at a higher rate for a shorter  
duration than alternative energy applications. Typically, batteries capacity ratings are for discharge periods  
of 20 hours. This means that a 100-amp hour battery can deliver 5 amp hours for 20 hours. It cannot  
deliver 100 amp hours for 1 hour. Battery manufactures can provide de-rating curves for their products. If  
the battery is not large enough, unsatisfactory performance may result. For the best performance,  
oversizing of the battery is strongly recommended.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
82  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
OPERATION  
UTILITY INTERACTIVE MODE  
MAIN AC LOADS  
NOT PROVIDED  
WITH BACK-UP  
UTILITY GRID  
AC  
SOLAR ARRAY  
DC  
kWh METER  
AC  
AC  
AC  
OUTDOOR AC  
DISCONNECT  
INVERTER/  
CHARGER  
GROUND FAULT  
PROTECTION  
DC  
DC  
BACKED UP  
AC LOADS  
SUB-PANEL  
OVERVOLTAGE  
PROTECTION  
BATTERY  
DC  
IN BRIEF  
In this mode, SW Series Inverter/Chargers can be used to move power from the DC system into the AC  
utility grid. This is often called sellingpower since the utility pays for the power you produce. It is  
relatively simple to set the inverter up to accomplish this. However, this type of installation is so new that  
many utility companies have not formalized their regulations regarding acceptable installations.  
Regulations will vary from one utility to another. The utility companies have a right and a need to be  
careful about how power is fed into their system. Utility interactive should be done with the assistance  
of your dealer and must be done with the approval of the local utility company.  
As a minimum, an outdoor mounted AC disconnect should be installed at the service entrance or next to  
the utility meter. It should be clearly labeled SOLAR ELECTRIC SYSTEM AC DISCONNECT. This will  
allow utility and emergency personnel to easily and safely isolate the system from the utility grid if required.  
This disconnect should be lockable (by the utility) and installed between the AC HOT 1 INPUT of the  
inverter and the circuit breaker in the AC load center connected to the utility grid. This allows the utility to  
shut off the system if a problem occurs.  
Since a utility interactive installation requires an understanding of your local utility code, limited diagrams  
and details are included in this manual. Consult your utility or your local Xantrex dealer.  
To operate the system in utility interactive mode, set-up the system as follows:  
Connect utility AC power to the inverter's AC HOT IN 1 and NEUTRAL IN 1 terminals.  
Connect the critical AC loads that are required to be backed-up, to the inverters AC HOT OUT and  
NEUTRAL OUT terminals.  
Use the GRID USAGE TIMER (18) and the BULK CHARGE TRIGGER TIMER (15) with the battery  
charger parameters adjusted under the BATTERY CHARGING (10) menu heading to determine the  
battery voltage level you require for your batteries.  
Select SELL from the SET GRID USAGE menu item in the INVERTER SETUP (9) menu heading.  
Adjust the GRID (AC1) AMPS AC menu item located in the AC INPUTS (11) menu heading (See  
UTILITY SUPPORT/OVERLOAD PROTECTION, on page 82) to match the amperage of the circuit  
supplying AC to the inverter input.  
Adjust the AC input voltage parameters using the SET INPUT LOWER LIMIT VAC and the SET  
INPUT UPPER LIMIT VAC menu items, both located in the AC INPUTS (11) menu heading to match  
the AC voltage requirements of your connected utility.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
83  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
OPERATION  
THEORY OF OPERATION  
When SELL mode is selected from the SET GRID USAGE menu item located under the INVERTER  
SETUP (9) menu heading in the SETUP MENU, the inverter will move any excess power not required to  
charge the batteries into the utility grid.  
In SELL mode, the inverter can be thought of as a battery charger that is able to operate in either direction  
- it can send excess power from the battery back into the utility grid instead of drawing power from the  
utility to charge the battery. To regulate the battery charging process, the inverter takes DC power from  
the solar array and converts it to AC power that supplies other AC loads through the utility grid. The  
inverter is more accurately described as a utility interactive battery charger. This means that the inverter  
will control battery voltage whenever utility power is connected and available. If a utility outage occurs, the  
inverter can not control the battery voltage. Some external control must be provided by the system to  
prevent damaging the battery as the solar array tries to overcharge the battery.  
In a solar array configuration, a charge controller is not needed when the inverter is operational in SELL  
mode and utility is connected. If the inverter was turned off, or utility power was to fail, the batteries could  
quickly be over-charged. One of the inverters voltage controlled relays can be used to protect the  
batteries in case of utility failure. It would be programmed to open an additional external relay that controls  
the solar panels at a battery voltage above the battery chargers BULK VOLTS DC setting. Please see the  
OVERVOLTAGE PROTECTION FOR THE BATTERY section on page 89 for more information.  
UTILITY INTERACTIVE ISLANDING PROTECTION  
In utility interactive mode, the inverter is capable of detecting several types of failures.  
Grid shorted - Normally, when the utility power fails, the inverter momentarily tries to power the entire  
neighborhood. This condition looks like a short circuit to the inverter and causes it to reach the  
overcurrent protection setting and shuts off. It then opens its internal relay and disconnects from the  
utility grid. This protective system operates instantly.  
Grid open - The inverter can tell when there is no current being delivered to the grid and it will  
disconnect. This is used when a disconnect switch is opened or the power line which feeds the  
installation is cut. This protective system operates instantly.  
Islanding - This occurs when the grid has failed and the "neighborhood" that the inverter is powering  
requires a power level that the inverter can supply. This condition is called islanding. The islanding  
detection circuit checks grid condition on each cycle. The inverter watches the utility grid and waits for  
it to rise a couple of volts before it begins to invert again. This is done on each cycle when SELL  
mode is activated. Typically, disconnect is achieved in a few cycles after the utility has failed. If a large  
electric motor is connected, it may provide enough generator capacity that the inverter thinks the grid  
is still connected. This can fool this protective system. Two additional protective systems are provided  
to then handle this condition, over/under frequency and over/under voltage detection.  
Over/Under Frequency - Since the inverter is locked onto the frequency of the utility grid, the  
frequency of the islanding system will drift out of regulation in a short amount of time during an  
islanding condition. This protective system may require a couple of seconds to respond. The settings  
are 58 and 62 Hertz for 60 Hertz models (48 and 52 Hertz for 50-Hertz models) and are not  
adjustable.  
Over/Under Voltage - Since the inverter does not try to regulate the voltage of the utility grid while  
selling power into it, the AC voltage will drift out of regulation in a short amount of time during an  
islanding condition. This protective system may require a couple of seconds to respond. The default  
settings are 108 VAC as the lower limit and 132 VAC as the upper limit. These settings are adjustable.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
84  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
OPERATION  
SELLING POWER - FROM A DC CHARGING SOURCE  
The simplest and default operation of the SW Series Inverter/Charger in the SELL mode is to sellthe  
excess power from the charging source to the utility when the batteries are full. In this mode, the battery  
voltage is held to the regulation level determined by the SET BATTERY SELL VOLTS DC setting. Since  
the SET BATTERY SELL VOLTS DC setting is defaulted to the same value as the SET FLOAT VOLTS  
DC setting, the inverter will sell the power from the charging source (wind, hydro or solar, etc.), but will  
hold the battery at a charged level.  
The regulation process can also be accomplished and allow the three stage charging (float, bulk and  
absorption) of the batteries to occur each day by enabling the BULK CHARGE TRIGGER TIMER (15).  
The batteries will be maintained at the SET FLOAT VOLTS DC setting until the SET START BULK TIME,  
which will charge the batteries near the SET BULK VOLTS DC setting until the end of the ABSORPTION  
TIME.  
This operating mode offers the individual system owner with several advantages. The batteries would not  
be cycled thereby increasing their life and the batteries would be fully charged in case of a power failure,  
resulting in greater system efficiency.  
Begin Day  
00:00  
End Day  
23:59  
20:00  
Time  
Set Start Bulk  
Bulk Charge Trigger Timer is  
time  
20:00  
enabled (not the default setting)  
Battery Sell Volts  
Float Volts  
DC Setting  
Bulk Volts  
DC Setting  
DC Setting  
DC Volts  
DC Volts  
Set Float  
Volts DC 13.4 Volts DC 13.4  
Set Battery Sell  
Set Bulk Volts  
DC 14.4  
13.0  
Sell to grid period  
Set Absorption  
when the current from  
the DC source is greater  
than needed to maintain  
the Float/Sell Volts DC  
setting.  
time h:m 02:00  
Charging from the DC  
source (wind, hydro or  
solar) has started  
Absorption Time  
Battery  
charging from  
grid has  
POSITIVE (+) = Inverter is drawing power from grid.  
NEGATIVE (-) = Inverter is selling power to grid.  
Charging from the DC  
source (wind, hydro or  
solar) has stopped  
started  
Max Sell Amps  
AC Setting  
AC amps  
Input  
amps AC  
00  
Set Max Sell  
amps AC  
30  
AC amps to grid (-)  
Max Charge  
Amps AC Setting  
{
{
AC amps from grid (+)  
Set Max Charge  
amps AC  
30  
LEGEND  
Display/Settings  
on Control Panel  
Information  
Figure 27, Selling Power From A DC Charging Source; Hypothetical Time Of Day Operational History  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
85  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
OPERATION  
SELLING POWER - STORED IN THE BATTERIES  
Power stored in the batteries can also be sold into the utility grid. This can be used together with the solar  
array or alone without a solar array. The inverter can be programmed to sell the energy in the batteries at  
a specific time and then to recharge the batteries at another time. Both the discharge level and discharge  
rate can be adjusted to control the battery selling process.  
Selling the power stored in the batteries can be used to level the output of the combined solar array and  
battery system. This is beneficial during conditions of cloudy weather when the solar array output will vary  
with each cloud that passes over. To set-up this ability, adjust the SET BATTERY SELL VOLTS DC menu  
item under the BATTERY SELLING (17) menu heading for the maximum discharge voltage level  
acceptable. The SET MAX SELL AMPS AC menu item should be set for the expected maximum output of  
the solar array. Next, access the GRID USAGE TIMER (18) menu heading to allow setting of the time  
period that the battery will be allowed to recharge during by adjusting the SET START CHARGE TIME and  
SET END CHARGE TIME menu items. Outside of this time period, the inverter will sell the power stored in  
the battery to the utility grid until the voltage reaches the BATTERY SELL VOLTS DC setting.  
This mode can use the battery to maximize the output of the system during a specific period of time. An  
example of these setting follows:  
Begin Day  
00:00  
End Day  
23:59  
Battery charging  
from grid has  
stopped  
Battery charging  
from grid has  
started  
08:00 10:00  
18:00  
20:00  
Time  
Bulk charging  
has started  
End charge  
Start charge  
time  
08:00  
time  
18:00  
Bulk Volts  
DC Setting  
Float Volts  
DC Setting  
Battery Sell Volts  
Set Start Bulk  
time 20:00  
Set Float  
Volts DC 13.4  
DC Setting  
Set Float  
Volts DC 13.4  
Set Bulk Volts  
Set Battery Sell  
Volts DC 12.4  
DC Volts  
DC  
14.4  
Set Absorption  
Charging from the  
DC source (wind,  
hydro or solar) has  
started.  
time h: m 2:00  
Absorption Time  
Max Sell  
Amps Setting  
Max Charge  
Amps Setting  
POSITIVE (+) = Inverter is drawing power from grid.  
NEGATIVE (-) = Inverter is selling power to grid.  
Set Max Sell  
Set Max Charge  
amps  
30  
amps AC  
30  
Input  
amps AC  
AC amps  
00  
AC amps to grid (-)  
{
{
AC amps from grid (+)  
LEGEND  
Display/Settings  
on Control Panel  
Information  
Figure 28, Selling Power Stored In The Batteries; Hypothetical Time Of Day Operational History  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
86  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
OPERATION  
A system that includes 2400 watts of solar array is able to produce approximately 18 amps of AC power at  
120 VAC. The output is most needed from 12:00 noon to 18:00 by the utility. If the GRID USAGE TIMER  
is set to a START CHARGE TIME of 18:00 and a END CHARGE TIME of 12:00 noon, the inverter will sell  
the battery from 12:00 noon to 18:00. The energy in the batteries will be used only if the solar array is not  
able to provide enough power to reach the 18 amps AC (determined by the MAX SELL AMPS AC setting  
under the BATTERY SELLING MENU (17) menu heading. The battery will assist the solar array to meet  
the 18 amps AC MAX SELL AMPS AC setting during the battery sell period. If the battery reaches the  
SELL VOLTS DC setting during the sell period, the AC output current will slowly taper down to the solar  
arrays output level and the battery will not be further discharged. At 18:00, the battery will charge at the  
rate allowed by the SET MAX CHARGE AMPS AC (2 amps AC is the lowest setting allowed). The battery  
will be recharged only to the FLOAT VOLTS DC setting unless the BULK CHARGE TRIGGER TIMER  
(15) menu heading is used to trigger a bulk charge cycle.  
This system offers the utility several advantages. The system can be relied on for a specific amount of  
output at a set time. The AC output of the system from 12 noon to 4 PM will not vary with the level of  
sunlight (after all, the AC loads on the grid do not suddenly drop when a cloud passes over). Only if it is  
extremely cloudy will the system not produce its rated output for the full time period - which would not be  
as important since the ambient temperature would not be as high.  
This operating mode does not provide an individual system owner with many added values. The wear and  
tear on the batteries would be avoided and greater efficiency achieved if the standard sell mode was used.  
BATTERY REQUIREMENTS  
Batteries are required for utility inter-tie operation of this inverter. The batteries can, however, be small if  
the system does not provide back-up power in case of utility failure. Two thousand watt/hours is sufficient  
(100 amp/hours at 24 volts is 2400 watt hours). This can be achieved by using two Group 27sized  
batteries for a 24-volt system. This is a very common size for RV and boat applications. Since the  
batteries are not cycled excessively, sealed batteries may be used with good success.  
CAUTION: If using gelled batteries, the battery charger must be set to the appropriate settings or  
battery damage will occur.  
BATTERY REGULATION LEVEL - SELL MODE  
In the SELL mode, the regulation level of the battery is determined by the charge cycle (FLOAT or BULK)  
and the settings of the BULK CHARGE TRIGGER TIMER (15) and the GRID USAGE TIMER (18).  
The SET START CHARGE TIME menu item setting under the BULK CHARGE TRIGGER TIMER (15)  
menu heading can be used to increase the battery charging regulation voltage to the SET BULK VOLTS  
DC setting. The battery voltage will be held near the SET BULK VOLTS DC menu item setting under the  
BATTERY CHARGING (10) menu heading for the adjustable ABSORPTION TIME period setting upon  
encountering this BULK CHARGE TRIGGER TIMER event or after a loss of AC power to the AC HOT IN  
1 input terminal.  
The inverter will charge the battery to the FLOAT VOLTS DC setting at the START CHARGE TIME with  
the GRID USAGE TIMER enabled (the START CHARGE TIME beginning time is not equal to the END  
CHARGE TIME). This is indicated by the FLOAT LED indicator being on. After the END CHARGE TIME,  
the inverter turns off the battery charger and begins to sellpower into the utility grid from the battery (or  
any other DC sources available and connected to the batteries) to the SELL VOLTS DC setting. The  
FLOAT LED indicator blinking indicates this. The current will be limited to a maximum level controlled by  
the MAX SELL AMPS AC menu item setting under the BATTERY SELLING (17) menu heading.  
With the GRID USAGE TIMER disabled (the SET START CHARGE TIME beginning time is equal to the  
SET END CHARGE TIME) and the inverter in the FLOAT charge cycle, the inverter will use the utility grid  
(or any other DC sources available and connected to the batteries) to maintain the batteries to the SET  
FLOAT VOLTS DC setting. This is indicated by the FLOAT LED indicator being on.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
87  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
OPERATION  
UTILITY INTERACTIVE OPERATION WITH UTILITY BACKUP  
The SW Series Inverter/Charger is capable of operating both as a utility interactive and a stand-alone  
inverter. This allows the system to normally sell the excess power to the utility and, once an outage has  
occurred, provide power to the AC loads from the battery.  
The loads that will be provided with utility backup during outages must be isolated from the non-utility  
backed-up loads. This usually requires the addition of an AC load center sub panel for the output of the  
inverter.  
NOTE: THE BUY AND SELL METERS  
CAN BE COMBINED  
UTILITY INTERACTIVE  
LINE-TIE SYSTEM WITH  
BACKUP OF CRITICAL AC  
LOADS  
INTO ONE TWO-WAY METER  
IF NET BILLING IS ALLOWED.  
kWh METER WITH  
DETENTS (ONE-  
WAY) 120/240  
VAC  
kWh METER WITH  
DETENTS (ONE-  
WAY) 120/240  
VAC  
DESIGNATES  
BI-DIRECTIONAL  
CURRENT PATH  
UTILITY GRID  
120/240 VAC  
BUYMETER  
SELLMETER  
AC DISCONNECT  
(LOCKABLE)  
OUTDOORS NEXT  
TO THE UTILITY  
SERVICE  
SERVICE  
ENTRANCE  
PANEL  
(OPTIONAL)  
ENTRANCE  
kWh METER WITH  
DETENTS (ONE-  
WAY)  
FUSED  
DISCONNECT  
60A/120 VAC  
120/240 VAC  
AC LOADS  
BREAKER  
BREAKER  
120 VAC  
120/240 VAC  
60A/120 VAC 60A/120 VAC  
NEMA 3R  
OUTDOOR TYPE  
PRODUCED”  
CIRCUIT  
BREAKERS  
(FOR HOUSE)  
METER  
FUSED  
DISCONNECT  
60A/120 VAC  
NEXT TO THE  
INVERTER  
#6 AWG  
REQUIRED  
AC SUBPANEL  
FOR UTILITY  
BACK-UP AC  
LOADS  
AC LOADS  
TO BE  
BACKED UP  
120 VAC ONLY  
FUSED  
DISCONNECT  
60A/120 VAC  
AC OUTPUT  
TERMINALS  
AC INPUT  
TERMINAL  
PRODUCED”  
NEXT TO THE  
INVERTER  
TRACE SW-SERIES  
INVERTER/CHARGER  
120 VAC  
METER  
DC BATTERY  
TERMINALS  
WIND  
GENERATOR  
FUSED  
DISCONNECT  
CONTROLLER  
BATTERY  
STORAGE  
SYSTEM  
BATTERY  
DISCONNECT  
SOLAR  
ARRAY  
FUSED  
DISCONNECT  
PV CHARGE  
CONTROLLER  
Figure 29, Utility Interactive Line-Tie System With Battery Backup Flow Diagram  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
88  
Part No. 2031-5  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
OPERATION  
OVERVOLTAGE PROTECTION FOR THE BATTERY IN SELL MODE  
Normally, the inverter will regulate the charging process of the battery by selling excess power into the  
utility grid. The battery will receive a three-stage charge routine as previously described. If the utility grid is  
not available (due to an outage or tripped AC input circuit breaker, etc.) or if the inverter shuts off, then the  
inverter is not able to sell the excess power and the battery voltage will not be regulated, resulting in  
possible overcharging of the battery.  
Therefore, a separate control is required to provide overvoltage protection for the battery when an outage  
has occurred. The AUX Relays in the SW Series Inverter/Charger are designed to control an externally  
connected power relay that would disconnect the solar array and stop the charging process. The voltage  
and hysteresis (difference between opening and closing voltage) are both adjustable. The external relay  
can be either a standard mechanical type or a mercury displacement type, depending on the voltage and  
current required. The mercury displacement type relay is usually required when the system voltage is 48  
VDC or if the current of the solar array exceeds about 20 amps. Multiple relays can be used if the solar  
array is divided into several source circuits (do not parallel relays for higher current). Another option is to  
use a charge controller such as the TraceC40. For more on the C40 MULTI-FUNCTION  
CONTROLLER, see page 129.  
A typically wiring configuration for this overvoltage protection is as follows:  
SOLAR ARRAY  
+P -N  
This circuit does draw a small amount of power all of the time to power the coil of  
the relay. Other circuits are possible but may have other drawbacks. This circuit  
provides protection against overcharging the batteries.  
NORM.  
OPEN  
120VAC  
COIL  
RELA  
AC OUTPUT - NEU  
-N  
AC OUTPUT - HOT  
SW - SERIES  
INVERTER  
5 AMP  
FUSE  
+P  
AUX RELAY 9 COM.  
AUX RELAY 9 N.C.  
+P  
-N  
BATTERY BANK  
Figure 30, Overvoltage Protection for Battery  
AUX RELAYS  
Three voltage-controlled relays are provided to simplify installations that have battery voltage related tasks  
to perform. They are single pole double throw, five amp relays. Both the normally closed and normally  
open contacts are available for each relay. The operation of the relays are individually controlled and  
adjustable via the user menu. The battery voltage at which each of these relays are activated (SET  
RELAY 9, 10 or 11 VOLTS DC) and the number of volts by which the battery voltage must drop before  
the relay is de-activated (R9, R10 or R11 HYSTERESIS VOLTS DC) are both individually adjusted for  
each relay. The three AUX Relays operate independently of the inverter or charger. For location and wiring  
information on the AUX Relays, see the AUXILIARY AND GENERATOR CONTROL RELAY section on  
page 14.  
CAUTION: These relays are not intended to directly control a load or charging source - rather  
they can be used to send a signal or operate the coil of another higher amperage device which  
does the actual switching of the power. A fuse rated at 5 amps or less should be included to  
protect each of the relays. Damage to these relays from overloading is not covered by warranty  
and requires the inverter to be returned to a repair center. This also applies to the generator  
control relays.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
89  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
OPERATION  
ENERGY MANAGEMENT MODE  
INVERTER/  
CHARGER  
AC  
AC  
UTILITY GRID  
AC LOADS  
DC  
BATTERY  
IN BRIEF  
The purpose of this mode is to manage how utility power is used. One method is to charge the batteries at  
a favorable time and then use the power later. This is often desirable when time of day metering is  
available. A solar array is not required, but can be used to reduce the discharging of the battery. Since the  
most expensive power is often during the afternoon, the solar array may be a valuable addition. This mode  
is an alternative to utility interactive systems. This mode does not involve sellingpower into the utility grid  
and therefore does not usually require the approval of the utility. The same system is also able to operate  
as a utility back-up system to provide power when an outage occurs.  
In order to disconnect from the grid during a specific period of the day and operate only as an inverter, a  
window of time is created during which battery charging is allowed. Outside this window, the inverter will  
power the load from the battery. If the battery gets low, the system will transfer back to the utility and  
recharge the battery.  
To operate the system in Energy Management Mode, set up the system as follows:  
Connect utility AC power to the inverters AC HOT IN 1 and NEUTRAL IN 1 terminals.  
Connect AC loads to the inverters AC HOT OUT and NEUTRAL OUT terminals.  
Set the GRID (AC1) AMPS AC menu item, in the AC INPUTS (11) menu heading, to match the  
amperage of the circuit supplying AC to the inverter input (See UTILITY SUPPORT/OVERLOAD  
PROTECTION on page 82).  
Set the SET GRID USAGE menu item, under the INVERTER SETUP (9) menu heading, to FLT.  
Set the SET START CHARGE TIME menu item, under the GRID USAGE TIMER (18) menu heading,  
to the time the inverter connects to the utility. This is the beginning of the time the battery charger is  
allowed to operate and the end of the inverter operating period.  
Set the SET END CHARGE TIME menu item, under the GRID USAGE TIMER (18) menu heading, to  
the time that the inverter disconnects from grid and begins to run the loads from the battery. At this  
time, the battery charger will stop charging. If the battery voltage falls to the LOW BATTERY  
TRANSFER VDC menu item setting during the inverter operating time period, the AC loads will be  
reconnected to the utility grid and the battery will be charged to the FLOAT VOLTS DC or LOW  
BATTERY CUT IN VDC setting, whichever is lower. This prevents over-discharging the battery. The  
battery will be charged until the next END CHARGE TIME is reached.  
Set the START BULK TIME menu item under the BULK CHARGE TRIGGER TIMER (15) menu  
heading to a time after the START CHARGE TIME menu item setting. This allows delaying of the bulk  
charge cycle to a later time. Before the bulk charge is started, the battery will be charged only to the  
float voltage level. The START BULK TIME is usually set to occur during the lowest cost rate period.  
Adjusting the SET FLOAT VOLTS DC menu item to just above the normal at rest voltage (12.6 VDC)  
will reduce the amount of charging that occurs in the between time periods, yet will allow limited  
charging to prevent sulfation of the battery while being partially discharged.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
90  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
OPERATION  
The system should be designed so that the battery is able to operate the loads for the entire peak rate  
period without reaching the low battery transfer voltage. This may require that heavy loads be operated  
only during the non-peak rate period.  
This mode may be advantageous when the utility offers time-of-day metering that allows you to buy power  
at a variable rate during different time periods. For example, the rate may be only $0.04 per kilowatt-hour  
from midnight to 6 AM, but $0.16 during the peak period from noon to 6 PM. The in-between periods might  
cost $0.08 per kilowatt-hour. The idea is to not use utility power during the peak period and to charge the  
battery at night, during the off-peak period. A solar array is not required but, since it produces the most  
power during the peak period, it will reduce the amount of power required from the battery.  
The greater the difference between the peak and off-peak rates, the greater the value of this operating  
mode. When combined with a solar array, this mode may be more economic than operating the system in  
low battery transfer mode.  
If the battery is full and power is available from the solar array, it will be used to directly power the AC  
loads connected to the inverter output, even though the utility grid is also connected to the loads. If the  
amount of power exceeds the AC loads connected, the battery voltage will increase. An external solar  
array controller is required to limit the battery voltage to a safe level and to prevent overcharging and  
possible damage to the battery when only light loads are being powered.  
Note: The round-trip net energy efficiency of charging and discharging a Deep Cycle battery rarely  
exceeds 50%. In order for this technique to be cost effective, the off-peak rate foe electricity should be no  
more than half of the on-peak rate. The cost of battery replacement should also be calculated and  
included when evaluating this technique.  
To program the inverter for the example above:  
Set the SET GRID USAGE menu item, under the INVERTER SETUP (9) menu heading, to FLT.  
Set the START CHARGE TIME menu item, under the GRID USAGE TIMER (18) menu heading, to 6  
PM (18:00).  
Set the END CHARGE TIME menu item, under the GRID USAGE TIMER (18) menu heading, to  
NOON (12:00).  
Set the SET START BULK TIME menu item, under the BULK CHARGE TRIGGER TIMER (15) menu  
heading, to a time after MIDNIGHT (00:30) to delay most of the recharging for the cheapest period.  
Setting the SET FLOAT VOLTS DC menu item, under the BATTERY CHARGING (10) menu  
heading, to the nominal full battery voltage level will reduce the amount of battery charging that occurs  
between time periods, yet will allow limited charging to prevent sulfation of the battery while sitting  
partially discharged.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
91  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
OPERATION  
PEAK LOAD SHAVING MODE  
INVERTER/  
CHARGER  
AC  
UTILITY GRID  
AC  
AC LOADS  
DC  
BATTERY  
IN BRIEF  
The inverter can also be used to limit the maximum draw the AC loads place on the utility grid. Many  
utilities impose a surcharge on their customers based on the peak load used by a facility. The SW Series  
Inverter/Charger can be configured to provide all of the power above a specified level, eliminating the  
surcharges. With the Control Panel, simply adjust the SET GRID (AC1) AMPS AC menu item to the  
maximum value allowed by the utility without the peak load surcharge. All AC loads must be connected to  
the output of the inverter through the 60-amp AC transfer relay located internally. Multiple inverters may be  
required for larger applications with individual groups of loads connected to each inverter. This can be  
used in addition to time of day metering and still allows the inverter to provide a utility back-up function in  
addition.  
This mode is also useful for applications where AC loads require more power than a utility connection is  
able to supply. This often occurs in mobile applications where only a 15-amp outlet may be available. The  
inverter can provide the excess power above the 15 amps when the load is operating. If this condition  
occurs intermittently, then the inverter will be able to recharge the batteries between the heavy load  
periods. This can eliminate the need to increase the size of a utility supply circuit, providing substantial  
savings that can offset the cost of the inverter.  
This mode is used in some vehicle applications to improve the power quality by reducing the load placed  
on the AC line cord. The inverter provides the start-uppower to eliminate brown out problems  
experienced when starting air conditioners, etc. This also prevents tripping AC source circuit breakers  
when heavy loads are operating.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
92  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
OPERATION  
LOW BATTERY TRANSFER (LBX) MODE  
UTILITY GRID  
kWH METER  
AC LOADS  
SUB-PANEL  
SOLAR ARRAY  
DC  
AC  
AC  
AC LOADS  
MAIN PANEL  
INVERTER  
CHARGER  
GROUND FAULT  
PROTECTION  
AC  
DC  
DC  
OVERVOLTAGE  
PROTECTION  
DC  
BATTERY  
Low Battery Transfer mode is an alternative way of operating off the gridusing the utility for backup  
power instead of a generator. The system essentially operates as a stand-alone power system,  
independent of the utility grid. When the system is no longer able to keep up with the power requirements  
of the AC load, discharging the batteries to the LOW BATTERY TRANSFER VDC setting, the inverter  
connects to the utility grid. It then feeds utility power directly to the load and recharges the batteries.  
When the battery voltage reaches the LOW BATTERY CUT IN VDC setting, the inverter disconnects from  
the utility grid and once again operates the AC load from the batteries. Since power is never sold back to  
the utility, this configuration does not require utility approval.  
Simple in concept, this configuration may not provide the desired results. Incompatible settings and poor  
system designs (i.e., having excessive loads connected and/or low output of the charging source caused  
by undersizing the system or poor weather conditions affecting PV array output) often cause frequent  
cycling to and from the grid, thus reducing efficiency. Such cycling can actually increase power  
consumption from the utility grid.  
The most common problem occurs when the LOW BATTERY CUT IN setting is lower than the BULK  
VOLTS DC setting, causing the batteries to only partially recharge before transferring off utility power.  
Since the batteries are not fully recharged, they can only support the load for a limited amount of time.  
This results in rapid cycling (every day or even multiple times per day) between the battery system and the  
utility grid. One way to reduce the amount of cycling is to set the MAX CHARGE AMPS AC value to its  
minimum setting of 2 amps AC; however, this increases the systems dependency on the utility grid.  
If the system is also used for utility backup, performance could be drastically affected if the batteries are  
not fully charged when the utility outage occurs.  
The best performance can be achieved by recharging the battery from the utility grid and then waiting until  
the alternative power source (usually solar panels or a wind generator) has excess power available  
beyond what it takes to power the AC load. The system will continue to hold the batteries at the float  
voltage level until the alternative power source raises the battery voltage to a level that exceeds the battery  
charger settings before transferring. This is done by setting the LOW BATTERY CUT IN VDC setting  
higher than the BULK VOLTS DC and the FLOAT VOLTS DC settings. Once the battery is full, the  
charger will maintain the battery at the float voltage setting. If the alternative power source is able to  
contribute power, it will be used to offset the amount of power that the AC load draws from the utility grid.  
If the alternative power source is able to produce more power than the load requires, the battery voltage  
will then increase above the float level until it reaches the LOW BATTERY CUT IN VDC setting. At this  
time, the system will then transfer to the battery and operate off the grid.This reduces the amount of  
cycling by waiting until improved charging conditions (good sun or good wind) exist before transferring  
back to the battery.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
93  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
OPERATION  
Once the system has transferred back to the battery, the battery voltage will continue to increase if the  
power from the alternative source exceeds the loads. This can result in the battery voltage reaching the  
HIGH BATTERY CUT OUT VDC setting unless a charge control device limits the battery voltage. Note  
that the LOW BATTERY CUT IN VDC setting must be set below the external charge controllers regulation  
setting or the system would never transfer back to the battery. The best compromise involves setting the  
BULK VOLTS DC equal to the FLOAT VOLTS DC default value, and setting the LOW BATTERY CUT IN  
VDC setting to the default BULK VOLTS DC setting. Make sure the external charge controller is set  
slightly higher than the LOW BATTERY CUT IN VDC setting so that the voltage can be reached without  
the charging source shutting off.  
The LOW BATTERY TRANSFER VDC setting must be always set higher than the LOW BATTERY CUT  
OUT VDC setting. If utility back-up operation is expected, keep the LOW BATTERY TRANSFER VDC  
setting high to prevent excessive discharging of the battery. It should not be set to a level that is higher  
than the normal at rest battery voltage level or the system will transfer whenever no alternative power  
source is available (such as each night with solar). If the utility grid is not energized, the inverter will  
operate the AC loads until the battery voltage reaches the LOW BATTERY CUT OUT VDC setting. It will  
then shut off and only reset if the battery voltage reaches the LOW BATTERY CUT IN VDC level or the  
utility power becomes available again.  
If time of day metering is available from your utility, you might consider the ENERGY MANAGEMENT  
MODE as it may offer a more economical way to operate the system.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
94  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
OPERATION  
USING MULTIPLE INVERTERS  
Multiple SW Series Inverter/Chargers can be used in the same system. There are some limitations to the  
design of the system for successful and reliable operation. For North American applications, the inverters  
can be used in a seriesconfiguration to operate 240 VAC loads and to connect to 120/240 VAC power  
systems. Series stacking of Eversions (230 VAC / 50 Hz) would result in 230/460 VAC power.  
Two inverters can also be connected together and operated in parallel to provide twice the power at the  
same output AC voltage. The inverters can operate in parallel as battery chargers from the same AC  
source connected to the same battery. The AC input terminals and DC terminals would then be all in  
parallel. The inverters will synchronize individually to the AC source and then connect.  
SERIESSTACKED OPERATION  
As mentioned, in North America two inverters can be connected in a seriesstacked configuration to  
provide 120 and 240 VAC output.  
When series stacked, you get twice the power of a single inverter available for operating 240 VAC loads,  
but only one inverters power is available for operating a single large 120 VAC load. Separate 120 VAC  
loads can be operated from either inverter. Do not connect the AC output terminals of the inverters in  
parallel - this will not work. A special stacking interface cable (SWI) is required to connect the series  
stacking ports of the inverter to ensure the output voltage waveforms of the two inverters are phase  
synchronized and locked 180 degrees from each other. This allows connection to 120/240 VAC  
generators and utility grids. The 120 VAC loads are split and connected to either inverter. Both of the  
inverters operate completely independently - except their frequency is locked. They do not operate as a  
master-slave device as previous inverters have. One inverter can be in battery charger mode while the  
other is inverting to power an AC load. This independent operation allows many new possible applications  
and abilities that were previously not possible.  
When inverters are series stacked, they do coordinate all operations that affect 240 VAC loads. This  
requires that the inverters turn on together and switch to another AC source at the same time. If either  
inverter shuts down, both inverters are inoperable.  
If no 240 VAC loads are required to be operated, then the need and benefits of stacking are reduced.  
Stacking adds complexity and will cause both of the inverters to shut down if either inverter goes into an  
error condition. With separate (un-stacked) inverters, only one will shut down if over-loaded, etc.  
When two inverters are connected to a 120/240 VAC distribution system without using the stacking  
interface cable, the AC neutral wiring must be capable of handling twice the inverter output. This is due to  
the lack of synchronization between the inverters. If both inverters are operating in exact synchronization  
(as opposed to operating 180 degrees out of synch.), then the AC neutral will carry the current of both  
inverters, which was split among the two AC hot conductors. This often is not a problem since the AC  
distribution system may be oversized to handle the higher output level of a generator. When an AC source  
is connected to the inverters, the inverters will synchronize independently and transfer at different times.  
This is not a problem if no 240 VAC loads are connected to the output of the system.  
WARNING: You must connect the two chassis of the inverters together and to the grounding  
system by their grounding lugs or a hazardous voltage may be present on the chassis of the  
inverters.  
INPUT/OUTPUT BYPASS BREAKER SWITCH 240 VAC LOADS  
An inverter bypass-breaker switchdiverts power around an inverter and is meant to be used only during  
times of maintenance or to remove the inverter out of the installation. There is a possibility with a multiple  
inverter installation stacked in series(120/240 VAC) with two bypass switches installed, that one inverter  
bypass breaker switch could be in the Bypass Operation position (power diverted around the inverters)  
and the other inverter bypass breaker switch could be in the Normal Operation position (power passing  
thru the inverter). The resulting output of the two bypass switches may be less than 240 VAC, which could  
cause problems with any 240 VAC loads that are not protected against an AC phase shift.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
95  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
OPERATION  
240 VAC/60 HZ ONLY ELECTRICAL SYSTEMS  
Two 120 VAC / 60 HZ inverters seriesstacked can be used to provide 240 VAC. This provides both 120  
and 240 VAC since a center neutralis provided between the two inverters. If a 240 VAC only AC source  
is connected to the AC input terminals of the inverter without this center neutral, unacceptable operation  
will result. To allow connection of a 240 VAC only source to 120 VAC inverters, a small (2000 VA) auto-  
transformer must be connected across the 240 VAC source with the center of the transformer connected  
to the AC neutral terminals of the inverters. This will allow the inverter to operate properly. No transformer  
is required on the AC output side - the 240 VAC can be taken directly from the two AC hot output  
terminals (one from each inverter).  
PARALLELSTACKED OPERATION  
The parallel stacking interface allows twice the continuous and surge capacity to be available on a single  
output circuit from two inverters. The pass-through capacity is also doubled when connected to an AC  
source such as a fuel-powered generator or a utility grid. The inverters operate in parallel and split the  
loads between them. The inverters must be identical models and must have software revision REV 4.01 or  
higher software. The inverters must be connected to the same battery bank with equivalent cabling (both  
in length and in cable size). The inverter negative terminals of the inverters must be connected together  
either at the inverters or at a location close to the inverters (within 18 inches / 0.5 meters).  
The parallel stacking interface cable (SWI/PAR) simply plugs into the stacking port on the left end of each  
inverter and allows the two inverters to operate as a single inverter. The interface method is based on the  
series stacking system offered for the SW Series inverters since their introduction for the North American  
market. The parallel stacking system operates the inverters in phase by having one of the inverters  
operate as the MASTER and the other as a SLAVE. When an AC source is connected, the MASTER first  
synchronizes to the AC source, then connects to it and battery charges. Since the SLAVE follows the  
master and is set-up with a longer warm-up delay, the SLAVE inverter is already synchronized when it  
transfers the loads and starts battery charging. This allows very smooth transitions from inverter mode to  
charger mode.  
The parallel stacking interface system allows doubling of the AC pass through capacity. This is useful  
when large generators are used. Both inverters will battery charge as allowed by the settings in each of  
the inverters.  
The hook-up depends upon the other components included in the system and whether it was ordered as  
only inverters, a power panel system, or a power module system. With the power module system, the  
paralleling enclosure is eliminated and all of the wiring is completed for you. With the individual inverters  
and the power panel system, the paralleling enclosure and parallel stacking interface cable must be  
installed on site. The paralleling enclosure is connected to each of the inverters outputs and is also  
connected to the AC loads being powered.  
At this time, the paralleled inverters are intended to operate as a single unit. In case of an inverter fault or  
error condition, both inverters turn off as one. When the error has been corrected, the inverter will  
automatically or manually reset depending upon the type of error condition.  
If an inverter failure occurs, the parallel stacking interface can be manually bypassed and the special  
parallel stacking interface cable can be removed to allow temporary operation on one unit.  
GENERATOR CONTROL SETTINGS  
When using two units in parallel, it is recommended that only the SLAVE inverter be used to control the  
generator. This is required because the generator control system includes a cool down timer that causes  
the controlling inverter to disconnect from the generator before it turns the generator off. If the MASTER  
controls the generator, then the SLAVE may not stay in sync with the MASTER during the cool-down  
period since it will remain in sync with the generator and not follow the MASTER. There currently is no  
adjustment for the cool-down period, so restricting the generator control to the SLAVE is the only solution  
available at this time.  
The SLAVE also must be set with a longer warm-up period than the MASTER in order to prevent them  
from trying to synchronize to the generator at the same time. When the MASTER synchronizes first, the  
SLAVE will automatically sync after its warm-up period passes. This also makes the transfer from inverter  
to generator smoother and less noticeable.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
96  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
OPERATION  
BATTERY CHARGING WITH MULTIPLE INVERTERS  
The inverters can operate in parallel as battery chargers from the same AC source connected to the same  
battery. The AC input terminals and DC terminals would all be in parallel. The inverters will synchronize  
individually to the AC source and then connect.  
When multiple inverters are connected to the same battery and operated as in battery charger mode, the  
settings of the inverters are best set to the same settings. Only when a system is being operated in  
automatic generator control mode should staggered settings be used.  
The most significant problem with multiple inverters charging the same battery is the voltage ripple caused  
on the battery. This causes the chargers to not reach their full output - two battery chargers on the same  
battery may not provide twice the charging rate to fill the battery in half the time. The higher the charger  
rate and/or the smaller the battery, the more pronounced this problem would be. The only way to reduce  
the problem is to individually cable each inverter and to connect them at opposite cornersof the battery  
bank. Keeping the cable size as short as possible also helps.  
Since the inverters will all be charging the same battery, one inverter may taper off first and finish the bulk  
stage before the others. When a single inverter has reached the float stage, it is best to turn off the  
generator at this time. It may take a longer period of time for the remaining inverters to reach the float  
stage. Running the generator to only power an inverter that is float charging is very inefficient and should  
be avoided.  
If multiple Battery Temperature Sensors are installed, ensure they are all connected to the same location  
(battery). This will also help prevent one inverter from tapering off first.  
AUTOMATIC GENERATOR CONTROL WITH MULTIPLE INVERTERS  
Several considerations must be taken into account when using the automatic generator controlling system  
with multiple inverters. The inverter that controls the generator referred to as the generator controlling”  
inverter - along with the other inverter which does not control the generator - referred as the non-  
generator controllinginverter - must be programmed differently to achieve the best results. The two  
inverters should be programmed with the same BULK VOLTS DC and FLOAT VOLTS DC settings, but  
with the ABSORPTION TIME on the non-generator controllinginverter to a longer setting. This will  
ensure that the charge current is shared between the two inverters more equally during the absorption  
stage by preventing one of the inverters from switching to float before the other. When the inverter that  
controls the generator reaches float, it will shut down the generator.  
The same consideration should be made if you are trying to equalize the batteries. The two  
inverter/chargers should be programmed with the same EQUALIZE VOLTS DC settings, but with the  
EQUALIZE TIME on the non-generator controllinginverter to a longer setting. When you are ready to  
start the equalization process (either manually or automatically) you must select EQ from the SET  
GENERATOR menu item on both inverters (accessible by pressing the green GEN MENU button on the  
Control Panel). This will allow both units to help bring the voltage to the EQ voltage level. During the  
equalization process, the BULK LED will flash slowly on each inverter to indicate that the EQ position has  
been selected from the SET GENERATOR menu item.  
If you manually equalized your batteries by using a manually started generator or utility power - the  
FLOAT LED will come on to indicate that the equalization process has finished. You must return the  
cursor to the OFF position in the SET GENERATOR menu item on both inverter/chargers once the  
equalization period has been completed.  
If the automatic generator control system is used to equalize your batteries, the equalization process will  
begin during the next - automatically started - generator run period. When the equalization period has  
been completed, the generator will automatically stop and the cursor under the SET GENERATOR menu  
item will return to the AUTO position on the generator controllinginverter. At this time, you must  
manually return the cursor in the SET GENERATOR menu item on the non-generator controllinginverter  
from EQ back to OFF or you will allow this inverter to charge up to the EQ voltage the next time the  
generator comes on.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
97  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
OPERATION  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
98  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
TECHNICAL INFORMATION  
TECHNICAL INFORMATION  
BATTERY TYPE  
This section of the manual is included to help you better understand the factors involved with battery  
charging, care, and maintenance, by discussing the physical make-up and characteristics of chemical  
storage batteries. This is not intended to be an exhaustive discussion of battery types, but simply a  
guideline. The manufacturer of each specific battery is the best authority as to its use and care.  
Batteries come in different sizes, types, amp hours, voltages and chemistries. There are nearly as many  
descriptions of exactly how batteries should be charged, as there are people willing to offer explanations.  
It is not possible here to discuss all aspects in detail. However, there are basic guidelines you can follow  
that will help in battery selection and ensure that the batteries are better maintained than the majority.  
See the INVERTER/CHARGER TERMINOLOGY on page 115 for a brief description of terms that appear  
in this section with which you may not be familiar.  
SELECTION OF BATTERY TYPE  
There are two principal types of batteries: starting and deep-cycle. There are several different types of  
battery chemistries including liquid lead-acid, nickel-iron (NiFe), nickel-cadmium (NiCad), alkaline, and  
gel-cell. Batteries are either sealed or vented.  
STARTING BATTERY  
These are designed for high cranking power, but not deep cycling. Dont use them. It does not hurt the  
inverter - they simply will not last long in a deep cycle application. The way they are rated should give a  
good indication of their intended use. "Cold Cranking Amps", is a measure of the amperage output that  
can be sustained for 30 seconds. Starting batteries use lots of thin plates to maximize the surface area of  
the battery. This allows very high starting current but lets the plates warp when the battery is cycled.  
TELEPHONE COMPANY BATTERY  
Second-hand telephone company batteries are often available at far below original cost. They are often  
used to power the telephone system for short power outages. They are sometimes used successfully in  
remote home systems. Typically, they are a lead calcium type battery, similar in construction to a starting  
battery. Therefore, they should not be repeatedly discharged more than 20% of their amp/hr rating. Keep  
this in mind when evaluating their amp/hr to cost ratio.  
DEEP CYCLE BATTERY  
This is the type of battery best suited for use with inverters. The physical dimension of the plates are  
thicker and the active material that holds the charge is more dense to increase cycle life. The deep cycle”  
type of battery is designed to have the majority of their capacity used before being recharged. They are  
available in many sizes and in either non-sealedor sealedtypes.  
NON-SEALED LEAD ACID BATTERY  
The most common type of deep cycle battery is the non-sealed, liquid electrolyte battery. Non-sealed  
types have battery caps. The caps should be removed periodically to check the level of electrolyte.  
When a cell is low, distilled water should be added. The electrolyte level should be checked monthly  
and topped up if needed after recharging.  
The most common non-sealeddeep cycle battery is the type used with boats and motor homes.  
They typically are called Group 27batteries and are similar in size to a large truck battery. They are  
12-volt batteries rated at 80 to 100 amp-hours. Often the deep cycle claim is over-stated. They do  
work better than a car battery, but are not recommended for anything but the smallest systems.  
Another popular and inexpensive battery of this type is the "golf cart" battery. It is a 6-volt battery rated  
at 220 amp-hours. They can be cycled repeated to 80% of their capacity without being damaged. This  
is the minimum quality of battery that should be used with SW Series inverter applications.  
Many systems use the L16 type of battery. These are 6-volt batteries rated at 350 amp-hours and are  
available from a number of manufacturers. They are 17 inches in height and weigh up to 130 pounds  
each - which may be troublesome in some applications such as RV or marine installations.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
99  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
TECHNICAL INFORMATION  
Type 8D batteries are available with either cranking or deep cycle construction. The deep cycle  
versions are 12-volt batteries rated at 200 amp hours or so. Since they are most commonly used to  
start truck engines, you should make sure you purchase the deep cycle version.  
SEALED LEAD ACID BATTERIES  
CAUTION: if using gelled batteries, the battery charger must be set to the appropriate settings  
or battery damage will occur.  
Another type of deep cycle battery construction is the sealed "valve regulated" lead acid battery. They  
are a rechargeable battery which recombines suppressed gases, thus eliminating the need to add  
water. Since they are tightly sealed, these batteries will not leak and can be installed in certain  
applications where liquid typebatteries could not be installed.  
While there are many manufacturers of quality non-sealed batteries, there are only a few  
manufacturers of suitable sealed batteries. Dont confuse sealed batteries with maintenance free”  
batteries - the later is typically a standard liquid electrolyte type battery without caps for adding water -  
when the electrolyte gets low you replace the battery.  
The advantages of true deep cyclesealed batteries are no maintenance (does not require acid  
checks or periodic watering), long life (800 cycles claimed) and low self-discharge. The disadvantage  
is high initial cost and because water cannot be added, they are less tolerant of overcharging.  
Two methods are used to seal batteries by a process of immobilizing the electrolyte, which in turn  
eliminates free-flowing acid. Both these methods can be used in inverter applications.  
Gel Cell: Silica gel is added to the electrolyte, causing it to 'set' in gelatin form.  
Absorbed Glass Mat (AGM): Highly absorbent glass mat separators are used between each  
plate to retain the liquid electrolyte.  
Even with all the advantages of sealed batteries, there is still a place for the standard flooded deep  
cycle battery. Sealed batteries will cost 2 to 2.5 times as much as liquidor flooded batteries. In many  
installations, where the batteries are set in an area where you don't have to worry about fumes or  
leakage, a standard or industrial deep cycle is a better economic choice.  
NICAD AND NICKEL IRON (NIFE) BATTERY  
Traceinverters and battery chargers are optimized for use with lead acid batteries that have a nominal  
voltage of 2.0 volts per cell. NiCad/NiFe batteries (also called alkaline batteries) have a nominal cell  
voltage of 1.2 volts per cell. The nominal voltage of a NiCad/NiFe battery bank can be made the same as  
a lead acid bank by juggling the number of cells (10 cells for 12 volts, 20 cells for 24 volts and 40 cells for  
48 volt systems). However, the NiCad/NiFe battery bank must be charged to a higher voltage to fully  
recharge and will drop to a lower voltage during discharging compared to a similarly sized lead acid type  
battery. This makes the job for the inverter/charger much more difficult.  
The easiest way to use NiCad/NiFe batteries with a 24 volt inverter is to use nineteen NiCad/NiFe cells in  
the battery bank instead of the usual twenty. This will reduce the battery bank charging voltage  
requirements to about the same level as a lead-acid bank; so more standard charger settings can be  
used. The problem with this approach is that the battery voltage will drop as low as 18 volts to fully  
discharge the battery.  
A second option on 12-, 24- and 48-volt systems is to adjust the SET BULK VOLTS DC to its maximum  
setting. This will provide a complete charge although it may require a longer charging period to completely  
recharge the battery compared to using a higher charge voltage (or lesser number of cells) were used.  
The ABSORPTION TIME setting may be set shorter than with lead acid batteries since NiCad/NiFe  
batteries do not require an absorption stage. If the battery storage requirements are large, industrial grade  
2 volt batteries are often more suitable.  
Note: In alternative energy applications (solar, wind, hydro) all DC charge controllers must be set to a level  
below the inverter HIGH BATTERY CUT OUT setting or the inverter may shut off unexpectedly.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
100  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
TECHNICAL INFORMATION  
BATTERY SIZING  
Batteries are the inverters fuel tank. The larger the batteries, the longer the inverter can operate before recharging  
is necessary. An undersized battery bank results in reduced battery life and disappointing system performance.  
Batteries should not be discharged more than 50% of their capacity on a regular basis. Under extreme conditions  
(such as a severe storm or a long utility outage), cycling to a discharge level of 80% is acceptable. Totally  
discharging a battery may result in permanent damage and reduced life.  
For stand-alone applications, it is common to size a battery to provide between 3 and 5 days worth of storage  
before the battery requires recharging. The power contribution from other charging sources is not included in this  
calculation to duplicate the conditions present during a cloudy or windless period. This is often referred to as the  
number of days of autonomy. If the system is a hybrid system with daily generator run periods, then the battery  
size may be smaller. During cloudy periods the generator would be expected to run longer.  
Utility connected applications often have very small batteries. If the system does not provide utility backup function,  
the minimum battery capacity recommended is 320 amp-hours @ 12 vdc, 160 amp-hours @ 24 vdc, and 80 amp-  
hours @ 48 vdc. If utility back up is required, larger batteries will be needed.  
ESTIMATING BATTERY REQUIREMENTS  
In order to determine the proper battery bank size, it is necessary to compute the number of amp hours that will be  
used between charging cycles. When the required amp hours are known, size the batteries at approximately twice  
this amount. Doubling the expected amp hour usage ensures that the batteries will not be overly discharged and  
extends battery life. To compute total amp hours usage, the amp hour requirements of each appliance that is to be  
used are determined and then added together.  
You can compute your battery requirements using the nameplate rating of your appliances. The critical formula is  
Watts = Volts X Amps. Divide the wattage of your load by the battery voltage to determine the amperage the load  
will draw from the batteries.  
If the AC current is known, then the battery amperage will be:  
(AC current) X (AC voltage)  
= DC amps  
(battery voltage)  
Multiply the amperage by the number of hours the load will operate and you have, reasonably enough, amp-hours.  
Motors are normally marked with their running current rather than their starting current. Starting current may be 3 to  
6 times running current. Manufacturer literature may provide more accurate information compared to the motor  
nameplate. If large motors will be started, increase the battery size to allow for the high demand start-ups require.  
Follow this procedure for each item you want to use with the inverter. Add the resulting amp hour requirements for  
each load to arrive at a total requirement. The minimum properly sized battery bank will be approximately double  
this amount. This will allow the battery to be cycled only 50% on a regular basis.  
Table 5, Typical Wattage Of Common Appliances  
TYPICAL APPLIANCE WATTS  
Appliance  
Watts  
Appliance  
Watts  
One FL Light  
10  
100 - 500  
150  
Microwave (compact)  
Microwave (full size)  
Toaster  
600 - 800  
1500  
B&W TV (12)  
Color TV (19)  
Computer  
1000  
200 - 350  
50  
Hot Plate  
1800  
Stereo or VCR  
Hair Dryer or Iron  
Vacuum or coffee maker  
3/8Drill  
Washer/Dryer  
375 - 1000  
400  
1000  
Blender  
1200  
*Refrigerator (3 cu ft)  
*Refrigerator (12 cu ft)  
180  
500  
480  
* Refrigerators and icemakers typically only run about 1/3 of the time, therefore the running wattage is 1/3 of the total wattage of  
the appliance.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
101  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
TECHNICAL INFORMATION  
BATTERY BANK SIZING  
EXAMPLE  
Complete the steps that follow to calculate your inverters battery bank capacity. No two installations will  
require exactly the same battery bank capacity. The following example provides a guide for determining  
your needs. Read through the example and then complete the worksheet on the following page.  
STEP 1-4: Determine your Average Daily Watt-Hours Needed.  
STEP 1  
STEP 2  
STEP 3  
STEP 4  
AC APPLIANCE  
APPLIANCE RUNNING  
WATTS  
(X) HOURS USED  
EACH DAY  
(X) DAYS USED  
EACH WEEK  
(÷ 7 = ) AVERAGE DAILY  
WATT-HOURS NEEDED  
Microwave  
Lights (x4)  
Hair Dryer  
600  
40  
0.5  
6
7
7
3
7
2
7
1
300  
240  
81  
750  
0.25  
4
Television  
100  
400  
107  
3840  
171  
Washer  
375  
1
Refrigerator*  
Vacuum cleaner  
480/3 = 160  
1200  
24  
1
STEP 1: Determine what appliances the inverter will power and enter the Appliance Running Wattage  
of each appliance.  
* -  
Refrigerators and icemakers typically only run about 1/3 of the time, therefore the running  
wattage is 1/3 of the total wattage of the appliance.  
STEP 2: Determine the number of hours (or fractions of hours) you will use the appliance each day;  
STEP 3: Multiply the number of days you will use the appliance during the week; this is your Weekly  
Watt Hours Needed;  
STEP 4: Divide your Weekly Watt Hours Needed by 7 to obtain the Average Daily Watt Hours  
Needed;  
Total Daily Watt Hours Needed  
STEP 5: Total Average Daily Watt Hours Needed to determine your Total Daily  
Watt Hours Needed.  
5,139  
Autonomy Battery Size  
(Watt Hours)  
STEP 6: Multiply your Total Daily Watt Hours Needed (Step 5) by the number of  
anticipated days of autonomy (days between charging, usually 1 to 5)  
to determine your Autonomy Battery Size (example used 3 days).  
15,417  
Rough Battery Size (Watt Hours)  
STEP 7: Multiply your Autonomy Battery Size (Step 6) x 2 to allow for a 50%  
maximum battery discharge in normal operation and an additional  
50% for emergency situations to obtain your Rough Battery Size in  
watt-hours.  
30,834  
Safe Battery Size (Watt Hours)  
STEP 8: Multiply your Rough Battery Estimate x 1.2 to allow for an efficiency of  
80%. This number is your Safe Battery Size in watt-hours.  
37,001  
Safe Battery Size (Amp Hours)  
STEP 9: Convert your Safe Battery Size to amp-hours. Divide Safe Battery Size  
by the DC system voltage (i.e., 12, 24 or 48 VDC; example used 24-  
volts). This number is your Safe Battery Size in amp-hours, which is  
the battery bank capacity needed before recharging.  
1,542  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
102  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
TECHNICAL INFORMATION  
WORKSHEET  
Complete the steps that follow to calculate your inverters battery bank capacity.  
STEP 1-4: Determine your Average Daily Watt Hours Needed.  
STEP 1  
STEP 2  
STEP 3  
STEP 4  
AC APPLIANCE  
APPLIANCE RUNNING  
WATTS  
(X) HOURS USED  
EACH DAY  
(X) DAYS USED  
EACH WEEK  
(÷ 7 = ) AVERAGE DAILY  
WATT HOURS NEEDED  
STEP 1: Determine what appliances the inverter will power and enter the Appliance Running Wattage  
of each appliance.  
STEP 2: Determine the number of hours (or fractions of hours) you will use the appliance each day;  
STEP 3: Multiply the number of days you will use the appliance during the week; this is your Weekly  
Watt Hours Needed;  
STEP 4: Divide your Weekly Watt Hours Needed by 7 to obtain the Average Daily Watt-Hours  
Needed;  
Total Daily Watt-Hours Needed  
STEP 5: Total Average Daily Watt Hours Needed to determine your Total Daily  
Watt Hours Needed.  
.
.
Autonomy Battery Size  
(Watt Hours)  
STEP 6: Multiply your Total Daily Watt Hours Needed (Step 5) by the number of  
anticipated days of autonomy (days between charging, usually 1 to 5)  
to determine your Autonomy Battery Size (example used 3 days).  
.
.
Rough Battery Size (Watt-Hours)  
STEP 7: Multiply your Autonomy Battery Size (Step 6) x 2 to allow for a 50%  
maximum battery discharge in normal operation and an additional  
50% for emergency situations to obtain your Rough Battery Size in  
watt hours.  
.
.
Safe Battery Size (Watt-Hours)  
STEP 8: Multiply your Rough Battery Estimate x 1.2 to allow for an efficiency of  
80%. This number is your Safe Battery Size in watt-hours.  
.
.
Safe Battery Size (Amp-Hours)  
STEP 9: Convert your Safe Battery Size to amp-hours. Divide Safe Battery Size  
by the DC system voltage (i.e., 12, 24 or 48 VDC; example used  
24 volts). This number is your Safe Battery Size in amp hours, which is  
the battery bank capacity needed before recharging.  
.
.
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
103  
Rev. C: February 2001  
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TECHNICAL INFORMATION  
BATTERY CARE AND MAINTENANCE  
If you have read the battery charger mode section of this manual, you already have a good idea of the  
stages of battery charging that combine to promote fast charging and ensure long battery life. Basically,  
there are five charger-related considerations to properly care for your batteries.  
Charge Rate - The maximum safe charge rate is related to the size and type of your batteries.  
Standard vented lead acid batteries (with battery caps) can be charged at a high rate - equal to their  
capacity. Small batteries may require a lower charge rate. Check with the battery manufacturer. Adjust  
the MAX CHARGE AMPS AC setting to control the charging rate.  
Bulk Voltage - This is the maximum voltage the batteries reach during the normal charging process.  
Gel cell batteries are usually set to a lower value, while non-sealed batteries are set to the higher.  
Adjust the SET BULK VOLTS DC setting to control the battery voltage during the BULK and  
ABSORPTION stages.  
Float Voltage - The batteries experience less gassing if they are maintained at a lower voltage than the  
voltage at which they are charged. Adjust the FLOAT VOLTS DC setting to control the battery voltage.  
Temperature Compensation - Temperature affects the optimum voltage values for the bulk and float  
charging stages. The Battery Temperature Sensor (BTS) automatically fine-tunes these voltages for you.  
Equalization (Non-Sealed Batteries Only) - Many experts recommend that batteries be "equalized"  
(A fancy term for over-charged) every month or two. However, a leading battery manufacturer  
recommends equalizing only when low or wide ranging specific gravity (± 0.015) are detected after  
fully charging a battery. Since the individual battery cells are not exactly identical, some may still have  
sulfate on their plates after a complete charge cycle. On the other hand, if the batteries never received  
a full charge, all plates will have sulfate left on them. If the sulfate remains on the plates for an  
extended period of time, it will harden and seal off a percentage of the plate area, reducing the  
capacity of the battery. By equalizing the batteries, the entire sulfate is removed from the plates.  
Additionally, the gassing that result stirs up the electrolyte which tends to stratify. Stratification  
concentrates the sulfuric acid in the bottom of the cell while the top becomes watery. This corrodes  
the plates. Equalization is accomplished by charging batteries above a voltage of 2.6 VDC per cell.  
This is over 15 VDC for a 12 VDC system, 30 for a 24 VDC system and 60 for a 48 VDC system.  
Since equalizing is basically overcharging the battery, which can be harmful to battery's life and  
performance, it is done only when required.  
CAUTION: Equalization should be done only with standard electrolyte batteries. If you  
have sealed or gel cell batteries, check first with the battery manufacturer before  
equalizing. DC loads should be disconnected before equalization to protect them from damage  
by the high battery voltage involved.  
Table 6, Battery Charging: Charging Setpoints  
TYPICAL BULK AND FLOAT SETPOINTS FOR COMMON BATTERY TYPES  
Battery Type  
Bulk Volts  
Float Volts  
Equalizing Charge Process  
Sealed Gel  
14.1 VDC BULK  
13.6 VDC FLOAT  
Not Recommended - Consult manufacturer  
Lead Acid battery  
A.G.M.  
Lead Acid battery  
14.4 VDC BULK  
14.4 VDC BULK  
14.6 VDC BULK  
16.0 VDC BULK  
13.4 VDC FLOAT  
13.4 VDC FLOAT  
13.4 VDC FLOAT  
14.5 VDC FLOAT  
Charge to 15.5 VDC or as per manufacturer  
Not Recommended - Consult manufacturer  
Charge to 15.8 VDC or as per manufacturer  
Consult manufacturer  
Maintenance-Free RV/Marine  
Lead Calcium Battery  
Deep-Cycle, Liquid Electrolyte  
Lead Antimony Battery  
NiCad or NiFe Alkaline Battery*  
(using 10 cells in series)  
Note: Values shown are for 12-volt systems. For 24-volt systems, multiply the settings shown by  
two. For 48-volt systems, multiply the settings shown by four. These settings are guidelines, refer to  
your battery manufacturer for specific settings.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
104  
Rev. C: February 2001  
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TECHNICAL INFORMATION  
MONTHLY MAINTENANCE  
At the minimum, check the level of the electrolyte in each battery cell once a month. It should be above  
the top of the plates but not completely full. Most batteries have a plastic cup that the electrolyte should  
just touch when full. Dont overfill the batteries or the electrolyte will spill out of the batteries when they are  
being charged. Only refill the batteries with distilled water - springwater and regular tap water may have  
high levels of minerals that can poison the battery chemistry and reduce battery performance and life.  
It is also good to check the battery interconnections for tightness and corrosion. If any corrosion is found,  
disconnect the cables and carefully clean with a mild solution of baking soda and water. DO NOT ALLOW  
THE SOLUTION TO ENTER THE BATTERY. Rinse the top of the battery with clean water when finished.  
To reduce the amount of corrosion on the battery terminals, coat them with a thin layer of petroleum jelly  
or anti-corrosion grease available from automotive parts stores or battery suppliers. Do not apply any  
material between the terminal and the cable lugs - the connection should be metal to metal. Apply the  
protective material after the bolts have been tightened.  
BATTERY STATE OF CHARGE  
A good estimate of a batterys state of charge can be made by measuring the voltage across the battery  
terminals with the battery at rest (No energy input, no energy output) for at least three hours. These  
readings are best taken in the early morning, at or before sunrise, or in late evening. Take the reading  
while almost all loads are off and no charging sources are producing power. Connect a voltmeter across  
the positive and negative outputs of the battery or battery bank. Voltages are for a 12 volt battery system.  
For 24-volt systems, multiply by 2; for 48-volt systems, multiply by 4. Monitor your cell voltage, if you  
measure more than a 0.2 volt difference between each cell, you may need to equalize (Do not equalize  
Gel Cell Batteries). The following table will allow conversion of the readings obtained to an estimate of  
state of charge. The table is good for batteries at 77°F that have been at rest for 3 hours or more. If the  
batteries are at a lower temperature, you can expect lower voltage readings.  
Table 7, Battery State of Charge Voltage  
PERCENT OF  
12 VOLT DC SYSTEM  
CELL VOLTAGE  
FULL CHARGE  
100%  
90%  
12.7  
12.6  
12.5  
12.3  
12.2  
12.1  
12.0  
11.8  
11.7  
11.6  
<=11.6  
2.12  
2.10  
2.08  
2.05  
2.03  
2.02  
2.00  
1.97  
1.95  
1.93  
<=1.93  
80%  
70%  
60%  
50%  
40%  
30%  
20%  
10%  
0%  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
105  
Rev. C: February 2001  
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TECHNICAL INFORMATION  
BATTERY INSTALLATION  
CAUTION: Batteries can produce extremely high currents if they are short-circuited. Be  
very careful when working around them. Read the important safety instructions at the start  
of this manual and the battery suppliers precautions before installing the inverter and  
batteries.  
LOCATION  
Batteries should be located in an accessible location with nothing restricting the access to the battery caps  
and terminals on the tops. At least 2 feet of clearance above is recommended. They must be located as  
close as possible to the inverter, but can not limit the access to the inverter and the inverters DC  
disconnect. With the SW Series inverter, the batteries are best located to the right side. This is where the  
DC connections are located.  
Battery to inverter cabling should be only as long as required. For 12 VDC systems, do not exceed 5 feet  
(one way) if 4/0 AWG cables are used. For 24 VDC systems, do not exceed 10 feet (one way) if 4/0 AWG  
cables are used. For 48 VDC cables, do not exceed 10 feet (one way) if 2/0 AWG cables are used, or 20  
feet (one way) if 4/0 AWG cables are used.  
BATTERY ENCLOSURES  
The batteries must be protected inside a ventilated, lockable enclosure or room to prevent access by  
untrained personnel. The enclosure should be ventilated to the outdoors from the highest point to prevent  
accumulation of hydrogen gasses released in the battery charging process. An air intake should also be  
provided at a low point in the enclosure to allow air to enter the enclosure to promote good ventilation. For  
most systems, a 1-inch diameter vent pipe from the top of the enclosure is adequate to prevent  
accumulation of hydrogen. A sloped top can help direct the hydrogen to the vent location and prevent  
pockets of hydrogen from occurring. The enclosure should also be capable of holding at least one battery  
cells worth of electrolyte incase a spill or leak occurs. It should be made of acid resistant material or have  
an acid resistant finish applied to resist the corrosion from spilled electrolyte and fumes released. If the  
batteries are located outside, the enclosure should be rainproof and include mesh screens over any  
openings to prevent insects and rodents from entering. Before putting the batteries in, cover the bottom of  
the enclosure with a layer of baking soda to neutralize any acid that might be spilled in the future.  
BATTERY TEMPERATURE  
The effective capacity of a battery is reduced when cold. This phenomenon is more significant with lead  
acid type batteries compared to alkaline types. When the internal temperature of a lead acid battery is  
32 °F (0 °C) the capacity can be reduced by as much as 50%. This effectively reduces the size of the  
systems gas tank, requiring more frequent refuelingby the backup source (usually a generator). This  
should be considered when designing the system. If extremely cold temperatures are expected at the  
location of a system, either a heated equipment room or alkaline batteries should be considered.  
If the system is located in an unheated space, an insulated enclosure is highly recommended for the  
batteries. During the charging process, the batteries release heat due to the internal resistance of the  
battery. If the batteries are insulated, the heat can be kept in the batteries to keep them warmer. This will  
substantially increase the performance of the system.  
Insulated battery enclosures also ensure that the temperatures of the individual battery cells are more  
consistent, preventing unequal charging which can cause battery failure (some cells will be overcharged  
while others are undercharged).  
The batteries should also be protected from high temperature as well. This can be caused by high  
ambient temperatures, solar heating of the battery enclosure, or heat released by a closely located  
generator. High battery temperatures will result in short battery life and should be avoided by ventilating  
the enclosure and reducing the external heat sources by shading and insulation.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
106  
Rev. C: February 2001  
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TECHNICAL INFORMATION  
BATTERY HOOK-UP CONFIGURATIONS  
Battery banks of substantial size are generally created by connecting several smaller batteries together.  
There are three ways to do this. Batteries can be connected in series, to increase voltage; in parallel to  
increase amp-hour capacity; or in series parallel, to achieve the required voltage and capacity.  
The cables which connect the individual batteries together to make a larger battery bankshould be  
connected together will heavy cables. The actual size of the cable depends upon whether the batteries are  
connected in parallel or series. Generally, the cables should not be smaller than the inverter cables - if the  
main cables are 4/0 AWG, the battery interconnects should be 4/0 AWG.  
Remember, for safety and to comply with UL regulations, battery over-current protection is  
required in the ungrounded battery cable.  
SERIES CONNECTION  
When batteries are connected with the positive terminal of one to the negative terminal of the next, they  
are connected in series. In a series configuration, the battery bank has the same amp/hour rating of a  
single battery, but an overall voltage equal to the sum of the individual batteries. This is common with 24  
volt or higher battery-inverter systems.  
6V  
6V  
6V  
6V  
6V  
6V  
FUSED  
DISCONNECT  
FUSED  
DISCONNECT  
24V INVERTER  
12V INVERTER  
(Total Battery Capacity  
= 100 Amp Hours)  
(Total Battery Capacity  
= 100 Amp Hours)  
6V  
6V  
6V  
6V  
6V  
6V  
6V  
6V  
FUSED  
DISCONNECT  
48V INVERTER  
(Total Battery Capacity  
= 100 Amp Hours)  
Each individual 6-volt battery capacity = 100 amp hours  
Figure 31, Series Configuration: 6-Volt Battery Wiring  
12V  
12V  
12V  
12V  
12V  
12V  
FUSED  
DISCONNECT  
FUSED  
DISCONNECT  
24V INVERTER  
48V INVERTER  
(Total Battery Capacity  
= 50 Amp Hours)  
(Total Battery Capacity  
= 50 Amp Hours)  
Each individual 12-volt battery capacity = 50 amp hours  
Figure 32, Series Configuration: 12-Volt Battery Wiring  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
107  
Rev. C: February 2001  
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TECHNICAL INFORMATION  
PARALLEL CONNECTION  
Batteries are connected in parallel when all the positive terminals of a group of batteries are connected  
and then, separately, all the negative terminals are connected. In a parallel configuration, the battery bank  
have the same voltage as a single battery, but an amp/hour rating equal to the sum of the individual  
batteries. This is usually only done with 12-volt battery-inverter systems.  
12V  
12V  
12V  
12V  
FUSED  
DISCONNECT  
12V INVERTER  
(Total Battery Capacity  
= 200 Amp Hours)  
Each individual 12-volt battery capacity = 50 amp hours  
Figure 33, Parallel Configuration: 12-Volt Battery Wiring  
SERIES - PARALLEL CONNECTION  
As the name implies, both the series and parallel techniques are used in combination. The result is an  
increase in both the voltage and the capacity of the total battery bank. This is done very often to make a  
larger, higher voltage battery bank out of several smaller, lower voltage batteries. This is common with all  
battery-inverter system voltages. The smaller, lower voltage batteries are first connected in series to  
obtain the needed voltage, then these batteries, connected in seriessets are connected in parallel to  
increase the battery bank capacity.  
The best arrangement when using a series-parallel configuration is to connect all the smaller, lower  
voltage batteries in parallel, then connect all these batteries in parallelinto series sets to obtain the  
needed voltage. This configuration is often called cross-tying. This is less convenient and requires  
additional cables but reduces imbalances in the battery, can improve the overall performance and in a  
shorted cellscenario, would cause only the battery(s) that are actually in parallel with the shorted”  
battery to discharge. This would allow you to re-configure your battery bank with the other batteries that  
are in parallel with the shorted/discharged battery(s) and still be operational only at a lower capacity.  
The more efficient cross-tyingmethod is shown in Figure 34 and Figure 35 as dash(- - -) lines. If  
cross-tyingis not desired, the dash lines shown may be ignored.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
108  
Rev. C: February 2001  
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TECHNICAL INFORMATION  
6V  
6V  
6V  
6V  
6V  
6V  
6V  
6V  
6V  
6V  
6V  
6V  
FUSED  
DISCONNECT  
FUSED  
DISCONNECT  
12V INVERTER  
(Total Battery Capacity  
= 200 Amp Hours)  
24V INVERTER  
(Total Battery Capacity  
= 200 Amp Hours)  
6V  
6V  
6V  
6V  
6V  
6V  
6V  
6V  
6V  
6V  
FUSED  
DISCONNECT  
6V  
6V  
6V  
48V INVERTER  
(Total Battery Capacity  
= 200 Amp Hours)  
6V  
6V  
Each individual 6-volt battery capacity = 100 amp hours  
NOTE: If cross-tyingis not required, the dash(- - -) connections are not needed.  
Figure 34, Series-Parallel Configuration: 6-Volt Battery Wiring  
12V  
12V  
12V  
12V  
12V  
12V  
12V  
12V  
12V  
12V  
12V  
12V  
FUSED  
DISCONNECT  
FUSED  
DISCONNECT  
24V INVERTER  
(Total Battery Capacity  
= 100 Amp Hours)  
48V INVERTER  
(Total Battery Capacity  
= 100 Amp Hours)  
Each individual 12-volt battery capacity = 50 amp hours  
NOTE: If cross-tyingis not required, the dash(- - -) connections are not needed.  
Figure 35, Series-Parallel Configuration: 12-Volt Battery Wiring  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
109  
Rev. C: February 2001  
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TECHNICAL INFORMATION  
BATTERY CABLE INDUCTANCE  
When current passes through a conductor a magnetic field is set up around the conductor. As this  
magnetic field builds, it induces voltage in any conductor that is close by, and it induces a voltage in the  
original conductor. The voltage induced into the original conductor is called self-inductance, and tends to  
oppose the current that produced it.  
The magnitude of the self-induced voltage is proportional to the size of the loop formed by a wire. The  
larger the loop, the larger the self-induced voltage. The positive and negative battery cables in a system  
are in reality only a single circuit (wire), and so the inductance of the battery circuit depends on how the  
cables are physically positioned or arranged with respect to one another.  
If battery cables are separated by a distance, they have much more inductance than if they are close  
together. If the two battery cables were coaxial there would be virtually no induced current flow since the  
magnetic fields would cancel one another. However, we dont have coaxial battery cables, but we can  
approximate them by taping the cables together every four to six inches. When the cables are taped  
together, the magnetic fields around each battery cable tend to cancel each other. When cables are  
separated the magnetic fields add together and increase the inductance of the battery cables. If you arent  
convinced that taping battery cables together helps reduce inductance, consider the following table of  
information collected by Xantrex. We tested two sixteen foot long #4/0 AWG battery cables connected  
together at one end and parallel to one another.  
Table 8, Battery Cable Inductance  
Distance Between  
Battery Cables  
Taped Together  
3.3  
12Separation  
48+ Separation  
Inductance  
in micro-Henries  
6.0  
8-9  
The above table shows that with only a foot of distance between the battery cables the inductance almost  
doubles, and at four feet between cables the inductance is almost three times the inductance of cables  
taped together.  
Since the induced voltage in a conductor varies as the inductance times the rate of change of current in  
the inductor, the induced voltage may be three times greater than it would be if cables were not taped  
together. For more advanced readers, consider flyback effects and the induced voltage spikes can get into  
the thousands of volts range if the battery were suddenly removed from the circuit (worst case).  
These induced voltage changes cause ripple in the battery cables and must be absorbed or filtered by the  
filter capacitors in the inverter. This ripple will lead to eventual premature breakdown of the filter capacitors  
and performance loss in the inverter.  
In addition to the problems mentioned, the induced current opposes the applied current (battery current)  
which directly causes a loss of inverter performance as greatly reduced efficiency.  
To avoid this problem, route your positive and negative DC cables in parallel, as close together as  
possible. Secure the cables against movement with clamps or straps every 18 inches. Avoid routing  
conductors near heat sources such as dry exhaust or furnace piping. Avoid chafing sources such as  
steering cables, engine shafts, and throttle connections.  
Hopefully this information gives a much more realistic and clear idea of why battery cables should be kept  
short and close together. Maximum performance is the goal of any well designed power system and the  
details such as this will help achieve the goal.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
110  
Rev. C: February 2001  
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TECHNICAL INFORMATION  
APPLICATIONS  
RESISTIVE LOADS  
These are the loads that the inverter finds the simplest and most efficient to drive. Voltage and current are  
in phase, or, in this case, in step with one another. Resistive loads usually generate heat in order to  
accomplish their tasks. Toasters, coffee pots and incandescent lights are typical resistive loads. Larger  
resistive loads--such as electric stoves and water heaters--are usually impractical to run off an inverter.  
Even if the inverter could accommodate the load, the size of battery bank required would be impractical.  
INDUCTIVE LOADS  
Any device that has a coil of wire in it probably has an inductive load characteristic. Most electronic  
devices have transformers (TVs, stereos, etc.) and are therefore inductive. Typically, the most inductive  
loads are motors. The most difficult load for the inverter to drive will be the largest motor you manage to  
start. With inductive loads, the rise in voltage applied to the load is not accompanied by a simultaneous  
rise in current. The current is delayed. The length of the delay is a measure of inductance. The current  
makes up for its slow start by continuing to flow after the inverter changes AC voltage polarity.  
Inductive loads, by their nature, require more current to operate than a resistive load of the same wattage  
rating, regardless of whether power is being supplied by an inverter, a generator or grid. Induction motors  
(motors without brushes) require 2 to 6 times their running current on start-up. The most demanding are  
those that start under load e.g. compressors and some pumps. The largest motor of this type that the  
inverter will run varies from 1/2 to 3/4 hp. Of the capacitor-start motors, typical in drill presses, band saws,  
etc., the largest you may expect to run is 1 to 1.5 hp. Universal motors are generally easier to start. The  
inverter may start up to 2.5 hp universal motors. Since motor characteristics vary, only testing will  
determine if a specific load can be started and how long it can be run.  
SUBMERSIBLE WELL PUMPS  
The well pump is often the hardest load to start for inverter system. Submersible pump motors are  
particularly hard because the motor is very narrow (in order to fit down the well) and draws extremely high  
starting current.  
When selecting a pump, check the LOCKED ROTOR AMPS in the motor specifications. This is usually  
the best guide to the maximum load the pump will place on the inverter. It must be less than the AC amps  
noted under the Maximum Output (RMS) given in the Specifications And Features section starting on  
page 118. Pump suppliers and well drillers often oversize the pump considerably in order to reduce  
complaints of poor pressure, low flow, etc. Get several quotations and explain that you are very concerned  
about the inverter being able to power the pump. It makes sense to operate a smaller pump longer instead  
of a larger pump for a shorter period of time when you are powering it from batteries or a solar electric  
system.  
When buying a pump, select a three-wire type. This refers to the electrical configuration of the power and  
starting windings in the pump motor. A three-wire pump requires a separate box at the top of the well for  
the starting circuit - a two-wire pump has the start electronics built inside. The separate starting box is  
preferred. If possible, select a relay type starting box instead of an all-electronic type - the relay types have  
been found to work better with inverters and generators. The relay types also allow use of a larger or  
additional starting capacitor - it may help if the inverter has a hard time starting the pump. Consult your  
pump supplier for more information.  
If a 220/240-Vac motor is required, you must either use two 120 Vac inverters in a stacked configuration  
or include a step-up transformer in the system. When used with a well pump, connect the step-up  
transformer after the pressure switch in order to reduce the load the transformer itself puts on the inverter.  
This requires that 120 Vac instead of 240 Vac be connected to the pressure switch.  
As a last resort, consider powering the well pump directly from the generator instead of the inverter. Many  
systems do not have enough battery capacity or excess power to handle a load as heavy as a well pump.  
Using the generator with a storage tank with several days capacity may be more economical than  
oversizing the inverter, battery and solar array just to power the well pump.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
111  
Rev. C: February 2001  
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TECHNICAL INFORMATION  
Page 1  
TROUBLESHOOTING GUIDE  
INVERTER - If ERROR LED comes on, see ERROR CAUSES section  
PROBLEM  
INDICATION  
SOLUTION  
DC voltage on the inverters DC  
Check the battery voltage, fuses or  
Unit will not come on  
terminals is incorrect.  
breakers and DC cable connections to  
the inverter  
(no LEDs are on) and the  
Control Panel Display is blank or off  
DC voltage on the inverters DC  
Have unit serviced  
terminals is correct  
Excessive load on output, unit is in over-temperature protection (needs to cool  
down), incorrect battery voltage.  
Unit comes on, but goes off quickly  
(several attempts made)  
See ERROR CAUSES section  
Correct AC voltage on Control Panel display but no AC voltage on inverter AC  
terminal block.  
No AC power output  
INVERTING LED is on, with no ERROR  
LED.  
Check for open circuit breaker on the inverter. If circuit breaker on the inverter is not  
open (popped), have the inverter serviced.  
Look at Control Panel display under  
Inverter voltsand check AC voltage on  
inverter AC terminal block.  
Correct AC voltage on Control Panel display and on inverter AC terminal block.  
Check for open AC output breakers or fuses and bad output wire connections  
AC voltage on Control Panel display or inverter AC terminal block is incorrect: have  
unit serviced  
Have unit serviced  
AC1/AC2 IN GOOD LED is flashing  
(with no AC connected to the input).  
AC load too small for Search mode  
circuit to detect  
Reduce search watts setting, increase  
load above search watts setting, or defeat  
search mode by selecting ON.  
No AC power output  
INVERT LED is flashing.  
Insufficient DC current being provided  
to the inverter to operate the AC loads  
Check the battery voltage, fuses or  
breakers and cable connections.  
Low AC power output or  
Low surge power  
INVERT LED is on  
Ensure the battery bank is sufficient  
(check for low DC voltage while running  
the load).  
(AC inductive loads are not running at  
full speed).  
Ensure the cable length and size is  
correct (see owner's manual for correct  
cable). Tie the battery cables together to  
reduce inductance.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
Page  
112  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
TECHNICAL INFORMATION  
TROUBLESHOOTING GUIDE  
Page 2  
BATTERY CHARGER - If ERROR LED comes on, see ERROR CAUSES section.  
PROBLEM  
INDICATION  
SOLUTION  
AC frequency at the AC input terminal  
is out-of- tolerance (too high or low) or  
AC voltage outside Upper/Lower VAC  
limitsettings  
If AC source is a generator, adjust AC  
voltage or frequency accordingly.  
AC IN GOOD LED is flashing, but will  
not start charging  
(allow 40 seconds to synchronize)  
Check for the correct AC voltage or  
frequency at the AC input terminal.  
AC frequency at the AC input terminal  
drops out-of- tolerance (too high or low)  
or AC voltage falls outside  
If AC source is generator, adjust AC  
voltage/frequency accordingly.  
Charger drops off before full  
charging has finished. (No ERROR  
comes on)  
Reduce your Set AC Ampssetting to  
limit the pull on the AC source.  
Upper/Lower VAC limitsettings.  
Check for the correct AC voltage or  
frequency using the Control Panel.  
Open the Upper/Lower VAC limit’  
settings windowto allow  
synchronization.  
Circuit breaker on inverter is open  
Engage circuit breaker on side of unit  
(press hard on breaker button to ensure  
it is engaged)  
Ambient temperature may be high  
causing unit to overheat and ramp down  
the charging.  
Cool the unit down or check the inverter  
cooling fan, or check for anything  
preventing air flow  
Cold temperature around batteries with  
BTS (Battery Temperature Sensor)  
installed may be causing unit to reach  
HIGH BATTERY CUTOUT setting  
Disconnect BTS during charging or  
increase HIGH BATTERY CUTOUT  
setting.  
Charger drops off before full  
charging (or equalization) has  
finished  
ERROR LED flashes and AC output  
drops momentarily.  
Charger drops off before full  
charging has finished.  
See ERROR CAUSES section  
(ERROR comes on)  
Loose or corroded battery connections  
Loose AC input connections  
Weak/soft batteries  
Check and clean all connections  
Check all AC wiring connections  
Replace batteries  
Charger output is low  
Battery cables too small or too long  
Refer to cable and battery  
recommendations in owners manual  
NOTE: To bring batteries that are cold to the correct state of charge may require  
charging at a higher voltage. Remove the BTS and determine if your voltage returns  
to the bulk/float voltage  
Batteries being charged above the  
Bulk/Float setting  
Temperature probe is installed  
Refer to the 'Battery TempComp volts  
DC' reading while charging.  
(a) Ensure that the temperature probe  
is not in a cold area or has not fallen off  
the batteries.  
(b) Ensure that there is no other DC  
charging source on the batteries  
Temperature probe is not installed  
Refer to the ''Battery actual volts DC'  
reading while charging.  
Ensure that there is no other DC  
charging source on the batteries  
Ensure your 'Set Low Battery Cut In  
VDC' setting is lower than the 'Set Bulk  
volts DC'' setting  
Low Battery Cut In voltage is set to high  
to prevent the charger from going into  
the float charge  
LBX mode is enabled, but you do not  
want the unit to go into Float mode  
(Float LED is ON)  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
113  
Part No. 2031-5  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
TECHNICAL INFORMATION  
TROUBLESHOOTING GUIDE  
Page 3  
ERROR CAUSES - ERROR LED is On or Flashing (look under the ERROR CAUSES display)  
INDICATION  
SOLUTION  
Disconnect all wires on the AC input and output.  
OVER CURRENT  
Excessive load on the AC output  
Reset the inverter by pressing the On/Off switch to OFF, then to SRCH or ON. If  
unit comes on, then check AC wire system (shorts or miswired)  
Charging: AC input voltage may be too high, check for high input ac voltage  
Inverting: operating too large of a load for too long, remove excessive loads  
Ambient temperature may be high  
TRANSFORMER OVERTEMP or  
HEATSINK OVERTEMP  
Unit is warm/hot to the touch  
Let inverter cool down and try  
restarting.  
Inverter cooling fan may have failed hold a piece of paper to inverter vents to  
check fan, (fan is hard to hear).  
Inverter airflow intake may be blocked (small clearance or clogged).  
MAX CHARGE AMPS setting needs to be lowered (charging setting is too high  
based on ambient temperature around inverter).  
Check for the correct battery voltage at the inverters DC input terminals.  
HIGH BATTERY VOLTAGE or  
LOW BATTERY VOLTAGE  
High battery voltage: Ensure your DC source is regulated below your High battery  
cut-out or adjust your HIGH BATTERY CUT-OUT to a higher setting  
Battery voltage is not within the High or  
Low battery cut-out settings.  
Low battery voltage: Check for an external DC load on the batteries. Check the  
condition of batteries and recharge if possible or adjust your LOW BATTERY CUT-  
OUT to a lower setting.  
The cause for this error could be high battery voltage or an excessively large load.  
LOW AC OUTPUT VOLTAGE  
The AC output voltage has fallen below  
SET INPUT LOWER LIMIT VAC  
setting.  
Check for proper AC input and output wiring (output of inverter is wired to an AC  
source)  
AC SOURCE WIRED TO OUTPUT  
Indicates that an AC source was wired  
directly to the AC output.  
Reset the auto generator control system by selecting OFF and then AUTO or ON  
from the SET GENERATOR menu.  
GENERATOR START ERROR  
Five attempts were made to start the  
generator without obtaining the correct  
input AC voltage or frequency  
Check the generators output voltage and frequency (ensure that the 'Set Input lower  
GENERATOR SYNC ERROR  
or upper limit VAC' is set correctly)  
Indicates that the generator was  
running but was not operating within the  
voltage or frequency tolerances and  
was not able to connect  
This is an advisory ERROR only and will not cause any other effect.  
GEN MAX RUN TIME ERROR  
If you continue to have repeated error conditions, then increasing the SET  
MAXIMUM RUN TIME menu item setting, under the GEN AUTO SETUP (12) menu  
heading, may be necessary for your application.  
Indicates that the generator ran for a  
period of time that exceeded the 'SET  
MAX RUN TIME'  
(a) Voltage has not reached 80 VAC during the 'MAX CRANK PERIOD' or  
GEN UNDER/OVER SPEED  
(b) Voltage did not maintain >80 VAC for the majority of time while the inverter was  
charging  
Indicates that five 'Auto generator start  
attempts' have occurred without  
successfully starting the generator  
No problem with AC source or inverter. The error LED is a visual indicator to fine  
tune your AC frequency (this error does not affect operation)  
Error LED is flashing (no error under  
ERROR CAUSES display)  
AC source frequency is just out of  
tolerance  
(53-57 Hz or 63-67 Hz)  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
Page  
114  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
TECHNICAL INFORMATION  
INVERTER/CHARGER TERMINOLOGY  
The following is a glossary of terms with which you may not be familiar while reading this manual. They  
appear in the description of inverter and battery charger operation.  
Absorption Stage - In this second stage of three-stage charging, the batteries are held at a constant  
voltage (the bulk voltage setting) and the battery is charged to its maximum capacity.  
AC - Alternating Current. Electrical current that varies with time. The rate at which the voltage changes  
polarity is the frequency in Hertz (Hz).  
Ampacity The ampacity of a wire is its current carrying capacity with reference to the cross-sectional  
area of the conductors, the temperature rating of the insulation and the ambient temperature.  
Automatic Transfer Relay (inside the inverter) - An automatic switch that switches between inverter  
and charger mode depending on availability of AC input power. If AC is present, the unit will be a  
battery charger; when AC goes away, the unit becomes an inverter.  
Bulk Charge Stage - This is the first of the three stages in three stage charging. In this stage, a constant  
current is fed to the batteries and as they accept the current the battery voltage will rise.  
Current (Amps) - The volume of electricity flowing through a conductor. Equivalent to a volume of water  
flowing through a hose.  
DC - Direct Current. Electrical current that does not vary with time.  
Deep Cycle - A deep cycle occurs when a battery is discharged to less than 20% of its capacity (80%  
depth-of-discharge).  
Deep Cycle Battery - A battery designed to be routinely discharged to 20% of its maximum capacity  
without damage. This is the type of battery most commonly used with an inverter system.  
Digital VoltMeter (DVM):  
True RMS - A voltmeter that incorporates a RMS converter to read true RMS for any waveform  
shape.  
Averaging Type - A voltmeter that requires a sine wave waveform shape to provide an accurate  
reading.  
Efficiency - Usually given as a percentage, efficiency is the ratio of the output to the input. The efficiency  
changes with power output levels of any inverter.  
Electrolyte - Typically a mixture of water and sulfuric acid, it is commonly referred to as battery acid.  
Equalization - Controlled overchargingof the battery causing it to bubble and mix. This reduces  
stratification.  
Float stage - During the third stage of three stage charging, the voltage and current are reduced to a level  
that will trickle charge or maintenance charge the battery. This assures the battery remains fully  
charged even while sitting.  
Fuse or Disconnect- An electrical pressure relief valve. When current exceeds a preset limit the fuse or  
disconnect will fail before the wiring or equipment it is protecting. Disconnects are also called circuit  
breakers. These are usually resettable and can act as a switch to turn off power to equipment for  
servicing.  
Grid (The grid) - Also called the utility grid, this refers to the public power distribution system.  
Impedance - Opposition to flow of alternating current (AC)  
Islanding - The condition present when the utility power grid fails and the inverter attempts to power the  
grid. An inverter which is islanding protectedsenses the loss of AC power from the grid and does not  
back feed into the grid system.  
LED - Light Emitting Diode. A light made up of semi-conducting material.  
Line Tie - Term used when the inverter is connected to the public power or gridsystem.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
115  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
TECHNICAL INFORMATION  
Load(s) - Any electrical item which draws power. (i.e., lights, radio, washer/dryer, refrigerator, etc.)  
Locked Rotor Amps - The current drawn by an electric motor with the shaft or rotor stopped and locked  
in position. This can be used to determine if an inverter has enough surge current to start a motor. If  
the inverter is capable of producing more amperage than the locked rotor amps rating of a motor, it  
will most likely start the motor easily.  
Modified Sine wave - Also called a quasi sine wave or a modified square wave. This output looks like a  
one step staircase. Most loads that will run from a sine wave will run from a modified sine wave.  
However, things such as clocks and furnace controllers may have trouble. (See graph below)  
Figure 36, AC Waveforms  
NEC - National Electric Code. The guidelines and acceptable practices for electrical installations. It is a  
book published every three years.  
Off Grid - Not connected to public power in any way  
Output Waveform- Shape of the wave that alternating current makes as its voltage rises and falls with  
time.  
Pass Through Current - The amount of current the inverter can safely pass directly from the AC input to  
the AC output.  
Plates - Originally made of lead, now fabricated from lead oxide. Plates connect to the battery terminals  
and provide a structure for the chemicals that create current. There are several plates in each cell;  
each insulated from the other by separators.  
PV - Photovoltaic. Solar powered.  
Resistance - The opposition to flow of direct current (DC)  
RMS - Root Mean Square, a measure of AC voltage that would provide the equivalent heating value  
across a resistor as a DC source of the same voltage.  
Sellback or Selling Back To The Grid - Some inverters have the capability to take energy stored in  
batteries or from solar panels and put it back into the utility grid. The Public Utility Company will then  
pay you for using your energy. Check with the Public Utility Company before attempting this.  
Sine Wave An AC waveform that looks like rolling waves on water. It rises and falls smoothly with time.  
The grid puts out a sine waveform. Any plug in AC equipment will operate from a sine wave output.  
This is shown in Figure 36, AC Waveforms.  
Square Wave - The simplest AC waveform, this is shown in Figure 36, AC Waveforms. Some types of  
equipment behave strangely when run from a square wave.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
116  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
TECHNICAL INFORMATION  
Stacking:  
Series - Two inverters operating together to produce twice the power and voltage of a single inverter.  
Required when operating 240 VAC loads and separate 120 VAC loads from either inverter.  
Parallel - Two inverters operating together to provide twice the continuous and surge capacity on a  
single output circuit. Required when a single load is too large for one inverter.  
The units must be stackable, and an interface cable must be utilized. See the manual for details on  
stacking if it is an option.  
Stratification - Over time, a batterys electrolyte (liquid) tends to separate. The electrolyte at the top of the  
battery becomes watery while at the bottom it becomes more acidic. This effect is corrosive to the  
plates.  
Sulfating - As a battery discharges, its plates become covered with lead sulfate. During recharging, the  
lead sulfate leaves the plates and recombines with the electrolyte. If the lead sulfate remains on the  
plates for an extended period of time (over two months), it hardens, and recharging will not remove it.  
This reduces the effective plate area and the batterys capacity.  
Temperature Compensation - Peak available battery voltage is temperature dependent. As ambient  
temperatures fall, the proper voltage for each charge stage needs to be increased. An optional  
temperature-probe (BTS) automatically re-scales charge-voltage settings to compensate for ambient  
temperatures. The compensation slope based on cell voltage is -2.17 mv per degree Fahrenheit  
(30 mv per degree Celsius) per cell for lead-acid batteries.  
Voltage - The pressure of electrical flow. Equivalent to water pressure in a hose.  
Watts - Measure of power output or utilization. Watts = Volts x Amps.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
117  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
TECHNICAL INFORMATION  
SPECIFICATIONS AND FEATURES (60 Hz Models)  
Note: All specifications are subject to change without notice.  
MODEL  
SW2512 SW4024 SW4048 SW5548 SW4024K SW4048K SW4024W  
General Specifications  
Nominal DC Input Voltage  
AC Output Voltage (RMS)  
Nominal Frequency  
12 Vdc  
120 vac  
24 Vdc  
120 vac  
48 Vdc  
120 vac  
48 Vdc  
120 vac  
24 Vdc  
105 vac  
48 Vdc  
105 vac  
24 Vdc  
220 vac  
60 Hz  
60 Hz  
60 Hz  
60 Hz  
60 Hz  
60 Hz  
60 Hz  
2500 VA  
21 amps AC  
60 amps AC  
90%  
4000 VA  
33 amps AC  
78 amps AC  
94%  
4000 VA  
33 amps AC  
78 amps AC  
95%  
5500 VA  
46 amps AC  
78 amps AC  
96%  
4000 VA  
4000 VA  
38 amps AC  
78 amps AC  
95%  
4000 VA  
Continuous Power @ 20°C  
Continuous Output (@ 25°C)  
Maximum Output (RMS)  
Efficiency (peak)  
38 amps AC  
78 amps AC  
94%  
18 amps AC  
39 amps AC  
94%  
Automatic Transfer Relay  
Maximum Charging Rate  
Charger Regulation Method  
60 amps AC  
60 amps AC  
60 amps AC  
60 amps DC  
3 stage  
60 amps AC  
75 amps DC  
3 stage  
60 amps AC  
120 amps DC  
3 stage  
60 amps AC  
60 amps DC  
3 stage  
30 amps AC  
120 amps DC  
3 stage  
150 amps DC 120 amps DC  
3 stage  
3 stage  
DC Input Requirements  
Search Mode  
0.08 A (1 W)  
0.04 A (1 W) 0.025 A (1 W) 0.04 A (1 W)  
0.04 A (1 W) 0.025 A (1 W) 0.04 A (1 W)  
On Mode (no load - idle)  
At Full Rated Power  
Short Circuited Output  
Input Voltage Range  
1.0 A (12 W) 0.66 A (16 W) 0.33 A (16 W) 0.40 A (20 W) 0.66 A (16 W) 0.33 A (16 W) 0.66 A (16W)  
275 amps  
700 amps  
200 amps  
360 amps  
100 amps  
180 amps  
137 amps  
180 amps  
200 amps  
360 amps  
100 amps  
180 amps  
200 amps  
360 amps  
11.8 to 16.5 Vdc 22 to 33 Vdc  
44 to 66 Vdc  
44 to 66 Vdc  
22 to 33 Vdc  
44 to 66 Vdc  
22 to 33 Vdc  
AC Output Characteristics  
AC Output Waveform  
Voltage Regulation  
Sine wave, 34 to 52 steps per cycle  
± 2%  
Total Harmonic Distortion  
Power Factor Allowed  
Frequency Regulation  
Load Sensing Range  
3 to 5% (stand alone operation)  
-1 to 1  
± 0.04% (crystal regulated)  
16 to 240 Watts  
Standard Features  
Control Panel  
Built-in 2 line back-lit alphanumeric liquid crystal display with eight LED status indicators  
Adjustable low battery cut out and cut in with current compensation  
Low Battery Protection  
Battery Temperature Sensor  
Auto Generator Control system  
Auxiliary Relays  
15 foot plug in battery temperature sensor with phone type jack (can be extended)  
Automatic generator control system for two and three wire start generators (no glow-plug control)  
Three user adjustable voltage controlled signal relays for control of loads or charging sources  
Variable speed brushless DC fans  
Fan Cooling  
Options  
Remote Control Panel  
SWRC  
SWRC  
SWRC  
SWRC  
SWRC  
SWRC  
SWRC  
Stacking Interface for 2X power  
(* requires two inverters)  
SWI *  
SWI*  
SWI *  
SWI *  
No  
No  
No  
(120/240 vac) (120/240 vac) (120/240 vac) (120/240 vac)  
Conduit Box  
SWCB SWCB SWCB SWCB  
SWCB  
SWCB  
SWCB  
Environmental Limitations  
Enclosure Type  
Indoor, ventilated, steel chassis with powdercoat finish  
Specified Temp Range  
Allowed Temperature Range  
Non-operating Temperature  
Altitude Limit Operating  
Altitude Limit Non-operating  
Dimensions - Inverter Only  
Dimensions - Shipping  
Mounting  
32°F to 104°F (0°C to +40°C) (output will meet specified tolerances)  
-40°F to 140°F (-40°C to +60°C) (output may not meet specified tolerances)  
-67°F to 284°F (-55°C to +75°C)  
15,000 feet (5000 meters)  
50,000 feet (16,000 meters)  
15(38 cm) high, 22.5(57 cm) wide, 9(23 cm) deep (when wall mounted)  
20.5(52 cm), 27(69 cm), 15.5(40 cm)  
Wall or Shelf Mount  
Weight - Inverter Only  
Weight - Shipping  
90 lb (42 kg ) 105 lb (48 kg) 105 lb (48 kg) 136 lb (63 kg ) 105 lb (48 kg) 105 lb (48 kg) 105 lb (48 kg)  
96 lb (44 kg) 111 lb (50 kg) 111 lb (50 kg) 143 lb (65 kg) 111 lb (50 kg) 111 lb (50 kg) 111 lb (50 kg)  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
118  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
TECHNICAL INFORMATION  
SPECIFICATIONS AND FEATURES (50 Hz Models)  
Note: All specifications are subject to change without notice.  
MODEL  
SW2612E SW3024E SW3048E SW4548E SW3024J SW4048J SW4548A  
General Specifications  
Nominal DC Input Voltage  
AC Output Voltage (RMS)  
Nominal Frequency  
12 Vdc  
230 Vac  
24 Vdc  
230 Vac  
48 Vdc  
230 Vac  
48 Vdc  
230 Vac  
24 Vdc  
105 Vac  
48 Vdc  
105 Vac  
48 Vdc  
240 Vac  
50 Hz  
50 Hz  
50 Hz  
50 Hz  
50 Hz  
50 Hz  
50 Hz  
2600 VA  
11 amps AC  
28 amps AC  
90%  
3300 VA  
14 amps AC  
34 amps AC  
94%  
3300 VA  
14 amps AC  
34 amps AC  
95%  
4500 VA  
20 amps AC  
34 amps AC  
96%  
3300 VA  
4000 VA  
33 amps AC  
78 amps AC  
95%  
4500 VA  
20 amps AC  
34 amps AC  
96%  
Continuous Power @ 20°C  
Continuous Output (@ 25°C)  
Maximum Output (RMS)  
Efficiency (peak)  
31 amps AC  
78 amps AC  
94%  
Automatic Transfer Relay  
Maximum Charging Rate  
Charger Regulation Method  
30 amps AC  
30 amps AC  
30 amps AC  
50 amps DC  
3 stage  
30 amps AC  
60 amps DC  
3 stage  
60 amps AC  
100 amps DC  
3 stage  
60 amps AC  
60 amps DC  
3 stage  
30 amps AC  
60 amps DC  
3 stage  
150 amps DC 100 amps DC  
3 stage  
3 stage  
DC Input Requirements  
Search Mode  
0.08 A (1 W)  
1.6 A (12 W)  
300 amps  
0.04 A (1 W) 0.025 A (1 W) 0.04 A (1 W)  
0.04 A (1 W) 0.025 A (1 W) 0.04 A (1 W)  
On Mode (no load - idle)  
At Full Rated Power  
0.66 A (16W) 0.33 A (16 W) 0.40 A (20 W) 0.40 A (20 W) 0.33 A (16 W) 0.40 A (20 W)  
166 amps  
320 amps  
83 amps  
160 amps  
137 amps  
180 amps  
137 amps  
180 amps  
83 amps  
160 amps  
137 amps  
180 amps  
Short Circuited Output  
Input Voltage Range (VDC)  
700 amps  
11.8 to 16.5 Vdc  
22 to 33 Vdc  
44 to 66 Vdc  
44 to 66 Vdc  
44 to 66 Vdc  
44 to 66 Vdc  
44 to 66 Vdc  
AC Output Characteristics  
AC Output Waveform  
Voltage Regulation  
Sine wave, 34 to 52 steps per cycle  
± 2%  
Total Harmonic Distortion  
Power Factor Allowed  
Frequency Regulation  
Load Sensing Range  
3 to 5% (stand alone operation)  
-1 to 1  
± 0.04% (crystal regulated)  
16 to 240 Watts  
Standard Features  
Control Panel  
Built-in 2 line back-lit alphanumeric liquid crystal display with eight LED status indicators  
Adjustable low battery cut out and cut in with current compensation  
Low Battery Protection  
Battery Temperature Sensor  
Auto Generator Control system  
Auxiliary Relays  
15 foot plug in battery temperature sensor with phone type jack (can be extended)  
Automatic generator control system for two and three wire start generators (no glow-plug control)  
Three user adjustable voltage controlled signal relays for control of loads or charging sources  
Variable speed brushless DC fans  
Fan Cooling  
Options  
Remote Control Panel  
SWRC  
No  
SWRC  
No  
SWRC  
No  
SWRC  
No  
SWRC  
No  
SWRC  
No  
SWRC  
No  
Stacking Interface for 2X power  
(*requires two inverters)  
Conduit Box  
SWCB  
SWCB  
SWCB  
SWCB  
SWCB  
SWCB  
SWCB  
Environmental Limitations  
Enclosure Type  
Indoor, ventilated, steel chassis with powdercoat finish  
Specified Temp Range  
Allowed Temperature Range  
Non-operating Temperature  
Altitude Limit Operating  
Altitude Limit Non-operating  
Dimensions - Inverter Only  
Dimensions - Shipping  
Mounting  
32°F to 104°F (0°C to +40°C) (output will meet specified tolerances)  
-40°F to 140°F (-40°C to +60°C) (output may not meet specified tolerances)  
-67°F to 284°F (-55°C to +75°C)  
15,000 feet (5000 meters)  
50,000 feet (16,000 meters)  
15(38 cm) high, 22.5(57 cm) wide, 9(23 cm) deep (when wall mounted)  
20.5(52 cm), 27(69 cm), 15.5(40 cm)  
Wall or Shelf Mount  
Weight - Inverter Only  
Weight - Shipping  
95 lb (43 kg ) 105 lb (48 kg) 105 lb (48 kg) 136 lb (63 kg) 105 lb (48 kg) 105 lb (48 kg) 136 lb (63 kg)  
110 lb (50 kg) 111 lb (50 kg) 111 lb (50 kg) 143 lb (65 kg) 111 lb (50 kg) 111 lb (50 kg) 143 lb (65 kg)  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
119  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
TECHNICAL INFORMATION  
DIMENSIONS  
Figure 37, SW Series Dimensions: With AC Access Covers Showing Knockout Sizes  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
120  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
TECHNICAL INFORMATION  
INSTALLATION DIAGRAMS  
The following diagrams and information is provided to assist you or your system installer with the design  
and installation of the TraceSW Series Inverter/Charger. Due to the variety of applications, models  
available, and differences in local and national electrical codes, these diagrams and information should be  
used as general guidelines only. You must consider your application and local and national electrical  
codes when designing and installing your system.  
Figure 38, Installation Diagram, 120 VAC, 1 Phase, Grid Connected, Generator Backup  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
121  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
TECHNICAL INFORMATION  
Figure 39, Installation Diagram, 240 VAC, 3 Wire, Grid Connected, Generator Backup  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
122  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
TECHNICAL INFORMATION  
USER SETTINGS WORKSHEETS  
Your SW Series Inverter/Charger may have USER and/or SETUP operating settings that are different or  
are changed from the standard factory settings. The USER DEFAULT settings are the same for all  
models. The SETUP DEFAULT settings are dependent on the specific model of the SW Series  
Inverter/Charger. Worksheets are provided for domestic (US) models. Use the following Worksheets to  
record your specific USER and SETUP operating settings for:  
SW Series Inverter/Charger Model SW  
, S/N  
.
USER MENU  
SELECTION  
RANGE  
DEFAULT  
SETTINGS  
USER  
SETTINGS  
MENU HEADING  
MENU ITEM  
Inverter Mode  
Generator Mode  
1 Set Inverter  
OFF SRCH ON CHG  
OFF  
2 Set Generator  
OFF AUTO ON EQ  
DISPLAY  
OFF  
NO  
NO  
NO  
NO  
NO  
NO  
NO  
None  
None  
None  
None  
None  
None  
None  
None  
Gen Under/Over Speed  
Generator Start Error  
Generator Sync Error  
Gen Max Run Time Error  
Load Amp Start Ready  
Voltage Start Ready  
Exercise Start Ready  
DISPLAY  
DISPLAY  
DISPLAY  
DISPLAY  
DISPLAY  
DISPLAY  
Trace Engineering  
Meters  
3 Revision 4.01  
DISPLAY  
None  
4 Inverter/Charger Amps AC  
Input Amps AC  
DISPLAY  
DISPLAY  
DISPLAY  
DISPLAY  
DISPLAY  
DISPLAY  
DISPLAY  
DISPLAY  
DISPLAY  
00  
None  
None  
None  
None  
None  
None  
None  
None  
None  
00  
Load Amps AC  
00  
Battery Actual Volts DC  
Battery TempComp Volts DC  
Inverter Volts AC  
Battery Volts  
Battery Volts  
00  
00  
00  
60  
Grid (AC1) Volts AC  
Generator (AC2) Volts AC  
Read Frequency Hertz  
Error Causes  
5 Over Current  
DISPLAY  
DISPLAY  
DISPLAY  
DISPLAY  
DISPLAY  
DISPLAY  
DISPLAY  
DISPLAY  
DISPLAY  
DISPLAY  
DISPLAY  
DISPLAY  
DISPLAY  
NO  
NO  
NO  
NO  
NO  
NO  
NO  
NO  
NO  
NO  
NO  
NO  
NO  
None  
None  
None  
None  
None  
None  
None  
None  
None  
None  
None  
None  
None  
Transformer Overtemp  
Heatsink Overtemp  
High Battery Voltage  
Low Battery Voltage  
Low AC Output Voltage  
Manual Off  
AC Source Wired to Output  
External Error (Stacked)  
Generator Start Error  
Generator Sync Error  
Gen Maximum Run Time Error  
Gen Under/Over Speed  
Time of Day  
6
SET HR/MIN/SEC  
00:00  
Generator Timer  
7 Start Quiet Time H:M  
End Quiet Time H:M  
00:00 – 23:59  
00:00 – 23:59  
08:00  
08:00  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
123  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
TECHNICAL INFORMATION  
SETUP MENU 12 VDC (120 VAC/60HZ) MODELS  
To access the SETUP MENU, press the RED and GREEN buttons on your CONTROL PANEL (or  
SWRC) at the same time. To exit the Setup Menu, press the ON/OFF MENU button or use the down  
MENU HEADING button until you reach the USER MENU (menu headings 1 8).  
SELECTION  
RANGE  
DEFAULT  
SETTINGS  
USER  
SETTINGS  
MENU HEADING  
MENU ITEM  
Inverter Setup  
9 Set Grid Usage  
FLT SELL SLT LBX  
0.80 25.5  
00 - 255  
FLT  
11.0  
15  
Set Low Battery cut out VDC  
Set LBCO delay minutes  
Set Low battery cut in VDC  
Set High battery Cut Out VDC  
Set search watts  
00.0 16.5  
00.0 16.5  
00 - 240  
13.0  
16.0  
48  
Set search spacing  
00 255  
59  
Battery Charging  
10 Set Bulk volts DC  
Set Absorption time h:m  
Set Float volts DC  
Set Equalize volts DC  
Set Equalize time h:m  
Set Max Charge amps AC  
Set Temp Comp  
10.0 16.0  
00:00 23:50  
10.0 16.0  
10.0 16.0  
00:00 23:50  
01 - 25  
14.4  
02:00  
13.4  
14.4  
02:00  
20  
LeadAcid Nicad  
LeadAcid  
AC Inputs  
11 Set Grid (AC1) amps AC  
Set Gen (AC2) amps AC  
00 - 63  
00 - 63  
60  
30  
Set Input lower limit VAC  
Set Input upper limit VAC  
80 - 111  
128 - 149  
108  
132  
Gen Auto Start Setup  
12 Set Load Start amps AC  
Set Load Start delay min  
Set Load Stop delay min  
Set 24 hr start volts DC  
Set 2 hr start volts DC  
Set 15 min start volts DC  
Read LBCO 30 sec start VDC  
Set Exercise period days  
Set Maximum run time h:m  
00 - 63  
00.0 25.5  
00.0 25.5  
05.0 25.5  
05.0 16.5  
05.0 16.5  
05.0 16.5  
00 - 255  
33  
05.0  
05.0  
12.3  
11.8  
11.3  
11.0  
30  
00:00 23:50  
08:00  
Gen Starting Details  
13 Set RY7 Function  
GlowStop Run  
16 - 255  
00 - 255  
01 - 15  
Run  
60  
Set Gen warmup seconds  
Set Pre Crank seconds  
Set Max Cranking seconds  
Set Post Crank seconds  
10  
10  
00 - 255  
30  
Auxiliary Relays R9 R10  
14 Set Relay 9 volts DC  
R9 Hysteresis volts DC  
Set Relay 10 volts DC  
R10 Hysteresis volts DC  
Set Relay 11 volts DC  
R11 Hysteresis volts DC  
00.0 16.5  
00.1 12.8  
00.0 16.5  
00.1 12.8  
00.0 16.5  
00.1 12.8  
00:00 23:50  
14.5  
01.0  
14.8  
01.0  
15.0  
01.0  
00:00  
Bulk Charge Trigger Timer 15 Start Bulk Time H:M  
Low Battery Transfer (LBX) 16 Set Low Battery transfer VDC  
Set Low Battery cut in VDC  
05.0 16.5  
05.0 16.5  
11.3  
13.0  
Battery Selling  
17 Set Battery Sell volts DC  
Set Max Sell amps AC  
10.0 16.0  
13.4  
30  
01 - 25  
Grid Usage Timer  
18 Set Start Charge time h:m  
End Stop Charge time h:m  
00:00 23:50  
00:00 23:50  
21:00  
21:00  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
124  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
TECHNICAL INFORMATION  
SETUP MENU 24 VDC (120 VAC/60HZ) MODELS  
To access the SETUP MENU, press the RED and GREEN buttons on your CONTROL PANEL (or  
SWRC) at the same time. To exit the Setup Menu, press the ON/OFF MENU button or use the down  
MENU HEADING button until you reach the USER MENU (menu headings 1 8).  
SELECTION  
RANGE  
DEFAULT  
SETTINGS  
USER  
SETTINGS  
MENU HEADING  
MENU ITEM  
Inverter Setup  
9 Set Grid Usage  
FLT SELL SLT LBX  
16.0 35.5  
00 - 255  
FLT  
22.0  
15  
Set Low Battery cut out VDC  
Set LBCO Delay minutes  
Set Low battery cut in VDC  
Set High battery cut out VDC  
Set search watts  
10.0 35.5  
10.0 33.0  
00 - 240  
26.0  
32.0  
48  
Set search spacing  
00 255  
59  
Battery Charging  
10 Set Bulk volts DC  
Set Absorption time h:m  
Set Float volts DC  
Set Equalize volts DC  
Set Equalize time h:m  
Set Max Charge amps AC  
Set Temp Comp  
20.0 32.0  
00:00 23:50  
20.0 32.0  
20.0 32.0  
00:00 23:50  
01 - 35  
28.8  
02:00  
26.8  
28.8  
02:00  
30  
LeadAcid Nicad  
LeadAcid  
AC Inputs  
11 Set Grid (AC1) amps AC  
Set Gen (AC2) amps AC  
00 - 63  
00 - 63  
60  
30  
Set Input lower limit VAC  
Set Input upper limit VAC  
80 - 111  
128 - 149  
108  
132  
Gen Auto Start Setup  
12 Set Load Start amps AC  
Set Load Start delay min  
Set Load Stop delay min  
Set 24 hr start volts DC  
Set 2 hr start volts DC  
Set 15 min start volts DC  
Read LBCO 30 sec start VDC  
Set Exercise period days  
Set Maximum run time h:m  
00 - 63  
00.0 25.5  
00.0 25.5  
10.0 35.5  
10.0 35.5  
10.0 35.5  
10.0 35.5  
00 - 255  
33  
05.0  
05.0  
24.6  
23.6  
22.6  
22.0  
30  
00:00 23:50  
08:00  
Gen Starting Details  
13 Set RY7 Function  
GlowStop Run  
16 - 255  
00 - 255  
01 - 15  
Run  
60  
Set Gen warmup seconds  
Set Pre Crank seconds  
Set Max Cranking seconds  
Set Post Crank seconds  
10  
10  
00 - 255  
30  
Auxiliary Relays R9 R10  
14 Set Relay 9 volts DC  
R9 Hysteresis volts DC  
Set Relay 10 volts DC  
R10 Hysteresis volts DC  
Set Relay 11 volts DC  
R11 Hysteresis volts DC  
10.0 35.5  
00.1 12.8  
10.0 35.5  
00.1 12.8  
10.0 35.5  
00.1 12.8  
00:00 23:50  
29.0  
02.0  
29.5  
02.0  
30.0  
02.0  
00:00  
Bulk Charge Trigger Timer 15 Start Bulk Time H:M  
Low Battery Transfer (LBX) 16 Set Low Battery transfer VDC  
Set Low Battery cut in VDC  
10.0 35.5  
10.0 35.5  
22.6  
26.0  
Battery Selling  
17 Set Battery Sell volts DC  
Set Max Sell amps AC  
20.0 32.0  
26.8  
30  
01 - 35  
Grid Usage Timer  
18 Set Charge time h:m  
End Charge time h:m  
00:00 23:50  
00:00 23:50  
21:00  
21:00  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
125  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
TECHNICAL INFORMATION  
SETUP MENU 48 VDC (120 VAC/60HZ) MODELS  
To access the SETUP MENU, press the RED and GREEN buttons on your CONTROL PANEL (or  
SWRC) at the same time. To exit the Setup Menu, press the ON/OFF MENU button or use the down  
MENU HEADING button until you reach the USER MENU (menu headings 1 8).  
SELECTION  
RANGE  
DEFAULT  
SETTINGS  
USER  
SETTINGS  
MENU HEADING  
MENU ITEM  
Inverter Setup  
9 Set Grid Usage  
FLT SELL SLT LBX  
32.0 70.0  
00 - 255  
FLT  
44.0  
15  
Set Low Battery cut out VDC  
Set LBCO delay minutes  
Set Low battery cut in VDC  
Set High battery cut out VDC  
Set search watts  
20.0 71.0  
20.0 66.0  
00 - 240  
52.0  
64.0  
48  
Set search spacing  
20 255  
59  
Battery Charging  
10 Set Bulk volts DC  
Set Absorption time h:m  
Set Float volts DC  
Set Equalize volts DC  
Set Equalize time h:m  
Set Max Charge amps AC  
Set Temp Comp  
40.0 64.0  
00:00 23:50  
40.0 64.0  
40.0 64.0  
00:00 23:50  
01 - 35  
57.6  
02:00  
53.6  
57.6  
02:00  
30  
LeadAcid Nicad  
LeadAcid  
AC Inputs  
11 Set Grid (AC1) amps AC  
Set Gen (AC2) amps AC  
00 - 63  
00 - 63  
60  
30  
Set Input lower limit VAC  
Set Input upper limit VAC  
80 - 111  
128 - 149  
108  
132  
Gen Auto Start Setup  
12 Set Load Start amps AC  
Set Load Start delay min  
Set Load Stop delay min  
Set 24 hr start volts DC  
Set 2 hr start volts DC  
Set 15 min start volts DC  
Read LBCO 30 sec start VDC  
Set Exercise period days  
Set Maximum run time h:m  
00 - 63  
00.0 25.5  
00.0 25.5  
20.0 71.0  
20.0 71.0  
20.0 71.0  
20.0 71.0  
00 - 255  
33  
05.0  
05.0  
49.2  
47.2  
45.2  
44.0  
30  
00:00 23:50  
08:00  
Gen Starting Details  
13 Set RY7 Function  
GlowStop Run  
16 - 255  
00 - 255  
00 - 15  
Run  
60  
Set Gen warmup seconds  
Set Pre Crank seconds  
Set Max Cranking seconds  
Set Post Crank seconds  
10  
10  
00 - 255  
30  
Auxiliary Relays R9 R10  
14 Set Relay 9 volts DC  
R9 Hysteresis volts DC  
Set Relay 10 volts DC  
R10 Hysteresis volts DC  
Set Relay 11 volts DC  
R1 Hysteresis volts DC  
20.0 71.0  
00.2 25.6  
20.0 71.0  
00.2 25.6  
20.0 71.0  
00.2 25.6  
00:00 23:50  
58.0  
04.0  
59.0  
04.0  
60.0  
04.0  
00:00  
Bulk Charge Trigger Timer 15 Start Bulk Time H:M  
Low Battery Transfer (LBX) 16 Set Low Battery transfer VDC  
Set Low Battery cut in VDC  
20.0 71.0  
20.0 71.0  
45.2  
52.0  
Battery Selling  
17 Set Battery Sell volts DC  
Set Max Sell amps AC  
40.0 64.0  
53.6  
30  
01 - 35  
Grid Usage Timer  
18 Set Start Charge time h:m  
End Stop Charge time h:m  
00:00 23:50  
00:00 23:50  
21:00  
21:00  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
126  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
TECHNICAL INFORMATION  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
127  
Part No. 2031-5  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
APPENDIX  
APPENDIX  
OPTIONS  
Options available for the SW Series Inverter/Charger include a choice of remote controls, and a battery  
temperature control.  
SWRC  
The optional SWRC Remote Control (SWRC or SWRC/50FT) has the ability to communicate with and  
adjust settings in the SW Series Inverter/Charger. It is operational whenever DC power is applied to the  
inverter DC input terminals.  
The SWRC is connected to the remote control port labeled REMOTE* on the left side (AC side) of the SW  
Series Inverter/Charger, using the provided DB-25 communications cable. Two cable lengths are available  
- 25 feet (8 meters) or 50 feet (16 meters). Distances longer than 50 feet (16 meters) are not  
recommended.  
The SWRC displays its information on a LCD screen, which duplicates the functions of the integral Control  
Panel on the SW Series Inverter/Charger, but it allows these functions to be performed and/or observed  
from a remote location (up to 50 feet from the inverter). Once the desired changes have been made, the  
SWRC may be unplugged and these changes will be retained, except if the inverter is completely powered  
down. When the SWRC is connected to the inverter, the inverters status LEDs still operate normally.  
Installation and operating instructions are included with the SWRC.  
You may connect either the SWRC or SWCA. Both options cannot be connected at the same time.  
SWCA  
The Sine wave Communications Adapter (SWCA) serial communications interface adapter allows for  
remote set-up, adjustment, troubleshooting and monitoring of SW Series inverters from a personal  
computer and allows modem access monitoring over long distances. The SWCA allows direct access of  
up to eight SW Series inverters via standard telephone type wire.  
The SWCA is connected to the remote control port labeled REMOTE* on the left side (AC side) of the SW  
Series Inverter/Charger, using the provided DB-25 communications cable.  
You may connect either the SWRC or SWCA. Both options cannot be connected at the same time.  
The SWCA provides the following features:  
Remote set-up: The SWCA is capable of direct connection to a modem for use in remote sites  
where a computer is not desired. This makes remote set-up simple and easy for end users, dealer,  
distributors or anyone familiar SW Series Inverter/Chargers. With an on-site modem and cellular  
communications network, costly trips are no longer necessary. Simply dial up your onsite modem and  
reset or adjust your systems via a virtual control panel simulation.  
Troubleshooting: In the event that problems occur in the field, the SWCA can be used to do simple  
troubleshooting by accessing meters and error conditions from your home or office. This feature is  
great for new users and allows dealers to guide their customers through simple set-up and adjustment  
problems that would usually require on-site assistance. An ideal service program for authorized  
Xantrex service centers distributors and dealers.  
Monitoring: By simply paralleling the four-cable conductor, access to eight adapters is made  
possible. Further long-term monitoring can be made via an external data-logging device.  
SWCB  
The SWCB conduit box consists of a metal enclosure for connection to the SW Series Inverter/Charger  
and is provided to meet applicable codes and safety standards. The SWCB may be fitted to the DC side of  
the SW Series Inverter/Charger. The SWCB has ½”, ¾” and 2knockouts for attaching conduit hardware.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
128  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
APPENDIX  
OTHER PRODUCTS  
Contact your Xantrex dealer for details of any of the products below.  
C40 MULTI-FUNCTION CONTROLLER  
The C40 Multi-Function Controller may be used as a PV (solar) charge controller, DC load controller, or  
DC diversion regulator. The unit works with 12, 24, or 48 volts systems and is rated at 40 amps  
continuous capacity. Other features of the C40 Multi-Function Controller are field adjustable setpoints,  
temperature compensation and protection, electronic overload protection with manual or auto-reset ability,  
optional LCD meter and an optional battery temperature compensation sensor (BTS).  
C12 CHARGE CONTROLLER  
The C-12 Charge Controller is a 12 amp 3 stage solar charge controller, DC load, and automatic lighting  
control center. The C12 Charge Controller is fully protected against overload, short-circuit, and reverse  
polarity. It is ideal for controlling lighting systems as it uses a PV array as an electric eye to seewhen it is  
dark, so it knows when to turn on the lights! Automatic reset, battery over discharge and overcharge  
protection, two-stage lightning protection and surge suppression, and optional temp compensation sensor  
are a few of the features of the C12 Charge Controller .  
SW SERIES POWER PANEL SYSTEMS  
Pre-assembled complete power panels featuring the SW Series Inverter/Chargers are now available.  
Each panel is complete and complies with all codes (it is ETL listed). All you do is connect to the battery  
and hook up AC loads. An AC system bypass allows AC loads to operate while the inverter is locked out  
for servicing.  
TM500 TRACEMETER (BATTERY STATUS MONITOR)  
The TraceTM500 battery status monitor features seven data-monitoring functions and two alarms that  
monitor battery state of charge, real-time amps, total charging amps, total load amps, days since fully  
charged, cumulative amp-hours, recharge alarm and full charge indicator. Mounts up to 50 feet from the  
batteries. Easily configured for liquid lead-acid or gel cell batteries. Works with 12, 24, or 48-volt systems  
with an optional 48V shunt board.  
STEP-UP/STEP-DOWN (BALANCING) TRANSFORMER  
The TraceT240 Transformer uses high efficiency transformer technology and is constructed with high  
temperature rated materials. This provides an unusually high efficiency device for voltage conversion from  
an inverter, generator or conventional AC source. The T240 Transformer has two identical windings that  
can be connected and used for line isolation, voltage step-up and step-down or generator balancing. The  
3.9 Kva continuous power of the T240 Transformer is sized to take advantage of the Traceinverter line.  
OVERCURRENT PROTECTION FUSES AND DISCONNECTS  
The Tracefuseblock (TFB) protects your battery, inverter, and high amperage cables from damage by  
short circuits and overloads. Simply select the proper size fuseblock and install between the inverter and  
battery in the ungrounded conductor (typically the positive cable).  
TFBs include a fast acting, current limiting class-T fuse. This fuse provides extremely fast protection  
when a short circuit occurs. When properly selected, it also has a time delay that allows the inverter to  
surge to full power without blowing the fuse.  
TFBs provide the code required inverter overcurrent protection for RV and Marine applications. A slide off  
cover prevents accidental contact with the fuses live terminals. For maximum protection, install the  
fuseblock within 18 inches (45 cm) of the battery.  
For residential and commercial electrical systems, the National Electrical Code requires both overcurrent  
protection and a disconnect switch. Xantrex offers the DC250 and DC175 circuit breaker disconnects with  
enclosure for applications requiring NEC compliance. The DC250 and DC175 are also designed to accept  
2-inch conduit to protect the inverter and battery cables.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
129  
Rev. C: February 2001  
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APPENDIX  
REFERENCE TABLES AND GRAPHS  
Table 9, Power Consumption Of Common Appliances  
TIME IN MINUTES  
APPLIANCE  
Single PL Light  
WATTS  
10  
5
.1  
.4  
1
15  
.3  
1
30  
.7  
60  
1.3  
4
120  
2.7  
8
240  
5.3  
17  
B & W TV  
Computer  
Color TV  
Blender  
50  
2
100  
2
4
8
17  
34  
200  
2
4
8
17  
34  
67  
93  
114  
176  
34  
67  
400  
3
8
17  
34  
46  
57  
88  
67  
133  
266  
370  
455  
706  
Skil Saw  
Toaster  
800  
6
17  
23  
28  
44  
133  
185  
227  
353  
1000  
1200  
1800  
8
Microwave  
Hot Plate  
10  
15  
AMP-HOURS  
If the current draw at 120 VAC is known, then the battery amperage at 12VDC will be 10 times the AC  
amperage divided by the efficiency (90% in this table).  
Motors are normally marked with their running rather than their starting current. Starting current can be  
five times running current. Keep this in mind when sizing a motor into a system.  
Refrigerators and icemakers typically run about 1/3 of the time. Therefore, their average battery current  
draw is 1/3 what their amp rating would indicate.  
Table 10, AWG to Metric Wire Conversion Chart  
DC RESISTANCE  
AWG  
DIAMETER/MM  
AREA/MM²  
1000 FT  
14  
1.63  
2.05  
2.59  
3.26  
4.11  
5.19  
6.54  
7.35  
8.25  
9.27  
10.40  
11.68  
2.08  
3.31  
5.27  
8.35  
13.3  
21.2  
33.6  
42.4  
53.4  
67.5  
85.0  
107.2  
3.14  
12  
1.98  
10  
1.24  
8
0.778  
0.491  
0.308  
0.194  
0.154  
0.122  
0.0967  
0.0766  
0.0608  
6
4
2
1
0 (1/0)  
00 (2/0)  
000 (3/0)  
0000 (4/0)  
Note: Stranded wire sizes and ampacity for 75°C.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
130  
Rev. C: February 2001  
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APPENDIX  
SIZE  
DIAMETE  
R
14  
12  
10  
.115  
8
.146  
6
.184  
4
.235  
3
.281  
2
.295  
1
.335  
1/0  
.380  
.073 .072  
SIZE  
DIAMETE  
R
2/0  
.420  
3/0  
.475  
4/0  
.530  
250 MCM  
.580  
300 MCM  
.635  
350 MCM  
.690  
400 MCM  
.730  
500 MCM  
.820  
Note: Sizes shown are for the conductor do not include any insulation when determining your wire  
size.  
Figure 40, AWG Wire Size  
Table 11, Minimum Recommended Battery Cable Size vs. Cable Length  
TYPICAL  
INVERTER  
MODEL  
NEC  
1 TO 3 FEET  
ONE WAY  
3 TO 5 FT  
ONE WAY  
5 TO 10 FT  
ONE WAY  
DC  
AMPS2  
AMPS1  
SW2512  
SW2612E  
267 Amps  
278 Amps  
160 Amps  
334 Amps  
348 Amps  
201 Amps  
267 Amps  
#4/0 AWG/107 mm2 #4/0 AWG/107 mm2 Not Recommended  
#4/0 AWG/107 mm2 #4/0 AWG/107 mm2 Not Recommended  
#4/0 AWG/107 mm2 #4/0 AWG/107 mm2 #4/0 AWG/107 mm2  
#4/0 AWG/107 mm2 #4/0 AWG/107 mm2 #4/0 AWG/107 mm2  
SW3024E or J  
SW4024 or W, K 214 Amps  
SW3048E or J  
SW4048 or K  
SW4548E or A  
SW5548  
80 Amps  
107 Amps  
120 Amps  
147 Amps  
100 Amps #2/0 AWG/67.4 mm2 #2/0 AWG/67.4 mm2 #4/0 AWG/107 mm2  
134 Amps #2/0 AWG/67.4 mm2 #2/0 AWG/67.4 mm2 #4/0 AWG/107 mm2  
150 Amps #2/0 AWG/67.4 mm2 #2/0 AWG/67.4 mm2 #4/0 AWG/107 mm2  
184 Amps  
#4/0 AWG/107 mm2 #4/0 AWG/107 mm2 #4/0 AWG/107 mm2  
1TYPICAL DC AMPS is based on Low Battery Voltage with an efficiency of 85%.  
2NEC AMPS is based on Low Battery Voltage, an efficiency of 85%, and a 125% NEC de-rating.  
Table 12, Battery Cable to Maximum Breaker/Fuse Size  
CABLE SIZE  
REQUIRED  
RATING IN  
CONDUIT  
MAXIMUM  
BREAKER SIZE  
RATING IN  
FREE AIR”  
MAXIMUM  
FUSE SIZE  
#2 AWG  
115 amps  
175 amps  
230 amps  
125 amps*  
175 amps  
250 amps*  
170 amps  
265 amps  
360 amps  
175 amps*  
300 amps*  
400 amps*  
#2/0 (00) AWG  
#4/0 (0000) AWG  
* The NEC allows rounding up to the next standard fuse size from the cable rating, i.e. 150-amp cable size  
rounds up to a standard 175-amp size.  
The term "free air" is defined by the NEC as cabling that is not enclosed in conduit or a raceway. Cables  
enclosed in raceways or conduits have substantially lower continuous current carrying ability due to  
heating factors.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
131  
Rev. C: February 2001  
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APPENDIX  
Table 13, Recommended Minimum AC Wire Sizes (75° C)  
FULL  
PASS-THRU  
CAPABILITY  
CABLE SIZE  
REQUIRED  
IN CONDUIT  
CABLE SIZE  
REQUIRED  
IN FREE AIR*  
INVERTER  
MODEL  
FUSE/BREAKER  
REQUIRED  
105-120 VAC  
UNITS  
60 amps  
30 amps  
60 amps  
30 amps  
# 6 AWG (THHN)  
# 10 AWG (THHN)  
# 8 AWG (THHN)  
# 10 AWG (THHN)  
220-240 VAC  
UNITS  
The term "free air" is defined by the NEC as cabling that is not enclosed in conduit or a raceway.  
Cables enclosed in raceways or conduits have substantially lower continuous current carrying ability  
due to heating factors.  
Table 14, Knockout/Hole Size to Conduit Size Required  
KNOCKOUT OR HOLE  
TRADE SIZE OF CONDUIT  
DIAMETER  
INCHES  
7/8 (.875)  
MM  
22.2  
27.8  
34.5  
43.7  
50.0  
62.7  
76.2  
INCHES  
½
¾
1 3/32 (1.093)  
1 23/64 (1.359)  
1 23/32 (1.719)  
1 31/32 (1.968)  
2 15/32 (2.468)  
3
1
1 ¼  
1 ½  
2
2 ½  
Table 15, Safety Ground Wire Size Table  
The ground wire should be sized per NEC 250-95. The following table is derived from this portion of the  
NEC code.  
Battery DC Disconnect Size  
Minimum Size of Copper  
Ground Wire  
30 Amp or 60 Amp  
100 Amp  
#10 AWG  
#8 AWG  
200 Amp  
#6 AWG  
300+ Amps  
#2 AWG or greater  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
132  
Rev. C: February 2001  
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APPENDIX  
Storage Checklist  
If the SW Series Inverter/Charger is used in a vehicular application such as a motor coach, truck, or  
boat, certain steps must be taken prior to seasonal storage. These steps are especially important for  
maintaining batteries as well as ensuring the automatic generator function, if installed, is disabled.  
Preparation for Storage  
Interior Storage  
Check that all batteries are fully charged.  
Press the SW Inverter/Chargers green, GEN MENU pushbutton to access the  
SET GENERATOR menu. Select OFF to disable the auto generator start feature.  
Configure the vehicles electrical system for the correct shore power service settings.  
Connect the vehicles shore power cord to a properly rated receptacle (confirm it is live).  
Press the SW Inverter/Chargers red, ON/OFF MENU pushbutton to access the  
SET INV menu. Select CHG to put the unit into the charger only mode.  
Switch OFF all unnecessary AC and DC loads.  
WARNING: DO NOT STORE THE VEHICLE INDOORS WITH THE AUTO GEN START  
FEATURE ENABLED. GENERATORS EXHAUST DANGEROUS FUMES WHEN RUNNING.  
Exterior Storage  
For exterior storage, follow the same steps as above. If shore power is not available, enable the Auto-  
Gen Start feature and ensure there is enough fuel available to run the generator for charging the batteries.  
The generator will automatically start and stop, depending on the batteriesstate-of-charge.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
133  
Rev. C: February 2001  
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APPENDIX  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
134  
Rev. C: February 2001  
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WARRANTY/REPAIR INFORMATION  
WARRANTY/REPAIR INFORMATION  
LIMITED WARRANTY  
Xantrex Technology Inc. warrants its power products against defects in materials and workmanship for a  
period of two (2) years from the date of purchase and extends this warranty to all purchasers or owners of the  
product during the warranty period. This warranty is void under the following circumstances:  
(1)  
improper and/or unauthorized repair not provided by Xantrex Technology Inc., or its Authorized  
Service Centers;  
(2)  
when the product is installed or exposed or exposed to an unsuitable environment as evidenced  
by generalized corrosion or biological infestation;  
(3)  
(4)  
abnormal use of the product or use in violation of the instructions;  
when used as a component parts of a product expressly warranted by another manufacturer.  
Xantrex Technology Inc., agrees to supply all parts and labor or repair or replace defects covered by this  
warranty with parts or products of original or improved design, at the companys option. Xantrex  
Technology Inc., also reserves the right to improve the design of its products without obligation to modify  
or upgrade those previously manufactured. Defective products must be returned to Xantrex Technology  
Inc., or its Authorized Service Center in the original packaging. The cost of transportation and insurance  
on items returned for service is the responsibility of the customer.  
All remedies and the measure of damages are limited to the above. Xantrex Technology Inc., shall in no  
event be liable for consequential, incidental, contingent, or special damages, even if Xantrex Technology Inc.,  
has been advised of the possibility of such damages. Any and all other warranties, expressed or implied,  
arising by law, course of dealing, course of performance, usage of trade or otherwise, including, but not  
limited to, implied warranties of merchantability and fitness for a particular purpose, are limited in duration for  
a period of two (2) years from the original date of purchase.  
Some countries or states do not allow limitations on the term of an implied warranty, or the exclusion or  
limitation of incidental or consequential damage, which means the limitations and exclusions of this  
warranty, may not apply to you. Even though this warranty gives you specific legal rights, you may also  
have other rights that vary from state to state.  
WARRANTY REGISTRATION  
Complete the warranty card and mail it to Xantrex Technology Inc., within 10 days from the date of  
purchase. keep your bill of sale as proof of purchase, should any difficulties arise concerning the  
registration of the warranty card.  
Warranty Registration is tracked by model and serial numbers only, not by owners name. Therefore, any  
correspondence or inquiries made to Xantrex Technology Inc., must include the model and serial number  
of the product in question.  
LIFE SUPPORT POLICY  
As a general policy, Xantrex Technology Inc., does not recommend the use of any of its products in life  
support applications where failure or malfunction of the Trace Engineering product can be reasonably  
expected to cause failure of the life support device or to significantly affect its safety or effectiveness.  
Xantrex Technology Inc., does not recommend the use of any of its products in direct patient care.  
Xantrex Technology Inc., will not knowingly sell its products for use in such applications unless it receives  
in writing assurances satisfactory to Xantrex Technology Inc., that (a) the risks of injury or damage have  
been minimized, (b) the customer assumes all such risks, and the liability of Xantrex Technology Inc., is  
adequately protected under the circumstances  
Examples of devices considered to be life support devices are neonatal oxygen analyzers, nerve  
stimulators (whether used for anesthesia, pain relief, or other purposes), autotransfusion devices, blood  
pumps, defibrillators, arrhythmia detectors and alarms, pacemakers, hemodialysis systems, peritoneal  
dialysis systems, neonatal ventilator incubators, ventilators for both adults and infants, anesthesia  
ventilators, and infusion pumps as well as any other devices designated as criticalby the U.S. FDA.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
135  
Rev. C: February 2001  
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WARRANTY/REPAIR INFORMATION  
WARRANTY OR REPAIR SERVICE REQUIRED  
If your product needs repair at the factory, it must be shipped fully insured in the original packaging or  
equivalent (shipping damage is not covered under warranty and will likely delay the repair and return of  
your unit). The shipper will not accept any damage claims even if insured - on products damaged  
through improper packaging (i.e., peanuts, soft foam, undersized boxes, etc.). If possible, avoid sending  
products through the mail.  
Warranty or repair service should be performed only at an Authorized Xantrex Service Center, or at the  
Xantrex Technologies factory. Unauthorized service performed on any Traceproduct will void the  
existing warranty.  
You must notify Xantrex Technology Inc., before returning any equipment for repair. To obtain an RMA  
(Return Merchandise Authorization number, please contact our Warranty Coordinator at:  
Phone: 360-435-8826  
Fax: 360-474-0616  
Please provide:  
Model Number: _____________________________  
Serial Number: _____________________________  
Purchase Date: _____________________________  
Problem: __________________________________  
.
Ship the item for repair to:  
Trace Engineering Company, Inc.  
Attn: Service Department.  
RMA # ___________  
5916 195th NE  
Arlington, WA 98223  
Be sure to include in the package:  
1. Complete return shipping address (P.O. Box numbers are not acceptable) and telephone number  
where you can be reached during work hours.  
2. A detailed description of any problems experienced, including the make and model numbers of any  
other equipment in the system, types and sizes of loads, operating environment, time of unit operation  
and temperature.  
3. If your unit has not been registered, a copy of your proof of purchase or (purchase receipt) is required  
for Warranty repair.  
Repaired products will be returned freight C.O.D., unless sufficient return shipment funds are included  
with the unit.  
Products sent to the factory from outside the U.S. must include return freight funds, and sender is fully  
responsible for all customs documents, duties, tariffs, and deposits.  
Record the model and serial numbers on your product and retain for your files.  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
136  
Rev. C: February 2001  
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INDEX  
INDEX  
Sizing............................................................................ 22  
Battery Charging  
A
Absorption Time............................................................ 54  
Absorption Time................................................ 64, 67, 87  
AC Input Requirements................................................. 65  
Bulk Charging .......... 45, 53, 55, 64, 67, 69, 82, 83, 87, 90  
Bulk Voltage................................................................ 104  
Charge Rate................................................................ 104  
Charger Only Operation ................................................ 65  
Charging Setpoints................................................ 67, 104  
Equalization Charging........ 38, 47, 67, 68, 79, 80, 97, 104  
Float Charging .....................................47, 65, 87, 97, 104  
Float Voltage ............................................................... 104  
Max Charge Amps ...................................................... 104  
Multiple Inverters........................................................... 97  
Charger Settings ....................................................... 97  
Recommended Battery Charger Settings...................... 66  
Selecting Battery Type.................................................. 48  
State of Charge........................................................... 105  
Temperature Compensation......................................... 104  
Battery Charging, Menu (10)............................................. 47  
Battery Overvoltage Protection ......................................... 89  
Battery Selling..................................................54, 83, 86, 87  
Battery Selling, Menu (17)................................................. 54  
Battery Sizing.......................................................... 101, 102  
Example...................................................................... 102  
Worksheet .................................................................. 103  
Battery TempComp Volts DC, Menu ( 4)........................... 40  
Battery Temperature Sensor (BTS)................................... 97  
Battery Terminals.............................................................. 14  
Bonding The Grounding System ....................................... 26  
BTS Port........................................................................... 13  
Bulk Charge Trigger Timer.............55, 64, 69, 82, 83, 87, 90  
Bulk Charge Trigger Timer, Menu (15).............................. 53  
Bulk Charging .............. 45, 53, 55, 64, 67, 69, 82, 83, 87, 90  
Bulk LED........................................................................... 11  
Absorption Time ..............................................................100  
AC Inputs, Menu (11) ........................................................48  
AC Pass Through Ability....................................................18  
AC Safety Ground .............................................................14  
AC Side.............................................................................12  
AC Source Wired To Output, Menu ( 5).............................42  
AC Terminal Block.............................................................13  
AC Wiring..........................................................................18  
AC Input Connections....................................................18  
AC Output Connections.................................................18  
Installation Guidelines ...................................................20  
AC1 In Good LED..............................................................11  
AC1 Relay Indicator...........................................................13  
AC2 In Good LED..............................................................11  
Automatic Generator Control Mode .............................61, 73  
Generator Auto Start Requirements...............................76  
Three Wire Start Generators .....................................77  
Two Wire Start Generators........................................76  
Generator Control Sequence.........................................78  
Equalization Charging................................................80  
Generator Error Causes.............................................79  
Generator Stop Cool Down Period.............................79  
Generator Exercising.....................................................75  
Generator Start/Stop Configurations..............................75  
Generator Starting Scenarios ........................................74  
Automatic ..................................................................74  
Manual.......................................................................75  
Aux and Gen Control Relays .............................................14  
Aux Relays ............................................................14, 25, 89  
Auxiliary Relays, Menu (14)...............................................51  
AWG ...............................................................................132  
AWG to Metric Wire Conversion......................................130  
AWG Wire Size ...............................................................131  
B
C
Battery...............................................................................99  
Amphour Usage.............................................................101  
Battery Type  
C12 Charge Controller .................................................... 129  
C40 Multi-Function Controller.......................................... 129  
Charger Mode................................................................... 61  
AC Input Requirements................................................. 65  
Charger Only Operation ................................................ 65  
Recommended Battery Charger Settings...................... 66  
Circuit Breaker  
Deep Cycle Battery....................................................99  
Absorbed Glass Mat ............................................100  
AGM....................................................................100  
Gel Cell................................................................100  
Maintenance Free................................................100  
Non-sealed Lead Acid ...........................................99  
Sealed Lead Acid ................................................100  
NiCad/NiFe Battery..................................................100  
Starting Battery..........................................................99  
Care And Maintenance................................................104  
Enclosure ....................................................................106  
Hook Up Configurations...............................................107  
Parallel Connection..................................................108  
Series Connection ...................................................107  
Series-Parallel Connection ......................................108  
Hydrogen Sulfide Gas....................................................17  
Installation...................................................................106  
Monthly Maintenance...................................................105  
Polarity...........................................................................24  
Temperature................................................................106  
Terminals ......................................................................14  
Battery Actual Volts DC, Menu ( 4)....................................40  
Battery Cable  
Inverter/Charger............................................................ 12  
Compressors ........................................ See Inductive Loads  
Conduit ............................................................................. 20  
Conduit Box (SWCB) ................................................ 23, 128  
Conduit Connectors .......................................................... 20  
CONTRAST Control.......................................................... 10  
Control Panel...................................................................... 9  
CONTRAST Control...................................................... 10  
Display............................................................................ 9  
LED Status Indicators ................................................... 10  
AC1 In Good ............................................................. 11  
AC2 In Good ............................................................. 11  
Bulk........................................................................... 11  
Error.......................................................................... 11  
Float.......................................................................... 11  
Inverting.................................................................... 10  
Line Tie..................................................................... 10  
Overcurrent............................................................... 11  
Menu Buttons................................................................ 10  
GEN MENU Button ................................................... 10  
Menu Access/Adjustment Buttons............................. 10  
MENU HEADING Buttons ......................................... 10  
MENU ITEM Buttons................................................. 10  
ON/OFF MENU Button.............................................. 10  
SET POINTS Buttons ............................................... 10  
Battery To Inverter Cabling..........................................106  
Cable Inductance.........................................................110  
Cable Size vs. Cable Length..................................22, 131  
Connections ..................................................................24  
Installation Procedure....................................................24  
Maximum Breaker/Fuse Size.......................................131  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
137  
Rev. C: February 2001  
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INDEX  
RESET TO FACTORY DEFAULTS Button ................... 10  
Control Wiring................................................................... 25  
Aux Relay Wiring........................................................... 25  
Fusing............................................................... 25, 74, 89  
Gen Control Relays....................................................... 25  
Remote Control Wiring.................................................. 25  
Input Amps AC, Menu ( 4) .............................................40  
Inverter Volts AC, Menu ( 4) ..........................................40  
Inverter/Charger Amps AC, Menu ( 4)............................40  
Load Amps AC, Menu ( 4) .............................................40  
Read Frequency Hertz, Menu ( 4)..................................41  
Software Revision, Menu ( 3).........................................39  
D
E
DC Disconnect And Overcurrent Protection ...................... 23  
DC Ground........................................................................ 14  
DC Side ............................................................................ 14  
DC Wiring ......................................................................... 22  
Battery Cable Connections............................................ 24  
Battery Cable Sizing...................................................... 22  
Default Setting  
End Charge Time ..................................................86, 87, 90  
End Charge Time, Menu (18) ............................................54  
End Quiet Time, Menu ( 7) ................................................43  
Energy Management Mode..........................................61, 94  
Equalization Charging............ 38, 47, 67, 68, 79, 80, 97, 104  
Equalizing Batteries...........................................................67  
Equipment Or Chassis Grounds ........................................26  
Error Causes  
End Charge Time, Menu (18)........................................ 54  
End Quiet Time, Menu ( 7)............................................ 43  
R 9 Hysteresis Volts DC, Menu (14).............................. 52  
R10 Hysteresis Volts DC, Menu (14)............................. 52  
R11 Hysteresis Volts DC, Menu (14)............................. 52  
Read 30 Sec LBCO Start VDC, Menu (12).................... 49  
Set 15 Min Start Volts DC, Menu (12) ........................... 49  
Set 2 Hr Start Volts DC, Menu (12) ............................... 49  
Set 24 Hr Start Volts DC, Menu (12) ............................. 49  
Set Absorption Time, Menu (10).................................... 47  
Set Aux Relay 9 Volts DC, Menu (14) .......................... 52  
Set Aux Relay 10 Volts DC, Menu (14).......................... 52  
Set Aux Relay 11 Volts DC, Menu (14).......................... 52  
Set Battery Sell Volts DC, Menu (17) ............................ 54  
Set Bulk Volts DC, Menu (10) ....................................... 47  
Set Clock Hours, Menu ( 6)........................................... 43  
Set Clock Minute, Menu ( 6).......................................... 43  
Set Clock Second, Menu ( 6) ........................................ 43  
Set Equalize Time, Menu (10)....................................... 47  
Set Equalize Volts DC, Menu (10)................................. 47  
Set Exercise Period Days, Menu (12)............................ 50  
Set Float Volts DC, Menu (10)....................................... 47  
Set Gen (AC2) Amps AC, Menu (11)............................. 48  
Set Gen Warmup Seconds, Menu (13) ......................... 50  
Set Generator, Menu ( 2) .............................................. 37  
Set Grid (AC1) Amps AC, Menu (11)............................. 48  
Set Grid Usage, Menu ( 9) ............................................ 45  
Set High Battery Cut Out VDC, Menu ( 9) ..................... 46  
Set Input Lower Limit VAC, Menu (11) .......................... 48  
Set Input Upper Limit VAC, Menu (11) .......................... 48  
Set Inverter, Menu ( 1) .................................................. 37  
Set LBCO Delay Minutes, Menu ( 9) ............................. 46  
Set Load Start Amps AC, Menu (12)............................. 49  
Set Load Start Delay Min, Menu (12) ............................ 49  
Set Load Stop Delay Min, Menu (12)............................. 49  
Set Low Battery Cut in VDC, Menu ( 9)......................... 46  
Set Low Battery Cut In VDC, Menu (16)........................ 53  
Set Low Battery Cut Out VDC, Menu ( 9) ...................... 46  
Set Low Battery Transfer VDC, Menu (16) .................... 53  
Set Max Charge Amps AC, Menu (10) .......................... 48  
Set Max Cranking Seconds, Menu (13)......................... 51  
Set Max Sell Amps AC, Menu (17)................................ 54  
Set Maximum Run Time, Menu (12).............................. 50  
Set Post Crank Seconds, Menu (13)............................. 51  
Set Pre Crank Seconds, Menu (13)............................... 51  
Set RY7 Function, Menu (13)........................................ 50  
Set Search Spacing, Menu ( 9) ..................................... 46  
Set Search Watts, Menu ( 9)......................................... 46  
Set Temp Comp, Menu (10).......................................... 48  
Start Bulk Time, Menu (15) ........................................... 53  
Start Charge Time, Menu (18)....................................... 54  
Start Quiet Time, Menu ( 7)........................................... 43  
Dimensions..................................................................... 120  
Display  
AC Source Wired To Output, Menu ( 5).........................42  
Exercise Start Ready, Menu ( 2)....................................39  
External Error (Stacked), Menu ( 5) ...............................42  
Gen Max Run Time........................................................50  
Gen Max Run Time Error, Menu ( 2)..............................38  
Gen Under/Over Speed, Menu ( 2) ................................38  
Generator Start Error, Menu ( 2)....................................38  
Generator Start Error, Menu ( 5)....................................42  
Generator Sync Error, Menu ( 2)....................................38  
Generator Sync Error, Menu ( 5)....................................42  
Generator Under/Over Speed, Menu ( 5).......................42  
Heatsink Overtemp, Menu ( 5).......................................41  
High Battery Voltage, Menu ( 5).....................................42  
Inverter Breaker Tripped, Menu ( 5)...............................43  
Load Start Amps Ready, Menu ( 2)................................39  
Low Battery Voltage, Menu ( 5)......................................42  
Overcurrent, Menu ( 5)...................................................41  
Transformer Overtemp, Menu ( 5) .................................41  
Voltage Start Ready, Menu ( 2)......................................39  
Error Causes, Menu ( 5) ....................................................41  
Error LED .................................................. 11, 38, 41, 66, 79  
Estimating Battery Requirements ....................................101  
Exercise Period ...............................................39, 43, 50, 75  
Exercise Start Ready, Menu ( 2)........................................39  
External Error (Stacked), Menu ( 5) ...................................42  
External Transfer Relays ...................................................20  
F
Float Charging......................................... 47, 65, 87, 97, 104  
Float LED ..........................................................................11  
FLT mode..............................................................45, 53, 54  
Frequency Tolerance.........................................................66  
Fuse Block (TFB) ..............................................................23  
Fuses and Disconnects ...................................................129  
Battery Cable Disconnect/Breaker Rating......................23  
G
Gen Auto Start Setup, Menu (12) ......................................49  
Gen Control Relays ...............................................14, 25, 74  
Gen Max Run Time Error...................................................79  
Gen Max Run Time Error, Menu ( 2)..................................38  
GEN MENU Button............................................................10  
Gen Size Amps AC Setting................................................72  
Gen Starting Details, Menu (13) ........................................50  
Gen Under/Over Speed.....................................................79  
Gen Under/Over Speed, Menu ( 2)....................................38  
General Precautions............................................................1  
Generator  
120/240 VAC Generators...............................................72  
Automatic Control...........................................................78  
Automatic Start...................................... 68, 71, 77, 79, 97  
With Multiple Inverters ...............................................97  
Automatic Start/Stop......................................................73  
Control...........................................................................51  
Control Relays ..........................................................50, 74  
Battery Actual Volts DC, Menu ( 4)................................ 40  
Battery TempComp Volts DC, Menu ( 4)....................... 40  
Generator (AC2) Volts AC, Menu ( 4)............................ 41  
Grid (AC1) Volts AC, Menu ( 4)..................................... 41  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
Page  
138  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
INDEX  
Cool Down Period....................................................75, 79  
Equalization Charging...................... 38, 47, 68, 79, 80, 97  
Exercise Period .............................................................50  
Frequency ...............................................................38, 42  
Gen Control Wiring........................................................25  
Maximum Run Time ......................................................50  
Spin Up .........................................................................31  
Start Routines....................................................50, 75, 76  
Start Status ...................................................................39  
Starting and Stopping....................................................37  
Status............................................................................37  
Three Wire Start............................................................77  
Two Wire Start...............................................................76  
Warm-up time................................................................66  
Generator (AC2) Volts AC, Menu ( 4) ................................41  
Generator Auto Start Requirements ..................................76  
Two Wire Start Generators............................................76  
Generator Control Sequence.............................................78  
Equalization Charging....................................................80  
Generator Error Causes ................................................79  
Generator Max Run Time ..............................................79  
Generator Stop Cool Down Period.................................79  
Generator Error Causes ....................................................79  
Gen Max Run Time Error...............................................79  
Gen Under/Over Speed.................................................79  
Generator Start Error.....................................................79  
Generator Sync Error.....................................................79  
Generator Exercising.........................................................75  
Generator Max Run Time ..................................................79  
Generator Mode, Menu ( 2) ...............................................37  
Generator Start Error.........................................................79  
Generator Start Error, Menu ( 2)........................................38  
Generator Start Error, Menu ( 5)........................................42  
Generator Start/Stop Configurations..................................75  
Generator Starting Scenarios ............................................74  
Automatic ......................................................................74  
Manual...........................................................................75  
Generator Stop Cool Down Period.....................................79  
Generator Support Mode.............................................61, 71  
Generator Support/Overload Protection.............................72  
Generator Sync Error.........................................................79  
Generator Sync Error, Menu ( 2)........................................38  
Generator Sync Error, Menu ( 5)........................................42  
Generator Timer, Menu ( 7)...............................................43  
Generator Under/Over Speed, Menu ( 5)...........................42  
GFI (Ground Fault Interrupt)..............................................21  
Grid (AC1) Volts AC, Menu ( 4) .........................................41  
Grid Usage Timer...................................... 54, 69, 83, 86, 90  
Grid Usage Timer, Menu (18) ............................................54  
Ground Fault Interrupt (GFI)..............................................21  
Grounding..........................................................................26  
Grounding Electrodes/Ground Rods..................................26  
Grounding Vs. Lightning ....................................................29  
Menu (17) Battery Selling.............................................. 54  
Menu (18) Grid Usage Timer......................................... 55  
Menu (19) Information File Battery................................ 55  
Information File Battery, Menu (19)................................... 55  
Input Amps AC, Menu ( 4)................................................. 40  
Input Lower Limit VAC ...................................................... 48  
Input Requirements  
AC Current.................................................................... 66  
AC Voltage.................................................................... 65  
Delay Period ................................................................. 66  
Frequency..................................................................... 66  
Installation Diagrams ...................................................... 121  
Internal LED Indicators...................................................... 13  
AC1 Relay Indicator ...................................................... 13  
RY7 Indicator................................................................ 13  
RY8 Indicator................................................................ 13  
Inverter  
Unpacking..................................................................... 17  
Inverter Breaker Tripped, Menu ( 5) .................................. 43  
Inverter Mode.............................................................. 61, 62  
Low Battery Protection.................................................. 63  
Search Mode................................................................. 62  
Theory of Operation ...................................................... 57  
Block Diagram........................................................... 57  
Output Waveform...................................................... 58  
Inverter Mode, Menu ( 1)................................................... 37  
Inverter Setup, Menu ( 9) .................................................. 45  
Inverter Ventilation............................................................ 18  
Inverter Volts AC, Menu ( 4).............................................. 40  
Inverter/Charger  
Circuit Breaker .............................................................. 12  
Inverter/Charger Amps AC, Menu ( 4)............................... 40  
Inverter/Charger Mode ................................................ 61, 69  
Transfer Time ............................................................... 70  
Transferring Based On Battery Voltage......................... 69  
Transferring Upon Availability Of AC Power.................. 69  
Inverter/Charger Terminology.......................................... 115  
Inverting LED.................................................................... 10  
Islanding Protection .......................................................... 84  
K
Knockout/Hole Size To Conduit Size............................... 132  
L
LED Status Indicators ....................................................... 10  
AC1 In Good................................................................. 11  
AC2 In Good................................................................. 11  
Bulk............................................................................... 11  
Error.............................................................................. 11  
Float.............................................................................. 11  
Inverting.................................................................. 10, 31  
Line Tie......................................................................... 10  
Overcurrent................................................................... 11  
Life Support Policy.......................................................... 135  
Lightning ........................................................................... 29  
Line Tie LED..................................................................... 10  
Load Amps AC, Menu ( 4)................................................. 40  
Load Start Amps Ready, Menu ( 2)................................... 39  
Loads: 240 VAC.......................................................... 72, 95  
Location............................................................................ 17  
Locked Rotor Amps ........................................................ 111  
Low Battery Cut Out VDC ................................49, 53, 63, 94  
Adjustment.................................................................... 63  
Low Battery Protection...................................................... 63  
Low Battery Transfer Mode......................................... 45, 61  
Low Battery Transfer, Menu (16)....................................... 53  
Low Battery Voltage, Menu ( 5)......................................... 42  
H
Heatsink Overtemp, Menu ( 5)...........................................41  
High Battery Voltage, Menu ( 5).........................................42  
I
Identification Label...............................................................7  
Induced Voltage ..............................................................110  
Inductive Loads ...............................................................111  
Information Display  
Menu ( 1) Inverter Mode ................................................37  
Menu ( 2) Generator Mode ............................................39  
Menu ( 3) Trace Engineering .........................................39  
Menu ( 4) Meters ...........................................................41  
Menu ( 7) Generator Timer ............................................43  
Menu (12) Gen Auto Start Setup ...................................50  
Menu (14) Auxiliary Relays ............................................52  
Menu (15) Bulk Charge Trigger Timer............................53  
Menu (16) Low Battery Transfer ....................................53  
M
Max Charge Amps ...................................................... 87, 93  
Max Sell Amps.................................................................. 86  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
139  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
INDEX  
Menu ( 1) Inverter Mode.................................................... 37  
Menu ( 2) Generator Mode................................................ 37  
Menu ( 3) Trace Engineering............................................. 39  
Menu ( 4) Meters............................................................... 40  
Menu ( 5) Error Causes..................................................... 41  
Menu ( 6) Time of Day ...................................................... 43  
Menu ( 7) Generator Timer................................................ 43  
Menu ( 9) Inverter Setup ................................................... 45  
Menu (10) Battery Charging .............................................. 47  
Menu (11) AC Inputs......................................................... 48  
Menu (12) Gen Auto Start Setup....................................... 49  
Menu (13) Gen Starting Details......................................... 50  
Menu (14) Auxiliary Relays................................................ 51  
Menu (15) Bulk Charge Trigger Timer............................... 53  
Menu (16) Low Battery Transfer........................................ 53  
Menu (17) Battery Selling.................................................. 54  
Menu (18) Grid Usage Timer............................................. 54  
Menu (19) Information File Battery.................................... 55  
Menu Buttons.................................................................... 10  
GEN MENU Button ....................................................... 10  
Menu Access/Adjustment Buttons................................. 10  
MENU HEADING Buttons ............................................. 10  
MENU ITEM Buttons..................................................... 10  
ON/OFF MENU Button.................................................. 10  
SET POINTS Buttons.................................................... 10  
MENU HEADING Buttons ................................................. 10  
Menu Headings  
P
Parallel Stacked Operation................................................96  
Generator Control Settings ............................................96  
Peak Load Shaving Mode..................................................61  
Personal Precautions ..........................................................3  
Power Consumption Of Common Appliances..................130  
Power Vs. Efficiency..........................................................59  
Press Reset Now For Defaults, Menu ( 3)..........................39  
Q
Quick Install.......................................................................16  
AC In Cabling ................................................................16  
AC Out Cabling..............................................................16  
DC Cabling....................................................................16  
Mounting........................................................................16  
Wrap Up........................................................................16  
R
R 9 Hysteresis Volts DC, Menu (14) ..................................52  
R10 Hysteresis Volts DC, Menu (14) .................................52  
R11 Hysteresis Volts DC, Menu (14) .................................52  
Radio Frequency Interference (RFI) ..................................17  
Read 30 Sec LBCO Start VDC, Menu (12) ........................49  
Read Frequency Hertz, Menu ( 4)......................................41  
Recommended Minimum AC Wire Sizes.........................132  
Remote Control (SWRC).................................................128  
Remote Port ......................................................................12  
Repair Required ..............................................................135  
RESET TO FACTORY DEFAULTS Button........................10  
Resistive Loads ...............................................................111  
Reverse Polarity ..........................................................14, 24  
RFI (Radio Frequency Interference) ..................................17  
RY7 Indicator.....................................................................13  
RY8 Indicator.....................................................................13  
Setup Menu................................................................... 44  
User Menu .................................................................... 36  
MENU ITEM Buttons......................................................... 10  
Menu Map  
Setup Menu................................................................... 35  
User Menu .................................................................... 34  
Meters, Menu ( 4).............................................................. 40  
Model Identification ............................................................. 7  
Model Number .................................................................... 7  
Mounting........................................................................... 17  
Multiple Inverter Stacking Port .......................................... 12  
Multiple Inverters............................................................... 95  
Automatic Generator Control......................................... 97  
Battery Charging ........................................................... 97  
Charger Settings ....................................................... 97  
Parallel Stacked Operation............................................ 96  
Generator Control Settings........................................ 96  
Series Stacked Operation ............................................. 95  
240 VAC Input/Output Breaker.................................. 95  
240 VAC Only Systems............................................. 96  
S
Safety Instructions...............................................................1  
General Precautions........................................................1  
Personal Precautions.......................................................3  
Special Notices................................................................2  
Search.............................................................................112  
Search Mode.....................................................................62  
Sell Mode .................................................. 45, 54, 66, 70, 84  
Input Amps AC ..............................................................40  
SELL Mode........................................................................54  
Selling Power.....................................................................85  
From A DC Charging Source.........................................85  
Stored In The Batteries..................................................86  
Serial Number .............................................................7, 135  
Series Stacked Operation..................................................95  
240 VAC Input/Output Breaker ......................................95  
240 VAC Only Systems .................................................96  
Set 15 Min Start Volts DC, Menu (12)................................49  
Set 2 Hr Start Volts DC, Menu (12)....................................49  
Set 24 Hr Start Volts DC, Menu (12)..................................49  
Set Absorption Time, Menu (10)........................................47  
Set Aux Relay 9 Volts DC, Menu (14)...............................52  
Set Aux Relay 10 Volts DC, Menu (14)..............................52  
Set Aux Relay 11 Volts DC, Menu (14)..............................52  
Set Battery Sell Volts DC, Menu (17).................................54  
Set Bulk Volts DC, Menu (10)............................................47  
Set Clock Hours, Menu ( 6) ...............................................43  
Set Clock Minute, Menu ( 6) ..............................................43  
Set Clock Second, Menu ( 6).............................................43  
Set Equalize Time, Menu (10) ...........................................47  
Set Equalize Volts DC, Menu (10) .....................................47  
Set Exercise Period Days, Menu (12)................................50  
Set Float Volts DC, Menu (10)...........................................47  
Set Gen (AC2) Amps AC, Menu (11).................................48  
Set Gen Warmup Seconds, Menu (13)..............................50  
N
NEC code ....................................................................... 132  
Neutral-To-Ground Bond Switching................................... 27  
External AC Source Connected..................................... 28  
RV And Marine Applications.......................................... 27  
O
ON/OFF MENU Button...................................................... 10  
Options ........................................................................... 128  
Remote Control........................................................... 128  
SineWave Communications Adapter........................... 128  
SWCA......................................................................... 128  
SWRC......................................................................... 128  
Other Products................................................................ 129  
C12 Charge Controller ................................................ 129  
C40 Multi-Function Controller...................................... 129  
Overcurrent Protection ................................................ 129  
SW Series Power Panel Systems ............................... 129  
T240 Transformer ....................................................... 129  
TM500 Trace Meter (Battery Status Monitor)............... 129  
Over-Current Device ......................................................... 24  
Overcurrent LED ............................................................... 11  
Overcurrent Protection.................................................... 129  
Overcurrent, Menu ( 5)...................................................... 41  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
Page  
140  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
INDEX  
Set Generator, Menu ( 2)...................................................37  
Set Grid (AC1) Amps AC, Menu (11).................................48  
Set Grid Usage, Menu ( 9).................................................45  
Set High Battery Cut Out VDC, Menu ( 9)..........................46  
Set Input Lower Limit VAC.....................................71, 72, 73  
Set Input Lower Limit VAC, Menu (11)...............................48  
Set Input Upper Limit VAC ..........................................71, 73  
Set Input Upper Limit VAC, Menu (11)...............................48  
Set Inverter, Menu ( 1).......................................................37  
Set LBCO Delay Minutes, Menu ( 9)..................................46  
Set Load Start Amps AC, Menu (12) .................................49  
Set Load Start Delay Min, Menu (12).................................49  
Set Load Stop Delay Min, Menu (12).................................49  
Set Low Battery Cut in VDC, Menu ( 9) .............................46  
Set Low Battery Cut In VDC, Menu (16) ............................53  
Set Low Battery Cut Out VDC, Menu ( 9)...........................46  
Set Low Battery Transfer VDC, Menu (16).........................53  
Set Max Charge Amps.................................................66, 70  
Set Max Charge Amps AC, Menu (10)...............................48  
Set Max Charge Amps Setting...........................................64  
Set Max Cranking Seconds, Menu (13) .............................51  
Set Max Sell Amps AC, Menu (17) ....................................54  
Set Maximum Run Time, Menu (12)..................................50  
SET POINTS Buttons........................................................10  
Set Post Crank Seconds, Menu (13) .................................51  
Set Pre Crank Seconds, Menu (13)...................................51  
Set RY7 Function, Menu (13) ............................................50  
Set Search Spacing, Menu ( 9)..........................................46  
Set Search Watts, Menu ( 9) .............................................46  
Set Temp Comp, Menu (10) ..............................................48  
Setup Menu.......................................................................44  
Menu (14) Auxiliary Relays ............................................51  
Menu (15) Bulk Charge Trigger Timer............................53  
Menu Headings .............................................................44  
Menu Map .....................................................................35  
Silent (SLT) Mode........................................................45, 82  
SineWave Communications Adapter (SWCA).................128  
SLT (Silent) Mode........................................................45, 82  
Software Revision......................................................1, 5, 96  
Software Revision, Menu ( 3).............................................39  
Special Notices....................................................................2  
Specifications and Features ....................................118, 119  
50 Hz Models...............................................................119  
60 Hz Models...............................................................118  
Stacking - Parallel .............................................................96  
Stacking - Series ...............................................................95  
Stacking Inverters (120/240 VAC) ...............................72, 95  
Stacking Port.....................................................................12  
Start Bulk Time, Menu (15)................................................53  
Start Charge Time.................................................86, 87, 90  
Start Charge Time, Menu (18) ...........................................54  
Start Quiet Time, Menu ( 7) ...............................................43  
SW Series Power Panel Systems....................................129  
SWCA .............................................................................128  
Remote Monitoring ......................................................128  
Remote Setup .............................................................128  
Remote Troubleshooting .............................................128  
SWCB (Conduit Box).................................................23, 128  
SWRC.............................................................................128  
System Grounding.............................................................26  
Bonding The Grounding System....................................26  
Equipment Or Chassis Grounds ....................................26  
Grounding Electrodes/Ground Rods..............................26  
Grounding Vs. Lightning ................................................29  
Neutral-To-Ground Bond Switching ...............................27  
Time of Day Metering............................................ 90, 92, 94  
Time of Day, Menu ( 6) ..................................................... 43  
Torque  
Wire Connections.......................................................... 20  
Trace Engineering Menu, ( 3)............................................ 39  
Trace Meter (TM500) ...................................................... 129  
Transfer Time ....................................................... 20, 70, 81  
Inverter/Charger Mode .................................................. 70  
Transferring Based On Battery Voltage  
Inverter/Charger Mode .................................................. 69  
Transferring Upon Availability Of AC Power  
Inverter/Charger Mode .................................................. 69  
Transformer Overtemp, Menu ( 5)..................................... 41  
Two Wire Start Generators ............................................... 76  
U
Universal motors................................... See Inductive Loads  
Unpacking......................................................................... 17  
User Menu ........................................................................ 36  
Menu Headings............................................................. 36  
Menu Map..................................................................... 34  
User Settings Worksheet ................................................ 123  
Setup Menu 12 VDC ................................................ 124  
Setup Menu 24 VDC ................................................ 125  
Setup Menu 48 VDC ................................................ 126  
User Menu .................................................................. 123  
Using Multiple Inverters..................................................... 95  
Utility Back-Up ............................................................ 88, 92  
Utility Back-Up Mode................................45, 61, 90, 94, 101  
Battery Requirements ................................................... 82  
Silent (SLT) Mode......................................................... 82  
SLT (Silent) Mode......................................................... 82  
Utility Support/Overload Protection ............................... 82  
Utility Inter-Active Mode .............................................. 61, 83  
Battery Overvoltage Protection...................................... 89  
Islanding Protection ...................................................... 84  
Selling Power................................................................ 85  
From A DC Charging Source .................................... 85  
Stored In The Batteries ............................................. 86  
Utility Back-Up .............................................................. 88  
Utility Support/Overload Protection ................................... 82  
V
Ventilation......................................................................... 18  
Voltage Start Ready, Menu ( 2)......................................... 39  
W
Warning Label................................................................... 21  
Warranty  
Corrosion ...................................................................... 17  
Generator...................................................................... 25  
Not Covered...................................................... 24, 25, 51  
Shipping Address........................................................ 136  
Warranty Registration And Repair............................... 135  
Well pumps........................................... See Inductive Loads  
Inverter Surge .............................See Locked Rotor Amps  
Wiring  
AC Wiring ..................................................................... 18  
AC Input Connections ............................................... 18  
AC Output Connections ............................................ 18  
Installation Guidelines............................................... 20  
Control Wiring............................................................... 25  
Aux Relay Wiring ...................................................... 25  
Fusing........................................................... 25, 74, 89  
Gen Control Relays................................................... 25  
Remote Control Wiring.............................................. 25  
DC Wiring ..................................................................... 22  
Battery Cable Connections........................................ 24  
Battery Cable Sizing.................................................. 22  
Worksheet  
T
T240 Transformer............................................................129  
TFB (Fuse Block) ..............................................................23  
Theory of Operation...........................................................57  
Block Diagram...............................................................57  
Output Waveform ..........................................................58  
Three Wire Start Generators .............................................77  
Battery Sizing.............................................................. 103  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Page  
141  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
INDEX  
User Settings .............................................................. 123  
Setup Menu 12 VDC ............................................ 124  
Setup Menu 24 VDC ............................................ 125  
Setup Menu 48 VDC ............................................ 126  
User Menu .............................................................. 123  
Telephone: 360/435-8826  
Fax: 360/435-2229  
www.traceengineering.com  
SW Series Inverter/Charger  
Part No. 2031-5  
2001 Xantrex Technology, Inc.  
Page  
142  
5916 - 195th Street N. E.  
Arlington, WA 98223  
Rev. C: February 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Download from Www.Somanuals.com. All Manuals Search And Download.  
5916 - 195th Street N.E., Arlington, WA 98223 Phone: (360) 435-8826 Fax: (360) 435-2229  
visit our website at: www.traceengineering.com  
Download from Www.Somanuals.com. All Manuals Search And Download.  

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