Honeywell 500 User Manual

Class 500 Advanced KWh/Demand  
Meter  
INSTALLATION INSTRUCTIONS  
APPLICATION  
The Class 500 Meter is a 3-element meter with communications. The device is used to monitor electric power usage of individual  
loads after the utility meter. Installation must only be performed by qualified personnel and in accordance with these  
instructions and all applicable local and national electrical codes.  
62-0304-05  
CLASS 500 ADVANCED KWH/DEMAND METER  
INSTALLATION  
VERIFY the input voltage rating and configuration on the unit panel label to ensure it is suitable for the intended electrical service.  
Meters labeled for 115/208 volt service MUST NOT be installed on service feeds of 277/480 volt and vice versa.  
VERIFY that the Class 500 Meter current sensors are sized suitably for the load to be monitored. Compare the color of the arrows  
on the current sensors to the chart below to confirm the correct current sensor is being used.  
Table 1. Sensor arrow color and rating  
Sensor Arrow Color Code  
Brown  
Sensor  
100 Amp  
200 Amp  
400 Amp  
800 Amp  
1600 Amp  
3200 Amp  
Red  
Yellow  
Black  
Blue  
White/Black  
CAUTION  
Internal circuit card components are extremely sensitive to electrostatic discharge. Prior to handling or touching  
the internal circuitry, discharge any static build-up on your person. To discharge yourself, touch a grounded  
metal object such as conduit or an earth grounded metal enclosure.  
WARNING  
Use of the Class 500 Meter in a manner inconsistent with this manual or not specified by the manufacturer in  
writing can cause permanent damage to the unit and/or serious injury to the operator. The protection and safety  
features provided by this equipment may become impaired or otherwise compromised.  
WARNING  
High voltages are present on main power terminal block, TB1. Risk of serious injury and/or electrical shock  
exists. Prior to performing any wiring operations, review all the contents of the user’s manual and de-energize  
the MAINS power switch. Only qualified personnel should perform installation wiring. Installation wiring must  
comply with all local and national electrical codes.  
WARNING  
Failure to ground the enclosure creates a possible shock hazard. Do not operate the Class 500 Meter without a  
protective earth wire attached securely to the PE terminal screw. After installing the protective earth wiring,  
secure the screw tightly (10 N-m torque). NEVER open the front panel of the unit while the unit has MAINS power  
applied. Failure to comply can increase the risk of serious injury and for electrical shock.  
Internal Electronic Assemblies  
The unit is composed of two major subassembly boards: the main power and display boards (See Fig. 1).  
NOTE: Units supplied in a NEMA 12 metal enclosure are suitable for indoor applications only. For outdoor installation, use the  
NEMA 4 enclosure.  
POWER SUPPLY BOARD  
DISPLAY BOARD  
M28750  
Fig. 1. Subassembly boards in the Class 500 Meter.  
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CLASS 500 ADVANCED KWH/DEMAND METER  
Main Power Board  
Connections to this board include the MAINS input voltage, current sensors, and external pulse input (See Fig. 2).  
The MAINS input terminals are covered with a protective clear shield for safety purposes. The current sensor assemblies  
interface to TB2, TB3 or TB4. Each header connector input corresponds to an input voltage phase; therefore, care must be  
exercised to ensure each current sensor is connected to the correct input header.  
MAINS INPUT TERMINALS  
TB2, TB3 AND TB4 SENSOR INTERFACES  
M28745  
Fig. 2. MAINS power board of the Class 500 Meter.  
Display Board  
The display board interconnects to the main power board via a flex ribbon cable, and the board mounts on the inside of the  
housing door. The only required connection is for RS485 communications. When the meter is operated as a stand-alone unit  
using the modem for communications, the RS485 connections are not required. The display board LCD readout indicates the  
cumulative kWh value as well as errors associated with the Class 500 Meter, such as low battery or sensor errors.  
METER INSTALLATION  
Mounting  
1. Using appropriate sized mounting hardware, fasten the Class 500 Meter enclosure to the selected mounting surface. The  
four housing mounting holes are centered 6.75” H x 4” W.  
NOTE: Units installed outdoors must use the NEMA 4—rated enclosure.  
Main Power Board Connections  
1. Installing a temporary ground for ESD protection: With all the circuits de-energized, connect a temporary protective  
earth ground connection for ESD protection. Prior to performing any unit wiring, be sure to discharge any static on  
your person.  
2. Installing the Class 500 Meter protective earth ground: Connect an earth ground wire to the Class 500 Meter protective  
earth ground terminal screw located on the bottom right side of the main power board. After installing the protective earth  
ground wire, securely fasten the protective earth ground screw.  
WARNING  
Failure to attach the protective earth ground wire securely to the enclosure creates a potential shock hazard. Do  
not operate the meter without a protective earth ground connection securely installed.  
3. Wire entry: Two openings exist on the standard enclosure; one for 1/2” conduit and one for 3/4” conduit. The 3/4” conduit  
opening located on the bottom edge of the housing is used to bring in MAINS power and current sensor wiring. The 1/2”  
conduit opening located on the top edge of the housing is used to interface the low voltage signals and RS485 communica-  
tions wiring to the unit. Route the appropriate cabling to and through the respective enclosure opening.  
4. Unit MAINS wiring:  
a. Remove the clear shield located over terminal block TB1 on the main power board. This shield can be removed by  
pressing in on each locking tab located at the top of each standoff. While pressing the tabs inward, lift the shield from  
the standoffs. Wire each connection to terminal block TB1 with stranded wire 14-12 AWG, rated at 600 VAC.  
b. Strip back all wire insulation to expose between 1/4” and 3/8” of the copper conductors. Gently twist each wire’s con-  
ductors to prevent fraying. Insert the conductors into their respective terminal block position and tighten down the termi-  
nal block screw to securely fasten the conductor. Terminal block TB1 is clearly labeled PHASE A, PHASE B, PHASE C,  
and NEUTRAL.  
c. Connect the NEUTRAL wire to the appropriate terminal block position.  
NOTE: For delta MAINS input wiring, DO NOT connect the NEUTRAL wire. Remove the terminal block screw for this position.  
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4
CLASS 500 ADVANCED KWH/DEMAND METER  
d. Connect the three AC mains power wires (PHASE A, PHASE B, and PHASE C) to their respective positions as labeled  
on terminal block TB1. After all conductors are connected to their respective terminal block positions and tightened  
down, verify each terminal block screw is securely fastened by gently tugging on each conductor. Verify that no conduc-  
tor wires are frayed or shorting to adjacent terminal block positions.  
5. External switch mechanism/in-line fuse installation:  
a. To ensure a safe installation, the Class 500 Meter requires an external switch mechanism, such as a circuit breaker, be  
installed to the Class 500 Meter MAINS input wiring. The switch mechanism must be installed in close proximity to the  
Class 500 Meter and be easily reachable for the operator.  
This device must also be marked as the disconnecting device for the Class 500 Meter.  
b. Install 1/10 Amp Slow Activation inline fuses with the suitable voltage rating for each conductor phase at the MAINS  
input to the meter. The fuses must be labeled to indicate voltage and current rating as well as element characteristics.  
The fuse element must be a slow-activating type.  
6. Once the MAINS wiring is complete, close the enclosure front panel and secure the panel to the enclosure using the lock-  
ing mechanism. Activate the external circuit breaker or equivalent switch to apply AC MAINS power to the unit. The Class  
500 Meter display should turn on and indicate total kWh accumulation reading.  
NOTE: The unit display, clock, schedule, and other critical configuration parameters will be reset once the unit is completely  
wired and ready for commissioning. Resetting and configuring these parameters must be done through a host computer,  
locally or remotely, via an RS485 or ethernet link.  
7. Using an AC voltmeter, verify that the input voltage readings are within the limits specified in Table 2.  
NOTE: On 3-wire systems the voltages are measured Phase to Phase.  
On 4-wire systems the voltages are measured Phase to Neutral.  
Table 2. Input voltage limits  
Meter Input Voltage/Configuration  
120/208V, 3Ø, 4 Wire  
277/480V, 3Ø, 4 Wire  
346/600V, 3Ø, 4 Wire  
240V, 3Ø, 3 Wire  
Normal Voltage  
120 VAC  
Limits (+/-10%)  
108 to 132 VAC  
249 to 305 VAC  
311 to 381 VAC  
216 to 264 VAC  
432 to 528 VAC  
277 VAC  
346 VAC  
240 VAC  
480V, 3Ø, 3 Wire  
480 VAC  
8. Remove power from the unit by de-energizing the external switch.  
Current Sensor Installation and Wiring  
Once the AC voltages have been confirmed to be within acceptable limits, you are ready to install the current sensors. The main  
power board contains three header connectors located at the bottom center of the board, TB2, TB3, and TB4.  
TB2: Phase A current sensor input  
TB3: Phase B current sensor input  
TB4: Phase C current sensor input  
The Class 500 meters are shipped with split-core current sensors.  
1. Split-core current sensor: This sensor opens so that it can be attached around the circuit conductor being monitored with-  
out interrupting power.  
2. Split-core current sensors output a 0-2 VAC signal, proportional to the current being measured.  
Installing the Split Core Current Sensor Assembly  
1. Each phase being monitored will require one two-piece current sensor assembly. Therefore, a three-phase meter will  
require three (3) assemblies. Open the two-piece current sensor assembly by releasing the nylon clamp using a flat head  
screwdriver.  
2. Reassemble the current sensor assembly around the conductor(s) to be monitored. Ensure the current sensor halves  
marked “Load” are both facing the load side of the conductor. The colored arrow will be on the source side of the conductor  
being monitored and MUST be pointed in a clockwise direction around the conductor being monitored. Tighten the nylon  
clamp to complete the assembly.  
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CLASS 500 ADVANCED KWH/DEMAND METER  
Fig. 3. Split core current sensor assembly.  
Fig. 4. Split core current sensor assembly installed.  
IMPORTANT:  
When looking from the source side of the conductor(s) being monitored, you should see the arrow on the current sensor  
assembly. The arrow should be pointing in a clockwise direction around the conductor(s) being monitored. If the arrow is  
not positioned on the source side, the resulting readings will be inaccurate.  
Current Sensor Wiring  
Once all the current sensors are installed onto their appropriate phase conductors, you can begin terminating the current sensors  
onto the Class 500 Meter main board.  
The current sensor leads can be extended up to 500 feet for remote monitoring applications. To extend the length of the wires,  
use #22 AWG twisted pair wire with a black and white conductor, rated for 600 VAC.  
The current sensor connection points are located on the bottom center of the main power board. Three removable plugs exist,  
one for each current sensor phase input. The header portions of the connectors are labeled TB2, TB3, and TB4. The silkscreen  
located in front of each connector instructs you which terminal of the plug is for the white conductor and which terminal is wired to  
the black conductor. Once each current sensor is wired to its respective plug, insert each plug into the appropriate header.  
MAINS LINE VOLTAGE AND CURRENT SENSOR WIRING DIAGRAMS  
LINE VOLTAGE  
ØA ØB ØC  
CURRENT SENSORS  
ØB  
LINE VOLTAGE  
ØA ØB ØC  
CURRENT SENSORS  
ØB  
ØA  
ØC  
ØA  
ØC  
B
W
B
W
B
W
N
B
W
B
W
B
W
N
ØA  
ØA  
ØB  
ØC  
ØB  
ØC  
N
LOAD  
NOTES: LINE VOLTAGE CONNECTIONS: 14-22 AWG  
SOURCE  
LOAD  
NOTES: LINE VOLTAGE CONNECTIONS: 14-22 AWG  
SOURCE  
SENSOR CONNECTIONS: B=BLACK LEAD, W=WHITE LEAD  
SENSOR CONNECTIONS: B=BLACK LEAD, W=WHITE LEAD  
1/10A, 600 VAC INLINE FUSE PER CONDUCTOR.  
LITTLEFUSE PART NUMBER KLDR 100.  
1/10A, 600 VAC INLINE FUSE PER CONDUCTOR.  
LITTLEFUSE PART NUMBER KLDR 100.  
NEUTRAL NOT USED IN DELTA SYSTEM. REMOVE NEUTRAL  
NEUTRAL NOT USED IN DELTA SYSTEM. REMOVE NEUTRAL  
TERMINAL BLOCK SCREW FOR DELTA SYSTEMS.  
TERMINAL BLOCK SCREW FOR DELTA SYSTEMS.  
M32797  
M32788  
Fig. 6. 3-phase, 3-wire installation diagram.  
Fig. 5. 3-phase, 4-wire installation diagram.  
Line Voltage/Current Sensor Diagnostics  
Ensure that the three-phase AC MAINS voltage wiring and the current are connected in the proper phase sequence. If there is a  
phase sequence error, the display LCD will show the message “Check Sensor” in the upper right hand corner. Additionally, LED  
D5 labeled “MTR” (See Fig. 7) will flash at a rate of twice per second in the event of a phase error or missing phase voltage(s).  
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CLASS 500 ADVANCED KWH/DEMAND METER  
D5  
ETHERNET  
BOARD  
M28748A  
Fig. 7. Location of LED D5 (labeled “MTR”) and Ethernet board.  
Verify that the AC MAINS voltage wires are all connected to the correct positions on terminal block TB1. Inspect the MAINS input  
wiring to verify each conductor is terminated at the correct terminal block position. Using an AC voltmeter, measure the AC  
voltage for each Phase to Neutral terminal and to the frame ground point.  
Load each current sensor by running at least 1% of the full-scale rated current through the conductor being monitored by each  
phase. For example, a 2 Amp load is required on 200 Amp rated sensors for each phase to perform sensor diagnostic  
procedures.  
Verify that the current sensor white and black conductors are installed in the correct header positions.  
Verify that the current sensors are installed in the correct direction on the conductor being monitored.  
Verify that the current sensors plugs are terminated in the correct header on the Main Power board.  
If the error messages still haven’t been cleared, measure the AC voltage output across the plug terminals of each current sensor  
individually. Set the AC voltmeter to the 20 volt scale. If a reading of zero volts is indicated on the voltmeter, check for an open  
circuit. An open could exist at the plug terminals or at a splicing junction. Also verify that the core halves are assembled tightly.  
Final Main Power Board Checks  
Once the phase error has been corrected, the display LCD “Check Sensor” error should extinguish and the main power board  
LED D5 should flash at a rate of once per second. Also verify that LED D4, labeled “CPU”, is flashing at a rate of once per second  
and synchronously with LED D5.  
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CLASS 500 ADVANCED KWH/DEMAND METER  
Wiring to the Network  
RS-485 Wiring for BACnet MS/TP, Modbus RTU, or EZ-7  
The Class 500 Meter contains an RS-485 serial communications port allowing it to communicate via BACnet MS/TP, Modbus  
RTU, or EZ-7. The units can be daisy-chained together over distances of up to 4000 feet. Up to 52 unit nodes can be networked  
together. The meters are networked in a daisy-chain configuration with BELDEN 1120A cable or an equivalent. A cable rating of  
600V allows a RS-485 network to be connected to 480-volt meters. Communications wiring should enter/exit the Class 500 Meter  
enclosure through the 1/2 in. hole located on the upper (top) surface of the enclosure using a 4-conductor, UL-approved  
telephone cord terminated with an RJ-11 male connector.  
NOTE: A 3-screw terminal block is also available for the RS-485 wiring, as an optional method.  
WIRING METHOD  
M28751  
TERMINAL LOCATION  
Fig. 8. Modbus terminal location and wiring method.  
BACNET MS-TP: NOTE  
3 POSITION TERMINAL  
BLOCK FOR RS-485  
CONNECTIONS  
Fig. 9. BACnet wiring with RS-485 connection.  
62-0304—05  
8
CLASS 500 ADVANCED KWH/DEMAND METER  
The meter is shipped with a Modbus ID number of 01. This must be changed if the network has more than one meter installed.  
The change must be done before the meter is introduced into the network, or it can be put on the network as the only device on  
the network and Modbus address changed before adding additional devices.  
The meter can be numbered from 1 to 247. There can be no duplicate numbers on a network, so caution must be taken when  
assigning a meter ID number prior to its installation on the RS-485 network.  
EMS OR CONTROL  
UNIT WITH MODBUS  
COMMUNICATIONS  
M28752  
Fig. 10. Modbus installation overview.  
METHOD 1: DAISY-CHAIN WITH WIRE TERMINAL (MOST COMMON METHOD)  
1. Connect the “HI” terminal (Display PCB J3 Pin 1) of each Class 500 unit together so that all unit Hl terminals are linked (Hl  
to Hl to Hl, etc.).  
2. Connect the “LO” terminal (Display PCB J3 Pin 2) of each Class 500 unit together so that all unit LO terminals are linked  
(LO to LO to LO, etc.).  
3. Connect the “GND” terminal (Display PCB J3 Pin 3) of each Class 500 unit together so that all unit GND terminals are  
linked (GND to GND to GND, etc.).  
4. After completing the wiring of connector J3 for all units, complete the wiring to the EMS through the appropriate input termi-  
nals (RS485 or Ethernet).  
METHOD 2: DAISY-CHAIN WITH MODULAR JACKS  
1. Each display board has two RJ-11 jacks available to facilitate RS-485 daisy-chain connections. Using RJ-11 four-conductor  
cable, wire each cable end pin to pin. Interconnect all units together with the RJ-11 cabling.  
2. After daisy-chaining the units is complete, the system can be interfaced through the wire terminal on the meter closest to  
the EMS (see method 2).  
LON and BACnet MS/TP Wiring  
For LON and BACnet MS/TP connections, follow standard wiring procedures/topologies for these communication types. Both of  
these connections are found on the communications board which sits on the main power board (not on the display board). The  
LON is a two position terminal block for twisted pair, and the BACnet MS/TP is a 3 position terminal block.  
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CLASS 500 ADVANCED KWH/DEMAND METER  
SERVICE PIN SWITCH (BLUE  
PUSH BUTTON):  
BROADCASTS LON NEURON  
ID TO LON NETWORK.  
ASSISTS IN SETUP OF  
DEVICE ON LON NETWORK.  
LONWORKS MODULE. NOTE  
2 POSITION TERMINAL  
BLOCK FOR TWISTED PAIR  
CONNECTION  
Fig. 11. LON wiring.  
Ethernet wiring for BACnet IP, and Modbus TCP/IP and Ethernet EZ-7  
These models are shipped with a board that allows for Ethernet communication via Modbus TCP/IP, BACnet IP or Ethernet EZ-7.  
EZ-7 protocol is required when using the Energy Software.  
Modbus TCP/IP and BACnet IP, and Ethernet EZ-7 connections are made to the RJ45 connection on the Ethernet board (Fig. 7  
on page 7). No RS-485 daisy-chain capabilities exist with with these Ethernet connections.  
MONITORING MULTIPLE LOADS WITH ONE CLASS 500 METER  
The Class 500 Meter provides extreme flexibility by allowing additional sets of current sensors to be used in parallel so multiple  
load locations can be monitored by one Class 500 Meter. This feature allows a totalized display readout of two or more load  
circuits.  
You may use parallel sensors to monitor specific breakers from one panel, specific breakers from more than one panel, two or  
more complete panels, etc.  
When paralleling current sensors, the following rules must be followed for accurate readings:  
1. Current sensors must be installed in complete sets of three, with a maximum of three sensors installed in parallel per  
phase.  
2. All sensors used in parallel must be of the same amperage rating (i.e. 100 Amp, 200 Amp, etc.). The rating is determined  
by the current rating (amperage) of the Class 500 Meter. For example, a 200 Amp Class 500 Meter must use extra sets of  
200 Amp current sensors.  
3. All locations being monitored must have the same power source. A 480 volt Class 500 Meter, for example, cannot monitor  
a 208 volt load circuit nor can a Class 500 Meter monitor two 480 or 208 volt loads if they are from different originating  
power sources or from different transformers.  
4. The display readings must be multiplied by the number of sets of current sensors installed. For example, for Class 500  
Meter reading of 5 KWH with 2 sets of currents sensors you will have 5 x 2 = 10 KWH (actual usage).  
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CLASS 500 ADVANCED KWH/DEMAND METER  
NOTE: One set of current sensors equates to three sensors, one per phase. The multiplier only applies when extra sets of cur-  
rent sensors are installed on one Class 500 Meter. Therefore, if you are using only one set of three current sensors, the  
multiplier is not required.  
LINE VOLTAGE  
ØC  
CURRENT SENSORS  
ØA  
ØB  
ØC  
N
B
W
B
W
B
W
ØA ØB  
LINE VOLTAGE  
LEADS  
LOAD A  
A
B
C
N
CURRENT  
SENSOR  
LEADS  
LOAD  
SOURCE (LINE)  
LOAD B  
A
B
C
N
CURRENT SENSOR LEADS  
LOAD  
SOURCE (LINE)  
M29307  
Fig. 12. Parallel current sensor installation diagrams.  
CONFIGURING THE CLASS 500 USING E-MON ENERGY™  
SOFTWARE  
E-Mon Energy is a product of Honeywell, Inc. This software operates on a computer running Windows 2000, XP, Vista or  
Windows 7 and is used to interface to many products including the Class 500. E-Mon Energy Software requires data access via  
the EZ-7 protocol.  
Reference the E-Mon Energy software for specific instructions to perform the following operations:  
Peak Demand Reset  
Modem Initialization  
Setting or changing the Remote Dial Out Number  
Downloading Profile Data  
Unit Initialization  
Setting/Changing Unit ID, Group and Location information  
Confi guring Unit Call-In schedule  
Resetting Meter Display  
11  
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CLASS 500 ADVANCED KWH/DEMAND METER  
MAINTENANCE  
The Class 500 Meter unit is shipped in a calibrated and fully functionally tested condition. Since the unit is factory calibrated using  
proprietary firmware algorithms, no internal unit adjustments are necessary. This unit contains no internal adjustments. Therefore  
no preventative or scheduled maintenance is required, or cleaning or decontamination procedures.  
Lithium Battery Replacement Instructions  
The Class 500 Meter has a lithium battery cell that is used to retain the contents of SRAM and the RTC during power outages.  
The battery has a life expectancy greater than 8 years (See Table 3 for battery specifications).  
Table 3. Battery specifications (25 ºC)  
Nominal working voltage  
Nominal current capacity:  
Cell chemical:  
3.5 VDC output  
350 mAHr  
Lithium-thionyl chloride  
-40 to +95 ºC  
Eagle-Picher  
LTC-3PN  
Operating temperature range:  
Manufacturer:  
Manufacturer’s part number:  
WARNING  
Only replace battery with the exact part number from the manufacturer specified above.  
CAUTION  
The battery is not completely discharged, therefore DO NOT short the terminals on the battery with any  
conductive material.  
CAUTION  
The internal circuit card components are extremely sensitive to electrostatic discharge. Be careful not to touch  
internal circuitry prior to discharging any static build-up on your person. To discharge yourself, touch a  
grounded metal object such as a conduit or a metal enclosure exterior.  
The battery cell is mounted in a socket on the upper right side of the main power board (See Fig. 13). Should the battery capacity  
drop below 2.4 VDC, the display will illuminate a battery symbol on the left margin indicating a low battery. Additionally, the  
internal unit firmware will set a flag indicating the low battery condition. When the unit data is next downloaded, the monitoring  
facility will be alerted of the low battery and will schedule a service call.  
BATTERY  
M28744  
Fig. 13. Location of battery.  
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CLASS 500 ADVANCED KWH/DEMAND METER  
Use the following procedure to replace the lithium battery cell.  
1. Disconnect power from the Class 500 Meter at the unit external circuit breaker.  
2. Remove the battery from its socket and place it on a non-conductive surface.  
3. Install the new battery into the PCB battery socket.  
NOTE: The main power board battery socket is keyed to prevent the user from inserting the new battery in the wrong polarity.  
No damage will occur to the unit or battery if the battery is inadvertently installed in the wrong direction.  
4. Visually inspect the new battery to verify that all leads are fully inserted into their respective socket positions.  
5. Dispose of the used battery in accordance with the manufacturer’s (Eagle Picher) instructions.  
EXTERNAL CONTACT INPUT  
Two additional channels are available (channels 3 and 4) on the Class 500 Meter to be used for capturing pulses from external  
devices. These devices can be another electric meter, a water meter, a gas meter, or any unit with an output pulse. The output  
pulse of the device must be in the form of a dry contact - either physical or electronic.  
Count speeds of up to 10 Hz (600 ppm) are accepted by the Class 500 Meter, and the count is available at Modbus point  
locations 41083 and 41085. See the point-map (Table 4) for more information.  
Wiring  
The external pulse is wired into the Class 500 Meter through the terminals marked “INPUT 1” and “INPUT 2” (TB6 and TB7).  
These consist of removable plug and header assemblies similar to the current sensor inputs.  
The external device can be mounted up to 100 feet away from the Class 500 Meter, and wire sizes from 24 to 16 gauge (AWG)  
can be used for the connection. If the external device utilizes a polarity-dependent, solid-state contact, the plus (+) from  
the contact must terminate on the left hand pin of the headers on the Meter.  
M29701  
INPUT 1 and  
INPUT 2  
13  
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CLASS 500 ADVANCED KWH/DEMAND METER  
Modbus Point Map  
Modbus data points available from the Class 500 meter. Listed under Class 500.  
Table 4. Honeywell Modbus point map  
INTEGER W FLOAT  
UOM CALC. MEM  
OP  
R/W  
DESCRIPTION  
Energy delivered  
CLASS 500  
1
40001  
40003  
40005  
40007  
2
2
2
2
41001  
41003  
41005  
41007  
41009  
41011  
41013  
41015  
41017  
41019  
41021  
41023  
41025  
41027  
41029  
41031  
41033  
41035  
41037  
41039  
41041  
41043  
41045  
41047  
41049  
41051  
41053  
41055  
41057  
41059  
41061  
41063  
41065  
41067  
41069  
41071  
41073  
41075  
41077  
41079  
41081  
41083  
41085  
kWh  
kWh  
T-del  
T-rec  
NV  
NV  
NV  
NV  
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
2
R/W  
R/W  
R/W  
R
Energy received  
3
kVARh T-del  
kVARh T-rec  
Reactive energy delivered  
Reactive energy received  
Real power  
4
5
kW  
T
6
kVAR  
kVA  
T
R
Reactive power  
7
T
R
Apparent power  
8
%
T
R
Power factor  
9
Amps  
Amps  
Volts-N  
Volts-L  
Hz  
T
R
Current total  
10  
11  
12  
13  
14  
15  
16  
17  
18  
19  
20  
21  
22  
23  
24  
25  
26  
27  
28  
29  
30  
31  
32  
33  
34  
35  
36  
37  
38  
39  
40  
41  
42  
43  
A
R
Current average  
A
R
Voltage line-neutral  
A
R
Voltage line-line  
A
R
Frequency  
Degree  
kW  
A
R
Phase angle  
ØA  
ØB  
ØC  
ØA  
ØB  
ØC  
ØA  
ØB  
ØC  
ØA  
ØB  
ØC  
ØA  
ØB  
ØC  
R
Real power, phase A  
Real power, phase B  
Real power, phase C  
Reactive power, phase A  
Reactive power, phase B  
Reactive power, phase C  
Apparent power, phase A  
Apparent power, phase B  
Apparent power, phase C  
Power factor, phase A  
Power factor, phase B  
Power factor, phase C  
Current, phase A  
kW  
R
kW  
R
kVAR  
kVAR  
kVAR  
kVA  
R
R
R
R
kVA  
R
kVA  
R
% PF  
% PF  
% PF  
Amps  
Amps  
Amps  
R
R
R
R
R
Current, phase B  
R
Current, phase C  
Volts-N ØA  
Volts-N ØB  
Volts-N ØC  
Volts-L ØA  
Volts-L ØB  
Volts-L ØC  
Degree ØA  
Degree ØB  
Degree ØC  
R
Voltage, line to neutral, phase A-N  
Voltage, line to neutral, phase B-N  
Voltage, line to neutral, phase C-N  
Voltage, line to line, phase A-B  
Voltage, line to line, phase B-C  
Voltage, line to line, phase C-A  
Phase angle, phase A  
Phase angle, phase B  
Phase angle, phase C  
R
R
R
R
R
R
R
R
Pulse  
Pulse  
Auxiliary Input 1  
Auxiliary Input 2  
Y
Y
62-0304—05  
14  
 
CLASS 500 ADVANCED KWH/DEMAND METER  
Table 4. Honeywell Modbus point map  
DATA (SAMPLE) DESCRIPTION  
ITEM  
PM-I  
46001  
W
8
504D 324B 0106 0421 0800 454D 4F4E 2020 Firmware version: PM 5K, Ver, Ver date/time,  
Honeywell  
R
46009  
46017  
46025  
8
8
8
456E 6572 6779 204D 6574 6572 0000 0000 Device description: Honeywell Energy Meter  
1356 4503 0613 0300 0000 0000 0000 0000 Initialize device with date/time  
R
W
1356 4503 0613 0300 0000 0000 0000 0000 RTC date/time, will accept broadcast  
command  
R/W  
46033  
8
1356 4503 0527 0300 0000 0000 0000 0000 CPU date/time (7 bytes, rest is reserved for  
other future formats)  
R/W  
46041  
46049  
46057  
8
8
8
0001 0001 0000 0000 0000 0311 0020 1100 Group, location, Device ID number  
0041 0000 0000 0000 0000 0311 0020 1100 Dev. ID, Hookup, Serial numbers….  
R/W  
R/W  
R/W  
0592 0007 0000 0000 0000 0000 0000 0000 Recorder info.: idr, dem. int., dem. win.,  
dem. syn., timezone, DST…  
46065  
8
0101 0001 0D03 3531 1000 0320 0000 0000 Meter info.: SN1&2, pulse rate, Volt/Amp/  
CTs, PF/mult1&2, CT, PT  
R/W  
46513  
46521  
46529  
46537  
8
8
8
8
0000 0101 0000 0000 0000 0100 0000 0000 Flags L1  
0000 0000 0000 0000 0000 0000 0613 0316 Flags L2  
0000 0000 0000 0000 0000 0000 0000 0000 Flags L3  
0000 0000 0000 0000 0000 0000 0000 0000 Flags L4  
NOTE: To change device ID, set single point at 46049 with data set to new device ID (e.g., 1 to 247).  
To set date/time, set multiple points at 46025 for 4 points with data set to HHMM SSDW MMDD YYYY (DW=day of week).  
To clear single meter kWh/kW, set single point at 41001 with data set to 0000 (similarly for 41003, 41005, 41007).  
To clear multiple meter readings, set multiple point at 41001 for 8 points with data set to 0000's.  
NOTE: Jumper J5 & J6 must be closed in order for kWh del/rec and kVARh del/rec to be cleared.  
15  
62-0304—05  
CLASS 500 ADVANCED KWH/DEMAND METER  
FREQUENTLY ASKED QUESTIONS  
Q. When providing line voltage to the Class 500 Meter, can l tap off of the same breaker l am monitoring?  
A. Yes, the voltage can be pulled from the same breaker being monitored.  
Q. Can the Class 500 Meter line voltage wires be run in the same conduit as the sensor leads?  
A. Yes, there will be no effect on the Class 500 Meter if the sensor leads and line voltage wires are run in the same conduit.  
Q. How do l find the cost for kWh and kW to bill my tenants?  
A. Your local utility bill should list the cost per kWh and kW. If not, simply call your utility and ask them to provide you with the  
cost per kWh and kW.  
Q. What size wire do l use for the line voltage leads?  
A. These wires are normally sized at #14 AWG, but be sure to confirm this requirement with your local and national electrical  
codes requirements.  
Q. What size wire should l use to extend the current sensor leads?  
A. These wires are normally #14 AWG, twisted pair arrangement. Consult your local electrical code for proper sizing  
requirements.  
Q. The load l need to monitor has parallel feeds. How do l install the current sensors for this application?  
A. There are two ways you can monitor parallel feeds. One method is to clamp the sensors around all feed wires for each  
phase. The second way to monitor parallel feeds is to clamp the sensor around one of the feed wires for each phase. When  
you read the Class 500, the final reading must be multiplied by the number of feed wires for each phase.  
Q. I have two subpanels l would like to monitor with one Class 500 Meter. These subpanels are fed by different  
transformers in the building. Can l parallel the sensors and monitor both panels with one Class 500 Meter?  
A. No. These panels cannot be monitored by one Class 500 because they are different power sources. When you parallel  
current sensors, all loads being monitored must be from the same voltage source.  
Automation and Control Solutions  
Honeywell International Inc.  
1985 Douglas Drive North  
® U.S. Registered Trademark  
© 2011 Honeywell International Inc.  
62-0304—05 M.S. Rev. 06-11  
Printed in U.S.A.  
Golden Valley, MN 55422  
customer.honeywell.com  

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