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INSTRUCTION MANUAL
MODEL 200AU
NITROGEN OXIDES ANALYZER
TELEDYNE INSTRUMENTS
ADVANCED POLLUTION INSTRUMENTATION DIVISION
(T-API)
6565 NANCY RIDGE DRIVE
SAN DIEGO, CA 92121-2251
TOLL-FREE: 800-324-5190
FAX: 858-657-9816
TEL: 858-657-9800
E-MAIL: [email protected]
WEB SITE: www.teledyne-api.com
02293
REV. F
Copyright 1999 API Inc.
07/06/99
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
TABLE OF CONTENTS
SAFETY MESSAGES .........................................................................................II
TABLE OF CONTENTS.....................................................................................III
LIST OF FIGURES........................................................................................... VII
LIST OF TABLES............................................................................................ VIII
1 HOW TO USE THIS MANUAL..................................................................... 1-1
2 GETTING STARTED.................................................................................... 2-1
2.1 UNPACKING....................................................................................................................2-1
2.2 ELECTRICAL AND PNEUMATIC CONNECTIONS ....................................................................2-1
2.3 INITIAL OPERATION .........................................................................................................2-6
3 SPECIFICATIONS, AGENCY APPROVALS, WARRANTY ........................ 3-1
3.1 SPECIFICATIONS.............................................................................................................3-1
3.2 EPA EQUIVALENCY DESIGNATION ...................................................................................3-2
3.3 WARRANTY ....................................................................................................................3-3
4 THE M200AU NOX ANALYZER................................................................... 4-1
4.1 PRINCIPLE OF OPERATION...............................................................................................4-1
4.2 OPERATION SUMMARY ....................................................................................................4-3
4.2.1 Sensor Module, Reaction Cell, Detector................................................................4-3
4.2.2 Pneumatic Sensor Board.......................................................................................4-3
4.2.3 Computer Hardware and Software ........................................................................4-4
4.2.4 V/F Board ..............................................................................................................4-4
4.2.5 Front Panel............................................................................................................4-5
4.2.6 Power Supply Module............................................................................................4-7
4.2.7 Pump, Valves, Pneumatic System.........................................................................4-7
4.2.8 Ozone Generator...................................................................................................4-7
4.2.9 Molybdenum Converter – Ozone Scrubber ...........................................................4-8
5 SOFTWARE FEATURES............................................................................. 5-1
5.1 INDEX TO FRONT PANEL MENUS......................................................................................5-1
5.1.1 Sample Menu ........................................................................................................5-4
5.1.2 Set-Up Menu .........................................................................................................5-6
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
5.2 SAMPLE MODE .............................................................................................................5-10
5.2.1 Test Functions.....................................................................................................5-10
5.2.2 CAL, CALS, CALZ, Calibration Functions............................................................5-13
5.3 SET-UP MODE .............................................................................................................5-16
5.3.1 Configuration Information (CFG) .........................................................................5-16
5.3.2 Automatic Calibration (AutoCal) ..........................................................................5-16
5.3.3 Data Acquisition System (DAS)...........................................................................5-16
5.3.4 Range Menu........................................................................................................5-19
5.3.5 Password Enable.................................................................................................5-21
5.3.6 Time of Day Clock ...............................................................................................5-22
5.3.7 Diagnostic Mode..................................................................................................5-22
5.3.8 Communications Menu........................................................................................5-22
5.3.9 Variables Menu (VARS) ......................................................................................5-22
5.3.10 M200AU Operating Modes................................................................................5-22
5.4 STATUS OUTPUT ..........................................................................................................5-23
5.5 RS-232 INTERFACE......................................................................................................5-24
5.5.1 Setting Up the RS-232 Interface..........................................................................5-25
5.5.2 Command Summary............................................................................................5-28
5.5.3 TEST Commands and Messages........................................................................5-32
5.5.4 WARNING Commands and Messages................................................................5-33
5.5.5 CALIBRATION Commands and Messages.........................................................5-34
5.5.6 DIAGNOSTIC Commands and Messages...........................................................5-36
5.5.7 DAS Commands and Message ...........................................................................5-37
5.5.8 Internal Variables.................................................................................................5-39
6 OPTIONAL HARDWARE AND SOFTWARE............................................... 6-1
6.1 RACK MOUNT OPTIONS...................................................................................................6-1
6.2 ZERO/SPAN VALVES .......................................................................................................6-1
6.3 AUTOCAL - SETUP ZERO/SPAN VALVES............................................................................6-2
6.4 4-20 MA, CURRENT LOOP OUTPUT..................................................................................6-4
6.5 NOY CONVERTER ...........................................................................................................6-4
7 CALIBRATION & ZERO/SPAN CHECKS ................................................... 7-1
7.1 MANUAL ZERO/SPAN CHECK OR CAL WITH ZERO/SPAN GAS IN THE SAMPLE PORT..............7-4
7.2 MANUAL ZERO/SPAN CHECK OR CALIBRATION WITH ZERO/SPAN VALVES OPTION ...............7-6
7.3 AUTOMATIC ZERO/SPAN CHECK ......................................................................................7-7
7.4 DYNAMIC ZERO/SPAN CALIBRATION .................................................................................7-7
7.5 USE OF ZERO/SPAN VALVES WITH REMOTE CONTACT CLOSURE ........................................7-8
7.6 EPA PROTOCOL CALIBRATION ........................................................................................7-9
7.6.1 Calibration of Equipment .......................................................................................7-9
7.6.2 Calibration Gas and Zero Air Sources.................................................................7-11
7.6.3 Data Recording Device........................................................................................7-12
7.6.4 Gas Phase Titration (GPT) System .....................................................................7-12
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
7.6.5 Dynamic Multipoint Calibration Procedure...........................................................7-16
7.6.6 Moly Converter Efficiency....................................................................................7-23
7.6.7 Calibration Frequency .........................................................................................7-25
7.6.8 Other Quality Assurance Procedures ..................................................................7-25
7.6.9 Summary of Quality Assurance Checks ..............................................................7-27
7.6.10 ZERO and SPAN Checks..................................................................................7-29
7.6.11 Recommended Standards for Establishing Traceability ....................................7-30
7.6.12 Certification Procedures of Working Standards.................................................7-31
7.7 CALIBRATION OF INDEPENDENT RANGES OR AUTORANGING .............................................7-32
7.7.1 Zero Calibration with AutoRange or Independent Range ....................................7-32
7.7.2 Span Calibration with AutoRange or Independent Range ...................................7-33
7.8 CALIBRATION QUALITY ..................................................................................................7-33
7.9 REFERENCES ...............................................................................................................7-35
8 MAINTENANCE ........................................................................................... 8-1
8.1 MAINTENANCE SCHEDULE ...............................................................................................8-1
8.2 REPLACING THE SAMPLE PARTICULATE FILTER .................................................................8-3
8.3 SAMPLE PUMP MAINTENANCE..........................................................................................8-5
8.4 CLEANING THE REACTION CELL .......................................................................................8-7
8.5 REPLACING THE MOLYBDENUM CONVERTER .....................................................................8-9
8.6 PNEUMATIC LINE INSPECTION ........................................................................................8-11
8.7 LEAK CHECK PROCEDURE.............................................................................................8-15
8.8 LIGHT LEAK CHECK PROCEDURE ...................................................................................8-16
8.9 PROM REPLACEMENT PROCEDURE ................................................................................8-16
9 TROUBLESHOOTING, ADJUSTMENTS .................................................... 9-1
9.1 OPERATION VERIFICATION-M200AU DIAGNOSTIC TECHNIQUES.........................................9-3
9.1.1 Fault Diagnosis with TEST Variables ....................................................................9-3
9.1.2 Fault Diagnosis with WARNING Messages...........................................................9-8
9.1.3 Fault Diagnosis using DIAGNOSTIC Mode .........................................................9-11
9.1.4 M200AU Internal Variables..................................................................................9-19
9.1.5 Test Channel Analog Output ...............................................................................9-21
9.1.6 Factory Calibration Procedure.............................................................................9-23
9.2 PERFORMANCE PROBLEMS............................................................................................9-26
9.2.1 AC Power Check .................................................................................................9-26
9.2.2 Flow Check..........................................................................................................9-27
9.2.3 No Response to Sample Gas ..............................................................................9-27
9.2.4 Negative Output...................................................................................................9-28
9.2.5 Excessive Noise ..................................................................................................9-28
9.2.6 Unstable Span.....................................................................................................9-29
9.2.7 Unstable Zero......................................................................................................9-30
9.2.8 Inability to Span...................................................................................................9-30
9.2.9 Inability to Zero....................................................................................................9-31
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
9.2.10 Non-Linear Response........................................................................................9-31
9.2.11 Slow Response..................................................................................................9-32
9.2.12 Analog Output Doesn't Agree with Display Concentration.................................9-32
9.3 SUBSYSTEM TROUBLESHOOTING AND ADJUSTMENTS.......................................................9-32
9.3.1 Computer, Display, Keyboard..............................................................................9-32
9.3.2 RS-232 Communications.....................................................................................9-36
9.3.3 Voltage/Frequency (V/F) Board...........................................................................9-39
9.3.4 Status/Temp Board..............................................................................................9-45
9.3.5 Power Supply Module..........................................................................................9-47
9.3.6 Ozone Generator.................................................................................................9-52
9.3.7 Flow/Pressure Sensor .........................................................................................9-55
9.3.8 NOx Sensor Module.............................................................................................9-60
9.3.9 Z/S Valves...........................................................................................................9-64
9.3.10 Pneumatic System.............................................................................................9-65
10 M200AU SPARE PARTS LIST ................................................................ 10-1
APPENDIX A ELECTRICAL SCHEMATICS ..................................................A-1
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
LIST OF FIGURES
FIGURE 2-1: REMOVAL OF SHIPPING SCREWS & CHECK FOR CORRECT POWER ..........................2-3
FIGURE 2-2: REAR PANEL........................................................................................................2-4
FIGURE 2-3: INLET AND EXHAUST VENTING ...............................................................................2-5
FIGURE 2-4: FRONT PANEL....................................................................................................2-10
FIGURE 2-5: ASSEMBLY LAYOUT ............................................................................................2-11
FIGURE 4-1: BLOCK DIAGRAM..................................................................................................4-2
FIGURE 5-1: SAMPLE MENU TREE ............................................................................................5-2
FIGURE 5-2: SETUP MENU TREE ..............................................................................................5-3
FIGURE 7-1: CALIBRATION SETUP ............................................................................................7-3
FIGURE 7-2: DIAGRAM OF GPT CALIBRATION SYSTEM.............................................................7-18
FIGURE 8-1: REPLACING THE PARTICULATE FILTER ...................................................................8-4
FIGURE 8-2: SAMPLE PUMP ASSEMBLY.....................................................................................8-6
FIGURE 8-3: REACTION CELL ASSEMBLY ..................................................................................8-8
FIGURE 8-4: MOLYBDENUM CONVERTER ASSEMBLY ................................................................8-10
FIGURE 8-5: PNEUMATIC DIAGRAM - STANDARD CONFIGURATION.............................................8-12
FIGURE 8-6: PNEUMATIC DIAGRAM WITH ZERO/SPAN VALVE OPTION ........................................8-13
FIGURE 8-7: PNEUMATIC DIAGRAM WITH EXTERNAL CONVERTER OPTION .................................8-14
FIGURE 9-1: SPAN CALIBRATION VOLTAGE .............................................................................9-25
FIGURE 9-2: CPU BOARD JUMPER SETTINGS .........................................................................9-34
FIGURE 9-3: RS-232 PIN ASSIGNMENTS ...............................................................................9-38
FIGURE 9-4: V/F BOARD SETTINGS........................................................................................9-44
FIGURE 9-5: POWER SUPPLY MODULE LAYOUT.......................................................................9-49
FIGURE 9-6: ELECTRICAL BLOCK DIAGRAM .............................................................................9-50
FIGURE 9-7: OZONE GENERATOR SUBSYSTEM........................................................................9-54
FIGURE 9-8: FLOW/PRESSURE SENSOR..................................................................................9-57
FIGURE 9-9: NOX SENSOR MODULE .......................................................................................9-58
FIGURE 9-10: NOX SENSOR MODULE .....................................................................................9-59
FIGURE 9-11: PMT COOLER SUBSYSTEM...............................................................................9-61
FIGURE 9-12: HIGH VOLTAGE POWER SUPPLY........................................................................9-63
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
LIST OF TABLES
TABLE 2-1: FINAL TEST AND CALIBRATION VALUES..................................................................2-12
TABLE 2-1: FINAL TEST AND CALIBRATION VALUES (CONTINUED) .............................................2-13
TABLE 4-1: FRONT PANEL STATUS LED'S.................................................................................4-6
TABLE 4-2: OZONE GENERATOR START-UP TIMING....................................................................4-8
TABLE 5-1: SAMPLE MENU ......................................................................................................5-4
TABLE 5-2: SAMPLE MENU ......................................................................................................5-5
TABLE 5-3: SETUP MENU.........................................................................................................5-6
TABLE 5-3: SETUP MENU (CONTINUED)....................................................................................5-7
TABLE 5-4: SETUP MENU.........................................................................................................5-8
TABLE 5-5: SETUP MENU.........................................................................................................5-9
TABLE 5-6: DAS DATA CHANNEL EDITING ..............................................................................5-19
TABLE 5-7: CALIBRATE, SETUP PASSWORDS ..........................................................................5-21
TABLE 5-8: M200AU OPERATING MODES ..............................................................................5-23
TABLE 5-9: STATUS OUTPUT PIN ASSIGNMENTS......................................................................5-24
TABLE 5-10: RS-232 PORT SETUP - FRONT PANEL ................................................................5-25
TABLE 5-11: RS-232 SWITCHING FROM TERMINAL MODE TO COMPUTER MODE .......................5-27
TABLE 5-12: RS-232 TERMINAL MODE EDITING KEYS.............................................................5-27
TABLE 5-13: RS-232 COMMAND SUMMARY............................................................................5-29
TABLE 5-14: RS-232 COMMAND SUMMARY............................................................................5-30
TABLE 5-15: RS-232 INTERFACE COMMAND TYPES ................................................................5-31
TABLE 5-16: RS-232 TEST MESSAGES ..................................................................................5-32
TABLE 5-17: RS-232 WARNING MESSAGES ...........................................................................5-33
TABLE 5-18: RS-232 CALIBRATION COMMANDS......................................................................5-34
TABLE 5-19: RS-232 CALIBRATION EXAMPLES .......................................................................5-35
TABLE 5-20: RS-232 CALIBRATION MESSAGES ......................................................................5-36
TABLE 5-21: RS-232 DIAGNOSTIC COMMAND SUMMARY .........................................................5-37
TABLE 6-1: ZERO/SPAN VALVE OPERATION ..............................................................................6-1
TABLE 6-2: EXAMPLE OF AUTOCAL SETUP................................................................................6-4
TABLE 7-1: TYPES OF ZERO/SPAN CHECK AND CALIBRATION .....................................................7-2
TABLE 7-2: MANUAL ZERO CALIBRATION PROCEDURE - ZERO GAS THRU SAMPLE PORT ..............7-4
TABLE 7-3: ENTER EXPECTED SPAN GAS CONCENTRATIONS PROCEDURE ..................................7-5
TABLE 7-4: MANUAL SPAN CALIBRATION PROCEDURE - SPAN GAS THRU SAMPLE PORT ..............7-5
TABLE 7-5: MANUAL ZERO CALIBRATION PROCEDURE - Z/S VALVES ..........................................7-6
TABLE 7-6: MANUAL SPAN CALIBRATION PROCEDURE - Z/S VALVES ..........................................7-7
TABLE 7-7: ENABLING DYNAMIC ZERO/SPAN.............................................................................7-8
TABLE 7-8: Z/S VALVES MODES WITH REMOTE CONTACT CLOSURE ...........................................7-9
TABLE 7-9: ACTIVITY MATRIX FOR CALIBRATION EQUIPMENT AND SUPPLIES ..............................7-10
TABLE 7-10: ACTIVITY MATRIX FOR CALIBRATION PROCEDURE.................................................7-11
TABLE 7-11: ZERO CALIBRATION PROCEDURE ........................................................................7-19
TABLE 7-12: EXPECTED SPAN GAS CONCENTRATION PROCEDURE...........................................7-20
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
TABLE 7-13: SPAN CALIBRATION PROCEDURE.........................................................................7-20
TABLE 7-14: AUTOMATIC CALCULATION OF CONVERTER EFFICIENCY ........................................7-24
TABLE 7-15: DEFINITION OF LEVEL 1 AND LEVEL 2 ZERO AND SPAN CHECKS ............................7-26
TABLE 7-16: ACTIVITY MATRIX FOR DATA QUALITY..................................................................7-28
TABLE 7-17: NIST-SRM'S AVAILABLE FOR TRACEABILITY OF CALIBRATION AND AUDIT GAS STANDARDS
........................................................................................................................7-31
TABLE 7-18: CALIBRATION QUALITY CHECK ............................................................................7-34
TABLE 8-1: PREVENTATIVE MAINTENANCE SCHEDULE................................................................8-1
TABLE 8-2: PREVENTATIVE MAINTENANCE CALENDAR...............................................................8-2
TABLE 9-1: TEST FUNCTIONS...................................................................................................9-4
TABLE 9-1: TEST FUNCTIONS (CONTINUED) ..............................................................................9-5
TABLE 9-1: TEST FUNCTIONS (CONTINUED) ..............................................................................9-6
TABLE 9-1: TEST FUNCTIONS (CONTINUED) ..............................................................................9-7
TABLE 9-2: FRONT PANEL WARNING MESSAGES .......................................................................9-9
TABLE 9-2: FRONT PANEL WARNING MESSAGES (CONTINUED).................................................9-10
TABLE 9-3: SUMMARY OF DIAGNOSTIC MODES........................................................................9-12
TABLE 9-4: DIAGNOSTIC MODE - SIGNAL I/O...........................................................................9-13
TABLE 9-4: DIAGNOSTIC MODE - SIGNAL I/O (CONTINUED)......................................................9-14
TABLE 9-4: DIAGNOSTIC MODE - SIGNAL I/O (CONTINUED)......................................................9-15
TABLE 9-4: DIAGNOSTIC MODE - SIGNAL I/O (CONTINUED)......................................................9-16
TABLE 9-5: MODEL 200AU VARIABLES...................................................................................9-20
TABLE 9-6: TEST CHANNEL READINGS....................................................................................9-21
TABLE 9-6: TEST CHANNEL READINGS (CONTINUED) ...............................................................9-22
TABLE 9-7: MOTHERBOARD JUMPER SETTINGS .......................................................................9-41
TABLE 9-8: V/F BOARD SWITCH SETTINGS .............................................................................9-42
TABLE 9-9: POWER SUPPLY MODULE SUBASSEMBLIES ............................................................9-48
TABLE 9-10: POWER SUPPLY MODULE LED OPERATION .........................................................9-51
TABLE 9-11: OZONE GENERATOR CONTROL CONDITIONS ........................................................9-53
TABLE 10-1: TELEDYNE API M200AU SPARE PARTS LIST...................................................10-1
TABLE 10-1: TELEDYNE API M200AU SPARE PARTS LIST (CONTINUED) ..............................10-2
TABLE 10-2: TELEDYNE API MODEL 200AU EXPENDABLE KIT ...........................................10-3
TABLE A-1: ELECTRICAL SCHEMATICS ..................................................................................... A-1
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
1 HOW TO USE THIS MANUAL
The Model 200AU has been designed to provide serviceability, reliability and ease of operation.
The M200AU’s microprocessor continually checks operating parameters such as temperature,
flow, and critical voltages. The instrument’s modular design uses captive screws to facilitate
repair and ease of access. If you encounter any difficulty refer to Section 9 General
Troubleshooting Hints.
We recognize that the need for information in this manual changes as time passes. When the
instrument first arrives, it is necessary to get it up and running quickly and verify its correct
operation. As time passes, more detailed information is often required on special configurations,
calibration alternatives and other operational details. Finally there is the need for periodic
maintenance and to quickly troubleshoot problems to assure maximum reliability and data
integrity.
To address these needs, we have created three indexes to the information inside. They are:
Table of Contents:
Outlines the contents of the manual in the order the information is presented. This is a good
overview of the topics covered in the manual. There is also a list of Tables and a list of Figures.
Index to M200AU Front Panel Menus:
The Menu Index (Figure 5-1, Figure 5-2, Table 5-1 and Table 5-2) briefly describes the front
panel menus and refers you to other sections of the manual that have a detailed explanation of
each menu selection.
Troubleshooting Section 9:
The Troubleshooting Section, outlined in the Table of Contents, allows you to diagnose and
repair the instrument based on variables in the TEST menu, the results of DIAGNOSTIC tests,
and performance faults such as excessive noise or drift. The troubleshooting section also
explains the operation, adjustment, diagnosis and testing of each instrument subsystem.
If you are unpacking the instrument for the first time, please refer to Getting Started in
Section 2.
1-1
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1-2
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
2 GETTING STARTED
2.1 Unpacking
1.
Verify that there is no apparent shipping damage. If damage has occurred please advise
shipper first, then Teledyne API.
CAUTION
To avoid personal injury, always use two persons to
lift and carry the Model 200AU.
2.
3.
4.
Before operation, it is necessary to remove the shipping hold-down screws. Remove the
instrument cover, then refer to Figure 2-1 for screw location.
Also check for internal shipping damage, and generally inspect the interior of the
instrument to make sure all circuit boards and other components are in good shape.
Please check the voltage and frequency label on the rear panel of the instrument for
compatibility with the local power before plugging in the M200AU.
2.2 Electrical and Pneumatic Connections
Refer to Figure 2-2 to locate the rear panel electrical and pneumatic connections.
1.
2.
Attach the pump to the Exhaust Out port on the instrument rear panel.
If you are connecting to a calibrator, attach a vented sample inlet line to the sample inlet
port. The pressure of the sample gas at the inlet port should be at ambient pressure. The
exhaust from the pump should be vented to atmospheric pressure. See Figure 2-3 for inlet
and exhaust line venting recommendations during calibration.
3.
4.
If desired, attach the analog output connections to a strip chart recorder and/or
datalogger. Refer to Figure 9-4 for the jumper settings for the desired analog output voltage
range. Factory default setting is 0-5VDC.
Connect the power cord to the correct voltage line, then turn to Section 2.3 Initial
Operation.
2-1
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
WARNING
Analyzer Exhaust –Sample Pump
For brief periods after power-up, analyzer
exhaust may contain ozone.
Make sure pump exhaust is routed to well ventilated
area at atmospheric pressure.
WARNING
Lethal voltages present inside case.
Do not operate with cover off during normal operation.
Before operation check for correct input voltage and frequency for
both the analyzer and the sample pump.
Do not operate without proper chassis grounding.
Do not defeat the ground wire on power plug.
Turn off analyzer power before disconnecting
electrical subassemblies.
2-2
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
Figure 2-1: Removal of Shipping Screws & Check for Correct Power
2-3
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
Figure 2-2: Rear Panel
2-4
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
Figure 2-3: Inlet and Exhaust Venting
2-5
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
2.3 Initial Operation
1.
2.
After confirming proper supply voltage, turn on the instrument power.
The display should immediately light, displaying the instrument type (M200AU) and the
computer's memory configuration. If you are unfamiliar with the M200AU, we recommend
that you read the overview Section 4 before proceeding. A diagram of the software menu
trees is in Figure 5-1 and Figure 5-2.
3.
The M200AU requires about 30 minutes for all internal components to come up to
temperature. During this time the ozone generator power is OFF until the membrane dryer
has time to purge itself, therefore there will be no response from the instrument, even if span
gas is coming in the sample port. During this time temperatures and other conditions are out
of specification. Because many warning conditions could be displayed the software
suppresses warning conditions for 30 minutes after power up. After 30 minutes, warning
messages will be displayed until the respective warning conditions are within specifications.
Use the CLR key on the front panel to clear warning messages.
4.
5.
While waiting for instrument temperatures to come up, you can check for correct
operation by using some of the M200AU's diagnostic and test features.
Examine the TEST functions by comparing the values listed in Table 2-1 to those in the
display. Remember that as the instrument warms up the values may not have reached their
final values yet. If you would like to know more about the meaning and utility of each TEST
function, refer to Table 9-1. Also, now is a good time to verify that the instrument was
shipped with the options you ordered. Table 2-1 also contains the list of options. Section 6
covers setting up the options.
6.
When the instrument is warmed up, re-check the TEST functions against Table 2-1. All
of the readings should compare closely with those in the Table. If they do not, see Section
9.1.1. The next task is to calibrate the analyzer. There are several ways to do a calibration,
they are summarized in Table 7-1. For instruments not equipped with the external converter
option, we recommend calibration with zero air and span gas coming in through the sample
port. The procedure is:
2-6
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
Step 1 - Enter the expected NOx and NO span gas concentrations:
Step Number Action
Comment
1.
Press
CAL-CONC-NOX
This key sequence causes the M200AU to prompt for the
expected NOx concentration. Enter the NOx span
concentration value by pressing the key under each digit until
the expected value is set.
2.
3.
Press ENTR
ENTR stores the expected NOx span value. This value will be
used in the internal formulas to compute subsequent NOx
concentration values.
Press
CAL-CONC-NO
In the same CAL-CONC sub menu press the NO button and
enter the expected NO span value, then ENTR. As before this
value will be used in the internal formulas to compute the
subsequent NO concentration values.
4.
5.
Press EXIT-EXIT
Returns instrument to SAMPLE mode.
Press
SETUP-RNGE-
If necessary, you may want to change ranges. Normally the
instrument is shipped in single range mode set at 500 ppb. We
MODE-SING-ENTR recommend doing the initial checkout on the 500 ppb range.
Press After SETUP-RNGE-SET, enter 500 and press ENTR. The
SETUP-RNGE-SET instrument will now be in the 500 ppb range.
6.
7.
Press EXIT
Returns instrument to SAMPLE mode.
2-7
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
Step 2 - Calibrate the instrument:
Zero/Span Calibration Procedure
Step Number
Action
Comment
1.
Input Zero gas
Allow Zero gas to enter the sample port on the rear of the
instrument.
2.
Press CAL
The M200AU enters the calibrate mode from sample mode.
When the CAL button is pressed, the adaptive filter is
activated. This allows the instrument to respond rapidly to
concentration changes regardless of their magnitude.
3.
Wait 10 min
Wait for reading to stabilize at the zero value. If you wait less
than 10 minutes the final zero value may drift.
4.
5.
Press ZERO
Press ENTR
The ZERO button will be displayed.
Pressing ENTR actually changes the calculation equations and
zeroes the instrument.
6.
7.
Input Span Gas
Wait 10 min
Switch gas streams to span gas.
Wait for reading to stabilize at the span value. If you wait less
than 10 minutes the final span value may drift.
8.
Press SPAN
The SPAN button should be displayed. If it is not, check the
Troubleshooting Section 9.2.8 for instructions on how to
proceed. In certain circumstances at low span gas
concentrations (<100ppb), both the ZERO and SPAN buttons
will appear.
9.
Press ENTR
Press EXIT
Pressing ENTR actually changes the calculation equations so
that the concentration displayed is the same as the expected
span concentration you entered above, thus spanning the
instrument.
10.
Pressing EXIT returns the instrument to SAMPLE mode.
2-8
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
Step 3 - Review the quality of the calibration:
Calibration Quality Check Procedure
Step Number
Action
Comment
1.
Scroll the TEST
function menu until
the NOx SLOPE is
displayed.
The SLOPE value for NOx should be 1.0 ± 0.3. If the value is
not in this range, check Section 7.8 or 9. If the SLOPE value
is in the acceptable range, the instrument will perform
optimally.
2.
Scroll the TEST
function menu until
the NO SLOPE is
displayed.
The SLOPE value for NO should be 1.0 ± 0.3. If the value is
not in this range, check Section 7.8 or 9. If the SLOPE is in
the acceptable range, the instrument will perform optimally.
NOTE:
The NO and NOx slopes should be equal within ± 0.1.
4.
5.
Scroll the TEST
function menu until
The M200AU will display the OFFSET parameter for the NOx
equation. This number should be near zero. A value of 0.0 mV
the NOx OFFSET is –10 +150 mV indicates calibration in the optimal range. If the
displayed.
OFFSET value is outside this range, check Section 7 or 9 for
procedures to correct the OFFSET value to near zero.
Scroll the TEST
function menu until
the NO OFFSET is
displayed.
The instrument will now display the NO OFFSET value. It
should also have a value near zero (0.0 mV –10 +150 mV).
Step 4 - The M200AU is now ready to measure sample gas.
2-9
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
Figure 2-4: Front Panel
2-10
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
Figure 2-5: Assembly Layout
2-11
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
Table 2-1: Final Test and Calibration Values
Observed
Value
Test Values
Units
Nominal Range
Reference Section
RANGE
ppb
ppb
5-2000
5.3.4
STABILITY
0.001-2000
9.1.1, 9.2.5,
Table 9-1
SAMP FLW
OZONE FL
PMT
cc/min
cc/min
mV
1000 ± 100
80 ± 15
9.3.7, Table 9-1
9.3.6, 9.3.7
9.3.8.1, Table 9-1
Table 9-1
9.3.8.5
0-5000
PREREACT
HVPS
mV
0-1000
V
450 - 900 constant
2500 ± 200
40 ± 1
DCPS
mV
oC
oC
oC
9.3.5, 9.3.4
9.3.8.2
RCELL TEMP
BOX TEMP
PMT TEMP
MOLY TEMP
RCEL PRES
SAMP PRES
8-48
9.3.4.1
-5 ± 1
9.3.8.4
oC
315 ± 5
9.3.4.1
IN-Hg-A
IN-Hg-A
1 - 4 constant
25 - 30 constant
9.3.7
9.3.7
Electric Test & Optic Test
Electric Test
PMT Volts
NO Conc
NOx Conc
mV
2000 ± 500
9.1.3.2
9.1.3.2
9.1.3.2
PPB
PPB
1000 ± 250
1000 ± 250
Optic Test
PMT Volts
NO Conc
mV
2000 ± 1000
1000 ± 500
1000 ± 500
9.1.3.3
9.1.3.3
9.1.3.3
PPB
PPB
NOx Conc
(table continued)
2-12
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
Table 2-1: Final Test and Calibration Values (Continued)
Observed
Value
Parameter
Units
Nominal Range
Reference Section
NO Span Conc
NOx Span Conc
NO Slope
PPB
PPB
-
1 - 2000
Table 7-3
Table 7-3
Table 7-18
Table 7-18
Table 7-18
Table 7-18
7.6.6, 5.2.2.6
Table 9-1
Table 9-1
1 - 2000
1.0 ± 0.3
NOx Slope
-
1.0 ± 0.3
NO Offset
mV
mV
%
-10 to +150
-10 to +150
0.96 - 1.02
0.001 - 2000
< 1 @ 400 ppb
NOx Offset
Moly Efficiency
Stability at Zero
Stability at Span
PPB
PPB
Measured Flows
Sample Flow
Ozone Flow
cc/min
cc/min
1000 ± 100
80 ± 15
9.3.7, Figure 9-8
9.3.7, Figure 9-8
Factory Installed Options
Power Voltage/Frequency
Option Installed
Rack Mount, w/ Slides
Rack Mount, w/ Ears Only
Rack Mount, External Pump w/ Slides
Rack Mount, External Pump w/o Slides
Stainless Zero/Span Valves
Current Loop - NOx Chan
Current Loop - NO Chan
Current Loop - NO2 Chan
Current Loop - TST Chan
4-20 mA
0-20 mA
Isolated
Isolated
Isolated
Isolated
Non-Isolated
Non-Isolated
Non-Isolated
Non-Isolated
4-20 mA
4-20 mA
4-20 mA
0-20 mA
0-20 mA
0-20 mA
PROM #
Date
Serial #
Technician
2-13
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
INTENTIONALLY BLANK
2-14
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
3 SPECIFICATIONS, AGENCY APPROVALS,
WARRANTY
3.1 Specifications
Ranges
In 1ppb increments from 5ppb to 2000ppb
independent ranges or autoranging
<25 ppt RMS
<0.25% RMS of reading above 50 ppb
50 ppt RMS
Noise at Zero1
Noise at Span1
Lower Detectable Limit1
Zero Drift2
<0.1 ppb / 24 hours
<0.2 ppb / 7 days
Span Drift2
<0.5% FS or 50 ppt RMS whichever is greater / 7 days
20 sec
Lag Time
Rise Time3
95% in <50 sec6
Fall Time3
95% in <50 sec6
Sample Flow Rate
Linearity
Precision
1000 cc/min. ± 10%
1% of full scale or ± 0.1 ppb whichever is greater
0.5% of reading above 50 ppb
Propylene rejection ratio > 20,000:1
Ethylene rejection ratio > 40,000:1
20-30oC within drift and noise specifications
5-35oC safe operating range
< 0.1% per oC
0-95% RH non-condensing
< 0.1% per V
7" H x 17" W x 23.6" D (18cm x 43cm x 61cm)
43 lbs (20 kg)
Hydrocarbon Interference
Temperature Range
Temp Coefficient
Humidity
Voltage Coefficient
Dimensions HxWxD
Weight, Analyzer
Weight, Ext Pump Pack
Power, Analyzer
Power, Analyzer4
Power, Ext Pump
Power, Ext Pump4
Environmental4
21 lbs (9.5 kg)
100V~ 50/60 Hz, 120V~ 60 Hz, 230V~ 50 Hz, 2.5A, 125 watts
230V~ 50 Hz, 2.5A
110V~ 60 Hz, 220V~ 50 Hz, 240V~ 50Hz, 150 watts
230V~ 50 Hz, 2.2A
Installation Category (Over-voltage Category) II
Pollution Degree 2
Recorder Output
Analog Resolution
Status Option
100 mV, 1, 5, 10V, isolated or non-isolated current loop
1 part in 1024 of selected voltage or current range
12 Status Outputs from opto-isolator
ppb, ug/m3
Measurement Units
1.
2.
3.
4.
As defined by USEPA.
At constant temperature and voltage.
With adaptive filter, > 20 ppb change.
Electrical rating for CE Mark compliance.
3-1
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
3.2 EPA Equivalency Designation
Teledyne Instruments Advanced Pollution Instrumentation Division, Model 200AU High
Sensitivity Nitrogen Oxides Analyzer is designated as Reference Method Number RFNA-1194-
099 as defined in 40 CFR Part 53, when operated under the following conditions:
1.
2.
3.
4.
5.
6.
7.
Range: Any range from 50 parts per billion (ppb) to 1 ppm.
Ambient temperature range of 20 to 30oC.
Line voltage range of 105-125 VAC, 60Hz; 220-240 VAC, 50Hz.
With 5-micron TFE filter element installed in the internal filter assembly.
Sample flow of 1000 ± 100 cc/min.
Vacuum pump capable of 6"Hg Abs pressure @ 2 slpm or better.
Software settings:
A. Dynamic span
B. Dynamic zero
C. Cal-on-NO2
D. Dilution factor
E. AutoCal
OFF
OFF
OFF
OFF
ON or OFF
ON or OFF
ON or OFF
F. Independent range
G. Autorange
H. Temp/Pres compensation ON
I. Converter Efficency 0.96 to 1.02
Under the designation, the Analyzer may be operated with or without the following options:
1.
2.
3.
4.
5.
6.
7.
8.
Rack mount with slides.
Rack mount without slides, ears only.
Rack mount for external pump w/o tray.
Stainless steel zero/span valves.
4-20mA, isolated outputs.
Status outputs.
RS-232 output.
1 micron sample filter.
3-2
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
3.3 Warranty
WARRANTY POLICY
Prior to shipment, Teledyne API equipment is thoroughly inspected and tested. Should
equipment failure occur, Teledyne API assures its customers that prompt service and support
will be available.
COVERAGE
After the warranty period and throughout the equipment lifetime, Teledyne API stands ready to
provide on-site or in-plant service at reasonable rates similar to those of other manufacturers in
the industry. All maintenance and the first level of field troubleshooting is to be performed by
the customer.
NON-TELEDYNE API MANUFACTURED EQUIPMENT
Equipment provided but not manufactured by Teledyne API is warranted and will be repaired to
the extent and according to the current terms and conditions of the respective equipment
manufacturers warranty.
GENERAL
TELEDYNE API warrants each Product manufactured by Teledyne API to be free from defects
in material and workmanship under normal use and service for a period of one year from the date
of delivery. All replacement parts and repairs are warranted for 90 days after the purchase.
If a Product fails to conform to its specifications within the warranty period, Teledyne API shall
correct such defect by, in Teledyne API's discretion, repairing or replacing such defective
Product or refunding the purchase price of such Product.
The warranties set forth in this section shall be of no force or effect with respect to any Product:
(i) that has been altered or subjected to misuse, negligence or accident, or (ii) that has been used
in any manner other than in accordance with the instruction provided by Teledyne API or (iii)
not properly maintained.
THE WARRANTIES SET FORTH IN THIS SECTION AND THE REMEDIES
THEREFORE ARE EXCLUSIVE AND IN LIEU OF ANY IMPLIED WARRANTIES OF
MERCHANTABILITY, FITNESS FOR PARTICULAR PURPOSE OR OTHER
WARRANTY OF QUALITY, WHETHER EXPRESSED OR IMPLIED. THE
REMEDIES SET FORTH IN THIS SECTION ARE THE EXCLUSIVE REMEDIES FOR
BREACH OF ANY WARRANTY CONTAINED HEREIN. TELEDYNE API SHALL
NOT BE LIABLE FOR ANY INCIDENTAL OR CONSEQUENTIAL DAMAGES
ARISING OUT OF OR RELATED TO THIS AGREEMENT OF TELEDYNE API'S
PERFORMANCE HEREUNDER, WHETHER FOR BREACH OF WARRANTY OR
OTHERWISE.
3-3
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
TERMS AND CONDITIONS
All units or components returned to Teledyne API should be properly packed for handling and
returned freight prepaid to the nearest designated Service Center. After the repair, the equipment
will be returned, freight prepaid.
3-4
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
4 THE M200AU NOX ANALYZER
4.1 Principle of Operation
The Teledyne API Model 200AU Analyzer is designed to measure the concentration of nitric
oxide [NO], total oxides of nitrogen [NOx] and, by calculation, nitrogen dioxide [NO2].
The instrument measures the light intensity of the chemiluminescent gas phase reaction of nitric
oxide [NO] and ozone [O3] as follows:
NO + O3 → NO2* +O2
NO2* → NO2 + hv
The reaction of NO with ozone results in electronically excited NO2 molecules as shown in the
first equation above. The excited NO2 molecules release their excess energy by emitting a
photon and dropping to a lower energy level as shown in the second equation. It has been shown
that the light intensity produced is directly proportional to the [NO] concentration present.
The Analyzer samples the gas stream and measures the [NO] concentration by digitizing the
signal from the Analyzer's photomultiplier tube (PMT). A valve then routes the sample stream
through a converter containing heated molybdenum to reduce any NOx present to NO by the
following reaction:
315o C
3NOx + Mo → 3NO + MoO3
The Analyzer now measures the total NOx concentration. The [NOx] and [NO] values are
subtracted from each other by the built-in computer, yielding the [NO2] concentration. In the
third measurement phase, the instrument measures sample gas which has been mixed with ozone
outside of the reaction cell. This Pre-Reactor allows the measurement of any hydrocarbon
interferents present in the sample gas stream. The three results [NO], [NOx], and [NO2] are then
further processed and stored by the computer yielding several instantaneous and long term
averages of all three components.
The software uses an adaptive filter to accommodate rapid changes in concentration. The
algorithm monitors the rate of change in concentration for both the NO and NOx channels. When
a change in concentration is detected, the software changes the sample filters to rapidly respond
to the change. The filters are adjusted to minimize the errors introduced by the time delay
between the NOx and NO channel measurements; this assures accurate NO2 measurements.
When the rate of change decreases, the filters are lengthened to provide better signal/noise ratio.
The parameters used to operate the adaptive filter have been tuned to match the electrical and
pneumatic characteristics of the M200AU.
4-1
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
Figure 4-1: Block Diagram
4-2
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
4.2 Operation Summary
4.2.1 Sensor Module, Reaction Cell, Detector
The sensor module (Figure 9-9) is where light from the chemilumenescent reaction is generated
and detected. It is the most complicated and critical sub-assembly in the entire analyzer. It
consists of the following assemblies and functions:
1.
2.
3.
4.
5.
The reaction cell and flow control module
Reaction cell heater/thermistor
PMT and high voltage power supply
PMT cooler/cold block/heatsink/fan
Preamp assembly:
A. Preamp range control hardware
B. HVPS control
C. PMT cooler temp control
D. Electric test electronics
E. Optic test electronics
4.2.2 Pneumatic Sensor Board
The sensor board consists of 2 pressure sensors and a flow sensor. One pressure sensor measures
the pressure in the reaction cell. The reaction cell is maintained at about 0.1 atmospheric
pressure. The second pressure sensor measures the pressure just upstream of the reaction cell,
which is near ambient pressure. From these two pressures the sample flow rate can be computed
and is displayed as sample flow in the TEST menu. Finally, a solid state flow meter measures the
ozone flow using a resistive bridge. Likewise, it is displayed as a TEST function.
The M200AU displays all pressures in inches of mercury-absolute (in-Hg-A). Absolute pressure
is the reading referenced to a vacuum or zero absolute pressure. This method was chosen so that
ambiguities of pressure relative to ambient pressure can be avoided.
4-3
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
NOTE
On vacuum vs absolute pressure:
Many vacuum gauges read relative to ambient pressure, therefore
a reading of 25" of mercury (Hg) at sea level (which would give an
absolute pressure of about 5" Hg in the reaction cell) would read
only 20" Hg at high altitude sites. Therefore in this manual the vacuum
specification of 5" Hg pressure is given as an absolute pressure
- 5"Hg-A - reference against zero absolute pressure (a perfect vacuum)
thus removing ambiguities for high altitude sites.
4.2.3 Computer Hardware and Software
CPU Board
The M200AU Analyzer is operated by an V40 series micro computer. The computer's
multitasking operating system allows it to do instrument control, monitor test points, provide
analog output and provide a user interface via the display, keyboard and RS-232 port. These
operations appear to be happening simultaneously but are actually done sequentially based on a
priority queuing system maintained by the operating system. The jobs are queued for execution
only when needed, therefore the system is very efficient with computer resources.
The M200AU is a true computer based instrument. The microprocessor does most of the
instrument control functions such as temperature control, valve switching. Data collection and
processing are done entirely in the CPU with the final concentration values being sent to a D/A
converter to produce the instrument analog output.
The computer memory is divided into 3 sections: ROM memory contains the multi-tasking
operating system code plus the instructions that run the instrument. The RAM memory is used to
hold temporary variables, current concentration data and data acquisition system data. The
EEPROM memory contains the instrument set-up variables such as range and instrument ID
number. The EEPROM data is non-volatile so the instrument can lose power and the current set-
up information is preserved.
4.2.4 V/F Board
The V/F board is multifunctional, consisting of A/D input channels, digital I/O channels, and
analog output channels. Communication with the computer is via a STD bus interface. The
computer receives all of the instrument data and provides all control functions through the V/F
board.
4-4
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
4.2.5 Front Panel
The front panel of the M200AU is shown in Figure 2-4. The front panel consists of a 2 line
display and keyboard, 3 status LED's and power switch. Communication with the display,
keyboard, and status LED's is done via the computer's on-board parallel port. The M200AU was
designed as a computer controlled instrument, therefore all major operations can be controlled
from the front panel display and keyboard.
The display consists of 2 lines of 40 characters each. The top line is divided into 3 fields, and
displays information. The first field is the mode field. A list of operating modes is given in
Table 5-8.
The center field displays TEST values. The TEST functions allow you to quickly access many
important internal operating parameters of the M200AU. This provides a quick check on the
internal health of the instrument. The right hand field shows current concentration values of NO,
NOx, and NO2. The display scrolls between the 3 values every 4 seconds.
4.2.5.1 Keyboard
The second line of the display contains eight fields. Each field defines the key immediately
below it. By redefining the keys dynamically it is possible to simplify the instrument electronics
and user interface.
When entering data in the keyboard, if the entered value is not accepted, the M200AU will
"beep" to notify the user that the value keyed in was not accepted. The original value remains
unchanged.
4.2.5.2 Status LED's
At the right of the display there are 3 status LED's. They can be in three states, OFF, ON, and
Blinking. The meanings of the LED's are given in Table 4-1.
4-5
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
Table 4-1: Front Panel Status LED's
LED
State
Meaning
Green
On
Off
Monitoring normally, taking DAS data
NOT monitoring, DAS disabled
Blinking
Monitoring, DAS in HOLDOFF mode (1)
Yellow
Red
Off
On
Blinking
Auto cal. disabled
Auto/Dynamic cal. enabled
Calibrating
Off
Blinking
No warnings exist
Warnings exist
(1) This occurs during Calibration, DAS holdoff, power-up holdoff, and when in Diagnostic mode.
4.2.5.3 Power Switch
The power switch has two functions. The rocker switch controls overall power to the instrument,
in addition it includes a circuit breaker. If attempts to power up the M200AU result in a circuit
breaker trip, the switch automatically returns to the off position, and the instrument will not
power up.
4-6
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
4.2.6 Power Supply Module
The Power supply module supplies AC and DC power to the rest of the instrument. It consists of
a 4 output linear DC power supply and a 15 volt switching supply. In addition, it contains the
switching circuitry to drive the DC operated valves and several switched AC loads to operate the
Rx cell heater, the Moly heater, and the ozone generator.
4.2.7 Pump, Valves, Pneumatic System
A standard M200AU comes with 2 valves. The NO/NOx valve switches sample from either the
sample inlet port or from the moly converter into the reaction cell. Each NO/NOx cycle, the Pre-
reactor valve re-routes sample gas into the Pre-reactor volume which allows time for the NO-
Ozone reaction to complete. The pneumatic timing of the Pre-reactor is set so that any
hydrocarbon interferences are measured and eliminated from the signal.
The M200AU is equipped with a high performance pump, capable of producing a reaction cell
pressure of less than 4” Hg-A. See Figure 2-3 for hook-up information. A catalytic ozone
scrubber protects the pump from the corrosive effects of ozone. See Section 4.2.8.
4.2.8 Ozone Generator
Because of the instability of ozone, it is necessary to generate this gas inside the analyzer. The
ozone generation module consists of a high frequency switching AC supply and pulse
transformer connected to a silent discharge tube. Air is supplied to the generator from a
permeation type air drier. A complete description of its function and service requirements can be
found in Section 9.3.6.
Although there are dangerous high voltages generated in the ozone generator, they are isolated
from the user by sealing the system in a single potted assembly. The dry air supply for the ozone
generator uses a membrane drier to supply air with a dew point of 0o C or less. The exhaust side
of the membrane is connected to the vacuum manifold at the rear of the instrument.
Normal room air contains enough water vapor to damage the generator and components
downstream. Because of this, the ozone generator may not turn on immediately at power up.
A heated catalytic ozone scrubber, located in the molybdenum converter assembly removes
excess ozone from the instrument exhaust. The delay is built into the instrument to allow the
dryer to start operating and purge the system with dry air. Table 4-2 details the conditions for
turning on the ozone generator.
4-7
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
Table 4-2: Ozone Generator Start-up Timing
Time Since Last
Ozone Gen State
Program Action
Power-up
< 1 hour
> 1 hour
ON at power-up
OFF at power-up
Gen ON immediately after power-up.
Wait 30 min, then turn gen ON.
4.2.9 Molybdenum Converter – Ozone Scrubber
The molybdenum converter is a stainless steel cartridge containing molybdenum chips heated to
315° C. The converter's function is to reduce NOx to nitric oxide NO. The temperature control
for this module is done by the Switch Card in the Power Supply Module using commands
generated by the CPU. The temperature is measured by a type J thermocouple and is conditioned
on the Status/Temp board. The analog voltage representing the Moly temperature is read by the
V/F board and sent to the CPU where signals are generated for temperature control. The
digitized voltage is translated to degrees for the TEST function on the front panel and for
warnings.
The molybdenum converter assembly also contains a catalytic ozone scrubber that removes
excess ozone from the instrument exhaust.
4-8
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
5 SOFTWARE FEATURES
5.1 Index To Front Panel Menus
The M200AU has 2 main operating modes, namely the SAMPLE and SETUP modes. The
instrument is operating in the SAMPLE mode when it is measuring gas. The SETUP mode is
used to create or change operating parameters such as range. Also in SETUP mode the
instrument has extensive fault diagnosis tools. A list of M200AU operating modes is given in
Table 5-8.
The next several pages contain two different styles of indexes that will allow you to navigate the
M200AU software menus. The first two pages show a "tree" menu structure to let you see at a
glance where each software feature is located in the menu. The second menu contains a brief
description of each key mnemonic and a reference to the section of the manual that describes its
purpose and function in detail.
5-1
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
Figure 5-1: Sample Menu Tree
5-2
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
Figure 5-2: Setup Menu Tree
5-3
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
5.1.1 Sample Menu
Table 5-1: Sample Menu
Menu Level
Reference
Section
Level 1
Level 2
Level 3
Level 4
Description
TEST
TST>
Test functions
5.2.1, Table 9-1
CAL
Zero/Span calibration w/ gas
through sample port
5.2.2.1, 7.1
CALZ
CALS
Zero calibration w/ zero gas
from zero valve option
5.2.2.2, 7.2, 7.3
5.2.2.3, 7.2, 7.3
5.2.2.2, 7.2, 7.3
5.2.2.3, 7.2, 7.3
7.1
Span calibration w/ span gas
from span valve option
ZERO
SPAN
CONC
Press ZERO then ENTR will
zero analyzer
Press SPAN then ENTR will
span analyzer
Expected NO/NOx span
concentrations and Moly conv.
efficiency setup
NOX
CONC
Enter expected NOx span
concentration
5.2.2, Table 7-3
5.2.2, Table 7-3
NO
CONC
Enter expected NO span
concentration
5-4
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
Table 5-2: Sample Menu
Menu Level
Reference
Section
Level 1
Level 2
Level 3
Level 4
Description
CONV
Sub-menu for converter
efficiency setup and
verification
5.2.2.6, 7.6.6
NO2
CAL
SET
Expected NO2 concentration for
converter efficiency calculation
5.2.2.6, 7.6.6
5.2.2.6, 7.6.6
5.2.2.6, 7.6.6
Automatic converter efficiency
calibration and entry
Set the converter efficiency
manually
MSG
Displays warning messages
Clears warning messages
9.1.2
CLR
9.1.2
SETUP
The SETUP Menu - See next
table
Table 5-2
5-5
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
5.1.2 Set-Up Menu
Table 5-3: Setup Menu
Setup Menu #1
Reference
Section
Level 1
Level 2
Level 3
Level 4
Description
CFG
CFG is primarily used for
showing special configuration
options and factory special
software
5.3.1
PREV,
NEXT, LIST
PREV, NEXT can be used to
scroll through the
5.3.1
configuration list. LIST
automatically scrolls the list
AUTOCAL
Automatic span check or
calibration
5.3.2, 6.4
SEQUENCE
Selects Sequence
5.3.2, 6.4
5.3.2, 6.4
PREV-
NEXT
Scrolls display to select
calibration sequence 1, 2, or 3
MODE
SET
Selects mode of calibration
(zero, span, zero-span) plus
disable
5.3.2, 6.4
5.3.2, 6.4
5.3.3
For a given Sequence and
Mode, sets timing and
calibration attributes
DAS
Data Acquisition System
(DAS) - keeps 1 to 1500
minute averages of data
(table continued)
5-6
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
Table 5-3: Setup Menu (Continued)
Setup Menu #1
Reference
Section
Level 1
Level 2
Level 3
Level 4
Description
VIEW
Select which DAS data
collector to view
5.3.3
PREV-
NEXT
Scroll through data collectors
CONC, PNUMTC, CAL
DAT, STABILITY
5.3.3
EDIT
Allows editing of the several
attributes of a data collection
channel.
5.3.3
5.3.3
UP
Displays the DAS data buffer
- Move UP 1 average in the
DAS data buffer
UP10
Move UP 10 averages in the
DAS data buffer
5.3.3
5.3.3
5.3.3
5.3.3
DOWN
DOWN10
PRNT
Move down 1 average in the
DAS data buffer
Move DOWN 10 averages in
the DAS data buffer
Prints the setup parameters of
a data collector to the RS-232
port
5-7
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
Table 5-4: Setup Menu
Setup Menu #2
Reference
Section
Level 1
Level 2
MODE
SET
Level 3
Level 4
Description
RANGE
Range control menu
5.3.4
5.3.4
Range mode select - Single,
Autorange, Independent,
Remote
Sets range if mode is Single
range
5.3.4.1
5.3.4.3
5.3.4.3
5.3.4.3
5.3.4.2
5.3.4.2
NO
NOx
NO2
LO
Sets NO concentration range if
indep ranges enabled
Sets NOx concentration range if
indep ranges enabled
Sets NO2 concentration range if
indep ranges enabled
Sets low range if Autorange
enabled
HI
Sets high range if Autorange
enabled
UNITS
DIL
Unit selection menu
5.3.4.5
5.3.4.5
5.3.4.4
PPB, UGM
Select units that instrument uses
Enter dilution factor if
connected to stack dilution
probe
PASS
Password enable/disable menu
5.3.5
5.3.5
ON-OFF
TIME
Enable/disable password
checking
CLOCK
Adjusts time on the internal
time of day clock
5.3.6
5.3.6
DATE
Adjusts date on the internal
time of day clock
MORE
Continue menus on next level
down
COMM
RS-232 communications
control menu
5.3.8, 5.5
5.3.8, 5.5
5.3.8, 5.5
BAUD
ID
Sets the BAUD rate to 300 -
19,200
Sets the instrument ID -
(included on all RS-232
messages)
5-8
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
Table 5-5: Setup Menu
Setup Menu #3
Reference
Section
Level 1
Level 2
Level 3
Level 4
Description
VARS
Internal variables
5.3.9, 9.2
5.3.9, 9.2
PREV,
NEXT,
JUMP,
EDIT
PREV, NEXT scroll up and
down through the VARS menu.
JUMP will go to variable
number selected, EDIT will
allow editing of the selected
variable.
DIAG
Diagnostic menu
5.3.7, 9.1.3
5.3.7, 9.1.3
PREV,
NEXT
PREV, NEXT scroll up and
down through the DIAG menu.
SIG I/O
Examines, changes analog and
digital internal signals
9.1.3.1
9.1.3.5
9.1.3.6
9.1.1
ANALOG
OUT
Writes a stepped analog output
voltage to the 4 analog outputs
D/A CAL
Calibrates V/F board and the
analog outputs
TEST
CHNL
Routes several internal signals
to TCHAN analog output - used
for diagnosis
OPTIC
TEST
Activates Optic Test feature
Activates Electric Test feature
Turns OFF/ON ozone generator
9.1.3.3
9.1.3.2
ELEC
TEST
O3 GEN
RS-232
9.1.3.4
9.1.3.7
Writes test data to RS-232 port
- used for diagnosis
5-9
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
5.2 Sample Mode
5.2.1 Test Functions
NOTE
In any of the following TEST functions, if a value of
XXXX is displayed, that indicates an off scale and
therefore meaningless reading.
To use the TEST functions to diagnose instrument faults, refer to Troubleshooting Section 9.1.
Range
This is the range of the instrument. Electronically, there is only one physical range. The range of
the instrument is just the software expanding various portions of the single physical range to fill
the selected analog output voltage range. In standard configuration there is one range for all 3
outputs.
Independent range option allows different ranges for each output. When enabled, there will be
three range values displayed, NO, NOx and NO2.
Auto range mode allows a low range and high range. The M200AU will automatically switch to
the other range dynamically as concentration values require. The TEST values will show the
range the instrument is currently operating in, and will dynamically display the alternate range as
the range changes occur.
NOTE
Each of the range modes Single range, Auto range, and
Independent ranges are mutually exclusive.
Stability
The instrument noise is computed using the standard deviation of the last 10 minutes of data,
with the value being computed at the end of each NO/NOx cycle. It is computed for the NOx
channel only. The stability value only becomes meaningful if sampling a constant concentration
for more than 10 minutes. The value should be compared to the value observed in the factory
check-out.
The Stability reading on the front panel TEST functions is different than the STABIL reading
found in the DAS. Check the DAS in Section 5.3.3 for more information on the STABIL - DAS.
5-10
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
Sample Flow
The SAMPLE FLOW test function is computed from the pressure measured up-stream of the
sample flow orifice. The pressure down-stream of the orifice is also checked to assure the
assumptions of the equation are valid. This will register variations in flow caused by changes in
atmospheric pressure, but will not detect a plugged sample flow orifice. The nominal value is
1000 ± 100 cc/min.
Ozone Flow
The OZONE FLOW test function is directly measured by a solid state flow meter. Variations in
this value indicate variations in ozone flow. The nominal value for ozone flow is 80 ± 15 cc/min.
PMT Voltage
The PMT VOLTAGE measures the PMT signal at the output of the preamp board. The
waveform of the PMT voltage can be complex, and vary from near 0 mV when zero gas is in the
reaction cell to 5000 mV when a high concentration of NOx is being measured. If the PMT
reading is consistently 5000 mV, that indicates an off-scale reading. Typical readings bounce
around, which is normal.
Normalized PMT Voltage
Like the PMT Voltage TEST function above, the NORMALIZED PMT VOLTAGE measures
the PMT signal at the output of the preamp board. The difference is that several normalization
functions are applied to this signal before it is displayed. The most important is the temperature
and pressure compensation factors. If NORM PMT is used as suggested in the Factory
Calibration Procedure (Section 9.1.6) the M200AU will be correctly calibrated.
PREREACT Voltage
This test measurement is the Pre-reactor voltage. It indicates the most recent reading from the
Pre-reactor circuit. The units are mV and readings up to 1000 are considered normal.
High Voltage Power Supply (HVPS)
The HVPS reading is a measure of the scaled-up HVPS programming voltage. The voltage used
to set the HVPS output is generated on the Preamp board. Its value is between 0 and 1 volt,
corresponding to a voltage of 0 to 1000 volts out of the HVPS. The HVPS front panel TEST
measurement should be greater than 450 volts and will typically be 500-800 V.
5-11
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
DC Power Supply (DCPS)
The DCPS voltage is a composite of the 5 and ± 15 VDC voltages in the Power Supply Module.
This is meant to be a quick indicator to show if the PSM is working correctly. The nominal value
is 2500 mV ± 200 mV.
Reaction Cell Temperature
This is a measurement of the temperature of the reaction cell. It is controlled by the computer to
40 ± 1° C. Temperatures outside this range will cause the M200AU output to drift.
Box Temperature
This TEST function measures the temperature inside the chassis of the M200AU. The
temperature sensor is located on the Status/Temp Board. Typically it runs 2 to 10° C higher than
the ambient temperature.
PMT Temperature
The temperature of the PMT is closely controlled by a dedicated proportional temperature
controller. The nominal set-point is -5 ± 1° C. Readings outside this range will cause instrument
drift due to gain changes in the PMT detector.
Block Temperature
The temperature of the sample flow and ozone flow control orifice blocks. The nominal set-point
is 40 ± 1° C. Readings outside this range will cause instrument drift.
Moly Temperature
The moly temperature is controlled by the computer. The nominal set-point is 315 ± 5° C. The
temperature sensor inside the moly is a type-J thermocouple. The thermocouple amplifier is
located on the STATUS/TEMP board. If the thermocouple breaks, the reading will go to 500° C
and remove power from the heater.
Reaction Cell Pressure
The pressure in the reaction cell is measured by a solid state pressure sensor, which measures
absolute pressure. This pressure will vary depending on several things.
1.
2.
3.
The type of pump attached to the analyzer.
Variations in local weather will cause a ± 0.3in-Hg change in pressure.
The altitude of the analyzer will cause the cell pressure to change.
Nominal values are 1 to 4 in-Hg-A. typical reading is about 3.5 in-Hg-A.
5-12
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
Sample Pressure
The pressure in the sample inlet line is measured by a solid state pressure sensor which measures
absolute pressure. This pressure typically runs 0.5" or so below atmospheric pressure due to the
pressure drop in the sample inlet lines and valves.
NOx, NO Slope and Offset Values
The coefficients of 2 (NOx and NO) straight line equations (y = mx + b) determine the
calibration of the M200AU. The slope parameter(m) can be thought of as a gain term which
determines the steepness of the calibration curve. The offset parameter (b) compensates for
differences in the background signal of the NO and NOx channels.
The values of these parameters can be used to determine the quality of the calibration. These 4
parameters contain valuable information about the quality and validity of the calibration. For
example, the NO and NOx slope values should not differ by more than .1 from each other. Larger
values indicate a flow imbalance such as a leak or problems with the molybdenum converter.
Refer to Section 7.8 Calibration Quality for details on how to use these values.
Time
This is an output of the M200AU's internal time of day clock.
5.2.2 CAL, CALS, CALZ, Calibration Functions
The calibration and zero/span checking of the M200AU analyzer is treated in detail in Section 7,
Table 7-1 summarizes types of calibration. The basic function of each of these keys is described
here. When any of the CAL buttons are pressed (or whenever the instrument enters the CAL
mode), the adaptive filter is activated. This allows the instrument to respond rapidly to
concentration changes regardless of their magnitude.
5.2.2.1 CAL, CALS, CALZ
These keys control the calibration functions of the analyzer. In the CAL mode the analyzer can
be calibrated without switching on the zero valve or the span valve. If the analyzer has the
Zero/Span valve option, there will be CALZ and CALS buttons also. These buttons operate the
Zero/Span valves. The setup of these options is covered in Section 6.3, and operation is
explained in Section 7.
5-13
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
5.2.2.2 Zero
Pressing the ZERO key along with ENTR will cause the instrument to adjust the OFFSET value
of the internal formula so that the instrument reads zero. The M200AU allows zero adjustment
over a limited range of signal levels, therefore the signal does not have to be exactly zero for the
instrument to do a zero cal. The instrument will not, however, allow a zero cal on any signal
level, therefore it is not possible to zero the instrument with high concentrations of span gas in
the reaction cell. If the ZERO key does not come on as expected, check Section 9.2.9.
5.2.2.3 Span
Pressing the SPAN key along with ENTR will cause the instrument to adjust the SLOPE value of
the internal formula so the instrument displays the span value. The expected NOx and NO span
concentrations must be entered before doing a SPAN calibration. See Table 7-3.
Like the Zero calibration, the Span cal cannot be done with any concentration of span gas. If the
signal level is outside certain limits the, SPAN key will not be illuminated. If you encounter this
condition see Section 9.2.8. It is also possible at low levels of span concentration that BOTH the
ZERO and SPAN keys might be on, thus allowing you to either zero or span the instrument. In
this case, care must be taken to perform the correct operation or the analyzer can become mis-
calibrated.
5.2.2.4 NO, NOx Cal Concentration
Before the M200AU can be spanned, it is necessary to enter the expected span concentrations for
NO and NOx. This is done by using CAL-CONC-NOX or CAL-CONC-NO keys for NOx and
NO span concentrations, respectively. Concentration values from 1 to 2000 ppb are valid
5-14
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
5.2.2.5 Formula Values
The slope and offset terms should be checked after each calibration. The values for these terms
contain valuable information about the internal health of the analyzer. The range of acceptable
values and their meanings is given in Section 7.8.
To compute the NOx and NO concentrations, the formula for a straight line is used.
Where:
y = the NOx or NO concentration
m = the slope
x = the conditioned PMT tube output
b = the offset
y = mx + b
In comparison with analog analyzers the slope term is equivalent to the "span pot" and the b term
is equivalent to the "zero pot". Again, like an analog analyzer there is only a limited range of
adjustment allowed for either term, and there are consequences of having the values near the
high or low limits of their respective ranges.
The x term is the conditioned PMT signal. PMT signal is adjusted for the Pre-reactor
background, range, temperature, and pressure.
The offset (b) term is the total background light with the Pre-reactor term subtracted out.
The Pre-reactor term measures detector dark current, amplifier noise, and ozone generator and
hydrocarbon background.
After every zero or span calibration, it is very important to check the QUALITY of the
calibration. The calibration of the M200AU involves balancing several sections of electronics
and software to achieve an optimum balance of accuracy, noise, linearity and dynamic range.
See Section 7.8 for the calibration quality check procedure.
5-15
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
5.2.2.6 Automatic Converter Efficiency Compensation
The M200AU can automatically compensate the NOx and NO2 readings for the molybdenum
converter efficiency. There are 2 ways to enter the converter efficiency into the instrument. The
first is to just type in the converter efficiency using the CAL-CONC-MOLY-SET menu. The
second method is to have the M200AU compute the efficiency using the CAL-CONC-MOLY-
CAL menu. See the Calibration Section 7.6.6.1 Molybdenum Converter Efficiency for details.
To disable the compensation, press CAL-CONC-MOLY-SET and enter 1.0000 as the efficiency.
Factory default is 1.0000.
5.3 Set-Up Mode
5.3.1 Configuration Information (CFG)
This menu item will tell if the installed software has factory special features or other non-
standard features. If you call Teledyne API service you may be asked for information from this
menu.
5.3.2 Automatic Calibration (AutoCal)
The AutoCal feature allows the M200AU to automatically operate the Zero/Span Valve option to
periodically check its calibration. Information on setting up AutoCal is in Section 6.3.
5.3.3 Data Acquisition System (DAS)
The M200AU contains a flexible and powerful built in data acquisition system (DAS) that
enables the analyzer to store concentration data as well as diagnostic parameters in its battery
backed memory. This information can be viewed from the front panel or printed out through the
RS-232 port. The diagnostic data can be used for performing “Predictive Diagnostics” and
trending to determine when maintenance and servicing will be required.
The logged parameters are stored in what are called “Data Channels.” Each Data Channel can
store multiple data parameters. The Data Channels can be programmed and customized from the
front panel. A set of default Data Channels has been included in the M200AU software. For
more information on programming custom Data Channels, a supplementary document containing
this information can be requested from Teledyne API.
5-16
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
5.3.3.1 Data Channels
The function of the Data Channels is to store, report, and view data from the analyzer. The data
may consist of NO, NOx, NO2 concentration, or may be diagnostic data, such as the sample flow
or reaction cell pressure.
The M200AU comes pre-programmed with a set of useful Data Channels for logging
concentration and predictive diagnostic data. The default Data Channels can be used as they are,
or they can be changed by the user to fit a specific application. They can also be deleted to make
room for custom user-programmed Data Channels.
The data in the default Data Channels can be viewed through the SETUP-DAS-VIEW menu.
Use the PREV and NEXT buttons to scroll through the Data Channels and press VIEW to view
the data. The last record in the Data Channel is shown. Pressing PREV and NEXT will scroll
through the records one at a time. Pressing NX10 and PV10 will move forward or backward 10
records. For Data Channels that log more than one parameter, such as PNUMTC, buttons labeled
<PRM and PRM> will appear. These buttons are used to scroll through the parameters located
in each record.
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
The function of each of the default Data Channels is described below:
Samples NOx, NO and NOy concentration data at one minute intervals and
stores an average every hour with a time and date stamp. Readings during
calibration and calibration hold off are not included in the data. The last 800
hourly averages are stored.
CONC:
Collects sample flow and sample pressure data at five minute intervals and
stores an average once a day with a time and date stamp. This data is useful for
monitoring the condition of the pump and critical flow orifice(sample flow) and
the sample filter(clogging indicated by a drop in sample pressure) over time to
predict when maintenance will be required. The last 360 daily averages (about 1
year) are stored.
PNUMTC:
Logs new slope and offset every time a zero or span calibration is performed,
also records the sample concentration reading just prior to performing a
calibration.
CALDAT:
STABIL:
Logs the standard deviation of the last 50 minutes of NOx data, with readings
taken 2 minutes apart(i.e. 25 readings taken 2 minutes apart.) The collector
operates in “sliding window” fashion with the oldest reading being deleted and
a new reading added every 2 minutes. A new value of STABIL is added to the
data buffer every 2 minutes. A time and date stamp is recorded for every data
point logged.
NOTE:
This Data Channel collects data based on an event (a calibration) rather than a
timer. This Data Channel will store data from the last 200 calibrations. This
does not represent any specific length of time since it is dependent on how often
calibrations are performed. As with all Data Channels, a time and date stamp is
recorded for every data point logged.
This is the EPA definition of noise used for equivalency testing. The collector provides a
continuous readout of the noise. In order for the data to be meaningful, the instrument must
sample a constant concentration of gas for at least 50 minutes.
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
Table 5-6: DAS Data Channel Editing
Step
Action
Comment
1.
2.
3.
4.
Enter DAS menu to edit Data Channels
Select Data Channel to edit
Press SETUP-DAS-EDIT
Press PREV/NEXT
Press EDIT
Enter the Edit menu for the selected Data Channel
Scroll through Data Channel properties until RS-232
REPORT: OFF is displayed
Press SET> (5 times)
5.
6.
7.
8.
Edit selected setup property
Change RS-232 REPORT property
Accepts change
Press EDIT
Toggle OFF to ON
Press ENTR
Exits back to sample menu
Press EXIT (4 times)
5.3.4 Range Menu
The instrument operates on any full scale range from 5 to 2000 ppb. The range is the
concentration value that equals the maximum voltage output on the rear panel of the instrument.
The front panel will read the concentration anywhere from 0 to 2000 ppb regardless of the range
selected.
NOTE
Only one of the following range choices can be active at any one time.
There are 3 range choices:
1.
2.
3.
Single Range
Auto Range
Independent Ranges
5.3.4.1 Single Range
This range option selects a single range for all output channels (NO, NOx, NO2) of the M200AU.
To select Single Range press SETUP-RNGE-MODE-SING, then press ENTR. To set the value
for the range press SETUP-RNGE-SET, enter the full scale range desired from 5 ppb to 2000
ppb, then press ENTR.
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
5.3.4.2 Auto Range
Auto Range allows the NO, NOx, NO2 outputs to automatically range between a low range and a
high range. There is only one low range and one high range for all outputs. The Hi range mode is
signaled by a bit on the STATUS option, see Table 5-9. When the instrument output increases to
98% of the low range value, it will Auto Range into Hi range. In Hi range, when the output
decreases to 75% of low range, it will change to the lower range. If you select a Hi range that is
less than Low range, the M200AU will remain locked in Low range and behave as a Single
Range instrument.
To set up Auto Range press SETUP-RNGE-MODE-AUTO, then press ENTR. To set the values
press SETUP-RNGE-SET. The M200AU will prompt you for LO, then HI which are the lower
and upper ranges of Auto Range. Key in the values desired, then press ENTR.
5.3.4.3 Independent Ranges
Independent Ranges allows you to select different ranges for NO, NOx, and NO2.
To set up Independent Ranges press SETUP-RNGE-MODE-IND, then press ENTR. To set the
values press SETUP-RNGE-SET. The M200AU will prompt you for the range of NO, NOx and
NO2 channels. Key in the desired range for each channel, press ENTR after each value.
5.3.4.4 Concentration Units
The M200AU can display concentrations in ppb, ug/m3 units. Concentrations displayed in ug/m3
use 0° C, 760 mm-Hg for STP. Consult your local regulations for the STP used by your agency.
The following equations give approximate conversions:
NO ppb x 1.34 = NO ug/m3
NO ppm x 1.34 = NO mg/m3
NO2 ppb x 2.05 = NO2 ug/m3
NO2 ppm x 2.05 = NO2 mg/m3
NH3 ppb x 0.76 = NH3 ug/m3
NH3 ppm x 0.76 = NH3 mg/m3
To change the current units press SETUP-RNGE-UNIT from the SAMPLE mode and select the
desired units.
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
NOTE
You should now reset the expected span concentration values in the new
units and re-calibrate the instrument using one of the methods in Section 7.
Changing units affects all of the RS-232 values, all of the
display values, and all of the calibration values.
Example:
If the current units are in ppb and the span value is 400 ppb, and
the units are changed to ug/m3 the span value is NOT re-calculated
to the equivalent value in ug/m3. Therefore the span value now
becomes 400 ug/m3 instead of 400 ppb.
5.3.4.5 Recorder Offset
If necessary, the analog outputs can be biased. This can be used to offset the output voltage of
each channel ±10% of the current output voltage setting. It is intended for recorders that cannot
show slightly negative readings. It can also be used to bias the input to a datalogger to offset
small external ground loop voltages that are sometimes present in monitoring systems
The offset is set in the V/F calibration menu. Press SETUP-MORE-DIAG, scroll to A/D
CALIBRATION, then press ENTR. Select CFG-SET-OFFSET, then enter the desired offset and
press ENTR. Press EXIT to return to the SAMPLE mode.
5.3.5 Password Enable
If password protection is enabled, a password is required to access calibration or setup menus. In
the VARS menu a password is always required. To enable passwords press SETUP-PASS-ON.
A list of passwords is in Table 5-7.
Table 5-7: Calibrate, Setup Passwords
Password Usage
Calibration Password
Setup Password
Password
512, 101
818, 101
Use to get into CAL menus
Use to get into SETUP menus
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
5.3.6 Time of Day Clock
The instrument has an internal time of day clock. The time of day can be set by pressing SETUP-
CLOCK-TIME and entering the time in 24hr format. In a similar manner the date can be entered
by pressing SETUP-CLOCK-DATE and entering the date in a dd-mmm-yy format.
If you are having trouble with the clock running slow or fast, the speed of the clock can be
adjusted by selecting the CLOCK_ADJ variable in the SETUP-MORE-VARS menu. The units
of CLOCK_ADJ are seconds per day.
5.3.7 Diagnostic Mode
The M200AU Diagnostic Mode allows additional tests and calibrations of the instrument. These
features are separate from the TEST functions because each DIAG function has the ability to
alter or disable the output of the instrument. While in DIAG mode no data is placed in the DAS
averages. Details on the use of Diagnostic mode are in Section 9.1.3.
5.3.8 Communications Menu
The COMM menu allows the RS-232 BAUD rate to be set. To set the BAUD rate press SETUP-
MORE-COMM-BAUD, select the appropriate BAUD rate, then press ENTR.
The instrument ID number can also be set. This ID number is attached to every RS-232 message
sent by the M200AU. To set the ID press SETUP-MORE-COMM-ID and enter a 4 digit number
from 0000-9999, then press ENTR
5.3.9 Variables Menu (VARS)
This menu enables you to change the settings on certain internal variables. The VARS Table 9-5
is located in the Troubleshooting Section 9.1.4.
5.3.10 M200AU Operating Modes
The M200AU has 2 main operating modes that were discussed earlier in this section, namely
SAMPLE and SETUP modes. In addition, there are other modes of operation when the
instrument is being diagnosed or calibrated. A list of M200AU operating modes is given in
Table 5-5.
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Table 5-8: M200AU Operating Modes
Mode
Description
ZERO CAL D
ZERO CAL A
ZERO CAL R
ZERO CAL M
SPAN CAL D
SPAN CAL A
SPAN CAL R
SPAN CAL M
M-P CAL
Automatic dynamic zero calibration
Automatic zero calibration
Remote zero calibration
Manual zero calibration
Automatic dynamic span calibration
Automatic span calibration
Remote span calibration
Manual span calibration
Manual multi-point calibration
Electrical diagnostic test
DIAG ELEC
DIAG OPTIC
DIAG OZONE
DIAG AOUT
DIAG
Optical diagnostic test
Ozone generator diagnostic test
D/A output diagnostic test
Main diagnostic menu
DIAG I/O
Signal I/O diagnostic
DIAG RS232
SETUP x.x
RS232 output diagnostic
Setup mode (x.x is software version)
Sampling; automatic dynamic zero and span calibration enabled
Sampling; automatic dynamic zero calibration enabled
Sampling; automatic dynamic span calibration enabled
Sampling; automatic cal. enabled
Sampling; automatic cal. disabled
SAMPLE ZS
SAMPLE Z
SAMPLE S
SAMPLE A
SAMPLE
5.4 Status Output
The status output is an option that reports Analyzer conditions via contact closures on the rear
panel. The closures are available on a 50 pin connector on the rear panel. The contacts are NPN
transistors which can pass 50 ma of direct current. The pin assignments are listed in Table 5-9.
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Table 5-9: Status Output Pin Assignments
Output #
Pin #
1,2
Definition
Condition
1
2
ZERO CAL
SPAN CAL
FLOW ALARM
TEMP ALARM
DIAG MODE
POWER OK
SPARE
CLOSED IN ZERO CAL
CLOSED IN SPAN CAL
3,4
3
5,6
CLOSED IF FLOW WARNING
CLOSED IF ANY TEMP WARNING
CLOSED IN DIAG MODE
CLOSED IF SYSTEM POWER OK
4
7,8
5
9,10
11,12
13,14
15,16
17,18
19,20
21,22
23,24
6
7
8
SPARE
9
SPARE
10
11
12
AUTORANGE - HI
SYSTEM OK
RX CELL PRESS
CLOSED IF IN HIGH RANGE
CLOSED IF NO FAULTS PRESENT
CLOSED IF ABS PRES > 15" HG
The Status Board schematic can be found in the Appendix Drawing 01087.
5.5 RS-232 Interface
The RS-232 communications protocol allows the instrument to be connected to a wide variety of
computer based equipment. The interface provides two basic functions in the M200AU.
1.
2.
First is a comprehensive command interface for operating and diagnosing the analyzer.
The interface can also provide an audit trail of analyzer events. In this function the port
sends out messages about instrument events like calibration or warning messages. If these
messages are captured on a printer or remote computer, they provide a continuous audit trail
of the analyzers operation and status.
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5.5.1 Setting Up the RS-232 Interface
The baud rate is set from the front panel by SETUP-MORE-COMM-BAUD. Select the baud rate
appropriate for your application, 300, 1200, 2400, 4800, 9600, or 19,200. It is important to note
that the other device must have identical settings in order for the communications to work
correctly.
Second is physical wiring of the analyzer to the other unit. We have incorporated into the
Analyzer LED's that signal the presence of data on the communications lines, and also switches
to easily re-configure the analyzer from DCE to DTE if necessary. In addition the front panel
diagnostics allow test data streams to be sent out of the port on command. This flexibility and
diagnostic capability should simplify attaching our equipment to other computers or printers. If
problems occur, see the Troubleshooting Section 9.3.2.
Setup from the Front Panel
There are 2 additional RS-232 setups that can be done via the front panel.
1.
2.
Set the instrument ID number by SETUP-MORE-COMM-ID, and enter a 4 digit number
from 0000-9999. This ID number is part of every message transmitted from the port.
Set the RS-232 mode bit field in the VARS menu. To get to the variable press, SETUP-
MORE-VARS, then ENTR and scroll to RS232_MODE, then press EDIT. The possible
values are in Table 5-10.
Table 5-10: RS-232 Port Setup - Front Panel
Decimal Value
Description
1
2
Turns on quiet mode (messages suppressed)
Places analyzer in computer mode (no echo of chars)
Enables Security Features (Logon, Logoff)
Enables API protocol and setup menus
Enable alternate protocol
4
8
16
32
Enable multidrop protocol
NOTE
To enter the correct value, ADD the decimal values of the features you
want to enable. For example if LOGON and front panel RS-232
menus are desired, the value entered would be 4 + 8 = 12.
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Security Feature
The RS-232 port is often connected to a public telephone line which could compromise
instrument security. If the LOGON feature is implemented, the port has the following attributes:
1.
2.
3.
A password is required before the port will operate.
If the port is inactive for 1 hour, it will automatically LOGOFF.
Repeat attempts at logging on with incorrect passwords will cause subsequent logins
(even with the correct password) to be disabled for 1 hour.
4.
5.
If not logged on, the only command that is active is the '?'.
The following messages will be given at logon.
LOG ON SUCCESSFUL
LOG ON FAILED
Correct password given
Password not given or incorrect
Logged off
LOG OFF SUCCESSFUL
The RS-232 LOGON feature must be enabled from the front panel by setting bit 4 of the
RS232_MODE variable in the VARS menu, see Table 9-5. Once the feature is enabled, to logon
type:
LOGON 940331
940331 is the default password. The password can be changed to any number from 0 to 999999
by the variable RS232_PASS. To change the password enter the command
V RS232_PASS=NNNNNN
which sets the password to the value NNNNNN.
Protocol of Port Communication
The RS-232 interface has two protocols of communication, because if the port is attached to a
computer it needs to have different characteristics than if used interactively. Consequently, there
are two primary styles of operation: terminal mode and computer mode.
When an operator is communicating with the analyzer via a terminal, the analyzer should be
placed into TERMINAL MODE, which echoes keystrokes, allows editing of the command line
using the backspace and escape keys, and allows recall of the previous command. When a host
computer or data logger is connected to the analyzer, it should be placed into COMPUTER
MODE, which does not echo characters received or allow the special editing keys. See
Table 5-11 for relevant commands.
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Table 5-11: RS-232 Switching From Terminal Mode to Computer Mode
Key
Function
Control-T (ASCII 20 decimal)
Control-C (ASCII 3 decimal)
Switch to terminal mode (echo, edit)
Switch to computer mode (no echo, no edit)
If the command line doesn't seem to respond to keystrokes or commands, one of the first things
you should do is send a Control-T to switch the command line interface into terminal mode.
Also, some communication programs remove CTRL-T and CTRL-C characters from the byte
stream, therefore these characters will not be sent to the analyzer. Check your communications
program owners manual.
Entering Commands in Terminal Mode
In terminal mode, all commands must be terminated by a carriage return; commands are not
processed until a carriage return is entered. While entering a command you may use the editing
keys shown in Table 5-12.
Table 5-12: RS-232 Terminal Mode Editing Keys
Key
Function
CR (carriage return)
BS (backspace)
ESC (escape)
Execute command
Backspace one character to the left
Erase entire line
Commands are not case-sensitive; you should separate all command elements (i.e. keywords,
data values, etc.) by spaces.
Words such as T, SET, LIST, etc. are called keywords and are shown on the help screen in
uppercase, but they are not case-sensitive. You must type the entire keyword; abbreviations are
not accepted.
NOTE
To open the help screen, Type "?" and press the Enter key.
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5.5.2 Command Summary
The information contained in the rest of this section covers commonly used commands that are
required to operate the instrument from a remote terminal. If you are going to be writing
computer programs to communicate with the M200AU (i.e. operating the port in COMPUTER
MODE) we suggest that you order a supplementary manual "The RS-232 Interface", Teledyne
API part number 01350. This manual describes additional features of the port.
The Teledyne API RS-232 interface protocol has a multidrop capability. This is why an optional
ID number is permitted for all commands. If you don’t include the ID number in the command,
all of the instruments connected to the RS-232 interface will respond. If you include the ID
number in the command, only the instrument whose ID number matches will execute the
command.
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Table 5-13: RS-232 Command Summary
Commands
? [id]
Definition
Print help screen. ID is an optional instrument ID number.
Print all active test messages
T [id] LIST
T [id] LIST name or
T [id] name
Print single test message "name" from Table 5-16
W [id] LIST
Print all active warnings
W [id] CLEAR name or
W [id] name
Clear single warning message "name" from Table 5-17
C [id] command
D [id] LIST
Execute calibration "command" from Table 5-18
Prints all I/O signal values
D [id] name
Print single I/O signal value/state
Sets I/O signal to new "value"
Lists diagnostic test names
D [id] name=value
D [id] LIST NAMES
D [id] ENTER name
D [id] EXIT
Enters and starts 'name' diagnostic test
Exits diagnostic mode
D [id] RESET
Resets analyzer(same as power-on)
D [id] RESET RAM
System reset, plus erases RAM. Initializes DAS, NO, NOx, NO2 conc
readings, calib not affected.
D [id] RESET EEPROM
System reset, plus erases EEPROM (RESET RAM actions + setup
variables, calibration to default values). Restores all factory defaults.
D [id] PRINT
Prints properties for all data channels (DAS)
D [id] PRINT "name”
Prints properties for single data channel. Quotes around name are
required.
D [id] REPORT "name"
[RECORDS=number]
[COMPACT|VERBOSE]
Prints DAS records for a data channel. Quotes around name are
required. Parameters in brackets are optional.
V [id] LIST
Print all setup variable names and values
Print individual setup variable value
Sets setup variable to new "value"
Print analyzer configuration
V [id] name
V [id] name=value
V [id] CONFIG
V [id] MODE
Print current analyzer mode
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Table 5-14: RS-232 Command Summary
Terminal Mode Editing Keys
Definition
BS
Backspace
ESC
Erase line
CR
Execute command
Switch to computer mode
Definition
^C
Computer Mode Editing Keys
LF
Execute command
Switch to terminal mode
Definition
^T
Security Features
LOGON [id] password
LOGOFF [id]
Establish connection to analyzer
Disconnect from analyzer
General Output Message Format
Reporting of status messages for use as an audit trail is one of the two principal uses for the RS-
232 interface. You can effectively disable the asynchronous reporting feature by setting the
interface to quiet mode. All messages output from the analyzer (including those output in
response to a command line request) have the format:
X DDD:HH:MM IIII MESSAGE
X is a character indicating the message type, as shown in the table below.
DDD:HH:MM is a time-stamp indicating the day-of-year (DDD) as a number from 1 to 366, the
hour of the day (HH) as a number from 00 to 23, and the minute (MM) as a number from 00 to
59.
IIII is the 4-digit machine ID number.
MESSAGE contains warning messages, test measurements, DAS reports, variable values, etc.
The uniform nature of the output messages makes it easy for a host computer to parse them.
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Table 5-15: RS-232 Interface Command Types
First Character
Message Type
Calibration
Diagnostic
C
D
T
Test measurement
Variable
V
W
Warning
There are 5 different types of messages output by the M200AU. They are grouped below by type
in Table 5-13 to Table 5-21. The meanings of the various messages are discussed elsewhere in
the manual. The TEST, DIAGNOSTIC and WARNING messages are discussed in Sections 9.1
and 9.2. DAS and VARIABLES are discussed in Section 5.3.5 and 5.3.9. CALIBRATE is
discussed in Section 7.
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5.5.3 TEST Commands and Messages
Table 5-16: RS-232 Test Messages
Name
RANGE2
Message
Description
RANGE=xxxxx PPB3
NOX RNG=xxxxx PPB3
NO RNG=xxxxx PPB3
NO2 RNG=xxxxx PPB3
NOX STB=xxxx.xx PPB
SAMP FLW=xxx CC/M
OZONE FL=xxxx CC/M
PMT=xxxxxx MV
Analyzer range
NOXRANGE1
NORANGE1
NO2RANGE1
STABILITY
SAMPFLOW
OZONEFLOW
PMT
Indep. Range for NOx channel
Indep. Range for NO channel
Indep. Range for NO2 channel
Std. Deviation NOx conc values.
Sample flow rate
Ozone flow rate
PMT output
NORMPMT
PRE-REACTOR
HVPS
NORM PMT=xxxxxx MV
PREREACT=xxxxx MV
HVPS=xxxxx V
Normalized PMT output
Pre-reactor filter value
High voltage power supply
DC power supply
DCPS
DCPS=xxxxxx MV
RCELL TEMP=xxx C
BOX TEMP=xxx C
PMT TEMP=xxx C
MOLY TEMP=xxx C
RCEL=xxx.x IN-HG-A
SAMP=xxx.x IN-HG-A
NOX SLOPE=xxxxx
NOX OFFS=xxxxx
NO SLOPE=xxxxxx
NO OFFS=xxxxxx
RCELLTEMP
BOXTEMP
PMTTEMP
CONVTEMP
RCELLPRESS
SAMPPRESS
NOXSLOPE
NOXOFFSET
NOSLOPE
NOOFFSET
NO2CONC
NOXCONC
NOCONC
Reaction cell temperature
Internal box temperature
PMT temperature
Molycon temperature
Rx cell pressure
Sample pressure
NOx slope parameter
NOx offset parameter
NO slope parameter
NO offset parameter
NO2=xxxxx PPB
Instantaneous NO2 concentration
Instantaneous NOx concentration
Instantaneous NO concentration
Test channel diagnostic output
Time of day
NOX=xxxxx PPB
NO=xxxxx PPB
TESTCHAN
CLOCKTIME
TEST=xxxxx MV
TIME=HH:MM:SS
1Displayed when independent range is enabled.
2Displayed when single or auto range is enabled.
3Depends on which units are currently selected.
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The T command lists TEST messages. Examples of the T command are:
T LIST
Lists all active test messages
T LIST ALL
T CONVTEMP
T LIST NOX
T NOX
Lists all test messages
Prints the temperature of the moly converter
Prints NOx concentration message
Prints NOx concentration message
5.5.4 WARNING Commands and Messages
Table 5-17: RS-232 Warning Messages
Name
Message
Description
WSYSRES
SYSTEM RESET
Analyzer was reset/powered on
RAM was erased
WRAMINIT
RAM INITIALIZED
WSAMPFLOW
WOZONEFLOW
WRCELLPRESS
WBOXTEMP
WRCELLTEMP
WCONVTEMP
WPMTTEMP
WPREREACT
SAMPLE FLOW WARN
OZONE FLOW WARNING
RCELL PRESS WARN
BOX TEMP WARNING
RCELL TEMP WARNING
MOLY TEMP WARNING
PMT TEMP WARNING
PRACT WARN XXX.X MV
Sample flow out of spec.
Ozone flow out of spec.
Rx cell pressure out of spec.
Box temp. out of spec.
Reaction cell temp. out of spec.
Molycon temp. out of spec.
Molycon temp. out of spec.
Pre-reactor filter receive a reading out
of limit spec.
WHVPS
HVPS WARNING
High voltage out of spec.
WDCPS
DCPS WARNING
DC Voltage out of spec.
WOZONEGEN
WDYNZERO
WDYNSPAN
WVFDET
OZONE GEN OFF
CANNOT DYN ZERO
CANNOT DYN SPAN
V/F NOT DETECTED
Ozone Generator is off
Dynamic zero cal. out of spec.
Dynamic span cal. out of spec.
V/F board not installed or broken
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Whenever a warning message is reported on the analyzer display, if the RS-232 interface is in
the normal mode(i.e. not in quiet mode) the warning message is also sent to the RS-232
interface. These messages are helpful when trying to track down a problem with the analyzer and
for determining whether or not the DAS reports are actually valid. The warning message format
is for example:
W 194:11:03 0200 SAMPLE FLOW WARN
The format of a warning command is W command. Examples of warning commands are:
W LIST
List all current warnings
Clear all current Warnings
W CLEAR ALL
Individual warnings may be cleared via the front panel or the command line interface. To clear
the sample flow warning shown above the command would be:
W WSAMPFLOW
5.5.5 CALIBRATION Commands and Messages
There are several methods of both checking the calibration and calibrating the M200AU, these
are discussed in Section 7. The C command executes one of the calibration commands shown in
Table 5-18.
Table 5-18: RS-232 Calibration Commands
Command
Description
C [id] ZERO [1 or 2]
Start remote zero calibration. The number is optional and selects the
range to calibrate. If not specified, the range defaults to range 1.
C [id] COMPUTE ZERO
Tells the instrument to compute a new slope and offset. Same as
pressing ZERO-ENTR on front panel.
C [id] SPAN [1 or 2]
Start remote span calibration.
C [id] COMPUTE SPAN
Tells the instrument to compute a new slope and offset. Same as
pressing SPAN -ENTR on front panel.
C [id] ASEQ number
C [id] EXIT
Executes automatic calibration sequence (1, 2, or 3).
Exits the current calibration step and goes to the next one.
Aborts the entire calibration sequence.
C [id] ABORT
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Table 5-19: RS-232 Calibration Examples
Action
RS-232 Commands
Comments
Zero Calibration
C ZERO
C COMPUTE ZERO
C EXIT
Z/S valves switched to admit
zero gas. Zero cal in Single
Range mode
Zero Calibration of low range -
AutoRange Enabled
C ZERO 1
C COMPUTE ZERO
C EXIT
Z/S valves switched to admit
zero gas. Zero calibration of
low range in Auto Range mode
Span Calibration of high range -
AutoRange Enabled
C SPAN 2
C COMPUTE SPAN
C EXIT
Z/S valves switched to admit
span gas. Span calibration of
high range in Auto Range
mode
Zero Calibration with Dynamic
Calibration enabled
C ZERO
C EXIT
Z/S valves switched to admit
zero gas. Instrument is zero
calibrated if DYN CAL is
enabled.
Zero Calibration
C ZERO
C EXIT
Z/S valves switched to admit
zero gas. Instrument zero is
just checked, but not changed.
Execute AutoCal Sequence #2
C ASEQ 2
Execute a predefined AutoCal
Sequence. Executes sequence
immediately, ignoring time and
date parameters.
Span Calibration Check
C SPAN
C EXIT
Z/S valves switched to admit
span gas. Instrument span is
just checked, but not changed.
Whenever the analyzer starts or finishes a ZS calibration, it issues a status report to the RS-232
interface. If the RS-232 interface is in the normal mode, these reports will be sent. Otherwise,
they will be discarded. Table 5-20 shows the format of the text of the calibration messages. An
example of an actual sequence of calibration status messages is:
C DDD:HH:MM IIII START MULTI-POINT CALIBRATION
C DDD:HH:MM IIII NOX=xxxxx PPB NO=xxxxx PPB NO2=xxxxx PPB
C DDD:HH:MM IIII FINISH MULTI-POINT CALIBRATION
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Table 5-20: RS-232 Calibration Messages
Message
Description
START ZERO CALIBRATION
NOX1=xxxxx PPB2 NO1=xxxxx PPB2 NO21=xxxxx PPB2
FINISH ZERO CALIBRATION
Beginning ZS zero calibration
Finished ZS zero calibration
START SPAN CALIBRATION
NOX1=xxxxx PPB2 NO1=xxxxx PPB2 NO21=xxxxx PPB2
FINISH SPAN CALIBRATION
Beginning ZS span calibration
Finished ZS span calibration
START MULTI-POINT CALIBRATION
NOX1=xxxxx PPB2 NO1=xxxxx PPB2 NO21=xxxxx PPB2
FINISH MULTI-POINT CALIBRATION
Beginning multi-point calibration
Finished multi-point calibration
1Depends on software options installed.
2Depends on which units are currently selected.
5.5.6 DIAGNOSTIC Commands and Messages
When Diagnostic mode is entered from the RS-232 port, the diagnostic mode issues additional
status messages to indicate which diagnostic test is currently selected. Examples of Diagnostic
mode messages are:
D DDD:HH:MM IIII ENTER DIAGNOSTIC MODE
D DDD:HH:MM IIII EXIT DIAGNOSTIC MODE
Example of turning on the Ozone Generator via the RS-232 port:
D ENTER SIG
D OZONE_GEN=ON
D EXIT
The following is a summary of the Diagnostic commands.
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Table 5-21: RS-232 Diagnostic Command Summary
Command
Description
Command
Description
D [id] LIST
D [id] name=value
Prints all I/O signal values. See Table 9-4 for Signal I/O definitions.
Examines or sets I/O signal. For a list of signal names see Table 9-4.
Must issue D ENTER SIG command before using this command.
D [id] LIST NAMES
Prints names of all diagnostic tests.
D [id] ENTER SIG
D [id] ENTER OT
D [id] ENTER ET
Executes SIGNAL I/O diagnostic test.
Executes Optic Test diagnostic test.
Executes Elect Test diagnostic test.
Example of Ozone Generator diagnostic is in Section 5.5.6.
Use D EXIT to leave these diagnostic modes.
D [id] EXIT
Must use this command to exit SIG, ET or OT Diagnostic modes
Resets analyzer software (same as power on).
D [id] RESET
D [id] RESET RAM
Resets analyzer software and erases RAM. Erases NO, NOx, NO2 conc
values. Keeps setup variables and calibration. (same as installing new
software version)
D [id] RESET EEPROM
Resets analyzer software and erases RAM and EEPROM. Returns all
setup variables to factory defaults, resets calibration, Pre-reactor values.
5.5.7 DAS Commands and Message
The M200AU contains a flexible and powerful built in data acquisition system (DAS) that
enables the analyzer to store concentration data as well as diagnostic parameters in its battery
backed memory. This information can be printed out through the RS-232 port. The diagnostic
data can be used for performing “Predictive Diagnostics” and trending to determine when
maintenance and servicing will be required.
To print out the properties of all of the data channels enter:
D PRINT
To print the properties of just a single data channel enter:
D PRINT "name”
For example to print the properties of the CONC data channel enter:
D PRINT “CONC”
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To print records from a DAS data channel enter:
D REPORT “name” RECORDS=nnn COMPACT|VERBOSE
Examples of reports are:
D REPORT “CONC” RECORDS=35 VERBOSE
D REPORT “CALDAT” RECORDS=10
D REPORT “PNUMTC” RECORDS=155 VERBOSE
Automatic RS-232 reporting can be independently enabled and disabled for each Data Channel.
For all default data channels, automatic reporting is initially set to “OFF.” If this property is
turned on, the Data Channel will issue a report with a time and date stamp to the RS-232 port
every time a data point is logged. The report format is shown below:
D 94:08:00 0200 CONC : AVG NXCNC1 = 1234.5 PPB
D 94:08:00 0200 CONC : AVG NOCNC1 = 1234.5 PPB
D 94:08:00 0200 CONC : AVG N2CNC1 = 1234.5 PPB
One CONC report consists of:
D
= Type of report (Diagnostic)
= Time and Date stamp (Julian day, Hr, Min)
= Instrument ID number
= Data Channel name
94:08:00
0200
CONC
CONC = concentration data
PNUMTC = pneumatic parameters
CALDAT = calibration parameters
= Type of data
AVG
AVG = average reading
INST = instantaneous reading
= Name of the parameter
NX = NOx
NXCNC1 = 1234.5 PPB
NO = NO
N2 = NO2
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All of the default Data Channels sample more than one parameter, for these channels, each
parameter is printed on a separate line.
There is also a compact format. If this attribute is enabled, all 3 concentration parameters are
printed on one line as shown below:
D 94:08:00 0200 CONC : 120.0 100.0 20.0
The parameters are in the order of NOx, NO, and NO2.
To change any of the attributes of a particular data channel, the channel attributes are edited
from the front panel by pressing the EDIT key.
5.5.8 Internal Variables
A list of M200AU variables is shown in Table 9-5.
A list of variables and their settings can be requested over the RS-232 port by:
V LIST
Lists internal variables and values
The output from this command is long and will not be shown here. The general format of the
output is:
name = value warning_lo warning_hi (data_lo to data_hi)
Where:
name
= name of the variable
value
= current value of variable
warning_lo
warning_hi
data_lo
data_hi
= lower limit warning (displayed if applicable)
= upper limit warning (displayed if applicable)
= lower limit of allowable values
= upper limit of allowable values
5-39
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
Variables can be changed. Before changing the settings on any variables, please make sure you
understand the consequences of the change. We recommend you call the factory before changing
the settings on any variables. The general format for changing the settings on a variable is:
V name[=value [warn_lo [warn_hi]]]
For example to change the warning limits on the box temperature type:
V BOX_SET 30 10 50
and the CPU should respond with:
V DDD:HH:MM IIII BOX_SET=30 10 50 (0 to 60)
The CONFIG command lists the software configuration. To show the software configuration,
type:
V CONFIG
In addition to SAMPLE and SETUP modes the M200AU has a number of additional operational
modes. They are listed in Table 5-8. To list the analyzer's current mode type:
V MODE
5-40
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
6 OPTIONAL HARDWARE AND SOFTWARE
Optional equipment offered with the M200AU includes:
1. Rack mount with slides
2. Rack mount without slides, ears only
3. Stainless steel zero/span valves
4. 4-20mA, isolated outputs
5. NOy Converter
6.1 Rack Mount Options
Rack Mount including slides and ears, permits the Analyzer to be mounted in a standard 19"
wide x 24" deep RETMA rack. Can also be ordered without slides for applications requiring the
instrument to be rigidly mounted in a RETMA rack.
6.2 Zero/Span Valves
The Zero/Span Valve option consists of two stainless steel solenoid valves. This option is
applicable only to the instrument with internal molybdenum converter. See Figure 2-5 for valve
location. Connections are provided on the rear panel for span gas and zero gas inputs to the
valves. (See Figure 2-2) The valves can be actuated by several methods shown in Table 6-1.
Table 6-1: Zero/Span Valve Operation
Mode
Description
Reference Section
1.
Front panel operation via
CALS and CALZ buttons
Calibration Section 7 - Manual Zero/Span Check.
2.
3.
Automatic operation using
AUTOCAL
Setup and use of AUTOCAL is described in Table 6-2,
and Section 7.3.
Remote operation using the
RS-232 interface
Setup described in Table 6-2. Operation of AUTOCAL
described in Section 5.3.2 and Section 7 - Calibration. A
complete description of the RS-232 interface is available.
Order part number 01350.
4.
Remote operation using
external contact closures
Section 7.7 - Automatic operation using external contact
closures. Truth Table 7-8 and Section 9.3.4.3.
6-1
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Zero/Span valves have 3 operational states:
1. Sample mode. Here both valves are un-energized and sample gas passes through the
sample/cal valve and into the analyzer for analysis.
2. Zero mode. The sample/cal valve is energized to the cal mode. The zero/span valve is un-
energized in the zero mode, thus allowing zero gas to be admitted through the rear panel
bulkhead fitting into the analyzer.
3. Span mode. The sample/cal and the zero/span valves are both energized and in the cal mode.
With both valves on, span gas is admitted through a rear panel bulkhead fitting into the
analyzer.
Zero air and span gas inlets should supply their respective gases in excess of the 1000 cc/min
demand of the Analyzer. Supply and vent lines should be of sufficient length and diameter to
prevent back diffusion and pressure effects. See Figure 2-3 for fitting location and tubing
recommendations.
Zero air for this instrument should have less than 1 ppt (.001 ppb) NO and have various
interferent gas concentrations such that they produce less than 1 ppt total interferent. We
recommend a tank of Ultra Zero Air commonly used in gas chromatographic applications as a
reliable and constant source of zero air. Another source of zero air is the Model 701 zero air
module.
6.3 Autocal - Setup Zero/Span Valves
The Autocal system operates by executing SEQUENCES. It is possible to enable 0-3 sequences,
each sequence operates in one of 4 MODES:
Mode No.
Mode Name
Disabled
Zero
Action
1.
2.
3.
4.
Disables the Sequence
Does a Zero Calibration
Does a Zero and Span Calibration
Does a Span Calibration
Zero-Span
Span
6-2
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For each mode there are seven attributes that the MODE can have that control operational details
of the SEQUENCE. They are:
Attribute No.
Attribute Name
Timer Enabled
Starting Date
Starting Time
Delta Days
Action
1.
2.
3.
4.
5.
6.
7.
Turns on the Sequence timer
Sequence will operate after Starting Date
Time of day sequence will run
Number of days to skip between each Seq. execution
Number of hours later each “Delta Days” Seq is to be run.
Number of minutes the sequence operates
Calibrate the instrument at end of sequence.
Delta Time
Duration
Calibrate
Example of enabling sequence #2:
Do a span check ½ hour later every other day, lasting 15 minutes, without calibration.
Mode and Attribute
Sequence
Value
Comment
2
Define Seq. #2
Mode
4
Select Span Mode
Timer Enable
Starting Date
Starting Time
Delta Days
Delta Time
Duration
ON
Enable the timer
Sept. 4, 1996
Start after Sept 4
01:00
2
First Span starts at 1:00AM
Do Seq #2 every other day
Do Seq #2 ½ hr later each time
Operate Span valve for 15 min
Do not calibrate at end of Seq
00:30
15.0
NO
Calibrate
6-3
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
Table 6-2: Example of AutoCal Setup
Step Action
Comment
1.
Press
SETUP-ACAL
This button sequence will cause the AUTOCAL menu to be
displayed.
2.
3.
3.
4.
5.
6.
7.
8.
9.
Press PREV-NEXT
Press MODE
Press PREV-NEXT until SEQ 2 is displayed
Select the MODE menu
Press PREV-NEXT
Press ENTR
Press PREV NEXT to scroll to SPAN
ENTR selects the SPAN MODE
Press SET
Select the SET menu to change the sequence attributes
Scroll the SET menu to TIMER ENABLE
Allows changing the TIMER ENABLE attribute, select ON
ENTR changes TIMER ENABLE to ON
Repeat steps 6-9 for each attribute
Press PREV-NEXT
Press EDIT
Press ENTR
Press PREV-NEXT
10. Press EXIT
Press the EXIT key to return to upper level menus
6.4 4-20 mA, Current Loop Output
The current loop option replaces the voltage output of the instrument with an isolated 4-20 mA
current output. The current outputs come out on the same terminals that were used for voltage
outputs, see Figure 2-2. See Troubleshooting Section 9.3.3 for setup and calibration.
6.5 NOy Converter
The NOy Converter Option allows placement of the molybdenum converter at the sample inlet
point. This configuration is useful for background studies and where it is desirable to
immediately convert certain components of the atmosphere that decompose rapidly, or may be
lost on the walls of a normal sample induction system. This group of compounds is sometimes
referred to as NOy.
The Option consists of a modified M200AU, a M501Y chassis and remote converter. The
pneumatic diagram for this system of components is in Figure 8-7. Because of the nature of this
option, there is a separate manual “M501Y – Remotely Mounted Converter” (P/N 02808). The
manual covers setup, calibration, and operation of the system.
6-4
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
7 CALIBRATION & ZERO/SPAN CHECKS
There are several ways to check and adjust the calibration of the M200AU. These different
methods are summarized in Table 7-1. In addition, all of the methods described in this section
can be initiated and controlled via the RS-232 port.
We strongly recommend that SPAN CALIBRATION be done with NO span gas. SPAN
CHECKS can be done with either NO only, NO2 only or a mixture of NO and NO2 (GPT).
Zero air used for all calibration procedures, including GPT, should have 1 ppt NO and NO2, less
than 1 ppt of major interferents such as SO2, NH3, and hydrocarbons and a dew point of -5o C or
less. The calibration gasses should be from a reliable supplier, since the quality of the tank
concentration values ultimately determines the accuracy of the analyzer. EPA protocol
calibration gasses should be used for EPA monitoring, see Section 7.6.
NOTE
If you are using the M200AU for EPA monitoring, only the
calibration method described in Section 7.6 should be used.
NOTE
If there are any problems completing any of the following procedures,
refer to Section 9.2.8 and 9.2.9 - Unable to Span or Zero.
7-1
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
Table 7-1: Types of Zero/Span Check and Calibration
Section
Type of Cal or Check
Description
7.1
Manual Z/S Check or Calibration
through the sample port
This calibration option uses calibration gas
coming in through the sample port. Zero/Span
valves do not operate.
7.2
7.3
7.4
7.5
Manual Z/S Check or Calibration with How to operate Zero/Span Valves Option. Can be
Z/S Valves Option. used to check or adjust calibration.
Automatic Z/S Check with Z/S Valves Operates Z/S valves once per day to check the
calibration.
Dynamic Z/S Calibration with Z/S
Valves
Operates Z/S valves once per day and adjusts
calibration.
Use of Z/S Valves with Remote
Contact Closure
Operates Z/S valves with rear panel contact
closures. Without valves, can be used to switch
instrument into zero or span cal mode. Used for
either checking or adjusting zero/span.
7.6
7.7
7.8
EPA Protocol Calibration
Covers methods to be used if data is for EPA
equivalency monitoring.
Special Calibration Requirements for
Independent Ranges or AutoRanging
Covers special requirements if using Independent
Range or AutoRange
Calibration Quality
Information on how to determine if the calibration
performed will result in optimum instrument
performance.
7.9
References
Contains a list of references on quality control
and calibration.
7-2
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Figure 7-1: Calibration Setup
7-3
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
7.1 Manual Zero/Span Check or Cal with Zero/Span Gas in
the Sample Port
The calibration of the instrument can be checked or adjusted using gas coming through the
sample port. This method is often used when the calibration gas is supplied from an external
calibrator and valve system.
This is the calibration procedure to use if the instrument is purchased without the Zero/Span
Valve option.
Since the zero gas concentration is defined as 0 ppb, it is not necessary to enter the expected zero
value. Table 7-2 details the zero calibration procedure with zero gas coming in through the
sample port.
Table 7-2: Manual Zero Calibration Procedure - Zero Gas thru Sample Port
Step Number
Action
Comment
1.
Press CAL
The M200AU enters the calibrate mode from sample mode.
The zero gas must come in through the sample port. When the
CAL button is pressed, the adaptive filter is activated. This
allows the instrument to respond rapidly to concentration
changes regardless of their magnitude.
2.
3.
Wait 10 min
Press ZERO
Wait for reading to stabilize at zero value or for STABIL
reading to get to < 2 ppb.
If you change your mind after pressing ZERO, you can still
press EXIT here without zeroing the instrument.
4.
5.
Press ENTR
Press EXIT
Pressing ENTR actually changes the calculation equations.
M200AU returns to sampling. Immediately after calibration,
data is not added to the DAS averages.
7-4
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
Enter the expected NOx and NO span gas concentrations:
Table 7-3: Enter Expected Span Gas Concentrations Procedure
Step Number
Action
Comment
1.
Press
This key sequence causes the M200AU to prompt for the
CAL-CONC-NOX expected NOx concentration.
Enter the NOx span concentration value by pressing the key
under each digit until the expected value is set. This menu can
also be entered from CALS or CALZ.
2.
3.
Press ENTR
ENTR stores the expected NOx span value.
Press
Now enter the expected NO span concentration as in step one.
CAL-CONC-NO
4.
5.
Press ENTR
Press EXIT
Pressing ENTR stores the NO span value and returns the
prompt to the CONC menu.
Returns instrument to SAMPLE mode.
If desired, compensation for moly converter efficiency (CE) can be included in the NOx
concentration calculation. The CE must be entered prior to calibration. Refer to Section 7.6.6.1
for the CE procedure.
Table 7-4: Manual Span Calibration Procedure - Span Gas thru Sample Port
Step Number
Action
Comment
1.
Press CAL
The M200AU enters the calibrate mode. NO span gas should
be fed to the sample port. When the CAL button is pressed,
the adaptive filter is activated. This allows the instrument to
respond rapidly to concentration changes regardless of their
magnitude.
2.
3.
Wait 10 min
Press SPAN
Wait for reading to stabilize at span value.
If you change your mind after pressing SPAN, you can still
press EXIT here without spanning the instrument.
4.
5.
Press ENTR
Press EXIT
Pressing ENTR actually changes the calculation equations and
causes the instrument to read the NO and NOx span
concentrations.
M200AU returns to sampling. Immediately after calibration,
data is not added to the DAS averages.
7-5
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
7.2 Manual Zero/Span Check or Calibration with
Zero/Span Valves Option
The Zero/Span valve option can be operated from the front panel keyboard. In the Zero/Span
valve option the zero and span gas come into the valves through ports on the rear panel of the
instrument.
Table 7-5: Manual Zero Calibration Procedure - Z/S Valves
Step Number
Action
Comment
1.
Press CALZ
The analyzer enters the zero calibrate mode. This switches the
sample/cal and zero/span valves to allow zero gas to come in
through the zero gas inlet port in the rear panel. When the
CALZ button is pressed, the adaptive filter is activated. This
allows the instrument to respond rapidly to concentration
changes regardless of their magnitude.
2.
3.
Wait 10 min
Press ZERO
Wait for reading to stabilize at zero value.
If you change your mind after pressing ZERO, you can still
press EXIT here without zeroing the instrument.
4.
5.
Press ENTR
Press EXIT
Pressing ENTR actually changes the calculation equations,
forcing the reading to zero.
M200AU returns to sample mode. Immediately after
calibration, readings do not go into the DAS averages.
Refer to Table 7-3 to enter expected NO and NOx values.
7-6
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
Table 7-6: Manual Span Calibration Procedure - Z/S Valves
Step Number
Action
Comment
1.
Press CALS
The M200AU enters the calibrate mode from sample mode.
This operates the sample/cal and zero/span valves to allow
span gas to come in through the cal gas inlet port in the rear
panel. When the CALS button is pressed, the adaptive filter is
activated. This allows the instrument to respond rapidly to
concentration changes regardless of their magnitude.
2.
3.
Wait 10 min
Press SPAN
Wait for reading to stabilize at span value.
If you change your mind after pressing SPAN, you can still
press EXIT here without spanning the instrument.
4.
5.
Press ENTR
Press EXIT
Pressing ENTR actually changes the calculation equations.
M200AU returns to sampling. Immediately after calibration,
data is not added to the DAS averages.
7.3 Automatic Zero/Span Check
In a typical air monitoring application it is desirable to have the analyzer automatically check
(AUTOCAL) its calibration each day. If provided with the proper options, the M200AU
provides this capability by using the time of day clock to signal the computer system to check
operations. When enabled, the instrument software will automatically check zero and span
(AUTOCAL) each day. Optionally, the Z/S cycle can be moved backwards or forwards a fixed
time each day.
AUTOCAL setup is covered in Table 6-2.
7.4 Dynamic Zero/Span Calibration
The AUTOCAL system described above can also optionally be used to calibrate the instrument
once each 24 hours. Dynamic Calibration is enabled by the CALIBRATE attribute in the
AUTOCAL setup menu, see Table 6-2 and Table 7-7. If calibration is initiated using the rear
panel contact closures, the DYN_ZERO and DYN_SPAN variables must be set to ON in the
VARS menu.
Before proceeding with enabling DYNAMIC Z/S you must setup the AUTOCAL feature.
Enabling AUTOCAL is described in Table 6-2. To enable DYNAMIC Zero/Span Calibration:
7-7
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
Table 7-7: Enabling Dynamic Zero/Span
Step Number
Action
Comment
1.
Press
Causes the M200AU go to the AutoCal menu.
SETUP-ACAL
2.
3.
4.
5.
Press PREV-NEXT Select the sequence you want for dynamic calibration.
Press SET Select the SET menu.
Press PREV-NEXT Scroll through the SET menu to the CALIBRATE attribute.
Press EDIT
Set the CALIBRATE attribute value to ON to enable
Dynamic Span.
6.
Press EXIT
Causes the M200AU to return to SAMPLE mode.
With dynamic calibration turned on, the instrument will re-set the slope and offset values for the
NO and NOx channel each day. This continual re-adjustment of calibration parameters can often
mask subtle fault conditions in the analyzer. It is recommended that if Dynamic Cal is enabled,
the TEST functions, SLOPE and OFFSET values in the M200AU should be checked frequently
to assure high quality and accurate data from the instrument.
7.5 Use of Zero/Span Valves with Remote Contact Closure
The Zero/Span valve option can be operated using Remote Contact Closures provided on the rear
panel. See Figure 2-2 for connector location and pinout. When the contacts are closed, the
analyzer will switch to zero or span mode. The contacts must remain closed for at least 1 second,
and will remain in zero or span mode as long as the contacts are closed. To calibrate the
instrument at the end of the Zero/Span valve cycle (DYNAMIC CAL), the CAL_ZERO and
CAL_SPAN variables in the VARS menu must be set to ON.
The CPU monitors these two contact closures and will switch the Analyzer into zero or span
mode when the contacts are closed for at least 1 second.
In order to do another remote check, both contact closures should be held open for at least 1
second, then may be set again. Table 7-8 shows what type of check is performed based on the
settings of the two contact closures.
7-8
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
Table 7-8: Z/S Valves Modes with Remote Contact Closure
Ext Zero CC
Contact Open
Contact Open
Contact Closed
Ext Span CC
Contact Open
Contact Closed
Contact Open
Operation
State when in SAMPLE mode, normal monitoring.
Span check or calibrate*
Zero check or calibrate*
* Calibrate only if Dynamic Calibration is enabled.
7.6 EPA Protocol Calibration
If the M200AU is to be used for EPA compliance monitoring, it must be calibrated in accordance
with the instructions in this section.
In order to insure that high quality, accurate measurements are obtained at all times, the
M200AU must be calibrated prior to use. A quality assurance program centered on this aspect
and including attention to the built-in warning features of the M200AU, periodic inspection,
regular zero/span checks and routine maintenance is paramount to achieving this.
In order to have a better understanding of the factors involved in assuring continuous and
reliable information from the M200AU, it is strongly recommended that Publication No. PB 273-
518 Quality Assurance Handbook for Air Pollution Measurement Systems (abbreviated, Q.A.
Handbook) be purchased from the NTIS (phone 703-487-4650). Special attention should be paid
to Section 2.3 which deals with chemiluminescent based NO2 analyzers and upon which most of
this section is based. Specific regulations regarding the use and operation of ambient oxides of
nitrogen analyzers can be found in 40 CFR 50 and 40 CFR 58. Both publications are available
from the U.S. Government Printing Office (phone 202-783-3238).
7.6.1 Calibration of Equipment
In general, calibration is the process of adjusting the gain and offset of the M200AU against
some recognized standard. The reliability and usefulness of all data derived from any analyzer
depends primarily upon its state of calibration. In this section the term dynamic calibration is
used to express a multipoint check against known standards and involves introducing gas
samples of known concentration into the instrument in order to adjust the instrument to a
predetermined sensitivity and to produce a calibration relationship. This relationship is derived
from the instrumental response to successive samples of different known concentrations. As a
minimum, three reference points and a zero point are recommended to define this relationship.
The true values of the calibration gas must be traceable to NIST-SRM's (Section 2.0.7, Q.A.
Handbook).
7-9
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
All monitoring instrument systems are subject to some drift and variation in internal parameters
and cannot be expected to maintain accurate calibration over long periods of time. Therefore, it
is necessary to dynamically check the calibration relationship on a predetermined schedule. Zero
and span checks must be used to document that the data remains within control limits. These
checks are also used in data reduction and validation. Table 7-9 summarizes the initial quality
assurance activities for calibrating equipment. Table 7-10 is a matrix for the actual dynamic
calibration procedure.
Table 7-9: Activity Matrix for Calibration Equipment and Supplies
Equipment/
Supplies
Frequency And Method Action If Requirements
Acceptance Limits
Of Measurement
Are Not Met
Recorder
Compatible with output
signal of analyzer; min
chart width of 150 mm
(6 in) is recommended
Check upon receipt
Return equimpent to
supplier
Sample line
and manifold
Constructed of PTFE,
glass, or stainless steel
Check upon receipt
Return equipment to
supplier
Calibration
equipment
Meets guide line reference See Section 2.3.9 (Q. A.
Return equipment/ supplies
to supplier or take corrective
action
1 and Section 2.3.2(Q. A.
Handbook)
Handbook)
Working
standard NO
cylinder gas or protocol for accuracy and
Traceable to NIST-SRM
Meets limits in traceability SRM; see protocol in
Analyzed against NIST-
Obtain new working
standard and check for
traceability
Section 2.0.7, Q.A.
NO2
stability. (Section 2.0.7, Q. Handbook
permeation
tube
A. Handbook)
Recording
forms
Develop standard forms
N/A
Revise forms as appropriate
Audit
equipment
Must not be the same as
used for calibration
System must be checked
out against known
standards
Locate problem and correct
or return to supplier
Calibrations should be carried out at the field monitoring site. The Analyzer should be in
operation for at least several hours (preferably overnight) before calibration so that it is fully
warmed up and its operation has stabilized. During the calibration, the M200AU should be in the
CAL mode, and therefore sample the test atmosphere through all components used during
normal ambient sampling and through as much of the ambient air inlet system as is practicable.
If the instrument will be used on more than one range, it should be calibrated separately on each
applicable range (See Section 7.7). Calibration documentation should be maintained with each
analyzer and also in a central backup file.
7-10
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
Table 7-10: Activity Matrix for Calibration Procedure
Equipment/
Supplies
Frequency And Method Action If Requirements
Acceptance Limits
Of Measurement
Are Not Met
Calibration
gases
Sec. 2.0.7, Subsec. 7.1
(Q.A. Handbook)
Assayed against an
NIST-SRM quarterly,
Sec. 2.0.7, (Q.A.
Handbook)
Working gas standard is
unstable, and/or
measurement method is
out of control; take
corrective action such as
obtaining new calibration
gas.
Dilution gas
Zero air, free of
See TAD2
Return to supplier or take
appropriate action with
generation system
contaminants; TAD2 and
Sec. 2.0.7, Subsec. 7.1
(Q.A. Handbook)
Multi-point
calibration
(GPT)
1. tR < 2 minutes PR >
2.75 ppm/min
Method
1. Adjust flow conditions
and/or reaction chamber
volume to meet
1. Sect. 7.6.4 (this
manual)
2. Use calibration
procedure in
suggested limits
2. Section 7.6.5.3 (this
manual), TAD2,
Federal Register and
Figure 7-2; see
Subsection 2.4 (Q.A.
Handbook); also TAD2
and Federal Register
2. Repeat the calibration
3. Replace or service the
converter
3. Converter efficiency >
96%
Section 7.6.7 for
frequency
3. Subsection 7.6.6 (this
manual)
7.6.2 Calibration Gas and Zero Air Sources
Production of Zero Air
Due to the high sensitivity of the M200AU special care must be taken to assure that the zero air
has extremely low levels of pollutants. We recommend using Ultra Zero Air, which is commonly
used for gas chromatographic applications. If other zero air sources are used, the NO
concentration should be < 1 ppt (0.001 ppb) and the concentration of interferent gasses should be
< 1 ppt (0.001 ppb) for the sum total of all interferents.
Devices that condition ambient air by drying and removal of pollutants are available on the
commercial market such as the Teledyne API Model 701 Zero Air Module. We recommend this
type of device for generating zero air. Detailed procedures for generating zero air are in TAD2.
7-11
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
Selection of NO span gas standards
The NIST-SRM's provide references against which all calibration gas mixtures must be
compared (Section 2.0.7, Q.A. Handbook). The procedure requires the comparison of the
concentration of a commercial, working calibration standard to an NIST-SRM. This is described
in Subsection 7.1 of Section 2.0.7, Q.A. Handbook. Subsections 7.1.4 and 7.1.5 describe the
verification and re-analysis of cylinder gases.
Care must be taken to assure that no oxygen is allowed in the NO tank, regulator, or sample
lines. If oxygen is present, it reacts with NO to produce NO2, which can lead to significant errors
in NO concentration measurement.
It is good practice to request a NOx analysis from the supplier of the NO calibration gas.
Generally the maximum NO2 impurity that should be allowed is 1% of the NO concentration.
The NO2 impurity in the NO standard can be measured by the M200AU. A procedure is given in
the TAD for NO2 measurement.
Use of NO2 permeation tubes as standards
The steps required to compare the concentration of a commercial working calibration standard to
an NIST-SRM are described in Subsection 7.3.3 of Section 2.0.7, Q.A. Handbook. See
Subsection 7.3.6 for the re-analysis of permeation tubes.
7.6.3 Data Recording Device
Either a strip chart recorder, data acquisition system, digital data acquisition system should be
used to record the data from the M200AU RS-232 port or analog outputs. If analog readings are
being used, the response of that system should be checked against a NIST referenced voltage
source or meter. Data recording device should be capable of bi-polar operation so that negative
readings can be recorded.
7.6.4 Gas Phase Titration (GPT) System
7.6.4.1 Gas Phase Titration (GPT
Gas Phase Titration (GPT) with serial dilution is recommended for checking the converter
efficiency and NO2 channel linearity of the M200AU. Those using a NO2 permeation tube
should refer to TAD.2
The principle of GPT is based on the rapid gas phase reaction between NO and O3 which
produces stoichiometric quantities of NO2 as shown by the following equation:
NO + O3 → NO2 + O2
7-12
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
Given that the NO concentration is known for this reaction, the resultant concentration of NO2
can be determined. Ozone is added to excess NO in a dynamic calibration system, and the NO
channel of the chemiluminescent analyzer detects the changes in NO concentration. After the
addition of O3, the observed decrease in NO concentration on the calibrated NO channel is
equivalent to the concentration of NO2 produced. The amount of NO2 generated may be varied
by adding varying amounts of O3 from a stable O3 generator. All zero air used in this procedure
should conform to the requirements stated in Section 7.
Dynamic calibration systems based on this principle are commercially available such as the
Teledyne API Model 700 Calibrator, or may be assembled by the user. A recommended
calibration system is described in the Federal Register1 and detailed in TAD.2
7.6.4.2 GPT Calibrator Check Procedure
It has been determined empirically that the NO-O3 reaction goes to completion (<1% residual
O3) if the NO concentration in the reaction chamber (ppm) multiplied by the residence time
(min.) of the reactants in the chamber is >2.75 ppm-min. The theory behind the development of
this equation is in the Federal Register1 and in TAD.2
It is currently not known whether this relationship holds up at the extremely low concentrations
of which the M200AU is capable. We therefore recommend that the GPT procedure be carried
out at the normal flow-rate and concentrations encountered in ambient air monitoring, then
performing a serial dilution of the resultant gas stream to get the low concentration values.
The following procedures and equations should be used to determine whether an existing GPT
calibration system will meet required conditions for a specific calibration.
For calibrators that have known pre-set flow rates, use equations 7-5 and 7-6 of steps 7 and 8
(below) to verify the required conditions. If the calibrator does not meet specifications, follow
the complete procedure to determine what flow modifications must be made.
1.
2.
3.
Select a NO standard gas that has a nominal concentration in the range of 50 to 100 ppm.
Determine the exact concentration [NO]STD by referencing against an NIST-SRM, as
discussed in Section 2.0.7 (Q.A. Handbook).
Determine the volume (cm3) of the calibrator reaction chamber (VRC). If the actual
volume is not known, estimate the volume by measuring the approximate dimensions of the
chamber and using an appropriate formula.
Determine the required minimum total flow output (FT) using Equation 7-1:
FT = analyzer flow demand (cm3/min) x 110/100 Equation 7-1
If more than one analyzer is to be calibrated at the same time, multiply FT by the number of
analyzers.
7-13
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
4. Calculate the NO concentration [NO]OUT needed to approximate 90% of the URL of the NO2
analyzer to be calibrated, using Equation 7-2:
[NO]OUT = URL of analyzer (ppm) x 90/100 Equation 7-2
5.
6.
Calculate the NO flow (FNO) required to generate the NO concentration [NO]OUT, using
Equation 7-3:
[NO
x
]
FT
OUT
=
Equation 7-3
FNO
[NO
]
STD
Calculate the required flow through the ozone generator (FO), using Equation 7-4:
[NO
X
X
]
FNO V RC
STD
=
-
Equation 7-4
Fo
FNO
2.75 ppm - min
7.
8.
Verify that the residence time (tR) in the reaction chamber is <2 min, using Equation 7-5:
VRC
t
R
=
≤ 2min Equation 7-5
FO
+ FNO
Verify that the dynamic parameter specification (PR) of the calibrator's reaction chamber
is >2.75 ppm-min using Equation 7-6:
FNO
VRC
PR
=
[
NO
]
STD
×
×
≥ 2.75 Equation 7-6
FO
+ FNO
FO
+ FNO
NOTE
If tr is >2 minutes or if PR is <2.75 ppm-min, changes in flow conditions
(FT, FO, FNO) or in the reaction chamber volume (VRC), or both will
have to be made, and tr and PR will have to be re-calculated.
9.
After equations 7-5 and 7-6 are satisfied, calculate the diluent air flow (FD) using
Equation 7-7:
FD = FT - FO - FNO Equation 7-7
7-14
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
7.6.4.3 Example Calculation
Following is an example calculation that can be used to determine whether an existing GPT
calibrator will meet the required conditions for a specific calibration. For this example, it is
assumed that only the volume of the reaction chamber, VRC, and the concentration of the NO
standard, [NO]STD, are known. All flow settings (FNO, FO, FT, and FD) will be calculated. In many
uses, these flow settings are known and need only to be substituted in Equations 7-5 and 7-6 to
verify the required conditions. Before doing any calculations, the URL and flow demand of the
analyzer being calibrated must be known. For the M200AU:
Upper range limit = 0.5 ppm
Flow demand = 1000 cm3/min.
Volume of calibrator reaction chamber is determined by physical measurement:
V
RC = 180 cm3
The concentration of the NO standard gas to be used is determined by reference against an
NIST-SRM (Section 2.0.7, Q.A. Handbook):
[NO]STD = 50.5 ppm
1.
Determine the total flow (FT) required at the output manifold using Equation 7-1:
FT = 1000 cm3/min (110/100) = 1100 cm3/min
Because low flows are difficult to control and measure, it is often advantageous to set a
higher total flow than needed. In this example, we will let FT = 3300 cm3/min
2.
3.
Determine the NO conc, [NO]OUT, required at the output manifold, using Equation 7-2:
[NO]OUT = 0.5 ppm (90/100) = 0.45 ppm
Calculate the NO flow (FNO) required to generate [NO]OUT, using Equation 7-3:
0.45 ppm× 3300 3 / min
cm
=
=
FNO
50.5 ppm
4.
Calculate the required flow rate through ozone generator (FO) using Equation 7-4:
3
cm
50.5 ppm x 29.4 3 / min x 180
cm
=
- 29.4 3 / min
cm
FO
=
2.75 ppm - min
cm6 min
2
97180
/
- 29.4
3 / min = 282
cm
3 / min
cm
7-15
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
5.
Verify that the residence time (tR) in the reaction chamber is <2 min using Equation 7-5:
3
180
cm
t
R
=
= 0.58 min
282 3 / min+ 29.5 3 / min
cm cm
6.
Verify the dynamic parameter specification (PR) of the calibrator reaction chamber using
Equation 7-6:
3
29.4 3 / min
cm
180
cm
P
R
= 50.5 ppm×
×
= 2.75 ppm
282 3 / min+ 29.4 3 / min 282 3 / min+ 29.4 3 / min
cm cm cm cm
7.
Calculate the diluent air flow (FD) required at the mixing chamber, using Equation 7-7:
FD = 3300 cm3/min - 282 cm3/min –29.4 cm3/min = 2988.6 cm3/min
7.6.5 Dynamic Multipoint Calibration Procedure
The procedure for calibration of chemiluminescent NOx analyzers by GPT is specified in the
Federal Register.1 This section applies the general procedure to the specific case of the
M200AU.
Calibration must be performed with a calibrator that meets all conditions specified in Subsection
2.3.2 (Q.A. Handbook). Flow settings used in the GPT calibration for NO2 must be determined
as illustrated in Section 7.6.4, this manual.
The user should be sure that all flow meters are calibrated under the conditions of use against a
reliable standard. All volumetric flow rates should be corrected to 25oC (78oF) and 760 mm
(29.92 in.) Hg. Calibrations of flow meters are discussed in TAD.2
Gas Phase Titration (GPT) requires the use of the NO channel of the analyzer to determine the
amount of NO2 generated by titration. Therefore it is necessary to calibrate and determine the
linearity of the NO channel before proceeding with the NO2 calibration. It is also necessary to
calibrate the NOx channel. This can be done simultaneously with the NO calibration. During the
calibration the M200AU should be operating in its normal sampling mode, and the test
atmosphere should pass through all filters, scrubbers, conditioners, and other components used
during normal ambient sampling and as much of the ambient air inlet system as is practicable.
All operational adjustments to the M200AU should be completed prior to the calibration. The
following software features must be set into the desired state before calibration.
7-16
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
1.
2.
3.
4.
Automatic Converter Efficiency compensation. See Sections 7.6.6, this manual.
Independent range selection. See Sections 5.3.4 and 7.7, this manual.
Automatic temperature/pressure compensation. See Table 9-5.
Alternate units, make sure ppb units are selected for EPA monitoring. See Section
5.3.4.5.
5.
Autoranging option. See Section 5.3.4.2.
Converter efficiency should be set prior to calibration since its value is used in the computation
of the NOx and NO2 concentration outputs.
The analyzer should be calibrated on the same range used for monitoring.
If AutoRanging or Independent range options are selected the highest of the ranges will result in
the most accurate calibration, and should be used.
Make sure the GPT calibration system can supply the range of concentrations at a sufficient flow
over the whole range of concentrations that will be encountered during calibration.
7-17
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
Figure 7-2: Diagram of GPT Calibration System
7-18
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
7.6.5.1 Zero Calibration Procedure
Since the zero gas concentration is defined as 0 ppb, it is not necessary to enter the expected zero
value. The following Table 7-11 details the zero calibration procedure.
Table 7-11: Zero Calibration Procedure
Step Number Action
Comment
1.
Press CAL
The M200AU enters the calibrate mode from sample mode.
NOTE:
The analyzer does not operate the zero/span valves in this mode,
the zero gas enters through the sample port. When the CAL
button is pressed, the adaptive filter is activated. This allows the
instrument to respond rapidly to concentration changes
regardless of their magnitude.
2.
3.
Wait 10 min
Press ZERO
Wait for reading to stabilize at the zero value.
If you change your mind after pressing ZERO, you can still
press EXIT here without zeroing the instrument.
4.
5.
Press ENTR
Press EXIT
Pressing ENTR actually changes the calculation equations.
M200AU returns to the SAMPLE mode.
7.6.5.2 NO/NOx Calibration Procedure
Adjust the NO concentration to approximately 80% of the URL of the NO channel. The expected
NO and NOx span concentrations can be determined by measuring the cylinder and diluent flows
and computing the resulting concentrations. If there is any NO2 impurity in the NO standard gas
it should be taken into account when the NOx concentration is entered during the NO/NOx
channel calibration. This is done by ADDING the impurity concentration to the NO
concentration to get the NOx concentration for calibration. Calculate the exact NO and NOx
concentrations as follows:
]
x [NO
FT
FNO
STD
]
[NO
=
Equation 7 - 8
OUT
Enter the respective concentrations using the procedure in Table 7-12. The expected span
concentrations need not be re-entered each time a calibration is performed unless they are
changed.
Enter the expected NOx and NO span gas concentrations:
7-19
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
Table 7-12: Expected Span Gas Concentration Procedure
Step Number Action
Comment
1.
Press
This key sequence causes the M200AU to prompt for the
CAL-CONC-NOX expected NOx concentration.
Enter the NOx span concentration value by pressing the key
under each digit until the expected value is set. This menu can
also be entered from CALS or CALZ.
2.
3.
Press ENTR
ENTR stores the expected NOx span value.
Press
Now enter the expected NO span concentration as in step one.
CAL-CONC-NO
4.
5.
Press ENTR
Pressing ENTR stores the NO span value and returns the prompt
to the CONC menu.
Press EXIT
Returns instrument to SAMPLE mode.
Sample the generated concentration until the NO and the NOx responses have stabilized.
Span the instrument by the following procedure:
Table 7-13: Span Calibration Procedure
Step Number Action
Comment
1.
Press CAL
The M200AU enters the calibrate mode from sample mode.
When the CAL button is pressed, the adaptive filter is activated.
This allows the instrument to respond rapidly to concentration
changes regardless of their magnitude.
2.
3.
Wait 10 min
Press SPAN
Wait for readings to stabilize at span values.
If you change your mind after pressing SPAN, you can still
press EXIT here without spanning the instrument.
4.
5.
Press ENTR
Press EXIT
Pressing ENTR actually changes the calculation equations.
M200AU returns to SAMPLE mode.
7-20
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
The analog voltage output should measure 80% of the voltage range selected. (e.g. 4.00VDC if
0-5V output is selected.) The readings on the front panel display should be equal to the expected
NO and NOx concentrations entered in the procedure given in Table 7-13. See the
Troubleshooting Section 9.2.8 if there are problems. Also see the Calibration Quality Check
procedure Section 7.8.
After the zero and the 80% URL points have been set, generate five approximately evenly
spaced calibration points between zero and 80% URL without further adjustment to the
instrument. Allow the instrument to sample these intermediate concentrations for about 10
minutes each and record the instrument NO and NOx responses.
Plot the analyzer NO and NOx responses versus the corresponding calculated concentrations to
obtain the calibration relationships. Determine the straight line of best fit (y = mx + b)
determined by the method of least squares.
After the best-fit line has been drawn for the NO and the NOx calibrations, determine whether
the analyzer response is linear. To be considered linear, no calibration point should differ from
the best-fit line by more than 2% of full scale.
7.6.5.3 GPT - NO2 Calibration Procedure
The M200AU computes the NO2 concentration by subtracting the NO from the NOx
concentration. Unlike analog instruments, this difference is calculated by the M200AU's internal
computer software. It is extremely unlikely that the NO2 concentration will be in error if the NO
and NOx channels are calibrated correctly. Therefore this procedure is a confirmation that the
NO2 subtraction algorithm in the computer is operating correctly.
NOTE
During this procedure do not make any adjustments to the instrument.
1.
Generate a NO concentration near 90% of the URL. Dilution air and O3 generator air
flows should be the same as used in the calculation of specified conditions of the dynamic
parameter according to Section 7.6.4. Sample this NO concentration until the NO and NOx
responses stabilize. Record the NO and NOx concentrations.
7-21
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
2.
Turn on and adjust the O3 generator in the calibrator to produce sufficient O3 to decrease
the NO concentration to about 10% of full scale. This will be equivalent to 80% of the URL
of the NO2 channel. After the analyzer responses stabilize, record the resultant NO, NOx, and
NO2 concentrations.
MOLY CONVERTER EFFICIENCY
IF THE NOX READING SHOULD DROP TO LESS THAN 96% OF ITS STARTING
VALUE DURING THIS STEP, IT INDICATES THE MOLY CONVERTER IS IN NEED
OF TROUBLESHOOTING OR REPLACEMENT. SEE SECTION 7.6.6 FOR FURTHER
DETAILS.
3.
4.
While maintaining all other conditions, adjust the ozone generator to obtain several other
concentrations of NO2 evenly spaced between the 80% URL point and the zero point. Record
the NO, NOx, and NO2 concentrations for each additional point.
Calculate the resulting NO2 concentrations as follows:
]
* [
FNO NO2
IMP
]
]
]
REM
[
= [NO
- [NO
+
Equation 7 - 10
NO2
OUT
ORIG
FT
Where:
[NO]ORIG is the NO concentration before the GPT ozone is turned on, and [NO]REM is the NO
remaining after GPT.
5.
Plot the NO2 concentration output by the instrument on the y-axis against the generated
NO2 [NO2]OUT on the x-axis. The plot should be a straight line within the ± 2% linearity
criteria given for the NOx and NO channels. If the plot is not linear the most likely cause is
that the converter needs replacing. See Section 7.6.6 on Moly converter efficiency.
7-22
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
7.6.6 Moly Converter Efficiency
The moly efficiency should be 96 to 102% efficient. If it is outside these limits it should be
replaced. The converter efficiency can be determined from the data collected in Section 7.6.5.3.
For each NO2 concentration generated:
1.
Calculate the concentration of NO2 converted as:
]
]
]
])
NOx
REM
[
= [
- ([
- [
Equation 7 - 11
NO2
NO2
NOx
CONV
OUT
ORIG
Where:
[NOx]ORIG is the NOx concentration before the GPT ozone is turned on, and [NOx]REM is the
NOx remaining after GPT.1
2.
3.
4.
Plot the [NO2]CONV concentration output by the instrument on the y-axis against the
concentration generated [NO2]OUT on the x-axis. The plot should be a straight line within the
± 2% linearity criteria given for the NOx and NO channels.
Determine the best straight line fit of the plot either by inspection or least squares. The
slope of the resulting straight line is the moly efficiency. The value should be between .96
and 1.02. If not, the moly needs to be replaced.
If you want the M200AU to automatically compensate (Section 7.6.6.1) for converter
efficiency, enter the efficiency value in the front panel by CAL-CONC-MOLY-SET, then
key in the slope from step 3 followed by ENTR. Press EXIT to return to the SAMPLE menu.
7.6.6.1 Automatic Moly Converter Efficiency Compensation
The M200AU can automatically compensate the NOx and NO2 readings for the molybdenum
converter efficiency. There are 2 ways to enter the converter efficiency into the instrument. The
first is to enter the efficiency as a decimal fraction using the CAL-CONC-MOLY-SET menu.
The second method is to have the M200AU compute the efficiency using the CAL-MOLY-CAL
menu. The procedure is given in Table 7-14. To disable the compensation, press CAL-CONC-
MOLY-SET and enter 1.0000 as the efficiency.
7-23
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
Table 7-14: Automatic Calculation of Converter Efficiency
Step Number Action
Comment
1.
2.
3.
Press
CAL-CONC-
CONV-NO2
From the SAMPLE mode the M200AU enters the Converter
Efficiency menu and requests expected NO2 cal gas
concentration.
Key in expected
Enter the expected NO2 cal gas concentration. (We suggest you
NO2 concentration. generate a NO2 concentration of 80% of current range.)
Then ENTR
Press
Reset the previous converter efficiency value to 1.00.
CAL-CONC-
MOLY-SET
Set CE to 1.0000
4.
Press
CAL-CONC-
CONV-CAL, wait
Allow the NO2 concentration reading to stabilize. It may take
time for the ENTR button to appear because the only valid
values for CE are .96 to 1.02. The ENTR button will not come
10 min. Then press on unless the value is in this range.
ENTR
When ENTR is pressed, the M200AU will compute the ratio of
observed NO2 concentration to expected NO2 concentration and
store the ratio.
5.
6.
Press SET
After the instrument calculates the CE it is good practice to
check the ratio.
Press EXIT
The M200AU will now compensate all readings for this
converter efficiency value.
7-24
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
7.6.7 Calibration Frequency
To ensure accurate measurements of the NO, NOx, and NO2 concentrations, calibrate the
analyzer at the time of installation, and re-calibrate it:
1. No later than three months after the most recent calibration or performance audit which
indicated analyzer calibration to be acceptable.
2. An interruption of more than a few days in analyzer operation.
3. Any repairs which might affect its calibration.
4. Physical relocation of the analyzer.
5. Any other indication (including excessive zero or span drift) of possible significant
inaccuracy of the analyzer.
Following any of the activities listed above, the zero and span should be checked to determine if
a calibration is necessary. If the analyzer zero and span drifts exceed the calibration limits in
Table 9-1 of Section 2.0.9, Subsection 9.1.3 (Q.A. Handbook), a calibration should be
performed.
7.6.8 Other Quality Assurance Procedures
Precision is determined by a one-point check at least once every two weeks. Accuracy is
determined by a three-point audit once each quarter.
Essential to quality assurance are scheduled checks for verifying the operational status of the
monitoring system. The operator should visit the site at least once each week. Every two weeks a
Level 1 zero and span check must be made on the analyzer. Level 2 zero and span checks should
be conducted at a frequency desired by the user. Definitions of these terms are given in
Table 7-16.
In addition, an independent precision check between 0.08 and 0.10 ppm must be carried out at
least once every two weeks. Table 7-16 summarizes the quality assurance activities for routine
operations. A discussion of each activity appears in the following sections.
To provide for documentation and accountability of activities, a checklist should be compiled
and then filled out by the field operator as each activity is completed.
For information on shelter and sample inlet system, an in-depth study is in Field Operations
Guide for Automatic Air Monitoring Equipment, Publication No. APTD-0736, PB 202-249 and
PB 204-650, U.S. Environmental Protection Agency, Office of Air Programs, October 1972.
7-25
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
Table 7-15: Definition of Level 1 and Level 2 Zero and Span Checks
(from Section 2.0.9 of Q.A. Handbook for Air Pollution Measurement Systems)
LEVEL 1 ZERO AND SPAN CALIBRATION
LEVEL 2 ZERO AND SPAN CHECK
A Level 1 zero and span calibration is a A Level 2 zero and span check is an "unofficial"
simplified, two-point analyzer calibration used check of an analyzer's response. It may include
when analyzer linearity does not need to be dynamic checks made with un-certified test
checked or verified. (Sometimes when no concentrations, artificial stimulation of the
adjustments are made to the analyzer, the Level 1 analyzer's detector, electronic or other types of
calibration may be called a zero/span check, in checks of a portion of the analyzer, etc.
which case it must not be confused with a Level
Level 2 zero and span checks are not to be used
2 zero/span check.) Since most analyzers have a
as a basis for analyzer zero or span adjustments,
reliably linear or near-linear output response with
calibration updates, or adjustment of ambient
concentration, they can be adequately calibrated
data. They are intended as quick, convenient
with only two concentration standards (two-point
checks to be used between zero and span
concentration). Furthermore, one of the standards
calibrations to check for possible analyzer
may be zero concentration, which is relatively
malfunction or calibration drift. Whenever a
easily obtained and need not be certified. Hence,
Level 2 zero or span check indicates a possible
only one certified concentration standard is
calibration problem, a Level 1 zero and span (or
needed for the two-point (Level 1) zero and span
multipoint) calibration should be carried out
calibration. Although lacking the advantages of
before any corrective action is taken.
the multipoint calibration, the two-point zero and
If a Level 2 zero and span check is to be used in
the quality control program, "reference
span calibration--because of its simplicity--can
be (and should be) carried out much more
frequently. Also, two-point calibrations are easily
automated. Frequency checks or updating of the
calibration relationship with a two-point zero and
span calibration improves the quality of the
monitoring data by helping to keep the
calibration relationship more closely matched to
any changes (drifts) in the analyzer response.
a
response" for the check should be obtained
immediately following a zero and span (or
multipoint) calibration while the analyzer's
calibration is accurately known. Subsequent
Level 2 check responses should then be
compared to the most recent reference response
to determine if a change in response has
occurred. For automatic Level 2 zero and span
checks, the first scheduled check following the
calibration should be used for the reference
response. It should be kept in mind that any
Level 2 check that involves only part of the
analyzer's system cannot provide information
about the portions of the system not checked and
therefore cannot be used as a verification of the
overall analyzer calibration.
7-26
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
7.6.9 Summary of Quality Assurance Checks
The following items should be checked on a regularly scheduled basis to assure high quality data
from the M200AU. See Table 7-16 for a summary of activities; also the QA Handbook should be
checked for specific procedures.
7-27
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
Table 7-16: Activity Matrix for Data Quality
Frequency And Method
Of Measurement
Action If Requirements
Are Not Met
Characteristic
Acceptance Limits
Shelter temperature
Mean temperature
between 22oC and
28oC (72o and 82oF),
daily fluctuations not
greater than ±2oC
Check thermograph chart
weekly for variations
greater than ±2oC (4oF)
1. Mark strip chart for
the affected time
period
2. Repair or adjust
temperature control
Sample introduction
system
1. No moisture,
foreign material,
leaks, obstructions
Weekly visual inspection
Weekly visual inspection
Clean, repair, or replace
as needed
2. Sample line
connected to
manifold
Recorder
1. Adequate ink &
paper
1. Replenish ink and
paper supply
2. Legible ink traces
2. Adjust time to agree
with clock; note on
chart
3. Correct chart
speed and range
4. Correct time
Analyzer operational 1. TEST
settings measurements at
Weekly visual inspection
Adjust or repair as
needed
nominal values
2. M200AU in
SAMPLE mode
Analyzer operational Zero and span within Level 1 zero/span every 2
1. Find source of error
and repair
check
tolerance limits as
described in Subsec.
9.1.3 of Sec. 2.0.9
(Q.A. Handbook)
weeks
Level 2 between Level 1
checks at frequency desired
by user
2. After corrective
action, re-calibrate
analyzer
Precision check
Assess precision as
described in Sec. 2.0.8 3.4.3 (Ibid.)
and Subsec. 3.4.3
Every 2 weeks, Subsec.
Calc, report precision,
Sec. 2.0.8 (Ibid.)
(Ibid.)
7-28
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
7.6.10 ZERO and SPAN Checks
A system of Level 1 and Level 2 zero/span checks (see Table 7-1) is recommended. These
checks must be conducted in accordance with the specific guidance given in Subsection 9.1 of
Section 2.0.9 (Q.A. Handbook). Level 1 zero and span checks must be conducted every two
weeks. Level 2 checks should be conducted in between the Level 1 checks at a frequency desired
by the user. Span concentrations for both levels should be between 70 and 90% of the
measurement range.
Zero and span data are to be used to:
1.
2.
3.
Provide data to allow analyzer adjustment for zero and span drift;
Provide a decision point on when to calibrate the analyzer;
Provide a decision point on invalidation of monitoring data.
Items 1 and 2 are described in detail in Subsection 9.1.3 of Section 2.0.9 (Q.A. Handbook). Item
3 is described in Subsection 9.1.4 of the same section.
Refer to the Troubleshooting Section 9 of this manual if the instrument is not within the allowed
variations.
7.6.10.1 Zero/Span Check Procedures
The Zero and Span calibration can be checked a variety of different ways. They include:
1.
2.
3.
4.
Manual Zero/Span Check
Zero and Span can be checked from the front panel keyboard. The procedure is in Section 7.1
of this manual.
Automatic Zero/Span Checks
After the appropriate setup, Z/S checks can be performed automatically every night. See
Table 6-2 and Section 7.3 of this manual for setup and operation procedures.
Zero/Span checks via remote contact closure
Zero/Span checks can be initiated via remote contact closures on the rear panel. See Section
7.5 of this manual.
Zero/Span via RS-232 port
Z/S checks can be controlled via the RS-232 port. See Section 5.5 of this manual for more
details.
7-29
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
7.6.10.2 Precision Check
A periodic check is used to assess the data for precision. A one-point precision check must be
carried out at least once every 2 weeks on each analyzer at an NO2 concentration between 0.08
and 0.10 ppm. The analyzer must be operated in its normal sampling mode, and the precision test
gas must pass through all filters, scrubbers, conditioners, and other components used during
normal ambient sampling. The standards from which precision check test concentrations are
obtained must be traceable to NIST-SRM. Those standards used for calibration or auditing may
be used.
7.6.10.3 Precision Check Procedure
1.
Connect the analyzer to a precision gas that has an NO2 concentration between 0.08 and
0.10 ppm. NO2 precision gas may be generated by either GPT or a NO2 permeation tube. If a
precision check is made in conjunction with a zero/span check, it must be made prior to any
zero or span adjustments.
2.
3.
Allow the analyzer to sample the precision gas until a stable trace is obtained.
Record this value. NO and NOx precision checks should also be made if those data are
being reported. Information from the check procedure is used to assess the precision of the
monitoring data; see Section 2.0.8 (Q.A. Handbook) for procedures for calculating and
reporting precision.
7.6.11 Recommended Standards for Establishing Traceability
To assure data of desired quality, two considerations are essential: (1) the measurement process must
be in statistical control at the time of the measurement and (2) the systematic errors, when combined
with the random variation in the measurement process, must result in a suitably small uncertainty.
Evidence of good quality data includes documentation of the quality control checks and the
independent audits of the measurement process by recording data on specific forms or on a quality
control chart and by using materials, instruments, and measurement procedures that can be traced to
appropriate standards of reference. To establish traceability, data must be obtained routinely by
repeated measurements of standard reference samples (primary, secondary, and/or working
standards). More specifically, working calibration standards must be traceable to standards of higher
accuracy, such as those listed below in Table 7-17.
7-30
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Table 7-17: NIST-SRM's Available for Traceability of Calibration and Audit Gas
Standards
Nominal
Concentration
NIST-SRM4
Type
Size, at STP
1683a
1684a
1685a
Nitric oxide in N2
Nitric oxide in N2
Nitric oxide in N2
870
870
870
50 ppm
100 ppm
250 ppm
Permeation Tubes
Concentration, ppm
at flow rates of:
1 L/min/5 L/min
Permeation rate,
ug/min
NIST-SRM4
Type
1629
Nitrogen dioxide
1.0
0.5/0.1
Cylinders of working gas traceable to NIST-SRM's (called EPA Protocol Calibration Gas) are
also commercially available (from sources such as Scott Specialty Gases, Scott-Marin etc.).
7.6.12 Certification Procedures of Working Standards
The NO content of the NO working standard must be periodically assayed against NIST-traceable
NO or NO2 standards. Any NO2 impurity in the cylinder must also be assayed. Certification of the
NO working standard should be made on a quarterly basis or more frequently, as required.
Procedures are outlined below for certification against NO traceable standard. The simplest and most
straightforward procedure is to certify against a NO standard.
NOTE
If the assayed concentration of NO2 impurity in the NO cylinder,
[NO2]imp, is greater than the 1 ppm value allowed in the calibration
procedure, make certain that the NO delivery system is not the
source of contamination before discarding the NO standard.
7-31
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
7.6.12.1 NO Working Standard Traced to NIST NO Standard
First, use the NIST-traceable NO standard and the GPT calibration procedure to calibrate the
NO, NOx, and NO2 responses of the analyzer. Also determine the efficiency of the Molycon.
Refer to the calibration procedure described in Section 7.6.4.2.
Then, generate several NO concentrations by diluting the NO working standard. Use the nominal
NO cylinder concentration, [NO]NOM, to calculate the diluted concentrations. Plot the analyzer
NO response (in ppm) versus the nominal diluted NO concentration and determine the slope,
SNOM. Calculate the NO concentration of the working standard [NO]STD from:
[NO]STD = [NO]NOM x SNOM
A procedure is presented in the TAD in Reference 2.
7.6.12.2 Other Methods of Establishing Traceability
They are:
1.
2.
3.
NO working standard traced to NIST NO2 standard
NO2 working standard traced to NIST NO2 standard
NO2 working standard traced to NIST NO2 standard
NOTE
For further information on calibration by GPT and NO2 permeation
devices, refer to part 50 of Chapter 1, Title 40 CFR, Appendix F
(revised December 1, 1976) and Reference 13 of that Appendix.
7.7 Calibration of Independent Ranges or Autoranging
There are additional considerations when AutoRange or Independent Ranges are selected. The
M200AU uses one physical range of 0-2000 ppb to cover all EPA concentration ranges. The
dynamic range of the internal hardware and computer software is sufficient to cover this entire
range. Internally the range only scales parts of the 0-2000 ppb physical range to cover the
voltage range selected for the analog outputs.
7.7.1 Zero Calibration with AutoRange or Independent Range
Having one physical range to cover all EPA concentration ranges simplifies zero calibration. No
matter what AutoRange or Independent Range values are selected the values computed from a
zero calibration are the same. Therefore no special precautions need to be taken when doing a
zero calibration.
7-32
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7.7.2 Span Calibration with AutoRange or Independent Range
Observe the following guidelines when calibrating in AutoRange or Independent Range.
1.
2.
When doing a span calibration of the M200AU use 80% of the highest of the ranges. This
will result in the most accurate calibration.
When selecting concentrations for the NO/NOx or NO2 (GPT) dynamic calibrations use
80% of the highest AutoRange or the highest Independent Range. This will produce the most
accurate calibration.
3.
4.
5.
If the calibration data is obtained from the RS-232 port or from the front panel display,
no special changes are necessary if the instrument is in AutoRange or Indep. Range. This is
because the internal hardware and software has sufficient dynamic range to cover the entire
EPA equivalent range, also those features only affect the analog outputs.
If using the analog outputs and a chart recorder or datalogger, be sure to note when
AutoRange occurs so that the correct concentration values are used. With Independent
Ranges, change the ranges so that all ranges are equal to the highest range so that all
calibration data is on scale.
Calibration curves or relationships should be obtained for each range used.
7.8 Calibration Quality
After calibration is complete, it is very important to check the QUALITY of the calibration. The
calibration of the M200AU involves balancing several sections of electronics and software to
achieve an optimum balance of accuracy, noise, linearity and dynamic range.
The following procedure checks the Slope and Offset parameters in the equations used to
compute the NO, and NOx concentrations. It is important that they fall within certain limits with
respect to themselves and to each other. For an explanation of the use of these terms in the
concentration calculation see Section 5.2.2.5.
The slope and offset parameters are similar to the span and zero pots on an analog instrument.
Just as in the analog instrument, if the slope or offset get outside of a certain range, the
instrument will not perform as well.
The slope value will be slightly different on the NO and NOx channels. This is due to slight
differences in pneumatic resistance in each pathway. If the slopes are significantly different,
there is a calibration error or a cross port leak in the switching valve. If there is a sudden large
change in slopes after a calibration, that usually indicates a change in reaction cell pressure. This
generally requires a Factory Calibration covered in Section 9.1.6.
7-33
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The offset value gives information about the background signal level. Check the observed offset
value against the factory value in Table 2-1. If significantly higher, check Section 9.1.6. Also,
after calibration check the PREREACT – TEST function reading and compare it against the
factory checkout value. Increasing readings are a predictor of problems.
Table 7-18: Calibration Quality Check
Step Number Action
Comment
1.
Scroll the TEST
The SLOPE value for NOx should be 1.0 ± 0.3. If the value is
not in this range, check Section 9.1.6. If the SLOPE value is in
the acceptable range the instrument will perform optimally.
function menu until
the NOx SLOPE is
displayed.
2.
Scroll the TEST
function menu until
the NO SLOPE is
displayed.
The SLOPE value for NO should be 1.0 ± 0.3. If the SLOPE is
in the acceptable range the instrument will perform optimally. If
the value is not in this range, check Section 9.1.6.
NOTE:
The NO and NOx slopes should be equal within ± 0.1.
3.
4.
Scroll the TEST
This number should be near zero. Values between –10 to 150
function menu until mV are acceptable. This number already has the PREREACT
the NOx OFFSET is value subtracted out and is mainly the background signal due to
displayed.
the molybdenum converter. If the OFFSET value is outside this
range, check Section 9.1.6.
Scroll the TEST
The instrument will now display the NO OFFSET value. Values
function menu until between –10 to 150 mV are acceptable. This number already
the NO OFFSET is has the PREREACT reading subtracted out and should be near
displayed.
zero. If the OFFSET value is outside this range, check
Section 9.1.6.
After the above procedure is complete, the M200AU is ready to measure sample gas.
7-34
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
7.9 References
1.
Environmental Protection Agency, Title 40, Code of Federal Regulations, Part 50,
Appendix F, Measurement Principle and Calibration Procedure for the Measurement of
Nitrogen Dioxide in the Atmosphere (Gas Phase Chemiluminescence), Federal Register, 41
(232): pp 52688-52692, December 1976.
2.
Ellis, Elizabeth C. Technical Assistance Document for the Chemiluminescence
Measurement of Nitrogen Dioxide, U.S. Environmental Protection Agency, Research
Triangle Park, NC. October 1976. 91 p.
3.
4.
5.
6.
7.
Quality Assurance Requirements for State and Local Air Monitoring Stations (SLAMS),
Appendix A, Federal Register, Vol. 44, No. 92, pp 27574-27582, May 1979.
Catalog of NBS Standard Reference Materials. NBS Special Publication 260, 1975-76
Edition. U.S. Department of Commerce, NBS. Washington, D.C. June 1975.
Quality Assurance Handbook for Air Pollution Measurement Systems - Volume I,
Principles. EPAN-600/9-76-005. December 1984.
Quality Assurance Handbook for Air Pollution Measurement Systems - Volume II,
Ambient Air Specific Methods. EPA-600/4-77/027a, December 1986.
Quality Assurance Requirements for Prevention of Significant Deterioration (PSD) Air
Monitoring, Appendix B, Federal Register, Vol. 44, No. 92, pp 27582-27584, May 1979
7-35
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8 MAINTENANCE
8.1 Maintenance Schedule
NOTE
The operations outlined in this chapter are to be
performed by qualified maintenance personnel only.
Table 8-1: Preventative Maintenance Schedule
Item
Maintenance Interval
6 - 12 month intervals
Annually or after repairs
Daily
Reference Section
Table 9-1
TEST Functions
Zero/Span Calibration
Zero/Span Checks
Particulate Filter
Filter for PermaPure Drier
Reaction Cell Window
Ozone Flow
Section 7
Section 7, Table 6-2
Figure 8-1
Weekly as needed
Replace every 12 months
Clean annually or as necessary
Check every year
Figure 9-7
Section 9.3.8, 8.4, Figure 8-3
Figure 9-9, Section 9.3.7
Figure 9-9, Section 9.3.7
Figure 8-4, Section 8.5
Sample Flow
Check every year
Moly Converter
Check efficiency every 6
months
Pneumatic Lines
Examine every 12 months, clean Figure 8-5, Figure 8-6, Figure 8-7
if necessary
Factory Calibration
Calibrate each year or after
repairs
Section 9.1.6
Leak Check
O-rings
Check every year
Section 8.7
Replace if seal is broken
Figure 9-9, Figure 9-10
8-1
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Table 8-2: Preventative Maintenance Calendar
Maintenance
Interval
Item
Jan Feb Mar Apr May Jun Jul
Aug Sep Oct Nov Dec
6 - 12 month
intervals
TEST Functions
Zero/Span
Calibration
Annually or after
repairs
Zero/Span Checks
Particulate Filter
Daily
Weekly as needed
Filter for PermaPure
Drier
Replace every 12
months
Reaction Cell
Window
Clean annually or as
necessary
Ozone Flow
Sample Flow
Check every year
Check every year
Check efficiency
every 6 months
Moly Converter
Examine every 12
months, clean if
necessary
Pneumatic Lines
Calibrate each year
or after repairs
Factory Calibration
Leak Check
O-rings
Check every year
Replace if seal is
broken
8-2
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8.2 Replacing the Sample Particulate Filter
The particulate filter should be inspected often for signs of plugging or contamination. It is also
common for dirt particles to absorb NO2, thus causing those readings to be low.
To check and change the filter:
1.
2.
Fold down the M200AU front panel.
Locate the filter on the left side of the analyzer front panel. See Figure 8-1 for an
exploded view of the filter assembly.
3.
4.
Visually inspect the filter through the glass window.
If the filter appears dirty, unscrew the hold-down ring, remove the teflon o-ring and then
the filter.
5.
Replace the filter, being careful that the element is fully seated in the bottom of the
holder. Replace the teflon o-ring, then screw on the hold-down ring and hand tighten.
8-3
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Figure 8-1: Replacing the Particulate Filter
8-4
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
8.3 Sample Pump Maintenance
The external sample pump is capable of maintaining the cell pressure at better than 4.0 "Hg-A. If
a higher pressure is noted, the pump may need servicing. Check the pump and pneumatic system
for leaks or rebuild pump. The ozone scrubber is integrated into the molybdenum converter
inside the instrument.
See Figure 8-2 for component locations.
8-5
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Figure 8-2: Sample Pump Assembly
8-6
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
8.4 Cleaning the Reaction Cell
The reaction cell should be cleaned whenever troubleshooting points to it as the cause of the
trouble. A dirty cell will cause excessive noise, unstable zero or span, or low response.
To clean the reaction cell it is necessary to remove the reaction cell from the sensor housing. Use
the following guide:
1.
2.
Turn off the instrument power and vacuum pump.
Loosen the hold down screws for pneumatic sensor assembly and move the assembly to
the side.
3.
4.
5.
6.
Disconnect the exhaust fitting and inlet fittings. See Figure 8-3.
Loosen four screws holding the reaction cell to the sensor.
Disconnect heater/thermistor and lift the cell away.
The reaction cell will separate into two halves:
A.
B.
The manifold assembly
The reaction block with reaction sleeve and window
7.
8.
The reaction sleeve and window should be cleaned with methanol and a clean tissue and
dried.
Normally it is not necessary to clean the sample and ozone flow orifices since they are
protected by sintered SS filters. If tests shows that cleaning is necessary then do the
following:
A.
The manifold O-rings, springs, sintered SS filters, and orifices should be removed
before cleaning. It is suggested that the orifice, filter and o-rings be replaced
unless an ultrasonic cleaner and methanol or methylene chloride is available. Both
orifice and sintered filter may be cleaned with an ultrasonic bath for 30 minutes in
either solvent.
B.
C.
D.
After cleaning with solvent, flush copiously with tap waster.
Now, rinse parts in either D1 or distilled water.
Dry parts prior to re-installation.
9.
Do not remove the sample and ozone nozzles. They are Teflon threaded and require a
special tool for re-assembly. If necessary, the manifold with nozzles attached can be
cleaned in an ultrasonic bath.
10.
11.
Reassemble in proper order and re-attach onto sensor housing. Reconnect pneumatics and
heater connections, then re-attach the pneumatic sensor assembly and the cleaning
procedure is complete.
After cleaning, the analyzer span response may drop 10 - 12% in the first 1-2 days as the
reaction cell window conditions.
8-7
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Figure 8-3: Reaction Cell Assembly
8-8
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
8.5 Replacing the Molybdenum Converter
The Molybdenum Converter is located in the center of the instrument, refer to Figure 2-5 for its
location. Refer to Figure 8-4. The heater, thermocouple, converter is designed to be replaced as a
single unit.
1.
2.
Turn off the power to the M200AU and allow the converter to cool.
Remove the entire assembly from the chassis
A. Remove the pneumatic fittings from the valves.
B. Remove the power to the valves, thermocouple wire and cartridge heater.
C. Remove the converter assembly from the chassis by loosening the 4 captive screws that
secures the assembly to the chassis.
CAUTION
The converter operates at 315ºC. Severe burns can result
if not enough time is allowed for the assembly to cool. Do
not handle assembly until it is at room temperature.
3.
4.
Disconnect the gas fittings and power cable grounding from the can.
Remove the valve assembly and bottom bracket and re-attach those two parts to the
replacement moly assembly.
5.
6.
Re-attach the pneumatic fittings and valve assembly to the can.
Install the assembly back into the analyzer. Re-attach the electrical and pneumatic
fittings. Leak check the assembly when completed.
7.
Turn the power back on. The insulation can emit a burnt odor for the first 24 hours, this is
normal. Allow the converter to burn-in for 24 hours, then re-calibrate the instrument.
8-9
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Figure 8-4: Molybdenum Converter Assembly
8-10
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8.6 Pneumatic Line Inspection
Particulate matter in the pneumatic lines will affect both flow rate and response time. It is
important that the pneumatic system be periodically inspected and thoroughly cleaned if
necessary. Clean by disassembling and passing methanol through three times. Dry with nitrogen
or clean zero air.
Also inspect all pneumatic lines for cracks and abrasion on a regular basis. Replace as necessary.
Refer to the pneumatic diagram in Figure 8-5, Figure 8-6 and Figure 8-7.
8-11
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Figure 8-5: Pneumatic Diagram - Standard Configuration
8-12
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Figure 8-6: Pneumatic Diagram with Zero/Span Valve Option
8-13
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Figure 8-7: Pneumatic Diagram with External Converter Option
8-14
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
8.7 Leak Check Procedure
If a leak checker is not available, it is possible to leak check the instrument using the M200AU's
pump plus a shut-off valve.
1.
2.
Turn off instrument power and pump power.
Cap the sample inlet port, ozone generator air inlet, and zero air inlet (if Z/S valve option
present).
3.
4.
Insert a shut-off valve between the sample pump and the vacuum manifold at the rear of
the instrument.
Turn on the sample pump and set the TEST function to RCEL, which measures the
reaction cell pressure. Close the shutoff valve and monitor the cell pressure. The pressure
should not drop more than 1"-Hg (0.5psi) in 5 minutes. If there is a leak, it is not possible by
this method to tell where it is located. You can locate the leak by using a pressure leak
checker described below.
5.
The sensor module is equipped with a fitting at the top of housing near the heat sink fins.
This fitting can be pressurized and the sensor checked for leaks. The leak-down rate is the
same as above.
If you have a leak checker:
1.
2.
Turn off instrument power and pump power.
Disconnect pump at rear panel. Cap the sample inlet port, ozone generator air inlet, and
zero air inlet (if Z/S valve option present) and connect the leak checker to the exhaust port.
CAUTION
Pressure must be less than 15 psi.
8-15
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3.
Pressurize system and check for leaks by watching overall pressure. The pressure should
not drop more than 1"-Hg (0.5psi) in 5 minutes.
If the instrument fails the pressure test, each fitting needs to be leak checked to find the location.
Be careful that the system is always pressurized so as not to draw soap solution into the
plumbing system. Make sure you dry off any accumulated bubble solution. Refer to Figure 8-5,
Figure 8-6 and Figure 8-7 for pneumatic diagrams.
The Sensor module can be leak checked as a unit using a 1/8" tubing fitting on top of the
assembly. The same rules as above apply.
1.
2.
Pressurize to <15psi.
After turning off pressure tester, pressure should not drop more than 1" Hg in 5 minutes.
8.8 Light Leak Check Procedure
1.
2.
3.
Scroll the TEST functions to PMT.
Input zero gas
Shine a powerful flashlight or portable incandescent light at the inlet and outlet fitting,
and at all the joints of the reaction cell. The PMT value should not respond to the light.
If there is a response, tighten the joints or replace the tubing with new black PTFE tubing.
We often find light leaks are caused by o-rings being left out of the assembly.
8.9 Prom Replacement Procedure
Preparation: If any setup changes such as RANGE, AUTOCAL ON/OFF etc. have been made,
record the changes because all settings should be checked after the PROM is changed. See
Figure 9-2 for location of prom on CPU card.
1.
2.
Turn the machine off.
Remove the hold down screw that holds in the V/F-CPU assembly to the motherboard.
Disconnect the J9 power connector from the motherboard. Gently lift the assembly far
enough out of the instrument to remove the connector to the display and the RS-232
connector.
3.
The CPU board is attached to the larger V/F board.
8-16
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4.
Remove the board, laying it down on an insulating surface such that the board edge pins
on the PCB are on the left. The PROM chip should be at the top center. The current chip
should be labeled with something like "2AUC8…". See Figure 9-2 for prom location. Gently
pry the chip from its socket and replace it with the new chip. Install the chip in the left end of
the socket with the notch facing to the right. Make sure that all of the legs insert into the
socket correctly.
5.
6.
Re-attach the CPU board to the V/F board, and re-attach the assembly to the
motherboard.
Turn the M200AU ON and observe the front panel display. As the machine goes through
the setup the version number will be displayed on the front panel. It should read the same as
the version number printed on the prom.
7.
8.
Re-enter any non-default settings such as RANGE or AUTOCAL. Re-enter the SPAN
values in the CAL-CONC menu. Check all settings to make sure that expected setup
parameters are present.
Re-calibrate the Analyzer so that the default slope and intercept are overwritten with the
correct values.
8-17
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
9 TROUBLESHOOTING, ADJUSTMENTS
NOTE
The operations outlined in this chapter are to be
performed by qualified maintenance personnel only.
This section of the manual contains information on diagnosing and repairing instrument
performance problems. It contains information on how to use and interpret TEST and
DIAGNOSTIC data as well as WARNING messages the instrument generates. There is
information on how to troubleshoot the instrument subsystems. Finally there is information to
perform adjustments such as DAC calibration procedures.
This manual provides troubleshooting procedures that address problems to the board level. For
component level troubleshooting, consult the schematics for the appropriate board in the
Appendix.
NOTE
The values of the readings shown on the front panel of the
instrument may at times read XXXXXX. This means that the
reading is off scale and therefore meaningless.
General Troubleshooting Hints
1.
2.
If the fault light is on and it stays on after you clear the warning messages, see Section
9.1.2.
Think of the analyzer as three sections:
Section 1: Pneumatics - Over 50% of all analyzer problems are traced to leaks in the pump
assembly, sample filter, instrument internal pneumatics, calibrator or external sample
handling equipment. Suspect a leak first, and refer to Section 8.7.
Section 2: Electronics - data processing section. This can be readily checked out using
Electric Test in Section 9.1.3.2.
Section 3: Optics - Optical section consisting of PMT, HVPS, Preamp, and signal
processing. Refer to Section 9.1.3.3 on use of Optical Test.
9-1
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
3.
Check the TEST functions:
A. Compare the TEST functions to the factory values in Table 2-1. This will often provide
important clues as to the problem.
B. Pay special attention to the NO and NOx slopes:
C. The slopes are the software equivalent of the span pot on an analog instrument. If the
slopes are not 1.0 ± 0.3, the gain has changed.
D. Check the Pre-reactor - PREREACT - reading in the TEST functions. Compare it to the
value in the factory checkout Table 2-1. If the reading is significantly greater than the
factory test value, the reaction cell could be contaminated or there could be a light leak in
the cell. Verify this fault by turning the ozone generator off and see if the reading drops
more than 25 mV.
E. Check for a change in cell pressure (vacuum) - compare to value in Table 2-1. - possible
causes:
1)
2)
3)
4)
Partially plugged ozone killer
Change of pump or malfunctioning pump
Plugged pneumatics
Change in altitude
4.
Check for pneumatic leaks - perform the leak check procedure in Section 8.7. If slopes
are different from each other by > .1, this usually indicates a leak in the switching (NO/NOx)
valve or improper calibration.
5.
6.
7.
Check for light leaks - Turn off the ozone generator, then wait 7 minutes. If the reading
drops significantly, the reaction cell is contaminated. If not, a light leak is indicated.
Incorrect span gas concentration - this could come either from the calibrator or entering
the expected span gas concentration in the M200AU incorrectly, see Table 7-3.
If the instrument does not respond to span gas, check Section 9.2.3.
The above should get you started in diagnosing and repairing the most common faults. If these
reasons have been eliminated, the next thing to do is a Factory Calibration covered in Section
9.1.6 or check Section 9.2 for other fault diagnosis. If difficulties persist, contact our service
department. The 800 telephone number is on the cover page of this manual.
9-2
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
9.1 Operation Verification-M200AU Diagnostic Techniques
9.1.1 Fault Diagnosis with TEST Variables
Table 9-1 indicates possible fault conditions that could cause the TEST functions to be outside
the acceptable range.
9-3
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
Table 9-1: Test Functions
Test Function
Factory Set-Up
Comment
RANGE
500 PPB
This is the Range of the instrument. In standard configuration all 3
outputs have the same range.
Independent range option allows different ranges for each output.
When enabled, there will be 3 range values displayed.
Auto range option allows 2 different ranges for all outputs, and
will automatically switch to the other range dynamically as
concentration values require. The TEST values will show the
range the instrument is currently operating in, and will
dynamically display the alternate range as the range changes
occur.
STABIL
Check value in
Final Test Values
Table 2-1
The instrument stability is the Std. Deviation of the last 50 min of
NOx conc data. It is computed for the NOx channel only. The noise
value only becomes meaningful if sampling a constant
concentration for more than 50 minutes. The noise value should be
compared to the value observed in the factory check-out.
Faults that cause high noise values are:
1. Gas leaks
2. Light leak
3. Faulty HVPS
4. Defective Preamp board
5. Outgassing Moly converter
6. PMT recently exposed to room light
7. Dirty/contaminated reaction cell
8. Mis-calibrated (slope - offset outside of limits)
SAMPLE FLW
1000 cc/min
± 100
This is the instrument flow. It is computed using the up stream and
down stream pressures across the sample flow orifice. This
method can give a false flow indication if the orifice is plugged
and the sample pump is creating a pressure drop. It should be
taken into account when diagnosing instrument faults.
- A rapid method of determining if the orifice is plugged is to
disconnect the sample and ozone tubes from the reaction cell, then
briefly put your finger over the fittings on the cell. You should
feel the vacuum build up. Also note the difference between the
high sample flow and the low ozone flow rate.
- Another reliable method is to attach a rotameter or soap bubble
flowmeter to the fittings to measure the flows.
Flow rate will change ± a few cc/min due to changes in ambient
air pressure such as cycling of air conditioning, or passing weather
fronts. Changing altitude changes the ambient air pressure and
therefore the sample flowrate. This effect is about 15-20 cc/min
per 1000 feet of altitude change. If required, the output of the
instrument can be compensated for pressure. See Section 5.3.9,
Table 9-5.
(table continued)
9-4
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
Table 9-1: Test Functions (Continued)
Test Function
Factory Set-Up
Comment
OZONE FL
This is the Ozone flow. It is measured by a solid state flow meter,
and thus is a true indication of flow.
80 cc/min ± 10
If you suspect there is no ozone being generated, disconnect the
tube at the reaction cell and rub the end of the tube on your
fingertips, then sniff your fingers. The odor of ozone should be
readily apparent.
PMT
0-5000 mV
This is the instantaneous output of the PMT. During normal
operation the value varies widely as the M200AU switches from
NO to NOx to Pre-reactor modes. Changes in reading will be
synchronized with valve switching. The PMT voltage values will
be relatively constant when:
1. Electric test - variation in the 2000 mV signal observed will be
sampling errors of the V/F board and preamp noise. See Section
9.1.3.2.
2. Optic test - variation in the 2000 mV signal will be PMT dark
current, preamp, HVPS plus item 1 above. See Section 9.1.3.3.
3. Sampling zero gas - signal from 1, 2 plus signal from ozone
generator air
4. Sampling pure NO span gas - signal will be 1, 2, 3, above plus
signal from chemiluminescent reaction. Slight pulsations will
be noticed as the M200AU switches from NO to NOx. This is
due to differences in flowrates in each channel. These
differences are taken out in the calibration process resulting in
slightly different slopes for the NO and NOx channels. Large
pulsations when switching to the NOx channel is indicative of a
bad moly converter.
When sampling zero gas the PMT reading should be less than 150
mV and relatively constant.
High or noisy readings could be due to:
1. Excessive background light which is caused by a possible
contaminated reaction cell.
2. Humidity (undried ambient air) in the ozone generator feed air.
3. PMT recently exposed to room light. It takes 24-48 hours for
the PMT to adapt to dim light.
4. Light leak in reaction cell.
5. Improper slopes
NORM PMT
0-5000 mV
The Normalized PMT reading is to be used as the PMT reading
during the FACTORY CALIBRATION procedure. In addition to
the raw mV reading from the PMT this reading is adjusted using
certain other factors to produce an accurate reading for the Factory
Calibration procedure.
(table continued)
9-5
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
Table 9-1: Test Functions (Continued)
Test Function
Factory Set-Up
Comment
PREREACT
Check value in
Final Test Values
Table 2-1
PREREACT is the current value of the Pre-reactor circuit reading.
The number typically should be
0 mV -15/+35 if the instrument is sampling zero air. When the
M200AU is in SAMPLE mode readings may be higher if sample
gas contains hydrocarbons. If a problem is suspected, check the
Pre-reactor and NO/NOx valves for cross port leaks. Use
Diagnostic mode to manually switch the valves while checking for
leaks and correct operation.
HVPS
450 – 900 VDC
This represents the scaled-up HVPS programming voltage to the
HVPS. The design of the HVPS precludes taking a single reading
that indicates the health of the supply. Refer to the HVPS
Troubleshooting Section 9.3.8.5 for a procedure for testing the
HVPS. This TEST function is used primarily to set the HVPS
voltage value. A value not in the 450 to 900 volt range indicates
problems with the HVPS supply.
DCPS
2500 ± 200 mV
DCPS is a composite of the +5 and ± 15 VDC supplies. It has
been arbitrarily set at 2500 ± 200 mV. If it is not in this range one
of the voltages in the supply is not working. Check the procedures
for diagnosing the Power Supply Module in Section 9.3.5.
RCELL TEMP
40 ± 1° C
The reaction cell temperature is controlled to 40° C ± 1° C by the
computer. It should only read other values when the instrument is
warming up. If the value is outside the acceptable range, go to the
procedure for diagnosing the Reaction cell temp supply in Section
9.3.8.2. The alarm limits are less than 35° C and greater than
45° C.
BOX TEMP
PMT TEMP
The Box Temp is read from a thermistor on the Status/Temp
board. It should usually read about 5° C above room temp. The
M200AU is designed to operate from 20 to 30° C ambient.
Therefore the box temperature should be in the range of about 10
to 50° C. Temperatures outside this range will cause premature
failures of components, and poor data quality. Warning limits are
< 8° C and > 48° C.
8 - 48° C
The PMT detector is very temperature sensitive. The PMT
temperature should always be –5° C, except at power-up.
Temperatures more than ± 1° C from the set point indicate
problems with the cooler circuit. See Section 9.3.8.4 for PMT
cooler diagnostic and troubleshooting. Warning limits are < -8° C
and > -2° C.
-5 ± 1° C
40 ± 2o C
BLOCK TEMP
Reports the temperature of the sample flow and ozone flow
control orifices. Variations in these temperatures will cause span
concentration drift.
(table continued)
9-6
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
Table 9-1: Test Functions (Continued)
Test Function
Factory Set-Up
Comment
MOLY TEMP
Moly temp is controlled by the CPU to 315° C. After cold start it
requires about 30 min to come to temperature. After temperature is
315 ± 5° C
reached temperature should not vary more than ± 5° C. See
Section 9.3.4 for troubleshooting. Warning limits are < 290° C and
> 320° C.
RCEL PRESS
RCEL is the pressure in the Reaction Cell. The instrument is very
sensitive to variations in reaction cell pressure. A 10% change in
output per 1"Hg pressure is typical. The pressure reading will
change when the NO/NOx and Pre-reactor valves switch,
otherwise it should remain constant. The reaction cell pressure
will be lower at higher altitude due to lower pump back-pressure.
Pressures higher than the acceptable range will decrease
instrument noise performance and sensitivity.
3.5 ± 1 in-Hg-A
SAMP PRESS
29.5"Hg at sea
level
The sample pressure is taken upstream of the reaction cell. It
usually runs about 0.5" less than ambient pressure due to the
restrictions in the sample intake tubing. Sample pressure should be
within ± 1"Hg of atmospheric pressure. The pressure sensor used
reports absolute pressure and therefore is sensitive to altitude,
weather fronts, and room air conditioning. Changes due to altitude
is about 1" per 1000 ft., other changes are ± 0.4" maximum.
Pressurizing the sample inlet will cause the M200AU to be noisy
and to shift its reading.
SLOPE
OFFSET
TIME
This is the software slope value. It operates like a software gain
pot. Refer to Table 7-18 on Calibration Quality for additional
information.
1.0 ± 0.3
0 – 10, +150
This is the software offset value. It operates like a software DC
offset pot. Refer to Table 7-18 on Calibration quality for
additional information.
HH:MM:SS
This is the time of day clock readout. It is used to time the
AutoCal cycles. The speed of the clock can be adjusted by the
CLOCK_ADJ variable in the VARS menu. The clock can be set
via SETUP-CLOCK-TIME from the front panel.
9-7
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
9.1.2 Fault Diagnosis with WARNING Messages
The M200AU monitors several internal values for alarm conditions. If the condition for an alarm
is met, the alarm is displayed on the front panel and the warning is transmitted out the RS-232
port. If a warning is present, it can be cleared by pressing the CLR key on the front panel. If
uncleared warnings are present they can be examined by pressing the MSG button on the
keyboard. Any time the instrument is powered up, the SYSTEM RESET alarm will be displayed.
Generally, it is ok to ignore warnings that are displayed shortly after power-up, only if they
persist should they be investigated.
Table 9-2 shows the warning messages and gives some possible causes.
9-8
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
Table 9-2: Front Panel Warning Messages
Message
Description
SYSTEM RESET
Analyzer was reset/powered on. This warning occurs every
time the instrument is powered up, as in a power failure. It can
also occur if the RAM or EEPROM is reset.
RAM INITIALIZED
RAM was erased. The RAM contains the DAS averages which
get erased when the RAM is initialized. It also contains
temporary data used by the M200AU to calculate
concentrations. No setup variables are stored in the RAM.
SAMPLE FLOW WARN
OZONE FLOW WARNING
The calculated sample flow is outside the hi/low limits. Since
the flow is calculated, it probably means the pressure has
gotten too low. Flow warnings are caused by a plugged sample
inlet or ozone line.
Ozone flow out of spec. Warnings occur most often because of
loss of vacuum, which causes the ozone flow to go to zero.
They also can occur due to a flow sensor failure.
RxCELL PRESS WARNING
BOX TEMP WARNING
Vacuum out of spec. Warnings are caused by leaks, pump
failure or disconnected pump.
Box temp. out of spec. Instrument fan failure, enclosure
temperature failure. Operation of the M200AU in a too warm
or cold environment will cause degradation of data quality and
shorten the life of the instrument.
RCELL TEMP WARNING
PMT TEMP WARNING
Reaction cell temp. out of spec. The warning message is most
often present during initial warm-up or if the connector to the
heaters is not plugged in after dis-assembly. It has also
occurred if the thermistor is not in position in the reaction cell.
PMT temp. out of spec. The PMT temp has its own
proportional controller on the preamp board. Warnings might
occur during warmup. A warning can occur if the 7 pin
connector to the interior of the sensor is not plugged in. The
power connector to the PSM should be checked for proper
voltage (+15 VDC ± 0.5)
MOLY TEMP WARNING
Molycon temp. out of spec. The Moly temp is controlled by
the CPU. It has a thermocouple with amplifier on the
Status/Temp board. Because of the high temperature of the
Moly (315° C), the moly temp warning will tend to be the last
warning to clear as the instrument is powered on.
(table continued)
9-9
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
Table 9-2: Front Panel Warning Messages (Continued)
Message
Description
CANNOT DYN ZERO
Dynamic zero cal. out of spec. The reading of the PMT was
too high for the ZERO button to appear. Make sure the
instrument is receiving zero gas. Check for dirty reaction cell.
Do the factory calibration procedure located in Section 9.1.6.
CANNOT DYN SPAN
Dynamic span cal. out of spec. The reading of the PMT was
too high or low for the SPAN button to appear. Make sure the
instrument is receiving correct concentration span gas. Make
sure the expected span concentration is entered. Check for
dirty reaction cell. Do the factory calibration procedure located
in Section 9.1.6.
OZONE GEN OFF
Ozone generator is off. See Table 9-11 for conditions.
PRACT WRN XXX.X MV
The Pre-reactor circuit compensates for detector dark current,
and background light. Certain electrical faults cause high
readings to be added to the filter. First, the cause of the high
PREREACT reading should be found and repaired, then wait
10 minutes for the Pre-reactor filter to clear itself out.
A/D NOT INSTALLED
V/F board has failed. The V/F board did not respond to
commands from the CPU. This probably means 1. board not
seated in socket 2. defective board 3. defective back plane
connector
HVPS WARNING
DCPS WARNING
High Voltage Power Supply voltage out of limits. Limits are
400-900 VDC
DC Power Supply voltage out of limits. Limits are 2500
± 500 mV
9-10
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
9.1.3 Fault Diagnosis using DIAGNOSTIC Mode
Diagnostic mode can be looked at as a tool kit of diagnostics to help troubleshoot the instrument.
To enter DIAG mode press SETUP-MORE-DIAG.
The diagnostic modes are summarized in Table 9-3. To access these functions, after you have
pressed SETUP-MORE-DIAG, press NEXT, PREV to select the desired mode, then press
ENTR.
9-11
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
Table 9-3: Summary of Diagnostic Modes
DIAG Mode
Description
SIGNAL I/O
Gives access to the digital and analog inputs and outputs on
the V/F board. The status or value of all of the signals can be
seen. Some of the signals can be controlled from the keyboard.
Table 9-4 gives details on each signal and information on
control capabilities.
NOTE:
Some signals can be toggled into states that indicate warnings
or other faults. These settings will remain in effect until DIAG
mode is exited, then the M200AU will resume control over the
signals.
ANALOG OUTPUT
D/A CALIBRATION
Causes a test signal to be written to the analog output DAC's.
The signal consists of a scrolling 0%, 20%, 40%, 60%, 80%,
100% of the analog output value. The scrolling may be
stopped by pressing the key underneath the % display to hold
the current value. The exact voltage values depend on the
switch settings on the V/F board amplifiers.
The analog output is created by 4 digital-to-analog converters.
This selection starts a procedure to calibrate these outputs.
Refer to Section 9.3.3.1 for a detailed procedure.
TEST CHANNEL
OPTICAL TEST
Allows several different internal voltages to be routed to an
analog output port. Useful for diagnosing intermittent faults.
Sets the M200AU into a known state and turns on an LED
near the PMT to test the instrument signal path. See Section
9.1.3.3 for details on using this test.
ELECTRICAL TEST
O3 GEN OVERRIDE
RS-232
Tests just the electronic portion of the PMT signal path. Used
in conjunction with optic test, see Section 9.1.3.2.
This function switches the power to the ozone generator. It
does not indicate the OFF/ON status of the generator
Causes a 1 second burst of data to be transmitted from the RS-
232 port. Used to diagnose RS-232 port problems. See Section
9.1.3.7, 9.3.2 for RS-232 port diagnostic techniques.
9-12
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
9.1.3.1 Signal I/O Diagnostic
Table 9-4: Diagnostic Mode - Signal I/O
No.
Signal
Control
Description
0
DSP_BROWNOUT
NO
Display brownout is used to keep the display from
getting corrupted during low line voltage conditions.
Circuitry on the Status/Temp board senses low line
voltage and sets this bit. The CPU reads this and
generates the BROWNOUT_RST signal described
below.
1
2
EXT_ZERO_CAL
EXT_SPAN_CAL
NO
NO
Shows state of status input bit to cause the M200AU
to enter Zero Calibration mode. Use to check external
contact closure circuitry.
Shows state of status input bit to cause the M200AU
to enter the Span Calibration mode. Use to check
external contact closure circuitry.
3
4
5
6
SPAN_VALVE
CAL_VALVE
YES
YES
YES
YES
Switches the Zero/Span valve. Use this bit to test the
valve function.
Switches the Sample/Cal valve. Use this bit to test
the valve function.
NOX_VALVE
RCELL_HEATER
Switches the NO/NOx valve. Use this bit to test the
valve function.
Shows the status of the reaction cell heater. This has
the same function as the LED in the Power Supply
Module.
7
8
BLOCK_HEATER
ELEC_TEST
YES
YES
Shows the status of the block heater.
Turns on electric test bit on the preamp board. Should
be used for troubleshooting Preamp logic lines. We
recommend you use the ELEC TEST button in the
DIAG menu to operate electric test.
9
OPTIC_TEST
YES
YES
Turns on optic test bit in preamp. Should be used for
troubleshooting Preamp logic lines.
We recommend you use the OPTIC TEST button in
the DIAG menu to operate optic test.
10
BROWNOUT_RST
Brownout reset works in conjunction with
DSP_BROWNOUT. When DSP_BROWNOUT is
set, the CPU sends a signal to reset the display and
clear the DSP_BROWNOUT.
(table continued)
9-13
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
Table 9-4: Diagnostic Mode - Signal I/O (Continued)
No.
Signal
Control
Description
11
CONV_HEATER
YES
Shows the status of the Moly heater. This has the
same function as the LED in the Power Supply
Module.
12
13
O3GEN_STATUS
YES
YES
Switches ON/OFF power to the ozone generator.
PREREACT_VALVE
Switches the Pre-reactor valve. Use this bit to test the
valve function.
14
15
PREAMP_RANGE_HI
ST_RCEL_PRESS
YES
YES
Switches the preamp hardware range. Only the low
range is active in the M200AU
Status Bit - Reaction Cell Pressure alarm
Logic High = pressure out of acceptable range
Logic Low = pressure inside acceptable range
Status Bit - Zero Calibration mode
Logic High = M200AU in Zero cal mode
Logic Low = Not in Zero cal mode
Status Bit - Span Calibration mode
Logic High = M200AU in Span cal mode
Logic Low = Not in Span cal mode
Status Bit - Flow alarm
16
17
18
19
20
21
ST_ZERO_CAL
YES
YES
YES
YES
YES
YES
ST_SPAN_CAL
ST_FLOW_ALARM
ST_TEMP_ALARM
ST_DIAG_MODE
ST_POWER_OK
Logic High = Sample/Ozone flow out of spec
Logic Low = Flows within spec
Status Bit - Temperature alarm
Logic High = Rxcell, Moly, Box temps out of spec
Logic Low = Temps within spec
Status Bit - In Diagnostic mode
Logic High = M200AU in Diagnostic mode
Logic Low = Not in Diag mode
Status Bit - Power OK
Logic High = Instrument power is on
Logic Low = Instrument power is off
(table continued)
9-14
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
Table 9-4: Diagnostic Mode - Signal I/O (Continued)
No.
Signal
Control
Description
22
ST_SYSTEM_OK
YES
Status Bit - System OK
Logic High = No instrument warnings present
Logic Low = 1 or more alarms present
Status Bit - Autorange High Range
23
ST_HIGH_RANGE
YES
Logic High = M200AU in high range of autorange
mode
Logic Low = M200AU in low range of autorange
mode
24
PMT_SIGNAL
NO
Current PMT voltage. Same as PMT voltage in TEST
menu. Bi-polar, typically in 0-5000 mV range. A
constant value of 5000 mV indicates offscale.
25
26
SAMPLE_PRES
RCELL_TEMP
NO
NO
Sample pressure in mV. Typical sea level value =
4300 mV for 29.9" Hg-A.
Reaction Cell temperature. Typically 3500 mV for
50° C.
27
28
29
BOX_TEMP
BLOCK_TEMP
PMT_TEMP
NO
NO
NO
Box Temperature. Typically 1800 mV for 25° C
Block temperature.
PMT cold block temperature. Typically 3600 mV for
10° C.
30
31
DCPS_VOLTAGE
RCELL_PRESS
NO
NO
DC power supply composite voltage output.
Typically 2500 mV.
Reaction Cell Pressure in mV. Typically 1270 mV
for 5" Hg-A at sea level. Is an absolute pressure so
higher values means higher absolute pressures.
32
33
34
OZONE_FLOW
CONV_TEMP
NO
NO
NO
Ozone flowmeter voltage. Typically 2000 mV at
80 cc/min.
Molybdenum Converter temp. Typically 3150 mV at
315° C
HVPS_VOLTAGE
HVPS programming voltage. Output of HVPS is
1000x value present. 700 mV = 700 VDC output.
35
36
DAC_CHAN_0
DAC_CHAN_1
NO
NO
Output of NOx channel in mV.
Output of NO channel in mV.
(table continued)
9-15
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
Table 9-4: Diagnostic Mode - Signal I/O (Continued)
No.
37
Signal
Control
NO
Description
DAC_CHAN_2
DAC_CHAN_3
NOX_CONC
Output of NO2 channel in mV.
Test Channel output.
38
NO
39
YES
NOx DAC programming voltage. The following 4
signals can be set to output specific voltages to each
DAC. Use in conjunction with ANALOG OUTPUT
test to check each DAC output channel. The value
keyed in should appear on the appropriate analog
output channel. This value overrides data being
written from the analyzer. Value reverts to instrument
output when function is exited.
40
41
42
NO_CONC
YES
YES
YES
NO DAC programming voltage. See above for
description.
NO2_CONC
TEST_OUTPUT
NO2 DAC programming voltage. See above for
description.
TEST channel programming voltage. See above for
description.
9.1.3.2 Electric Test
This function injects a constant voltage between the preamplifier and the buffer amplifier on the
preamp board. Electric test checks part of the preamp, the V/F and computer for proper
functioning. The result of electric test should be a smooth quiet signal as shown by constant
values for the NO, NOx concentrations, the NO2 concentration should be near zero. Likewise the
analog outputs should produce a smooth quiet trace on a strip chart.
Procedure:
1.
2.
Scroll the TEST function to PMT.
Press SETUP-MORE-DIAG, then scroll to ELECT TEST by pressing the NEXT button.
When ET appears, press ENTR to turn it on.
3.
The value in PMT should come up to 2000 mV ± 500 mV in less than 15 sec.
If the HVPS or the span gain adjust on the preamp card has been changed without doing the
FACTORY CALIBRATION procedure, the reading in step 3 may be different than 2000
mV, since the overall calibration affects ELECTRIC TEST. See Section 9.1.6 for factory
calibration procedure.
9-16
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
4.
To turn off ET press EXIT
If ET is a steady 2000 ± 500 mV, that means the Power Supply Module, Preamp buffer
amplifier, V/F, CPU, and display are all working properly.
9.1.3.3 Optic Test
Optic test turns on a small LED inside the PMT housing which simulates the signal from the
reaction cell. OT tests the entire signal detection subsystem. By observing the level, noise and
drift of this test, correct operation of many sections of the analyzer can be verified.
The implementation of OT involves several changes to the instrument operating conditions. The
M200AU does the following when switching to optic test:
1.
2.
Saves the current instrument setup as to autorange, indep range, current range and places
the instrument into the 2000 ppb range.
Turns off power to the ozone generator to assure there is no interfering light from the
reaction cell.
3.
4.
Disables the PRE-REACTOR circuit.
Turns on the OT LED.
Procedure:
1.
2.
Scroll the TEST function to PMT.
Press SETUP-MORE-DIAG, then scroll to OPTIC TEST by pressing the NEXT button.
When OT appears, press ENTR to turn it on.
3.
4.
The value in PMT should come up to 2000 mV ±1000 mV in less than 15 sec.
To turn off OT press EXIT.
If the PMT reading observed in step three comes up to the stated value, the instrument is capable
of responding to the light generated by the chemiluminescent reaction. If the instrument passes
OT, but there is absolutely no response to span gas, the most common cause is that the ozone
generator is either broken or is turned off. A second common cause, is that what is thought to be
span gas is actually zero gas.
If the HVPS or the span gain adjust on the preamp card has been changed without doing a
FACTORY CALIBRATE the reading in step 3 may be different than 2000 mV, since the overall
calibration affects OPTIC TEST. See Section 9.1.6 for factory calibration procedure.
9-17
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
9.1.3.4 Ozone Gen Power
This diagnostic manually turns the power off and on to the ozone generator. When the M200AU
is powered up from a cold start the ozone generator is not immediately started. This is due to the
fact that humid air may be present in the generator cartridge. Humid air can produce nitric acid
aerosol which can permanently damage parts of the instrument down stream of the generator.
Using this diagnostic, it is possible to turn on the generator before the warmup time has elapsed.
If you turn the power on it will remain on after you exit the diagnostic.
9.1.3.5 Analog Out Step Test
The Step Test is used to test the functioning of the 4 DAC outputs on the V/F board. The test
consists of stepping each analog output 0-20-40-60-80-100% of the output. If the analog outputs
are set for 0-5V full scale the outputs would step 0-1-2-3-4-5 VDC. The stepping can be halted at
any value by pressing the key under the percentage on the front panel. When the test is halted,
square brackets are placed around the percentage value in the display. Pressing the key again
resumes the test. This test is useful for testing the accuracy/linearity of the analog outputs.
9.1.3.6 DAC Calibration
The Digital to Analog Converters (DAC) are calibrated when the instrument is set up at the
factory. Re-calibration is usually not necessary, but is provided here in case the V/F board needs
to be replaced and re-calibrated. The procedure for doing the DAC Calibration routine is in the
Troubleshooting Section 9.3.3.1.
9.1.3.7 RS-232 Port Test
This test is used to verify the operation of the RS-232 port. It outputs a 1 second burst of the
ASCII letter 'w'. During the test it should be possible to detect the presence of the signal with a
DVM on pin 2 or 3 (depending on the DTE/DCE switch setting) or by the flickering of the red
test LED. A detailed procedure is given in the Troubleshooting Section 9.3.2.
9-18
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
9.1.4 M200AU Internal Variables
The M200AU software contains many adjustable parameters. Most of the parameters are set at
time of manufacture and do not need to be adjusted for the lifetime of the instrument. Some of
the variables are user adjustable, they are listed in Table 9-5.
To access the VARS menu press SETUP-MORE-VARS-ENTR. Use the PREV-NEXT buttons
to select the variable of interest, then press EDIT to examine/change the value, then press ENTR
to save the new value and return to the next higher menu. If no change is required, press EXIT.
TPC_ENABLE
The M200AU has temperature and pressure compensation. T/P comp adjusts the output of the
instrument for changes in sample temperature, reaction cell pressure, and atmospheric pressure.
The temperature of the reaction cell controls the sample temperature. The setpoint is 40° C, and
the value of the adjustment parameter is equal to 1.0000 when the reaction cell temperature is
40° C. The temperature compensation increases sample concentration with increasing
temperature to compensate for the drop in density of gas in the reaction cell.
The reaction cell pressure compensation factor is equal to 1.0000 when the cell pressure is about
3.5"-Hg-A. The compensation factor increases sample concentration with increasing cell
pressure to compensate for increased quenching of the chemilumenscent reaction at higher
pressures.
The sample pressure compensation factor is equal to 1.0 at 29.92"-Hg-A. This factor increases
sample concentration with decreasing sample pressure to compensate for a lower head pressure
on the sample flow orifice.
Taken together, the three factors change the output of the instrument very little. The sample
temperature is essentially invariant, and the cell pressure and sample pressure factors tend to
cancel each other. The resultant coefficient has no practical variation with pressure changes due
to weather fronts. Changes in altitude of 1000 feet usually change the output of the instrument by
about .5% if compensation is turned off, much less if it is operating.
9-19
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
Table 9-5: Model 200AU Variables
Default
Value
Value
Range
No.
Name
Units
Description
0
DAS_HOLD_OFF
Min
15
0-60
Time that data is not put into
DAS after CAL or DIAG
modes
1
MEASURE_MODE
Logic
NONOX
Selects the measurement
mode of the M200AU. NO
measures NO only. NOx
measures NOx only, and
NONOx measures NO, NOx
and NO2, this is the default
mode.
2
3
4
TPC_ENABLE
DYN_ZERO
DYN_SPAN
Logic
Logic
Logic
ON
ON-OFF
ON-OFF
ON-OFF
Temp/Pres compensation
enable
OFF
OFF
Enable zero calibration when
rear panel contacts are closed.
Enable span calibration when
rear panel contacts are closed.
5
6
7
SFLOW_SET
OFLOW_SET
RS232_MODE
cc/min. 1000
cc/min. 80
400-1200
0-500
Nominal sample flow rate
Nominal ozone flow rate
Bit
0
0-99999
Value is SUM of following
decimal numbers:
Field
1=enable quiet mode
2=enable computer mode
4=enable security feature
8=enable front panel RS-232
menus
16=enable alternate protocol
32=enable multidrop protocol
8
CLOCK_ADJ
Sec.
0
Real-time clock speed
adjustment
± 60
9-20
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
9.1.5 Test Channel Analog Output
Many of the TEST functions have an analog voltage associated with them. As a diagnostic aid it
is possible to route the various test voltages out the 4th analog output port. Details on using the
test channel analog output are in the Troubleshooting Section.
Table 9-6: Test Channel Readings
TEST Channel
Minimum*
Maximum*
Description
PMT
DETECTOR
0 mV
5000 mV
PMT detector output from the preamp. This
signal has been amplified and filtered. Since the
instrument is switched and uses AutoZero,
normal values can vary from –100 to 5000 mV.
Wide variations in this signal are normal.
Values should be around 0 mV when sampling
zero air.
OZONE FLOW
0 cc/min
1000 cc/min
This signal is the output from the ozone
flowmeter. Values around 1150 mV indicate
zero flow. Typical values for 80cc/min ozone
flow are around 1800 mV. Voltage should be
steady, indicating stable flow.
SAMPLE
FLOW
0 cc/min
1000 cc/min
40 “-Hg-Abs
The sample flow is calculated from the
upstream pressure as measured by the
SAMPLE PRESSURE transducer.
SAMPLE
PRESSURE
0 “ Hg-Abs
The sample pressure is measured by an absolute
pressure meter. The absolute pressure at sea
level is 29.92”-Hg. The exact reading will vary
a few tenths due to passing weather fronts and
daily temperature cycling. The reading will
decrease about 1”-Hg with each 1000 ft gain in
altitude. For example, the absolute pressure at
10,000-ft (3000 m) is about 20”-Hg-A. A
typical value near sea level would be about
4200 mV.
RCELL
PRESSURE
0 “ Hg-Abs
40 “-Hg-Abs
Like the SAMPLE PRESSURE the RCELL
pressure is an absolute pressure measurement.
With the sample pump off, it should read about
atmospheric pressure. With the pump
operating, a typical value is 1300 mV for about
5”-Hg-A reaction cell pressure.
(table continued)
9-21
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
Table 9-6: Test Channel Readings (Continued)
TEST Channel
Minimum*
Maximum*
Description
RCELL TEMP
0o C
70o C
Reaction Cell temperature is set to 50o C. At the
setpoint, a typical reading is 3600 mV.
BLOCK TEMP
IZS TEMP
0o C
0o C
0o C
0o C
70o C
The Block temperature is set to 50o C. At the
setpoint, a typical reading is 3600 mV.
The IZS temperature is set to 50o C. At the
setpoint, a typical reading is 3600 mV.
The Converter temperature is 315o C. At the
setpoint, a typical voltage is 3150 mV.
70o C
CONV TEMP
PMT TEMP
1000o C
70o C
The PMT temperature is unique in that the
voltage is inverse to the temperature. A typical
reading for 8o C would be 4200 mV.
CHASSIS
TEMP
0o C
70o C
The Chassis (Box) temperature is variable due to
variable ambient air temperature. The Box temp
generally runs about 5o C above the surrounding
air temp. Thus in a 25o C room, the Box temp
would be about 30o C and have a TEST channel
voltage of about 2000 mV.
DCPS
VOLTAGE
0 mV
0 V
5000 mV
5000 V
The DCPS is a composite of several DC power
supply voltages in the instrument. It has been
arbitrarily set at 2500 mV, which is typical.
HVPS
VOLTAGE
The HVPS voltage is a scaled up reading of the
programming voltage going to the HVPS. Zero
to 1000 mV corresponds 0-1000 VDC for the
HVPS, which is the maximum voltage possible.
A typical reading would be 700 mV
corresponding to 700 VDC for the HVPS.
* Minimum and Maximum readings depend on the DAC 3 switch settings of the V/F board. For
the standard ± 5 VDC range, minimum corresponds to 0 VDC and maximum corresponds to
5 VDC.
9-22
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
9.1.6 Factory Calibration Procedure
This procedure is similar to that used at the factory when the instrument is first manufactured, it
balances the PMT, preamp, and software gain factors so the instrument has optimum noise,
linearity, and dynamic range. It should be used when you are unable to zero or span the
instrument, when the slope and offset values are outside of the acceptable range, or when other
more obvious reasons for problems have been eliminated.
Factory Calibration Procedure:
NOTE
In this procedure a range of 500 ppb and a span gas concentration
of 400 ppb is used as an example. Other values can be used.
1.
2.
On the Preamp board, set S1 and S2 to 8. Turn R19 25 turns counter-clockwise, then 12
turns clockwise.
Set RANGE MODE to SNGL by SETUP-RNGE-MODE-SNGL to select single range
operation.
3.
4.
Set the RANGE to 500 ppb by SETUP-RNGE-SET and key in 500, then press ENTR.
Input Zero gas into the sample port, and Scroll to the TEST function labeled PMT.
Typical reading should be less than 50 mV. Readings above 150 mV indicate a pneumatic
leak, light leak, contaminated reaction cell, bad zero gas, or wet air coming into the ozone
generator. If readings are greater than ± 150 mV, the instrument will not zero or span
properly, see Sections 9.2.8, 9.2.9.
5.
6.
Allow the instrument to sample zero gas for at least 20 minutes to re-fill the internal data
filters and Pre-reactor filter with zero readings. Then zero the instrument by CAL-ZERO-
ENTR.
Set the expected span concentration to 400ppb. Enter the expected NOx concentration of
400 ppb by pressing CAL-CONC-NOX. Then press CAL-CONC-NO, to enter the expected
NO concentration of 400 ppb. Then press EXIT to return to the CAL menu.
7.
8.
Input 400 ppb of NO span gas in the sample inlet port.
Scroll to the NORM_PMT - TEST function.
9-23
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
9.
Calculate the expected NORM_PMT mV reading.
Multiply the expected span value by 2 to get the mV reading. In this example the expected
span gas concentration is 400 ppb and therefore the expected voltage is 800 mV. As an
alternate method, the voltage can be determined from the graph in Figure 9-1. On the Y-axis
find the calibration concentration in ppb, then determine the expected voltage from the X-
axis.
10.
11.
Adjust S2, the HVPS coarse adjustment, on the preamp board to the setting that produces
a signal that is closest to 800 mV. Adjust S1, the HVPS fine adjustment, to the setting that
produces a signal that is closest to 800 mV. Use R19 to trim the reading to 800 ± 50 mV. The
readings will periodically go to zero as the Pre-reactor circuit operates, ignore the zero
readings.
Allow the instrument to sample span gas for 30 minutes. Then do a span calibration by
CAL-SPAN-ENTR. After the span is completed, do the span quality check procedure in
Table 7-18. This procedure is extremely important to assure that the instrument will operate
with optimum noise, linearity, and dynamic range.
12. Electric Test (ET) Procedure:
A. To adjust ET press SETUP-MORE-DIAG, then scroll to ELEC TEST and press ENTR.
B. Scroll the TEST functions until PMT is displayed.
C. Adjust R27 until 2000 mV ± 200 is displayed.
D. Press EXIT to return to SAMPLE mode.
13. Optic Test (OT) Procedure:
A. To adjust OT press SETUP-MORE-DIAG, then scroll to OPTIC TEST and press ENTR.
B. Scroll the TEST functions until PMT is displayed.
C. Adjust R25 until 2000 mV ± 250 is displayed.
D. Press EXIT to return to SAMPLE mode.
If this procedure does not produce an instrument that will properly span, please contact your
local distributor or the Teledyne API factory. Teledyne API's phone number is on the front page
of this manual.
9-24
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
Figure 9-1: Span Calibration Voltage
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
9.2 Performance Problems
When the response from a span check is outside the control limits, the cause for the drift should
be determined, and corrective action should be taken. Some of the causes for drift are listed
below:
NOTE
It has been our experience that about 50% of all analyzer performance
problems are sooner or later traced to leaks in some part of the system.
1.
2.
3.
Fluctuations in flow. Such as leaks or plugged orifices.
Lack of preventive maintenance.
Change in zero air source.
A. Air containing NO leaking into zero air line.
B. Saturation of charcoal and/or Purafil scrubbers.
Change in span gas concentration.
4.
A. Zero air or ambient air leaking into span gas line.
B. Permeation tube or cal gas tank exhaustion.
Leak in NO/NOx or Pre-reactor switching valves.
Loose pneumatic fittings.
5.
6.
9.2.1 AC Power Check
1.
Check that power is present at main line power input. Verify that correct voltage and
frequency is present. If unit is set for 240 VAC and is plugged into 115 VAC it will appear as
no power fault.
2.
3.
Check that the unit is plugged into a good socket. Analyzer must have 3-wire safety
power input.
Check circuit breaker. Circuit breaker is part of the front panel power switch. It is set
each time the instrument power is turned on. If there is an internal short causing a trip, the
switch will automatically return to the OFF position when an attempt is made to turn it on.
9-26
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
9.2.2 Flow Check
1.
Check TEST function RCEL - this is the absolute pressure in the reaction cell. It should
be
1-4 in-Hg-A.
2.
3.
4.
Check that pump is running. Check RCEL - TEST function for proper pressure.
Check that pump tubing is connected to rear of analyzer.
Test that the pump is producing vacuum by removing fitting at rear of analyzer and
checking for suction at fitting.
5.
Check for flow upstream of the sample flow orifice and ozone orifice on the valve
assembly.
A. Remove the 1/8" fitting that carries sample. Plug the fitting on the sample flow block
with your finger and note the vacuum produced.
B. Remove the ozone fitting also and compare relative flow rates. Sample should be much
higher (1000 cc/min) than ozone (80 cc/min).
6.
7.
Check for broken flow or pressure sensor.
Leak check the analyzer. See Section 8.7 for leak check procedure.
9.2.3 No Response to Sample Gas
1.
Confirm correct operation of analog output by performing Analog Output Step Test in
Section 9.1.3.5.
2.
Confirm general operation of analyzer.
A. Check for AC Power, Section 9.2.1.
B. Do flow checks, Section 9.2.2.
C. Confirm that sample gas contains NO or NO2.
Check instrument electronics.
3.
A. Do ELEC TEST procedure in DIAGNOSTIC menu Section 9.1.3.2.
B. Do OPTIC TEST procedure in the DIAGNOSTIC menu Section 9.1.3.3.
C. If the M200AU passes ET and OT, that means the instrument is capable of detecting light
and processing the signal to produce a reading. Therefore, the problem is in the
pneumatics or ozone generator.
4.
5.
Check ozone generator subsystem. Do the diagnostic test of the ozone generator
subsystem in Section 9.3.6.
Check for disconnected electrical cables to sensor module.
9-27
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
9.2.4 Negative Output
1. Mis-calibration. The 'zero' gas that was used to zero the M200AU contained some NO gas -
that is, it had more NO gas than that of the sample air. May also be caused by doing a zero
calibration using ambient air. If NO/NOx OFFSET - TEST functions are greater than 150
mV, reaction cell contamination is indicated. Verify quality of zero air used it should have
less than 1 ppt NO and correspondingly low equivalent values of interferent gasses .
2. Corruption of the Pre-reactor filter. If a significant signal was detected during the Pre-reactor
cycle, that higher reading can enter the Pre-reactor filter. The value of the Pre-reactor filter is
subtracted from the current reading, thus producing a negative reading. High Pre-reactor
readings can be caused by:
A. Leaking Pre-reactor valve.
B. Electronic fault in the preamp causing it to have a voltage on the PMT output pin during
the Pre-reactor cycle. Area around the high impedance section of the preamp contains
conductive dirt.
C. Reaction cell contamination causing high background ( >40 mV) light readings.
D. Broken PMT temperature control circuit, or broken PMT cooler power supply - allowing
high zero offset.
After fixing the cause of the high Pre-reactor filter readings, the M200AU will take 15
minutes for the filter to clear itself.
3. Check for leaks.
9.2.5 Excessive Noise
Common reasons for excessive noise are:
1.
2.
3.
4.
Leak in pneumatic system.
Light leak - check the sensor module with strong light.
HVPS noisy - see HVPS test procedure. See Section 9.3.8.5.
Defective electronic components on preamp board. - use optic test and electric test to
check electronics, optics and observe noise.
5.
Contamination of ozone generator and/or reaction cell - This can be wet air or impurities.
This can be detected by high PMT readings with zero air as sample gas. Verify this condition
by turning off the ozone generator using the DIAG mode command and observing a drop in
PMT reading of more than 50 mV or 25 ppb. If the ozone generator or reaction cell is
contaminated, disassemble and clean.
9-28
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
6.
Broken PMT temperature control circuit or broken PMT cooler power supply. Check
PMT TEMP - TEST function.
7.
8.
Mis-calibration. Check NO/NOx SLOPES in TEST function.
Reaction cell pressure too high – leak on vacuum side or bad sample pump. Check RCEL
- TEST function.
9.2.6 Unstable Span
Common causes are:
1.
2.
3.
4.
5.
6.
7.
8.
Leak in pneumatic system.
Light leak - check the sensor module with strong light.
Instrument not fully warmed up.
Sample lines or sample filter dirty - clean or replace.
Plugged sample inlet orifice - clean with methanol and sonic cleaner.
Defective HVPS - see HVPS test procedure.
Bad or defective PMT detector - replace.
Reaction cell temp not stable - observe warning messages, or RCELL TEMP in TEST
functions. Check diagnostic LED in Power Supply Module for normal cycling.
9.
Large variations in ambient temperature - observe warning messages, or BOX TEMP in
TEST functions.
10.
11.
Large variations in line voltage. - Line voltage should remain within ±10% of nominal.
Pump not maintaining steady vacuum - observe warning messages, or RCEL in TEST
functions.
12.
13.
Sample vent line too short, allowing room air to mix with span gas. Line should be a
minimum of 15" long.
Calibration gas source unstable.
9-29
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
9.2.7 Unstable Zero
Common causes are:
1.
2.
3.
4.
5.
Leak in pneumatic system. Perform leak check, see Section 8.7.
Miscalibration. See Table 7-1.
Light leak - check the sensor module with strong light.
Sample lines or sample filter dirty - clean or replace.
PMT temp control unstable
9.2.8 Inability to Span
If the SPAN button is not illuminated when attempting to span, that means the reading is outside
of the software gain ranges allowed. In an analog instrument it would be the equivalent to the
span pot hitting the rotation stop.
Here are some things to check:
1.
Check the expected span concentration values in CAL-CONC-NOX and CAL-CONC-
NO, and compare them to the values of the calibration span gas being input. They should be
nearly equal.
2.
3.
Check the NORM_PMT - TEST function. With NO span gas in the instrument, the value
should be 2x the expected span concentration.
Check ET and OT to verify instrument detector and signal processing is working
correctly.
4.
5.
If the above do not check out, perform the Factory Calibration Procedure Section 9.1.6.
If the PMT voltage is near zero with span gas, check fuse and power to ozone generator.
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
9.2.9 Inability to Zero
If the ZERO button is not illuminated when attempting to zero, that means the reading is outside
of the software gain ranges allowed. In an analog instrument it would be the equivalent to the
zero pot hitting the rotation stop. Check the following:
Select the PMT - TEST function. With zero gas going into the instrument, the value should be
less than 150 mV, typically less than 50 mV. If you are getting a high reading, the probable
reasons are:
1.
The reading may be temporarily high if the PMT has been recently exposed to room
light. If so, let the instrument run for several hours with zero gas to get the PMT accustomed
to low light levels.
2.
3.
4.
Leak that admits gas containing NO into the reaction cell.
Contaminated reaction cell. Remove and clean cell.
Wet (i.e., undried ambient air) air in the ozone generator. Check the PermaPure drier and
associated plumbing for leaks and correct operation.
5.
6.
Zero gas that isn't really zero. Make sure you're not trying to zero the machine with
ambient air or span gas.
Pre-reactor filter is corrupted with high readings. To clear the Pre-reactor filter, input
zero gas and wait for 15 minutes for the filter to clear.
9.2.10 Non-Linear Response
Common causes are:
1.
2.
A leak in the pneumatic system, see Section 8.7.
High zero background - the PMT TEST function should be near 50 mV with zero gas.
Readings above 100 mV indicate a light leak, contaminated reaction cell, bad zero gas, or
wet air coming into the ozone generator. If the reading is not less than 150 mV, the
instrument will not zero or span properly. Check Section 9.2.9.
3.
Calibration device in error - re-check flowrates and concentrations, especially at low
concentrations. If you are using a Mass Flow calibrator and the flow is < 10% of the full
scale flow on either flowmeter you may need to purchase lower concentration standards.
4.
5.
The standard gasses may be mis-labeled as to type or concentration. Labeled
concentrations may be outside the certified tolerance.
Contamination in sample delivery system:
A. Dirt in sample lines or reaction cell
B. Contaminated cal gas source (NO2 in NO cal gas is common)
C. Dilution air contains sample or span gas
9-31
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
6.
Ozone concentration too low
A. Wet air in ozone generator - need to flush out clean, dry
B. Ozone generator driver board failure.
C. Damaged transformer/ozone generator cartridge. The ozone generator cartridge is
partially made of glass. Extreme physical shock, such as dropping the generator on the
floor may cause the glass cartridge to crack and eventually fail.Sample inlet vent line too
short - should be at least 15".
7.
Sample exhaust not properly vented, creating a backpressure at the sample inlet port of
the instrument. See Figure 2-3 for venting recommendations.
9.2.11 Slow Response
1.
Contaminated or dirty sample delivery pneumatics
A. Dirty/plugged sample filter or sample lines
B. Dirty reaction cell
2.
3.
4.
Sample inlet line too long.
Wrong materials in contact with sample - use glass, stainless steel or Teflon
Sample vent line located too far from instrument sample inlet. Locate sample inlet vent
near analyzer.
5.
6.
7.
8.
9.
Insufficient time allowed for purging of lines upstream of analyzer.
Leaking NO/NOx valve.
Insufficient time allowed for NO or NO2 cal gas source to become stable.
Moly converter temperature too low.
Miscalibration, see Table 7-1.
9.2.12 Analog Output Doesn't Agree with Display Concentration
The analog output is proportional to the range. Zero volts output corresponds to zero ppb, and 5
volts corresponds to the maximum range setting in ppb. If this is not observed do the following:
1.
2.
V/F board DAC's out of calibration. Do DAC calibration and Factory Calibration.
Analog outputs electrically loaded down causing voltage to sag. Could be due to input
impedance to chart recorder or data logger being too low or improper grounding. The
Recorder and DAS outputs do not have separate output drivers, the problem could be the
combined load of both could be too high.
9.3 Subsystem Troubleshooting and Adjustments
9.3.1 Computer, Display, Keyboard
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
The purpose of this section is to determine if the computer subsystem electronics hardware are
working properly. Assessment will be made at the board level.
9.3.1.1 Front Panel Display
The front panel display is a 2 line by 40 character display. It has its own microprocessor to
decode commands and display characters. It contains a self test feature. To test the display:
1.
2.
3.
Turn off the power to the instrument.
Fold down the M200AU front panel
Disconnect the 26 line flat ribbon cable (J2) that connects the computer parallel port to
the keyboard.
4.
5.
Turn on the M200AU power switch.
Observe the front panel display. If the display successfully completes its power on self
test, it will display a single underline character "_" in the left most character of the top line of
the display. If this character is present, the display is working properly.
6.
Power down the analyzer, and re-attach the cable to J2, and proceed to the next test.
9.3.1.2 Single Board Computer
The SBC40 is a full function computer designed for instrument control applications. It consists
of a 16 bit V40 microprocessor, 2 serial and one parallel ports, Standard Bus interface, and 4
sockets for memory. The memory sockets consist of: 256k ROM containing the multitasking
operating system and application code, 8k EE prom containing the setup variables, a 128k RAM
and time-of-day clock to provide event timing services, and a second 128k RAM. The overall
function of this board is quite complex, therefore, complete testing is not possible in the field.
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Figure 9-2: CPU Board Jumper Settings
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Like the display, the overall functioning of the CPU can be confirmed by a simple test.
1.
2.
3.
4.
5.
Locate the CPU board on the mother board by referring to Figure 2-5.
Power the instrument on.
Locate the red LED at the top left edge of the board.
It should be flashing at a frequency of about once per second.
This flashing indicates the board is powered up and is executing instructions.
Testing and operation of the CPU RS-232 port is described in Section 9.3.2. It is possible for the
UART driver chip to malfunction in either the input or output port or both.
9.3.1.3 Front Panel Keyboard
The keyboard consists of 8 keys and 3 LED's. Key strokes are sent to the SBC40 computer's
parallel port. The computer software detects the key strokes via interrupts. The bottom line of the
display consists of 40 characters which is divided into 8 - 5 character fields. Each field defines
the function of the key immediately below it. The definition of the keys is variable and depends
on the menu level of the software.
To check the operation of the keyboard, each key should perform an operation indicated by its
current definition shown on the second line of the display.
Example #1 - testing key#1 (left most key).
At the top level menu key #1 is defined as the TEST function. Pressing this key should cause the
middle field of the top line of the display to show the various test functions.
Example #2 - testing key #8 (right most key). At the top level menu key #8 is defined as the
SETUP key. pressing key #8 should cause the SETUP menu to be displayed.
Example #3 - If the 5 character field above any key is blank, the key is not defined, pressing the
key has no effect.
The 3 status LED's indicate several functional states of the instrument such as calibration, fault,
and sample modes. The state of the LED's is controlled by 3 lines on the parallel port of the
SBC40. Functioning of the LED's can be checked by:
1.
2.
3.
Turn off the M200AU power.
While watching the LED's, turn on the instrument power.
When the power comes up, the computer momentarily applies power to all 3 LED's. If all
the LED's are observed to light, they are working properly.
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9.3.2 RS-232 Communications
The M200AU uses the RS-232 communications protocol to allow the instrument to be connected
to a variety of computer based equipment. RS-232 has been used for many years and is well
documented. Generally, every manufacturer observes the signal and timing requirements of the
protocol very carefully. Problems arise when trying to specify connectors, and wiring diagrams
that attach the analyzer to various devices.
9.3.2.1 RS-232 Connection
If the RS-232 port is not working, check the following:
Physical Wiring
First is to get the physical wiring hooked up correctly. Refer to Figure 9-3 for the wiring diagram
of the DB-9 plug on the M200AU rear panel. There are 2 features that make connecting the
wiring easier. First is the red/green LED’s on the rear panel. The M200AU provides the power to
run the red LED, the external equipment will provide the power for the green LED. If the wiring
is hooked up correctly both LED’s will be illuminated. Secondly, there is a DTE-DCE switch,
this switch interchanges pin 2 & 3 on the DB-9 connector. Set the DTE-DCE switch so that both
LED’s are illuminated.
RS-232 Protocol (BAUD rate, Data bits, Parity)
Second is to get the communication protocol for each instrument to match. In Figure 9-3 the
default RS-232 parameters are listed. The BAUD rate can be changed in the software menus
under SETUP-MORE-COMM-BAUD.
Data Communications Software for a PC.
You will need to have a software package to enable the computer to transmit and receive on its
serial port. There are many such programs, we use PROCOMM at Teledyne API. Once you set
up the variables in PROCOMM and your wiring connections are correct, you will be able to
communicate with the analyzer.
If connecting to a modem, check the following:
Modems are especially difficult because they may have pins that need to be at certain EIA RS-
232 levels before the modem will transmit data. The most common requirement is the Ready to
Send (RTS) signal must be at logic high (+5V to +15V) before the modem will transmit. The
Teledyne API analyzer sets pin 8 (RTS) to 10 volts to enable modem transmission.
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To troubleshoot a modem connection first disconnect the RS-232 cable from the Analyzer and
verify (use a DVM) that you are getting a signal on Pin 2 of the RS232 port on the Analyzer. The
signal will be between -5V and -15V with respect to signal ground (pin 5). If not, there is a
problem with the CPU board or the cable. This is the transmit (TD) signal out of the Analyzer.
This should then be connected to TD input on the modem, normally Pin 2. If the Analyzer is
equipped with a DTE/DCE switch, you may need to change its setting so the signal is on Pin 2.
Second: Go to the cable connected to the modem/terminal and verify (use a DVM) that you are
getting a -5V to -15V signal on Pin 3 of the cable. This pin should be connected to Pin 3 of the
Teledyne API Analyzer.
Third: (for modems) Check that the voltage level on Pin 8 of the Analyzer is between +5V and
+15V. This pin should be connected (through the cable) to Pin 4 of the modem.
Now set the baud rate of the Analyzer to the speed required by the modem and it should work. If
you are still experiencing problems, a cable adapter may be needed. Please contact the factory
for assistance.
9.3.2.2 RS-232 Diagnostic Procedures
There are several features of the M200AU to make connecting to RS-232 and diagnosing RS-
232 faults easier.
There are two LED's on the rear panel Connector Board which are connected to pin 2 and 3 of
the DB-9 connector on the board. If the switch is in the DCE position (default) the red LED is
connected to pin 3 of the DB-9 connector. When data is transmitted by the M200AU the red
LED will flicker, indicating data present on this line. When the M200AU is running, the LED
will normally be ON, indicating logic low. A one second burst of data can be transmitted over
the port by a command in the DIAGNOSTIC menu. Press SETUP-MORE-DIAG, then scroll to
RS232 OUTPUT. Each time you press ENTR the instrument transmits a 1 sec burst of lower
case "w"'s.
The green LED is connected to pin 2, if the switch is in the default DCE position. This is the pin
on which the M200AU receives data. The LED is ON if an outside device is connected. This
LED gets its power from the outside device. When data is being transmitted by the outside
device to the M200AU this LED will flicker.
When you are attempting to configure the RS-232 port, if either of the LED's go out when the
cable is connected, that generally means that there is a grounding problem. Switching the DCE-
DTE switch should fix the problem. See the schematic and assembly drawings in the Appendix.
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Figure 9-3: RS-232 PIN Assignments
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9.3.3 Voltage/Frequency (V/F) Board
The V/F Board consists of 16 analog input channels, each software addressable, 8 digital inputs,
and 24 digital outputs, each line independently addressable, and 4 independent analog output
channels. The analog input channels are connected to V/F converter capable of 80,000 counts,
which is approximately 16 bit resolution. The integration period is software selectable from
40msec to 2.4 sec. Commands from the SBC40 computer and digitized values from the V/F
section of the board are sent via the STD bus interface. The schematic for the board is in the
Appendix.
The overall operation of this board is quite complex. To fully check it out in all of its operational
modes is not possible in the field. Therefore, a few simple tests are described here that test one
analog input channel, the 4 analog output channels, one digital input, and one digital output.
1.
V/F board analog input test.
Each analog channel is routed through a programmable 16 channel multiplexer. Chances are
that if one channel works, they all work.
A. Turn on instrument.
B. Press TEST key on front panel keyboard until DCPS test is displayed.
C. The value displayed should read 2500 ± 200 mV.
If the M200AU passes this test, it has successfully digitized a 2500 mV composite voltage
output from the Power Supply Module. The signal should also be quiet ±25 mV.
2. Analog output channel test.
In the DIAGNOSTIC menu on the front panel, there is a test that outputs a step voltage to the
4 analog outputs. This test is useful for calibrating chart recorders and dataloggers attached
to the M200AU. The test can also be useful in diagnosing faults in the V/F board.
A. Turn on the instrument.
B. Enter the SETUP-MORE-DIAG-ENTR menu.
3.
Select the ANALOG OUTPUT test. This causes the M200AU to output a 5 step voltage
pattern to the 4 analog outputs on the rear panel. The status of the test is shown on the front
panel display. The scrolling can be stopped at any voltage by pressing the key below the
changing percentage display. The values are 0-20-40-60-80-100% of whatever voltage range
has been selected. For example the voltages would be 0, 1, 2, 3, 4, 5V if the 5V range had
been selected.
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4.
Use a DVM on each of the analog output channels to confirm the correct voltages.
If the voltages step, but are the wrong values, the V/F board may be set up wrong or out of
calibration. See Section 9.3.3.1 for information on how to calibrate the V/F board.
5.
Digital input channel test.
The digital I/O section of the V/F board has 8 input bits and 24 output bits. Two of the 8
input bits are assigned as calibration controls. See Section 7.5 for information on calibration
using external contact closures.
To test the digital inputs:
A. Turn on the M200AU.
B. Connect a jumper wire across pins 1 and 2 of the rear panel connector as shown in
Figure 2-2.
C. Shortly after closure is made the instrument should switch into zero mode as indicated on
the front panel display.
D. Remove the jumper.
Digital output channel test.
6.
There are 24 output bits on the V/F board. The 24 bits are made up of 3 - 8 bit ports. It is
possible for a single 8 bit port or even a single bit within a port to fail.
A quick observational test of the digital outputs is to observe the LED's in the Power Supply
Module(Refer to Figure 9-5 for the location of the LED's in the PSM) The state of the LED's
can be checked from Table 4-1. The comments section assumes the M200AU has been
running for at least 45 minutes.
A more detailed test is in the DIAGNOSTIC menu. See Diagnostic tests in Section 9.1.3.
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
9.3.3.1 ADC/DAC Calibration Procedure
Due to the stability of modern electronics, this procedure should only need to be performed if a
major sub-assembly is exchanged or when the display voltage does not match the input voltage
or current to the V/F card. After completion, a Factory Calibration Procedure should be
performed, see Section 9.1.6.
Before the actual calibration is performed, switches on the V/F card must be correctly set and
jumpers set on the motherboard. Jumper and switch setting changes must be performed with
the instrument power OFF.
Motherboard Jumpers
The motherboard contains 4 pairs of jumpers JP1 - JP8, one pair for each analog output channel.
Each channel can be configured for either voltage or current output. Use Table 9-7 to configure
the jumpers.
Table 9-7: Motherboard Jumper Settings
Terminal Pair
Rear panel
Jumper
Pair
Jumper Setting for
Voltage Mode
Jumper Setting
for Current Mode
Analog output
DAC 0 - NOx
DAC 1 - NO
DAC 2 - NO2
DAC 3 - TEST
3-4
5-6
1-2
7-8
JP3 - JP4
JP1 - JP2
JP5 - JP6
JP7 - JP8
B-C
B-C
B-C
B-C
A-B
A-B
A-B
A-B
V/F Board Switch Settings
There are 2 different types of current outputs, Non-Isolated and Isolated. Each requires a different switch
setting shown below. If you are operating the instrument in voltage output mode, the switches should be
set to the desired voltage range.
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Table 9-8: V/F Board Switch Settings
DAC #
Sw 1
ON*
ON*
ON*
ON*
Sw 2
Sw 3
Sw 4
Sw 5
Sw 6
Sw 7
0
1
2
3
OFF*
OFF*
OFF*
OFF*
OFF*
OFF*
OFF*
OFF*
*Required settings
10 V output or non-isolated current loop
Switch
State
ON
Comment
3
4
5
6
Use for non-isolated current loop or 10 V output
Use for non-isolated current loop or 10 V output
Use for non-isolated current loop or 10 V output
Use for non-isolated current loop or 10 V output
OFF
OFF
OFF
5 V output or isolated current loop
Switch
State
OFF
ON
Comment
3
4
5
6
Use for isolated current loop or 5 V output
Use for isolated current loop or 5 V output
Use for isolated current loop or 5 V output
Use for isolated current loop or 5 V output
OFF
OFF
1 V output
Switch
State
OFF
OFF
ON
Comment
3
4
5
6
Use for 1 V output
Use for 1 V output
Use for 1 V output
Use for 1 V output
OFF
100 mV output
Switch
State
OFF
OFF
OFF
ON
Comment
3
4
5
6
Use for 100 mV output
Use for 100 mV output
Use for 100 mV output
Use for 100 mV output
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1.
After the switches and jumpers are set, turn on instrument power and complete the
following:
A. Press SETUP-MORE-DIAG, then press ENTR. Scroll to D/A CALIBRATION, press
ENTR.
Press ADC to select the first task, which is to calibrate the A/D converter.
B. Connect a DVM ground lead to TP3-AGND on the V/F board. Connect the positive lead
to TP9-DAC0.
C. The M200AU will display a voltage near 1% of the voltage range set in the above
procedure. See Figure 9-4 for a table of approximate expected voltages. Adjust R27 until
the displayed voltage matches the DVM voltage, then press ENTR.
D. The M200AU will display a voltage near 90% of the voltage range set in the above
procedure. Adjust R31 until the displayed voltage matches the DVM voltage, then press
ENTR. This step calibrates the instrument A/D converter to the external DVM.
E. The M200AU will automatically scroll through the DAC output channels, calibrating
each one. The display will update the progress of the calibration. If operating all analog
outputs in voltage mode this completes the calibration procedure.
The calibration of each channel can be checked or recalibrated independently by scrolling the
PREV-NEXT buttons and pressing CAL for the desired channel. Also, a DC offset bias can be
entered by pressing the OFFSET button for the appropriate channel.
Calibrating a channel for current loop operation:
1.
BEFORE STARTING, make sure that hardware settings are correct as shown in Table 9-
6 and Table 9-7.
2.
3.
Calibrate the A/D converter as described in item 2 above, if necessary.
Connect a 250 ohm resistor in series with a current meter to the correct pair of terminals
on the rear panel, see Figure 2-2 for terminal assignments.
4.
In the D/A calibration Menu press CFG, then use PREV-NEXT to select the channel to
be calibrated.
5.
6.
7.
8.
Press the SET button to select CURR for current loop operation, then press ENTR.
To enter the calibration routine press CAL.
To calibrate the 4 mA zero point, press the UP-UP10 - DN-DN10, then press ENTR.
The M200AU will then output 20 mA. Press the UP-UP10 - DN-DN10 buttons to
calibrate the span point, then press ENTR.
9.
Repeat steps 2-6 for each channel that needs to be calibrated.
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Figure 9-4: V/F Board Settings
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9.3.3.2 Changing Output Voltage Ranges
Several different output voltage ranges can be selected by switches on the V/F board. See Figure
9-4 for the switch settings.
9.3.4 Status/Temp Board
The Status/Temp Board is a multi-function board that:
1.
2.
3.
4.
5.
6.
Converts the resistance readings of the thermistors to voltages
Conditions the thermocouple voltage for the V/F card
Provides status output circuitry
Provides circuitry for contact closure inputs
Provides circuitry for display brown-out/reset at low line voltage
Provides chip carriers for voltage-to-current modules
9.3.4.1 Temperature Amplifier Section
The Status/Temp board is a multi-function board consisting of 4 thermistor amplifiers that
monitor:
1.
2.
3.
4.
IZS temperature (not available on the M200AU)
Reaction Cell temperature
Box temperature
Spare
All 4 amplifiers have a single gain control - R34. If necessary, you can adjust the temperature
values by selecting the BOX TEMP - TEST function and adjusting R34 until the correct box
temp is shown. Remember that the temperature inside the case runs several degrees higher than
room temperature, which should be taken into account when setting BOX TEMP.
The voltages of the thermistor and thermocouple amplifier outputs are brought out to test points
on the edge of the board. Refer to the Status/Temp board schematic for details. The voltages can
also be read using the DIAGNOSTIC - SIGNAL I/O feature. See Table 9-4 for details.
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In addition there is a thermocouple amplifier for the Moly converter.
Thermistor Temperature Amplifier Adjustments
If the temperature readouts are in error:
1.
Locate the Box temp thermistor on the board and place a calibrated thermometer near the
thermistor.
2.
3.
Select the BOX TEMP - TEST function on the front panel.
Adjust R34 until the front panel readout matches the thermometer readout. This will
cause all of the readouts to accurately measure their respective temperatures.
Molybdenum Converter Thermocouple Amplifier Adjustments
The molybdenum converter temperature is sensed by a thermocouple. The cold junction
compensation and signal conditioning is done on the Temp/Status board.
The buffer amplifier from the thermocouple amplifier to the CPU for the Moly temperature has a
gain adjustment. The voltage times 100 at pins 8-9 of U1 is the Moly temperature in degrees C.
For example 3.15 VDC at pin 9 of U1 is 315o C. The CPU is programmed to always drive the
temp to 315° C, so the voltage at U1 must be used as the absolute reference as to the correct
temperature. The temperature will vary ± 3 degrees due to the operation of the temperature
control loop in the CPU.
The R6 pot on the Status/Temp board can adjust the temperature. To adjust the molybdenum
converter temperature:
1.
2.
3.
Select the CONV TEMP - TEST function on the front panel.
Wait until the converter is up to temperature, usually 30-45 min after a cold start.
Adjust R6 until the voltage at pin 8-9 of U1 is 3.15 VDC. The CONV TEMP - TEST
function will then read 315° C.
4.
Recheck the temperature 15 min later and re-adjust if necessary.
9.3.4.2 Display Brownout
During low AC line conditions the display can lock up due to insufficient voltage. When low
line conditions are approaching, this circuit senses the condition by monitoring the un-regulated
+5 VDC in the Power Supply Module. If brownout conditions are met, the DISP_BROWNOUT
line is asserted and the CPU sends a hardware RESET command to the display and sends a
BRNOUT RESET pulse back to U4. Brownout conditions will be noticed by the display flashing
every 8 seconds.
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9.3.4.3 Status Output Lines, External Contact Closures
The Status lines consist of 2 active input lines, and 12 active output lines. Additional circuits are
present on the board but currently unused. Individual lines are set or cleared under CPU control
depending on the assigned alarm condition. The CPU also monitors the 2 input lines for remote
calibration commands. The status inputs and outputs are terminated at the rear panel, see Rear
Panel Connector Board schematic diagram in the Appendix.
The output lines are opto-coupled NPN transistors which can pass 50 ma max of direct current
with a voltage of 30 VDC max.
The input lines are optically coupled with inputs pulled up to +5 VDC. External contacts can be
contact closures or open collector transistor contacts. DO NOT apply any voltage, since +5 VDC
is supplied internally.
Individual status lines can be set or cleared using the DIAGNOSTIC mode SIGNAL I/O. This
can be useful for simulating fault conditions in the analyzer to see if external circuitry is working
correctly. See Table 5-9 for pin assignments.
9.3.4.4 4-20 mA Current Output
4-20 mA current loop option replaces the voltage output of the instrument with an isolated 4-20
mA current output. The current outputs come out on the same terminals that were used for
voltage outputs, see Figure 2-2. It is programmable for 4-20mA or 0-20mA and has a 1500 V
common mode voltage isolation and 240 V RMS normal mode voltage protection.
Vloop = 28V max which is sufficient to drive up to a 1000 ohm load.
9.3.5 Power Supply Module
The Power Supply Module consists of several subassemblies described in Table 9-9.
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Table 9-9: Power Supply Module Subassemblies
Module
Description
Linear Power Supply
Board
The linear power supply board takes multiple voltage inputs from the
power transformer and produces +5, +15, -15, +12 VDC outputs. The
outputs are routed to two external connectors, P2 and P3. See
Figure 9-5. The +5 is used for operating the CPU. The ± 15 is used in
several locations for running op-amps and IC's. The +12 is used for
operating fans and valves.
Switching Power Supply
Switch Board
The switching power supply supplies +15 VDC at 4 A to the PMT
cooler control on the Sensor Module. The output is made available
through J10 on the Switch Board. There is a load resistor on the
Switch Board to keep the output stable when little current is required
from the supply.
The Switch Board has many different functions. It takes logic signals
from the V/F board and uses them to switch 4-115 VAC and 4-12VDC
loads. The board also contains the instrument central grounding tie
point. It routes unswitched AC and DC power as needed. Connector J2
programs the power transformers to take 115, 220, and 240 VAC
inputs
Power Transformers
There are potentially 2 input power transformers in the instrument. The
multi-tap transformer T1 is in every M200AU and supplies input
power for the Linear Power Supply board described above. A second
transformer T2 is added if 220 or 240 VAC input is required. Input
power selection is done via a programming connector P2 which
provides the proper connections for either foreign or domestic power.
Circuit Breaker/Power
Switch
The front panel contains a combination circuit breaker - input power
switch. It is connected to the PSM through J6 on the Switch Board. If
an overload is detected the switch goes to the OFF position. Switching
the power back on resets the breaker also.
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Figure 9-5: Power Supply Module Layout
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Figure 9-6: Electrical Block Diagram
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PSM Diagnostic Procedures
The Linear Power Supply board can be tested by checking the DCPS - TEST function on the
front panel. It should read 2500 mV ± 200 mV. If the value is outside this range, individual
output voltages can be tested on connector P3, see Schematic in the Appendix for pinouts.
The Switching Power Supply output can be tested by observing the temperature of the PMT cold
block using the PMT TEMP - TEST function. The temperature should be constant –5 ± 2°C. The
output voltage can be observed on J10 of the Switch Board. It should be 15 VDC ± 0.5.
The Switch Board can be tested by observing the diagnostic LEDS along the top edge of the
board. The following Table 9-10 describes the typical operation of each LED.
Table 9-10: Power Supply Module LED Operation
No.
Function
Description
1.
NO/NOx Valve
Should switch about every 5 sec.
On(click sound) = NOx mode
Off(thud sound) = NO mode
2.
Zero/Span Valve
Should switch ON when CALZ or CALS button is
pressed.
3.
4.
Sample/Cal Valve
Pre-reactor Valve
Should switch ON when CALS button is pressed.
ON when M200AU in Pre-reactor mode. Happens once
every 6 NO/NOx cycles or about once per minute.
5.
Ozone Generator Power
Ozone generator power is controlled by:
1. Molybdenum converter temp
2. Time since last power-up
The ozone generator will be on if:
1. Moly temp is < 100 C and its been more than 30 min
since power up.
2. Moly temp between 100-250 C and its been more than
10 min since power up.
3. Moly temp > 250 C
6.
7.
8.
Sample flow control block
heater
Should cycle ON-OFF every 20 sec to 2 min. On
continuously until up to temp.
Converter Heater
Should cycle ON-OFF every 20 sec to 2 min. On
continuously until up to temp.
Reaction Cell Heater
Should cycle ON-OFF every 20 sec to 2 min. On
continuously until up to temp.
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9.3.6 Ozone Generator
CAUTION - DANGER
Lethal voltages present inside Ozone Generator Turn
off instrument before servicing. Unplug Generator
before dis-assembling.
The ozone generator subsystem consists of a permeation drier, flowmeter, power supply -
generator module, and power switch. The location of the components is illustrated in Figure 9-7.
Ozone is generated by drying ambient air, passing the air between two electrodes that have a
large oscillating electric field generated by a high voltage transformer.
Common faults in the ozone generator are:
1.
A leak or some other failure in the drier will let ambient air into the generator. There is
enough water vapor in room air to cause the generator to make nitric acid aerosol. It is very
corrosive and causes the generator cartridge to short out due to salt build-up. This reduces
the ozone concentration generated which can cause the analyzer to be non-linear due to
insufficient ozone concentration.
2.
3.
Contaminated ozone generator cartridge. Salts and oxgenated hydrocarbons can be
removed by rinsing with 10% nitric acid at 50° C, followed by de-ionized water rinse, then
dry air purge.
Shorts, open circuits, arcing. Because of the very high voltages, the glass ozone generator
cartridge may crack and cause an internal arc or short circuit. Measure the voltage between
TP-4 and TP-5 on the Ozone Generator Driver Board. The voltage should be 0.045 ± .005
VDC, indicating that the drive current is about .45 A. If the value is either zero or
significantly greater than 0.45, the ozone generator is faulty.
9-52
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Table 9-11: Ozone Generator Control Conditions
Ozone
Generator
Condition
Description
1
2
3
OFF
ON
Manual override off (SETUP-MORE-DIAG-OZONE GEN).
Manual override on.
Ozone flow below low warning limit for 5 minutes (OFLOW_SET
OFF
setup variable, typically <40 cc/min).
4
5
Instrument powered on for more than 30 minutes.
ON
ON
Instrument powered off for less than 1 hour and ozone generator was
on when instrument was powered off.
6
Ozone flow above low warning limit for 0.5 minutes and condition 4
ON
or 5 is true.
NOTE
The ozone generator is independently controlled in the SIGNAL I/O, OPTIC
TEST, and ELECTRICAL TEST diagnostics. After exiting these diagnostics,
the ozone generator is restored to the state specified by the above conditions.
9.3.6.1 PermaPure Drier
The PermaPure drier is constructed of 2 concentric tubes. The inner tube is a special material
that has an affinity for water vapor. The outer annulus is evacuated by the instrument pump. This
creates a concentration gradient causing water in ambient air to diffuse into the outer annulus,
thus the air in the inner tube becomes progressively drier as it progresses down the tube.
Due to the large number of connections and fittings on the drier, the most common drier fault is
leaks. Before proceding with any other procedures check the drier for leaks.
Occasionally the drier gets contaminated. The manufacturer of the drier recommends replacing
the drier rather than trying to clean it. If cleaning is chosen, the following options are available:
1.
Dirt - Clean any solids from dryer inlet by brushing. Use clean dry air to blow any loose
particles from the inlet. Deionized water or dilute(5-10% conc HCl in deionized water)
hydrochloric acid can be passed through the dryer. This should be done only with the dryer
and HCl at room temperature.
2.
3.
Organic liquids and freons - Rinse the inner and outer tubes using 1,1,1 trichlorethane.
Follow the solvent with dry air to purge the solvent.
Inorganic salts and oxgenated hydrocarbons can be removed by rinsing with 10% nitric
acid at 50° C.
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Figure 9-7: Ozone Generator Subsystem
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9.3.7 Flow/Pressure Sensor
The flow/pressure sensor board consists of 2 pressure sensors and a flow sensor. See Figure 9-8
for a diagram of this board. From these three sensors four values are computed and displayed on
the front panel TEST functions. They are:
1.
2.
3.
4.
Ozone flow - measured directly - S3, R3
Reaction Cell Pressure - measured directly - S2, R2
Sample gas pressure - measured directly S1, R1
Sample Flow - computed from sample pressure and reaction cell pressure S1, S2
The above pressures and flows are filtered to produce the front panel readings. There is a small
delay after adjustment for a steady reading when observing the TEST functions.
To adjust the OZONE flow:
1.
Go to DIAG mode by pressing SETUP-MORE-DIAG, then select SIGNAL I/O, and
press ENTR. Select OZONE_FLOW by using NEXT-PREV keys.
2.
3.
Adjust R3 so that OZONE_FLOW reads 2000 mV. This is the coarse adjustment.
Press EXIT to return to the SAMPLE mode. Select the OZONE FL - TEST function. Use
a calibrated flow measuring device to make small adjustments in R3 to dial in correct flow.
To adjust the SAMPLE PRESSURE:
1.
Go to DIAG mode by pressing SETUP-MORE-DIAG, then select SIGNAL I/O, and
press ENTR. Select SAMPLE_PRESS by using NEXT-PREV keys.
2.
3.
Adjust R1 to read 4100 mV, which will give approximately the correct pressure.
Press EXIT to return to the SAMPLE mode. Select SAMP - TEST function. Use a
calibrated absolute pressure meter to make small adjustments to R1 until the correct absolute
pressure is displayed. 29.92 in-Hg-A is the target value at sea level. The rate of decrease is
about 1"-Hg per 1000 ft of altitude.
To adjust the REACTION CELL PRESSURE:
1.
Go to DIAG mode by pressing SETUP-MORE-DIAG, then select SIGNAL I/O, and
press ENTR. Select RCELL_PRESS by using the NEXT-PREV keys.
2.
3.
Adjust R2 to read 1450 mV, which will give approximately the correct pressure.
Press EXIT to return to the SAMPLE mode. Select RCEL - TEST function. Use a
calibrated absolute pressure meter to make small adjustments to R2 until the correct absolute
pressure is displayed. The target value is about 5 in-Hg-A for the external Thomas pump in
good condition at sea level.
9-55
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To adjust the SAMPLE FLOW
1.
2.
In SAMPLE mode, scroll the TEST functions to SAMP FLW. Observe the reading. Then
subtract the observed reading from the desired reading.
Go to the VARS menu by SETUP-MORE-VARS, then pressing ENTR. Scroll to
SFLOW_SET and press EDIT. The first value displayed is the SFLOW_SET:VALUE
reading, ADD the value from step 1 to the reading shown and key in the new reading, then
press ENTR. Check the low and high warning limits which are displayed as the next 2 values
to make sure the new value does not exceed the warning limits. Press exit to return to
SAMPLE mode.
3.
Observe the SAMP FLW value. If necessary, repeat step 2 to adjust the reading again to
match the desired flow rate.
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Figure 9-8: Flow/Pressure Sensor
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
Figure 9-9: NOx Sensor Module
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Figure 9-10: NOx Sensor Module
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9.3.8 NOx Sensor Module
Figure 9-9 and Figure 9-10 show the assembly of the NOx sensor module.
9.3.8.1 PMT
The PMT detects the light emitted by the reaction of NO with ozone. It has a gain of about
500,000 to 1,000,000. It is not possible to test the detector outside of the instrument in the field.
The best way to determine if the PMT is working is by using Optic Test. OT operation is
described in Section 9.1.3.3.
The basic method to diagnose a PMT fault is to eliminate the other components using ET, OT
and specific tests for other sub-assemblies.
9.3.8.2 Reaction Cell Temp
The CPU controls the reaction cell temperature. It operates by reading a thermistor amplifier on
the Status/Temp board. The CPU controls the temperature by toggling a bit on the V/F board.
The V/F board TTL logic controls a solid state switch on the switch board in the PSM. The
switched 115VAC comes out of the PSM to a connector near the underside of the reaction cell.
A warning message may be present during initial warm-up or if the connector is not plugged in
after cleaning the reaction cell.
9.3.8.3 Preamp Board
The NOx Preamp Board is a multi-function board providing circuitry to support the following
functions.
1.
2.
Preamp, buffer amplifier, physical range control hardware for the PMT detector.
Precision voltage reference and voltage generation, and control for the PMT - HVPS
inside the sensor module.
3.
4.
5.
Constant current generator and adjustment for the Optic Test LED.
Voltage generation and adjustment for Electric Test.
Thermistor amplifier, control signal generation for the PMT cooler.
The setup and adjustment of items 1-4 above is covered in the Factory Calibration procedure in
Section 9.1.6. Item 5 has no adjustable features.
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Figure 9-11: PMT Cooler Subsystem
9-61
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9.3.8.4 PMT Cooler
The PMT cooler uses a Peltier cooler supplied with DC current from the switching power supply
in the Power Supply Module. An overall view is shown in Figure 9-9. A proportional
temperature controller located on the Preamp board controls the temperature. Voltages applied to
the cooler element vary from .1 to 12 VDC. The input voltage from the supply is 15 VDC. The
actual -5° C setpoint will vary ± 1° C due to component tolerances. The temperature will be
maintained within 0.1° C about the setpoint. If the temperature fails to drop after a few minutes,
there is a problem in the cooler circuit. If the control circuit on the Preamp card is faulty a
temperature of -10° C is reported.
9.3.8.5 High Voltage P.S.
The HVPS is located in the interior of the Sensor Module, and is plugged into the PMT tube. It
requires 2 voltage inputs. The first is +15 VDC, which powers the supply. The second is the
programming voltage, which is generated on the Preamp Board. This power supply is unlike a
traditional PMT HVPS. It is like having 10 independent power supplies, one to each pin of the
PMT. The test procedure below allows you to test each supply.
Adjustment of the HVPS is covered in the Factory Calibration Procedure in Section 9.1.6. To
troubleshoot the HVPS:
1.
2.
Turn off the instrument.
Remove the cover and disconnect the 2 connectors at the front of the NOx Sensor
Module.
3.
4.
Remove the end cap from the sensor.
Remove the HVPS/PMT assembly from the cold block inside the sensor. Un-plug the
PMT tube.
5.
6.
7.
Re-connect the 7 pin connector to the Sensor end cap, and power-up the instrument.
Use Figure 9-12 to check the voltages at each pin of the supply, and the overall voltage.
Turn off the instrument power, and re-connect the PMT tube, then re-assemble the
sensor.
If any faults are found in the test, you must obtain a new HVPS as there are no user serviceable
parts inside the supply.
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Figure 9-12: High Voltage Power Supply
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9.3.9 Z/S Valves
Before troubleshooting this sub-assembly, check that the Z/S valve option was ordered, and that
they are enabled in the software.
Section 6.3 shows how the Z/S valves should be set-up, and how to use them with the AutoCal
and Dynamic Cal features.
Check for the Z/S valves:
1.
2.
Check for the physical presence of the valves. See Figure 2-5 for the Z/S Valve location.
Check front panel for option presence. The front panel should display CALS and CALZ
buttons when the instrument is in SAMPLE mode. The presence of the buttons indicates that
the option has been enabled in software.
Troubleshooting the Z/S valves.
1.
It is possible to manually toggle each of the valves in the DIAGNOSTIC mode. Refer to
Section 9.1.3 for information on using the DIAG mode. Also refer to Figure 8-5, Figure 8-6
and Figure 8-7 for a pneumatic diagram of the system.
9-64
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9.3.10 Pneumatic System
The pneumatic system is diagramed in Figure 8-5, Figure 8-6 and Figure 8-7.
9.3.10.1 Leak Check
CAUTION
When doing a leak check do not pressurize
the M200AU to greater than 15psi.
Damage to internal components will
occur at higher pressures.
The basic cause of many performance problems is a leak. Refer to Section 8.7 for the leak check
procedure.
9.3.10.2 Sample Pump Diagnostic Procedures
The sample pump is capable of maintaining the reaction cell pressure at 3-4”Hg-A. If higher
pressures are noted, the pump may need servicing. Check the pump, inlet fittings, and analyzer
for leaks first. If other causes have been eliminated, rebuild the pump.
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INTENTIONALLY BLANK
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
10 M200AU SPARE PARTS LIST
NOTE
Use of replacement parts other than those supplied by Teledyne API may
result in non-compliance with European Standard EN 61010-1.
Table 10-1: Teledyne API M200AU Spare Parts List
Part No.
025690000
000940400
000941000
002270100
002730000
002761010
003690000
003690100
005140300
007280000
009690000
009690100
010680100
010860000
011310000
011980000
012360000
013140000
013570000
014080100
014610000
016810000
018720000
019300000
(table continued)
Description
Teledyne API Model 200AU Spare Parts List
Orifice, 4 mil, 80 cc, Rx Cell (844-012600)
Orifice, 13 mil 1000 cc, Rx Cell
Gasket (Rx Cell) Qty. 12
Window 665 NM (002-013100)
CPU Board 200AU AMX)
Filter, TFE, 37 mm, Qty. 100 (872-006400)
Filter, TFE, 37 mm, Qty. 25 (872-006300)
V/F Board
NEW Display
Filter, TFE, 47 mm, Qty. 100
Filter, TFE, 47 mm, Qty. 25
Heater, MOLY Converter
Status/Temperature Board
Drier Assembly Complete with Flow Control
Assembly, MOLY Thermocouple
Fan, Power Supply Module
Fan, PMT Cooler
Thermistor Assembly (Cooler)
Assembly, High Voltage Power Supply
Cooler Assembly
O3 Generator Assembly W/ 01668E Driver Board
Molybdenum converter with O3 Scrubber
Keyboard
10-1
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
Table 10-1: Teledyne API M200AU Spare Parts List (Continued)
Part No.
Description
021070000
022220000
FL0000001
FL0000003
FM0000004
HE0000017
HW0000020
HW0000036
KIT000028
KIT000029
KIT000029
OR0000001
OR0000002
OR0000034
OR0000042
OR0000044
OR0000058
PS0000010
025690000
PU0000028
PU0000030
RL0000008
RL0000015
SW0000006
SW0000008
VA0000024
022300000
022930000
023180000
DR0000002
PMT Pre-amplifier Board Assembly
15 Vdc, 4A Switching Power Supply
Sintered Filter (002-024900)
Filter, DFU (036-040180)
Flow Meter, 0-1000 cc
Heater, Reaction Cell, 12W
Spring, Flow Control
TFE Thread Tape (48 FT)
Retrofit , 37mm Retaining Ring, Sample Filter
Retrofit , 47mm Retaining Ring, Sample Filter
Retrofit , 47mm Retaining Ring, Sample Filter
Tubing: 6’, 1/8” CLR
O-Ring, Bearing, Cell
O-Ring, Input/Output Mirror/Detector
O-Ring, Sensor Assembly
O-Ring, Reaction Cell
O-Ring, Sample Filter
15V Switching Power Supply
Teledyne API Model 200AU Spare Parts List
Pump, 115V/60Hz, M200AU
Pump Rebuild Kit, M200AU
Solid State Relay, 12 Vdc
Solid State Relay, 115 Vac
Overheat SW, Cell/Oven
Pressure Sensor
Manifold Valve, 3-Way, Vent
DC Power Supply Board
Instruction Manual for M200AU
M200AU Expendables Kit
PMT Desciccant Baggies
10-2
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
Table 10-2: Teledyne API MODEL 200AU Expendable Kit
Part No.
Description
023180000
Includes:
M200AU Expendables Kit
Qty
4
002270100
003690100
FL0000001
FL0000003
HW0000020
OR0000001
Gasket (Rx Cell) Qty. 12
Filter, TFE, 37 mm, Qty. 25 (872-006300)
Sintered Filter (002-024900)
Filter, DFU (036-040180)
Spring, Flow Control
1
2
1
2
O-Ring, Flow Control
4
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
APPENDIX A ELECTRICAL SCHEMATICS
Table A-1: Electrical Schematics
Part No.
00402
00403
00514
00515
00704
00705
01086
01087
01109
01110
01114
01115
0113912
01206
01207
01464
01465
01471
01668
01669
01839
01840
01916
01917
01930
Name
Sensor Board Assembly
Sensor Board Schematic
V/F Board Assembly
V/F Board Schematic
Keyboard Assembly
Keyboard Schematic
Status/Temp Assembly
Status/Temp Schematic
Motherboard Assembly
Motherboard Schematic
Connector Board Assembly
Connector Board Schematic
PSM Overall schematic - CE Mark
Switch Board Assembly
Switch Board Schematic
DC Power Supply Assembly
DC Power Supply Schematic
4-20 mA Output Option
Ozone Generator Power Supply Assembly
Ozone Generator Power Supply Schematic
Thermoelectric Cooler Control Assembly
Thermoelectric Cooler Control Schematic
Connector Board Schematic - CE MARK
Connector Board Assembly - CE MARK
Keyboard Assembly - CE MARK
Keyboard Schematic - CE MARK
01931
(table continued)
A-1
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Teledyne API Model 200AU NOX Analyzer Instruction Manual, 02293, Rev. F
Table A-1: Electrical Schematics (Continued)
Part No.
02034
02035
02037
02038
02107
02108
02222
02223
02230
02231
03172
03173
03174
03175
Name
A-Series Valve Driver Assembly
A-Series Valve Driver Schematic
ISBX I/O Port Assembly
ISBX I/O Port Schematic
Preamp Board Assembly
Preamp Board Schematic
Switch Board Assembly - CE MARK
Switch Board Schematic - CE MARK
DC Power Supply Assembly - CE MARK
DC Power Supply Schematic - CE MARK
M200A Interconnect Diagram
M200AH Interconnect Diagram
M200AU Interconnect Diagram
M201A Interconnect Diagram
A-2
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