Teledyne Microscope Magnifier GFC7000E User Manual

INSTRUCTION MANUAL

MODEL GFC7000E

CARBON DIOXIDE ANALYZER

16830 Chestnut St.

City of Industry, Ca. 91748

USA

Phone: 626-961-9221

Phone: 626-934-1500

Fax: 626-961-2538

Fax: 626-934-1651

04584

REV. A1

02-August-2004

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Model GFC7000E Instruction Manual

GFC7000E Documentation

TABLE OF CONTENTS

SAFETY MESSAGES I

TABLE OF CONTENTS ...................................................................................................................... II

LIST OF APPENDICES.................................................................................................................... VII

LIST OF FIGURES

VII

LIST OF TABLES

VIII

1. MGFC7000E DOCUMENTATION..................................................................................................... 1

1.1. Using This Manual ...................................................................................................................1

2. SPECIFICATIONS, APPROVALS AND WARRANTY.......................................................................... 5

2.1. Specifications..........................................................................................................................5

2.2. CE Mark Compliance ................................................................................................................6

2.3. Warranty................................................................................................................................6

3. GETTING STARTED....................................................................................................................... 9

3.1. Unpacking and Initial Set Up.....................................................................................................9

3.1.1. Electrical Connections......................................................................................................11

3.1.2. Pneumatic Connections:...................................................................................................15

3.1.2.1. Basic Pneumatic Connections......................................................................................15

3.1.2.2. Connections with Internal Valve Options Installed..........................................................19

3.2. Initial Operation....................................................................................................................21

3.2.1. Startup..........................................................................................................................22

3.2.2. Warm Up .......................................................................................................................23

3.2.3. Warning Messages ..........................................................................................................24

3.2.4. Functional Check.............................................................................................................25

3.3. Initial Calibration Procedure ....................................................................................................26

4. FREQUENTLY ASKED QUESTIONS............................................................................................... 33

4.1. FAQ’s...................................................................................................................................33

4.2. Glossary...............................................................................................................................34

5. OPTIONAL HARDWARE AND SOFTWARE .................................................................................... 37

5.1. Rack Mount Kits (Options 20a, 20b & 21)..................................................................................37

5.2. Current Loop Analog Outputs (Option 41) .................................................................................37

5.3. Expendable Kits (Options 42C, 42D and 43) ..............................................................................38

5.4. Calibration Valves Options ......................................................................................................38

5.4.1. Zero/Span/Shutoff Valve (Option 50).................................................................................38

5.4.2. Zero/Span/Shutoff with External CO₂Scrubber (Option 51)..................................................40

5.4.3. Zero/Span Valve (Option 52) ............................................................................................40

5.4.4. Zero/Span Valve with External CO₂Scrubber (Option 53)......................................................41

5.5. Communication Options..........................................................................................................41

5.5.1. RS232 Modem Cable (Option 60).......................................................................................41

5.5.2. RS-232 Multidrop (Option 62)...........................................................................................42

5.5.3. Ethernet (Option 63) .......................................................................................................42

5.6. Additional Manuals.................................................................................................................42

5.6.1. Printed Manuals (Option 70) .............................................................................................42

5.6.2. Manual on CD (Part number 045840200)............................................................................43

5.7. Extended Warranty (Options 92 & 93) ......................................................................................43

5.8. Dilution Ratio Option (Option ??) .............................................................................................43

5.9. Maintenance Mode Switch (Option ??) ......................................................................................43

5.10. Second Language Switch (Option ??)......................................................................................44

6. OPERATING INSTRUCTIONS ...................................................................................................... 45

6.1. Overview of Operating modes .................................................................................................45

6.2. Sample Mode........................................................................................................................46

6.2.1. Test Functions ................................................................................................................46

6.2.2. Warning Messages ..........................................................................................................48

6.3. Calibration Mode ...................................................................................................................50

6.3.1. SETUP – PASS: Calibration Password Security .....................................................................50

6.4. SETUP Mode .........................................................................................................................52

6.4.1. SETUP Mode Password Security.........................................................................................53

6.5. SETUP – CFG: Viewing the Analyzer’s Configuration Information ..................................................53

6.6. SETUP – CLK: Setting the Internal Time-of-Day Clock.................................................................54

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6.7. SETUP – RNGE: Analog Output Reporting Range Configuration.....................................................56

6.7.1. Physical Range versus Analog Output Reporting Ranges........................................................56

6.7.2. Reporting Range Modes ...................................................................................................57

6.7.3. Single Range mode (SNGL) ..............................................................................................58

6.7.4. Dual Range Mode (DUAL).................................................................................................60

6.7.5. Auto Range Mode (AUTO).................................................................................................61

6.7.6. Range Units ...................................................................................................................62

6.7.7. Dilution Ratio .................................................................................................................63

6.8. SETUP – VARS: Using the Internal Variables..............................................................................64

6.9. SETUP – DIAG: Using the Diagnostics Functions.........................................................................66

6.9.1. Accessing the Diagnostic Features .....................................................................................67

6.9.2. Signal I/O......................................................................................................................67

6.9.3. Analog Output Step Test ..................................................................................................68

6.9.4. Analog I/O Configuration..................................................................................................69

6.9.4.1. Analog Output Signal Type and Range Span Selection....................................................71

6.9.4.2. Analog Output Calibration Mode..................................................................................71

6.9.4.3. Manual Analog Output Calibration and Voltage Adjustment .............................................73

6.9.4.4. Current Loop Output Adjustment.................................................................................75

6.9.4.5. AIN Calibration.........................................................................................................77

6.9.5. Electric Test ...................................................................................................................77

6.9.6. Dark Calibration Test.......................................................................................................78

6.9.7. Pressure Calibration ........................................................................................................78

6.9.8. Flow Calibration..............................................................................................................80

6.9.9. Test Channel Output........................................................................................................81

6.10. SETUP – COMM: Using the Analyser’s Communication Ports.......................................................82

6.10.1. Analyzer ID Code ..........................................................................................................82

6.10.2. COMM Port Default Settings............................................................................................83

6.10.3. COMM Port Cable Connections.........................................................................................84

6.10.4. RS-485 Configuration of COM2........................................................................................84

6.10.5. DTE and DCE Communication..........................................................................................85

6.10.6. COMM Port Communication Modes ...................................................................................85

6.10.7. COM Port Baud Rate ......................................................................................................88

6.10.8. COM Port Testing ..........................................................................................................89

6.10.9. Ethernet Card Configuration............................................................................................89

6.10.9.1. Ethernet Card COM2 Communication Modes and Baud Rate...........................................90

6.10.9.2. Configuring the Ethernet Interface Option using DHCP..................................................90

6.10.9.3. Manually Configuring the Network IP Addresses...........................................................92

6.10.9.4. Changing the Analyzer’s HOSTNAME..........................................................................94

6.11. SETUP – ALRM: Using the Gas Concentration Alarms.................................................................95

6.12. SETUP – DAS: Using the Data Acquisition System (iDAS)...........................................................96

6.12.1. iDAS Structure..............................................................................................................96

6.12.1.1. iDAS Channels........................................................................................................97

6.12.1.2. iDAS Parameters.....................................................................................................98

6.12.1.3. iDAS Triggering Events ............................................................................................98

6.12.2. Default iDAS Channels ...................................................................................................99

6.12.2.1. Viewing iDAS Data and Settings.............................................................................. 103

6.12.2.2. Editing iDAS Data Channels.................................................................................... 104

6.12.2.3. Trigger Events...................................................................................................... 105

6.12.2.4. Editing iDAS Parameters ........................................................................................ 106

6.12.2.5. Sample Period and Report Period............................................................................. 107

6.12.2.6. Number of Records ............................................................................................... 109

6.12.2.7. RS-232 Report Function......................................................................................... 110

6.12.2.8. Compact Report.................................................................................................... 111

6.12.2.9. Starting Date ....................................................................................................... 111

6.12.2.10. Disabling/Enabling Data Channels.......................................................................... 111

6.12.2.11. HOLDOFF Feature................................................................................................ 112

6.12.3. Remote iDAS Configuration........................................................................................... 113

6.13. Remote Operation of the Analyzer........................................................................................ 115

6.13.1. Remote Operation Using the External Digital I/O.............................................................. 115

6.13.1.1. Status Outputs ..................................................................................................... 115

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6.13.1.2. Control Inputs ...................................................................................................... 116

6.13.2. Remote Operation Using the External Serial I/O............................................................... 117

6.13.2.1. Terminal Operating Modes...................................................................................... 117

6.13.2.2. Help Commands in Terminal Mode........................................................................... 118

6.13.2.3. Command Syntax ................................................................................................. 118

6.13.2.4. Data Types .......................................................................................................... 119

6.13.2.5. Status Reporting................................................................................................... 120

6.13.2.6. Remote Access by Modem...................................................................................... 120

6.13.2.7. COM Port Password Security................................................................................... 122

6.13.2.8. APICOM Remote Control Program............................................................................ 122

6.13.3. Additional Communications Documentation..................................................................... 123

6.13.4. Using the MGFC7000E with a Hessen Protocol Network ..................................................... 123

6.13.4.1. General Overview of Hessen Protocol ....................................................................... 123

6.13.4.2. Hessen COMM Port Configuration ............................................................................ 124

6.13.4.3. Activating Hessen Protocol ..................................................................................... 124

6.13.4.4. Selecting a Hessen Protocol Type ............................................................................ 125

6.13.4.5. Setting The Hessen Protocol Response Mode............................................................. 126

6.13.4.6. Hessen Protocol Gas ID.......................................................................................... 126

6.13.4.7. Setting Hessen Protocol Status Flags ....................................................................... 127

6.13.4.8. Instrument ID Code .............................................................................................. 128

7. CALIBRATION PROCEDURES.................................................................................................... 129

7.1. Before Calibration................................................................................................................ 129

7.1.1. Zero Air and Span Gas...................................................................................................129

7.1.2. Calibration Gas Traceability ............................................................................................130

7.1.3. Data Recording Devices ................................................................................................. 130

7.2. Manual Calibration without Zero/Span Valves .......................................................................... 130

7.3. Manual Calibration Checks .................................................................................................... 133

7.4. Manual Calibration with Zero/Span Valves............................................................................... 133

7.5. Manual Calibration Checks with Zero/Span Valves .................................................................... 137

7.5.1. Zero/Span Calibration on Auto Range or Dual Ranges......................................................... 137

7.5.2. Use of Zero/Span Valves with Remote Contact Closure ....................................................... 138

7.6. Automatic Zero/Span Cal/Check (AutoCal) .............................................................................. 139

7.6.1. AutoCal with Auto or Dual Reporting Ranges Modes Selected............................................... 142

7.7. Calibration Quality............................................................................................................... 142

8. EPA PROTOCOL CALIBRATION ................................................................................................. 143

9. MAINTENANCE SCHEDULE & PROCEDURES .............................................................................. 145

9.1. Maintenance Schedule.......................................................................................................... 145

9.2. Predicting Failures Using the Test Functions ............................................................................ 148

9.3. Maintenance Procedures....................................................................................................... 148

9.3.1. Replacing the Sample Particulate Filter............................................................................. 149

9.3.2. Rebuilding the Sample Pump .......................................................................................... 150

9.3.3. Performing Leak Checks................................................................................................. 150

9.3.3.1. Vacuum Leak Check and Pump Check........................................................................ 150

9.3.3.2. Pressure Leak Check ............................................................................................... 150

9.3.4. Performing a Sample Flow Check..................................................................................... 151

9.3.5. Cleaning the Optical Bench............................................................................................. 151

9.3.6. Cleaning Exterior Surfaces of the MGFC7000E ................................................................... 151

10. THEORY OF OPERATION......................................................................................................... 153

10.1. Measurement Method......................................................................................................... 153

10.1.1. Beer’s Law ................................................................................................................. 153

10.1.2. Measurement Fundamentals ......................................................................................... 154

10.1.3. Gas Filter Correlation................................................................................................... 154

10.1.4. Ambient CO₂Interference Rejection ............................................................................... 158

10.2. Pneumatic Operation.......................................................................................................... 158

10.2.1. Sample Gas Flow......................................................................................................... 159

10.2.1.1. Critical Flow Orifice ............................................................................................... 159

10.2.1.2. Sample Pressure Sensor ........................................................................................ 160

10.2.1.3. Sample Flow Sensor.............................................................................................. 160

10.2.1.4. Valve Options....................................................................................................... 161

10.2.2. Purge Gas Pressure and Flow Control ............................................................................. 161

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10.3. Electronic Operation........................................................................................................... 161

10.3.1. Overview ................................................................................................................... 161

10.3.2. CPU........................................................................................................................... 163

10.3.3. Optical Bench & GFC Wheel........................................................................................... 163

10.3.3.1. Sample Gas and GFC Temperature Control ............................................................... 163

10.3.3.2. IR Source ............................................................................................................ 164

10.3.3.3. GFC Wheel........................................................................................................... 164

10.3.3.4. IR Photo-Detector ................................................................................................. 165

10.3.4. Synchronous Demodulator (Sync/Demod) Assembly......................................................... 165

10.3.4.1. Overview.............................................................................................................165

10.3.4.2. Signal Synchronization and Demodulation ................................................................ 166

10.3.4.3. Phase Lock Warning .............................................................................................. 167

10.3.4.4. Sync/Demod Status LED’s...................................................................................... 167

10.3.4.5. Photo-Detector Temperature Control........................................................................ 168

10.3.4.6. Dark Calibration Switch.......................................................................................... 168

10.3.4.7. Electric Test Switch ............................................................................................... 168

10.3.5. Relay Board................................................................................................................ 168

10.3.5.1. Status LED’s.........................................................................................................169

10.3.5.2. I²C Watch Dog Circuitry........................................................................................ 170

10.3.6. Mother Board.............................................................................................................. 170

10.3.6.1. A to D Conversion................................................................................................. 170

10.3.6.2. Sensor Inputs....................................................................................................... 171

10.3.6.3. Thermistor Interface.............................................................................................. 171

10.3.6.4. Analog Outputs..................................................................................................... 172

10.3.6.5. Internal Digital I/O................................................................................................ 172

10.3.6.6. External Digital I/O ............................................................................................... 173

10.3.7. I²C Data Bus............................................................................................................... 173

10.3.8. Power Supply/ Circuit Breaker....................................................................................... 173

10.4. Interface .......................................................................................................................... 174

10.4.1. Front Panel Interface ................................................................................................... 175

10.4.1.1. Analyzer Status LED’s............................................................................................ 175

10.4.1.2. Keyboard............................................................................................................. 176

10.4.1.3. Display................................................................................................................ 176

10.4.1.4. Keyboard/Display Interface Electronics..................................................................... 177

10.5. Software Operation............................................................................................................ 178

10.5.1. Adaptive Filter ............................................................................................................ 179

10.5.2. Calibration - Slope and Offset........................................................................................ 179

10.5.3. Measurement Algorithm ............................................................................................... 180

10.5.4. Temperature and Pressure Compensation ....................................................................... 180

10.5.5. Internal Data Acquisition System (iDAS)......................................................................... 180

11. TROUBLESHOOTING & REPAIR PROCEDURES ........................................................................ 183

11.1. General Troubleshooting Hints............................................................................................. 183

11.1.1. Interpreting WARNING Messages................................................................................... 184

11.1.2. Fault Diagnosis with TEST Functions............................................................................... 186

11.1.3. Using the Diagnostic Signal I/O Function......................................................................... 188

11.1.4. Internal Electronic Status LED’s..................................................................................... 189

11.1.4.1. CPU Status Indicator ............................................................................................. 189

11.1.4.2. Sync Demodulator Status LED’s .............................................................................. 190

11.1.4.3. Relay Board Status LED’s ....................................................................................... 191

11.1.5. Gas Flow Problems ......................................................................................................192

11.1.6. Typical Sample Gas Flow Problems................................................................................. 193

11.1.6.1. Flow is Zero .........................................................................................................193

11.1.6.2. Low Flow .............................................................................................................193

11.1.6.3. High Flow ............................................................................................................ 194

11.1.6.4. Displayed Flow = “XXXX” ....................................................................................... 194

11.1.6.5. Actual Flow Does Not Match Displayed Flow .............................................................. 194

11.1.6.6. Sample Pump....................................................................................................... 194

11.1.7. Poor or Stopped Flow of Purge Gas ................................................................................ 194

11.2. Calibration Problems .......................................................................................................... 195

11.2.1. Miss-Calibrated ........................................................................................................... 195

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11.2.2. Non-Repeatable Zero and Span ..................................................................................... 195

11.2.3. Inability to Span – No SPAN Key.................................................................................... 196

11.2.4. Inability to Zero – No ZERO Key.................................................................................... 196

11.3. Other Performance Problems............................................................................................... 196

11.3.1. Temperature Problems................................................................................................. 197

11.3.1.1. Box or Sample Temperature ................................................................................... 197

11.3.1.2. Bench Temperature............................................................................................... 197

11.3.1.3. GFC Wheel Temperature ........................................................................................ 198

11.3.1.4. IR Photo-Detector TEC Temperature ........................................................................ 198

11.3.2. Excessive Noise........................................................................................................... 198

11.4. Subsystem Checkout.......................................................................................................... 199

11.4.1. AC Mains Configuration ................................................................................................ 199

11.4.2. DC Power Supply......................................................................................................... 200

11.4.3. I²C Bus...................................................................................................................... 200

11.4.4. Keyboard/Display Interface........................................................................................... 201

11.4.5. Relay Board................................................................................................................ 201

11.4.6. Sensor Assembly......................................................................................................... 202

11.4.6.1. Sync/Demodulator Assembly .................................................................................. 202

11.4.6.2. Opto Pickup Assembly ........................................................................................... 202

11.4.6.3. GFC Wheel Drive................................................................................................... 203

11.4.6.4. IR Source ............................................................................................................ 203

11.4.6.5. Pressure/Flow Sensor Assembly .............................................................................. 203

11.4.7. Motherboard............................................................................................................... 204

11.4.7.1. A/D Functions....................................................................................................... 204

11.4.7.2. Analog Outputs: Voltage ........................................................................................ 204

11.4.7.3. Analog Outputs: Current Loop................................................................................. 204

11.4.7.4. Status Outputs ..................................................................................................... 205

11.4.7.5. Control Inputs – Remote Zero, Span........................................................................ 205

11.4.8. CPU........................................................................................................................... 206

11.4.9. RS-232 Communications .............................................................................................. 206

11.4.9.1. General RS-232 Troubleshooting............................................................................. 206

11.4.9.2. Troubleshooting Analyzer/Modem or Terminal Operation............................................. 207

11.5. Repair Procedures.............................................................................................................. 207

11.5.1. Repairing Sample Flow Control Assembly........................................................................ 207

11.5.2. Removing/Replacing the GFC Wheel............................................................................... 209

11.5.3. Disk-On-Chip Replacement Procedure............................................................................. 210

12. A PRIMER ON ELECTRO-STATIC DISCHARGE.......................................................................... 213

12.1. How Static Charges are Created........................................................................................... 213

12.2. How Electro-Static Charges Cause Damage ........................................................................... 214

12.3. Common Myths About ESD Damage ..................................................................................... 215

12.4. Basic Principles of Static Control .......................................................................................... 216

12.4.1. General Rules ............................................................................................................. 216

12.4.2. Basic anti-ESD Procedures for Analyzer Repair and Maintenance ........................................ 218

12.4.2.1. Working at the Instrument Rack.............................................................................. 218

12.4.2.2. Working at a Anti-ESD Work Bench.......................................................................... 218

12.4.2.3. Transferring Components from Rack To Bench and Back............................................. 219

12.4.2.4. Opening Shipments from and Packing Components for Return to Teledyne Instruments

Customer Service. ..............................................................................................................219

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LIST OF APPENDICES

APPENDIX A - VERSION SPECIFIC SOFTWARE DOCUMENTATION

APPENDIX A-1: MGFC7000E Software Menu Trees, Revision E.0

APPENDIX A-2: Setup Variables For Serial I/O, Revision E.0

APPENDIX A-3: Warnings and Test Functions, Revision E.0

APPENDIX A-4: MGFC7000E Signal I/O Definitions, Revision E.0

APPENDIX A-5: MGFC7000E iDAS Functions, Revision E.0

APPENDIX A-6: Terminal Command Designators, Revision E.0

APPENDIX B - GFC7000E SPARE PARTS LIST

APPENDIX C - REPAIR QUESTIONNAIRE - MGFC7000E

APPENDIX D - ELECTRONIC SCHEMATICS

LIST OF FIGURES

Figure 3-1:

Figure 3-2:

Figure 3-3:

Figure 3-4:

Figure 3-5:

Figure 3-6

Removal of Shipping Screws.......................................................................... 10

Rear Panel Layout........................................................................................ 12

Pneumatic Connections–Basic Configuration–Using Bottled Span Gas .................. 16

Pneumatic Connections–Basic Configuration–Using Gas Dilution Calibrator ........... 17

Pneumatic Connections–MGFC7000E with Zero/Span/Shutoff Valves (OPT 50)...... 19

Pneumatic Connections–MGFC7000E with Zero/Span/Shutoff Valves and External

Zero Air Scrubber (OPT 51).......................................................................... 19

Pneumatic Connections–MGFC7000E with Zero/Span Valves (OPT 52)................. 20

Pneumatic Connections–MGFC7000E with Zero/Span Valves with External Zero air

Scrubber (OPT 53)...................................................................................... 20

Example of Pneumatic Set up for Multipoint Calibration of M360 ......................... 21

Figure 3-7:

Figure 3-8:

Figure 3-9:

Figure 3-10: Front Panel Layout ....................................................................................... 23

Figure 3-11: Assembly Layout.......................................................................................... 30

Figure 3-12: Optical Bench Layout.................................................................................... 31

Figure 3-13: Internal Pneumatic Flow – Basic Configuration ................................................. 31

Figure 5-1:

Figure 5-2:

Figure 5-3:

Figure 5-4:

Figure 6-1:

Figure 6-2

Figure 6-3

Figure 6-4:

Figure 6-5:

Figure 6-6:

Figure 6-7:

Figure 6-8:

Figure 6-9:

Current Loop Option Installed on the Motherboard............................................ 37

Internal Pneumatic Flow – Zero/Span/Shutoff Valves OPT 50 & 51...................... 39

Internal Pneumatic Flow – Zero/Span OPT 52 & 53........................................... 41

GFC7000E Ethernet Card and rear panel With Ethernet Installed......................... 42

Front Panel Display ...................................................................................... 45

Viewing MGFC7000E TEST Functions............................................................... 48

Viewing and Clearing MGFC7000E WARNING Messages...................................... 50

Analog Output Connector Pin Out................................................................... 56

Setup for Calibrating Analog Voltage Outputs................................................... 74

Setup for Calibrating Current Outputs............................................................. 75

Default iDAS Channels Setup....................................................................... 101

APICOM user interface for configuring the iDAS.............................................. 113

iDAS Configuration Through a Terminal Emulation Program.............................. 114

Figure 6-10: Status Output Connector............................................................................. 115

Figure 6-11: Control Inputs ........................................................................................... 117

Figure 6-12: APICOM Remote Control Program Interface.................................................... 123

Figure 7-1:

Figure 7-2:

Figure 7-3:

Figure 7-4

Pneumatic Connections–Basic Configuration–Using Bottled Span Gas ................ 130

Pneumatic Connections–Basic Configuration–Using Gas Dilution Calibrator ......... 131

Pneumatic Connections–MGFC7000E with Zero/Span/Shutoff Valves (OPT 50).... 134

Pneumatic Connections–MGFC7000E with Zero/Span/Shutoff Valves and External

Zero Air Scrubber (OPT 51)........................................................................ 134

Pneumatic Connections–MGFC7000E with Zero/Span Valves (OPT 52)............... 135

Figure 7-5:

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Figure 7-6:

Figure 9-1:

Pneumatic Connections–MGFC7000E with Zero/Span Valves with External Zero air

Scrubber (OPT 53).................................................................................... 135

Sample Particulate Filter Assembly ............................................................... 149

Figure 10-1: Measurement Fundamentals ........................................................................ 154

Figure 10-2: GFC Wheel................................................................................................ 155

Figure 10-3: Measurement Fundamentals with GFC Wheel ................................................. 155

Figure 10-4: Affect of CO₂in the Sample on CO2 MEAS & CO2 REF...................................... 156

Figure 10-5: Effects of Interfering Gas on CO2 MEAS & CO2 REF......................................... 157

Figure 10-6: Chopped IR Signal...................................................................................... 157

Figure 10-7: Internal Pneumatic Flow – Basic Configuration ............................................... 159

Figure 10-8: Flow Control Assembly & Critical Flow Orifice ................................................. 160

Figure 10-9: GFC7000E Electronic Block Diagram ............................................................. 162

Figure 10-10: GFC Light Mask.......................................................................................... 164

Figure 10-11: Segment Sensor and M/R Sensor Output ....................................................... 165

Figure 10-12: GFC7000E Sync / Demod Block Diagram ....................................................... 166

Figure 10-13: Sample & Hold Timing................................................................................. 167

Figure 10-14: Location of relay board Status LED’s ............................................................. 170

Figure 10-15: Power Distribution Block Diagram................................................................. 174

Figure 10-16: Interface Block Diagram.............................................................................. 175

Figure 10-17: MGFC7000E Front Panel Layout.................................................................... 175

Figure 10-18: Keyboard and Display Interface Block Diagram............................................... 177

Figure 10-19: Basic Software Operation ............................................................................ 179

Figure 11-1: Viewing and Clearing Warning Messages........................................................ 184

Figure 11-2: Example of Signal I/O Function .................................................................... 189

Figure 11-3: CPU Status Indicator .................................................................................. 190

Figure 11-4: Sync/Demod Board Status LED Locations ...................................................... 191

Figure 11-5: Relay Board Status LEDs............................................................................. 191

Figure 11-6: Critical Flow Restrictor Assembly Disassembly................................................ 208

Figure 11-7: Opening the GFC Wheel Housing .................................................................. 209

Figure 11-8: Removing the GFC Wheel............................................................................. 210

Figure 12-1: Triboelectric Charging................................................................................. 213

Figure 12-2: Basic anti-ESD Work Station........................................................................ 216

Figure A-1: Basic Sample Display Menu.......................................................................... 223

Figure A-2: Sample Display Menu - Units with Z/S Valve or IZS Option installed................... 224

Figure A-3: Primary Setup Menu (Except iDAS) ............................................................... 225

Figure A-4: Primary Setup Menu (iDAS) ......................................................................... 226

Figure A-5: Secondary Setup Menu (COMM & VARS) ........................................................ 227

Figure A-6: Secondary Setup Menu (COMM Menu with Ethernet Card)................................. 228

Figure A-7: Secondary Setup Menu (COMM Menu with HESSEN) ........................................ 229

Figure A-8: Secondary Setup Menu (DIAG) ..................................................................... 230

LIST OF TABLES

Table 2-1:

Table 3-1:

Table 3-2:

Table 3-3:

Table 3-4:

Table 3-5:

Table 3-6:

Table 5-1:

Table 5-2:

Table 6-1:

Model GFC7000E Basic Unit Specifications ..........................................................5

GFC7000E Analog Output Pin Outs .................................................................. 13

GFC7000E Status Output Pin Outs................................................................... 14

GFC7000E Control Input Pin Outs.................................................................... 15

Model GFC7000E Rear Panel Pneumatic Connections.......................................... 16

Front Panel Display During System Warm-Up.................................................... 23

Possible Warning Messages at Start-Up............................................................ 24

Zero/Span Valve Operating States for Options 50 & 51....................................... 38

Zero/Span Valve Operating States for Options 52 & 53....................................... 40

Analyzer Operating modes.............................................................................. 46

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GFC7000E Documentation

Table 6-2:

Table 6-3:

Table 6-4:

Table 6-5:

Table 6-6:

Table 6-7:

Table 6-8:

Table 6-9:

Test Functions Defined................................................................................... 46

List of Warning Messages............................................................................... 49

Primary Setup Mode Features and Functions ..................................................... 52

Secondary Setup Mode Features and Functions ................................................. 52

Variable Names (VARS) Revision B.3 ............................................................... 64

GFC7000E Diagnostic (DIAG) Functions............................................................ 66

DIAG - Analog I/O Functions........................................................................... 69

Analog Output Voltage Ranges........................................................................ 69

Table 6-10: Analog Output Current Loop Range.................................................................. 70

Table 6-11: Analog Output Pin Assignments....................................................................... 70

Table 6-12: Voltage Tolerances for Analog Output Calibration............................................... 73

Table 6-13: Current Loop Output Calibration with Resistor ................................................... 76

Table 6-14: Test Parameters Available for Analog Output A3 ................................................ 81

Table 6-15: COM1 and COM2 DB-9 Pin Assignments............................................................ 85

Table 6-16: COMM Port Communication modes................................................................... 86

Table 6-17: Ethernet Status Indicators.............................................................................. 89

Table 6-18: LAN/Internet Configuration Properties.............................................................. 90

Table 6-19: Internet Configuration Keypad Functions .......................................................... 94

Table 6-20: CO₂Concentration Alarm Default Settings......................................................... 95

Table 6-21: Front Panel LED Status Indicators for iDAS ....................................................... 96

Table 6-22: iDAS Data Channel Properties ......................................................................... 97

Table 6-23: iDAS Data Parameter Functions....................................................................... 98

Table 6-24: Status Output Pin Assignments ..................................................................... 116

Table 6-25: Control Input Pin Assignments ...................................................................... 116

Table 6-26: Terminal Mode Software Commands .............................................................. 118

Table 6-27: Command Types ......................................................................................... 119

Table 6-28: Serial Interface Documents........................................................................... 123

Table 6-29: RS-232 Communication Parameters for Hessen Protocol ................................... 124

Table 6-30: Teledyne Instruments Hessen Protocol Response Modes ................................... 126

Table 6-31: Default Hessen Status Bit Assignments........................................................... 127

Table 7-1:

Table 7-2:

Table 7-3:

Table 9-1:

Table 9-2:

Table 9-3:

AUTOCAL Modes ......................................................................................... 139

AutoCal ATTRIBUTE Setup Parameters ........................................................... 139

Calibration Data Quality Evaluation................................................................ 142

GFC7000E Maintenance Schedule.................................................................. 146

GFC7000E Test Function Record.................................................................... 147

Predictive uses for Test Functions.................................................................. 148

Table 10-1: Sync/Demod Status LED Activity ................................................................... 168

Table 10-2: Relay Board Status LED’s ............................................................................. 169

Table 10-3: Front Panel Status LED’s .............................................................................. 176

Table 11-1: Warning Messages - Indicated Failures........................................................... 185

Table 11-2: Test Functions - Indicated Failures................................................................. 187

Table 11-3: Sync/Demod Board Status Failure Indications ................................................. 190

Table 11-4: I²C Status LED Failure Indications ................................................................. 191

Table 11-5: Relay Board Status LED Failure Indications ..................................................... 192

Table 11-6: DC Power Test Point and Wiring Color Codes................................................... 200

Table 11-7: DC Power Supply Acceptable Levels ............................................................... 200

Table 11-8: Relay Board Control Devices ......................................................................... 201

Table 11-9: Opto Pickup Board Nominal Output Frequencies............................................... 202

Table 11-10: Analog Output Test Function - Nominal Values Voltage Outputs.......................... 204

Table 11-11: Analog Output Test Function - Nominal Values Current Outputs ......................... 205

Table 11-12: Status Outputs Check .................................................................................. 205

Table 12-1: Static Generation Voltages for Typical Activities............................................... 214

Table 12-2: Sensitivity of Electronic Devices to Damage by ESD ......................................... 214

Table A-1:

GFC7000E Setup Variables, Revision E.0 ........................................................ 231

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GFC7000E Documentation

Table A-2:

Table A-3:

Table A-4:

Table A-5:

Table A-6:

Table A-7:

Table D-1:

GFC7000E Warning Messages, Revision E.0 .................................................... 238

GFC7000E Test Functions, Revision E.0.......................................................... 239

GFC7000E Signal I/O Definitions, Revision E.0 ................................................ 240

GFC7000E DAS Trigger Events, Revision E.0................................................... 243

GFC7000E iDAS Functions, Revision E.0......................................................... 244

Terminal Command Designators, Revision E.0................................................. 245

List of Included Electronic Schematics............................................................ 251

User Notes

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Model GFC7000E Instruction Manual

MGFC7000E Documentation

1. MGFC7000E DOCUMENTATION

Thank you for purchasing the Model GFC7000E Gas Filter Correlation Carbon Dioxide Analyzer!

The documentation for this instrument is available in several different formats:

•

Printed format, part number 045840100

Electronic format on a CD-ROM, part number 045840200

The electronic manual is in Adobe^®Systems Inc. “Portable Document Format”. The Adobe^®

Acrobat Reader^®software, which is necessary to view these files, can be downloaded for free from

the internet at http://www.adobe.com/.

The electronic version of the manual has many advantages:

•

Keyword and phrase search feature

Figures, tables and internet addresses are linked so that clicking on the item will display

the associated feature or open the website.

•

A list of chapters and sections as well as thumbnails of each page are displayed to the left

of the text.

•

Entries in the table of contents are linked to the corresponding locations in the manual.

Ability to print sections (or all) of the manual

Additional documentation for the Model GFC7000E CO₂Analyzer is available from Teledyne

Analytical Instruments’ website at http://www.teledyne-ai.com/manuals/

•

APICOM software manual, part number 03945

Multi-drop manual, part number 01842

DAS Manual, part number 02837.

1.1. Using This Manual

This manual has the following data structures:

1.0 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, a list of figures and a

list of appendices. In the electronic version of the manual, clicking on a any of these table entries

automatically views that section.

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2.0 Specifications and Warranty

This section contains a list of the analyzer’s performance specifications, a description of the

conditions and configuration under which EPA equivalency was approved and Teledyne

Instruments Incorporated’s warranty statement.

3.0 Getting Started:

A concise set of instructions for setting up, installing and running your analyzer for the first time.

4.0 FAQ:

Answers to the most frequently asked questions about operating the analyzer.

5.0 Optional Hardware & Software

A description of optional equipment to add functionality to your analyzer.

6.0 Operation Instructions

This section includes step by step instructions for operating the analyzer and using its various

features and functions.

7.0 Calibration Procedures

General information and step by step instructions for calibrating your analyzer.

8.0 EPA Protocol Calibration

Because CO₂is not declared a criteria air pollutant by the US EPA, EPA equivalency is not required

for this type of analyzer. Therefore no special calibration methods are needed to satisfy EPA

requirements.

9.0 Instrument Maintenance

Description of certain preventative maintenance procedures that should be regularly performed on

you instrument to keep it in good operating condition. This section also includes information on

using the iDAS to record diagnostic functions useful in predicting possible component failures

before they happen.

10.0 Theory of Operation

An in-depth look at the various principals by which your analyzer operates as well as a description

of how the various electronic, mechanical and pneumatic components of the instrument work and

interact with each other. A close reading of this section is invaluable for understanding the

instrument’s operation.

11.0 Troubleshooting Section:

This section includes pointers and instructions for diagnosing problems with the instrument, such

as excessive noise or drift, as well as instructions on performing repairs of the instrument’s major

subsystems.

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Appendices:

For easier access and better updating, some information has been separated out of the manual

and placed in a series of appendices at the end of this manual. These include: software menu

trees, warning messages, definitions of iDAS & serial I/O variables, spare parts list, repair

questionnaire, interconnect listing and drawings, and electronic schematics.

NOTE

Throughout this manual, words printed in capital, bold letters, such as SETUP or ENTR

represent messages as they appear on the analyzer’s front panel display.

NOTE

The flowcharts in this manual contain typical representations of the analyzer’s display

during the various operations being described. These representations are not intended

to be exact and may differ slightly from the actual display of your instrument.

User Notes

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Specifications, Approvals and Warranty

2. SPECIFICATIONS, APPROVALS AND

WARRANTY

2.1. Specifications

Table 2-1:

Model GFC7000E Basic Unit Specifications

Min/Max Range

In 1ppb increments from 50ppb to 2 000ppm, dual ranges or auto

ranging

ppb, ppm, µg/m³, mg/m³, %(user selectable)

(Physical Analog Output)

Measurement Units

Zero Noise

< 0.1 ppm (RMS)

Span Noise

< 1% of reading (RMS)

< 0.2 ppm¹

<0.25 ppm¹

<0.5 ppm¹

1% of reading above 50 PPM¹

Lower Detectable Limit1

Zero Drift (24 hours)

Zero Drift (7 days)

Span Drift (7 Days)

Linearity

1% of full scale

Precision

0.5% of reading

Temperature Coefficient

Voltage Coefficient

Lag Time

< 0.1% of Full Scale per oC

< 0.05% of Full Scale per V

10 sec

Rise/Fall Time

95% in <60 sec

Sample Flow Rate

Temperature Range

Humidity Range

Dimensions H x W x D

Weight, Analyzer

AC Power Rating

800cm³/min. ±10%

5-40^oC

0 - 95% RH, non-condensing

7" x 17" x 23.5" (178 mm x 432 mm x 597 mm)

38 lbs. (17 kg); add 1 lbs (0.5 kg) for IZS

100 V, 50/60 Hz (3.25A);

115 V, 60 Hz (3.0 A);

220 – 240 V, 50/60 Hz (2.5 A)

Environmental

Installation category (over-voltage category) II; Pollution degree 2

Three (3) Outputs

Analog Outputs

Analog Output Ranges

0.1V, 1 V, 5 V, 10 V, 2-20 or 4-20 mA isolated current loop.

All Ranges with 5% Under/Over Range

Analog Output Resolution

Status Outputs

Control Inputs

1 part in 4096 of selected full-scale voltage

8 Status outputs - opto-isolated; including 2 alarm outputs

6 Control Inputs, 3 defined, 3 spare

Serial I/O

One (1) RS-232; One (1) RS-485

Baud Rate : 300 – 115200: Optional Ethernet Interface

Certifications

CE: EN61010-1:90 + A1:92 + A2:95, EN61326 - Class A

At constant temperature and voltage.

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Specifications, Approvals and Warranty

2.2. CE Mark Compliance

Emissions Compliance

The Teledyne Instruments Model GFC7000E Gas Filter Correlation CO₂Analyzer was tested and

found to be fully compliant with:

EN61326 (1997 w/A1: 98) Class A, FCC Part 15 Subpart B Section 15.107 Class A, ICES-003

Class A (ANSI C63.4 1992) & AS/NZS 3548 (w/A1 & A2; 97) Class A.

Tested on 11-29-2001 at CKC Laboratories, Inc., Report Number CE01-249.

Safety Compliance

The Teledyne Instruments Model GFC7000E Gas Filter Correlation CO₂Analyzer was tested and

found to be fully compliant with:

IEC 61010-1:90 + A1:92 + A2:95,

Tested on 02-06-2002 at Nemko, Report Number 2002-012219.

2.3. Warranty

Warranty Policy (02024)

Prior to shipment, Teledyne Instruments Incorporated equipment is thoroughly inspected and

tested. Should equipment failure occur, Teledyne Instruments Incorporated assures its customers

that prompt service and support will be available.

Coverage

After the warranty period and throughout the equipment lifetime, Teledyne Instruments

Incorporated 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-API Manufactured Equipment

Equipment provided but not manufactured by Teledyne Instruments Incorporated 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 Instruments Incorporated warrants each product manufactured by Teledyne Instruments

Incorporated 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 Instruments

Incorporated shall correct such defect by, in Teledyne Instruments Incorporated’s discretion,

repairing or replacing such defective product or refunding the purchase price of such product.

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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 ANALYTICAL

INSTRUMENTS 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

Instruments Incorporated SHALL NOT BE LIABLE FOR ANY INCIDENTAL OR

CONSEQUENTIAL DAMAGES ARISING OUT OF OR RELATED TO THIS AGREEMENT OF

TELEDYNE INSTRUMENTS INCORPORATED’S PERFORMANCE HEREUNDER, WHETHER

FOR BREACH OF WARRANTY OR OTHERWISE.

Terms and Conditions

All units or components returned to Teledyne Amnalytical Instruments 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.

User Notes

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3. GETTING STARTED

3.1. Unpacking and Initial Set Up

CAUTION

To avoid personal injury, always use two persons to lift and carry the

Model GFC7000E.

1. Verify that there is no apparent external shipping damage. If damage has occurred, please

advise the shipper first, then Teledyne Analytical Instruments.

2. Included with your analyzer is a printed record of the final performance characterization

performed on your instrument at the factory. This record, titled Final Test and Validation Data

Sheet (part number 04307) is an important quality assurance and calibration record for this

instrument. It should be placed in the quality records file for this instrument.

3. Carefully remove the top cover of the analyzer and check for internal shipping damage.

•

Remove the set screw located in the top, center of the rear panel.

Remove the four screws fastening the top cover to the unit (two per side).

Lift the cover straight up. Do not slide backwards.

NOTE

Some versions of the GFC7000E CO₂Analyzer may have a spring loaded fastener at the

top center of the rear panel and as many as eight screws (four per side) fastening the

top cover to the chassis.

NOTE

Static sensitive parts are present on PCA (Printed Circuit Assemblies). Before touching

PCAs, touch a bare metal part of the chassis to discharge any electrostatic potentials or

connect a grounding strap to your wrist.

CAUTION

Never disconnect PCAs, wiring harnesses or electronic subassemblies

while under power.

4. Inspect the interior of the instrument to make sure all circuit boards and other components

are in good shape and properly seated.

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5. Check the connectors of the various internal wiring harnesses and pneumatic hoses to make

sure they are firmly and properly seated.

6. Verify that all of the optional hardware ordered with the unit has been installed. These are

listed on the paperwork accompanying the analyzer.

7. Once you have determined that no shipping damage exists, and the unit includes all expected

hardware options, remove all red colored shipping screws from the bottom of the chassis as

shown in Figure 3-1.

Shipping

Screws

Figure 3-1:

Removal of Shipping Screws

NOTE

Save these shipping screws and re-install them whenever the unit is shipped to another

location.

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8. VENTILATION CLEARANCE: Whether the analyzer is set up on a bench or installed into an

instrument rack, be sure to leave sufficient ventilation clearance.

AREA

MINIMUM REQUIRED CLEARANCE

Back of the instrument

4 in.

1 in.

Sides of the instrument

Above and below the instrument

1 in.

•

Various rack mount kits are available for this analyzer. See Section 5.1 of this manual

for more information.

3.1.1. Electrical Connections

CAUTION

Check the voltage and frequency label on the rear panel of the

instrument (See Figure 3-2) for compatibility with the local

power before plugging the MGFC7000E into line power.

Do not plug in the power cord if the voltage or

frequency is incorrect.

CAUTION

Power connection must have functioning ground connection.

Do not defeat the ground wire on power plug.

CAUTION

Turn off analyzer power before disconnecting or

connecting electrical subassemblies.

Do not operate with cover off.

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Figure 3-2:

Rear Panel Layout

9. Attach a strip chart recorder and/or data-logger to the appropriate analog output connections

on the rear panel of the analyzer.

ANALOG

3 4

When the instrument is in its default configuration, the A1 and A2 channels output a signal

that is proportional to the CO₂concentration of the sample gas. Either can be used for

connecting the analog output signal to a chart recorder or for interfacing with a datalogger.

The third analog output, labeled A3 is special. It can be set by the user (see Section

6.9.9) to output any one of the parameters accessible through the <TST TST> keys of the

units sample display.

The standard configuration for these outputs is mVDC. An optional current loop output is

available for each.

Output A4 is not used on the Model 306E.

Pin-outs for the analog output connector at the rear panel of the instrument are:

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Table 3-1: GFC7000E Analog Output Pin Outs

Getting Started

Analog Output

VDC Signal

mADC Signal

V Out

I Out +

I Out -

Ground

V Out

I Out +

Ground

V Out

I Out -

I Out +

Ground

V Out

I Out -

Not Available

A4 (Spare)

Ground

•

The default analog output voltage setting of the GFC7000E CO₂Analyzer is 0 – 5 VDC

with a range of 0 – 500 ppm.

TO change these settings, see Sections 6.9.4 and 6.7 respectively.

10.If you wish utilize the analyzer’s status outputs to interface with a device that accepts logic-

level digital inputs, such as programmable logic controllers (PLC’s) they are accessed via a 12-

pin connector on the analyzer’s rear panel labeled STATUS.

STATUS

NOTE

Most PLC’s have internal provisions for limiting the current that the input will draw from

an external device. When connecting to a unit that does not have this feature, an

external dropping resistor must be used to limit the current through the transistor

output to less than 50mA. At 50mA, the transistor will drop approximately 1.2V from its

collector to emitter.

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The pin assignments for the status outputs can be found in the table below:

Table 3-2:

GFC7000E Status Output Pin Outs

Status

Definition

Output #

Condition

SYSTEM OK

On if no faults are present.

On if CO₂concentration measurement is valid.

If the CO₂concentration measurement is invalid, this bit is OFF.

CONC VALID

HIGH RANGE

ZERO CAL

On if unit is in high range of DUAL or AUTO range modes.

On whenever the instruments ZERO point is being calibrated.

On whenever the instruments SPAN point is being calibrated.

On whenever the instrument is in DIAGNOSTIC mode.

SPAN CAL

DIAG MODE

On whenever the measured CO₂concentration is above the set

point for ALM1

ALARM1

ALARM2

On whenever the measured CO₂concentration is above the set

point for ALM2

EMITTER BUSS

DC POWER

The emitters of the transistors on pins 1-8 are bussed together.

+ 5 VDC

Digital Ground

The ground level from the analyzer’s internal DC power supplies.

11.If you wish to use the analyzer’s to remotely activate the zero and span calibration modes,

several digital control inputs are provided via a 10-pin connector labeled CONTROL IN on the

analyzer’s rear panel. Two methods for energizing the inputs are provided below; the first

using the internal +5V available on the CONTROL IN connector and the second, if an external,

isolated supply is employed.

CONTROL IN

5 VDC Power

Supply

External Power Connections

Local Power Connections

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The pin assignments for the digital control inputs can be found in the table below:

Table 3-3:

GFC7000E Control Input Pin Outs

Status

Definition

Input #

On Condition

REMOTE ZERO

CAL

The Analyzer is placed in Zero Calibration mode. The mode

field of the display will read ZERO CAL R.

REMOTE

SPAN CAL

The Analyzer is placed in Span Calibration mode. The mode

field of the display will read SPAN CAL R.

SPARE

Digital Ground

May be connected to the ground of the datalogger/recorder.

Input pin for +5 VDC required to activate pins A – F. This

can be from an external source or from the “+” pin of the

instruments STATUS connector.

Pullup supply

for inputs

Internal +5V

Supply

Internal source of +5V which can be used to actuate control

inputs when connected to the U pin.

12.If you wish to utilize either of the analyzer’s two serial interface COMM ports, refer to Section

6.10 of this manual for instructions on their configuration and usage.

13.If your unit has a Teledyne Instruments Ethernet card (Option 63), plug one end into the 7’

CAT5 cable supplied with the option into the appropriate place on the back of the analyzer

(see Figure 5-4 in Section 5.5.3) and the other end into any nearby Ethernet access port.

3.1.2. Pneumatic Connections:

3.1.2.1. Basic Pneumatic Connections

Figures 3-3 and 3-4 illustrate the most common configurations for gas supply and exhaust lines to

the Model GFC7000E Analyzer. Figure 3-13 illustrates the internal gas flow of the instrument in

its basic configuration.

Please refer to Figure 3-2 for pneumatic connections at the rear panel and Table 3-4 for

nomenclature.

NOTE

Sample and calibration gases should only come into contact with PTFE (Teflon), FEP,

glass, stainless steel or brass. CAUTION

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CAUTION

In order to prevent dust from getting into the gas flow channels of your analyzer, it was

shipped with small plugs inserted into each of the pneumatic fittings on the back panel.

Make sure that all of these dust plugs are removed before attaching

exhaust and supply gas lines.

Table 3-4:

Rear Panel Label

SAMPLE

Model GFC7000E Rear Panel Pneumatic Connections

Function

Connect a gas line from the source of sample gas here.

Calibration gasses are also inlet here on units without

zero/span/shutoff valve or IZS options installed.

EXHAUST

Connect an exhaust gas line of not more than 10 meters long here.

On units with zero/span/shutoff valve options installed, connect a

gas line to the source of calibrated span gas here.

PRESSURE SPAN

Span gas vent outlet for units with zero/span/shutoff valve options

installed.

Connect an exhaust gas line of not more than 10 meters long here.

VENT SPAN

IZS

Internal zero air scrubber.

on units with zero/span/shutoff valve options installed but NO

internal zero air scrubber, attach a gas line to the source of zero air

here.

This inlet supplies purge air to the GFC wheel housing (see section

10.2.2)

PURGE IN

Connect a source of dried air that has been scrubbed of CO₂.

Calibrated CO₂

gas at desired

span gas

VENT

Source of

SAMPLE Gas

Removed

during

Calibration

concentration

Needle

valve to

control

flow

Indicating

soda-lime

Sample

Exhaust

MODEL

GFC7000E

Valve

Vent Span

Pressure Span

MODEL 701

Zero Air

IZS

Generator

Purge In

Figure 3-3:

Pneumatic Connections–Basic Configuration–Using Bottled Span Gas

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Source of

Calibrated

CO₂Gas

SAMPLE Gas

Removed

during

MODEL 700

Gas Dilution

Calibrator

Calibration

Indicating

soda-lime

VENT

Sample

Exhaust

Vent Span

Pressure Span

IZS

MODEL

GFC7000E

MODEL 701

Zero Air Generator

Purge In

Figure 3-4:

Pneumatic Connections–Basic Configuration–Using Gas Dilution Calibrator

1. Attach a sample inlet line to the sample inlet port. The SAMPLE input line should not be more

than 2 meters long.

NOTE

Ideally, the pressure of the sample gas should be at ambient pressure (0

psig). Maximum pressure of sample gas should not exceed 1.5 in-Hg over

ambient.

In applications where the sample gas is received from a pressurized

manifold, a vent must be placed as shown to equalize the sample gas with

ambient atmospheric pressure before it enters the analyzer.

This vent line must be:

•

At least 0.2m long

No more than 2m long and vented outside the shelter or immediate

area surrounding the instrument.

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2. Attach sources of zero air and span gas (see Figures 3-3 through 3-8 inclusive).

•

Span Gas is a gas specifically mixed to match the chemical composition of the type of gas

being measured at near full scale of the desired measurement range.

In the case of CO₂measurements made with the Teledyne Analytical Instruments Model

GFC7000E Analyzer it is recommended that you use a gas calibrated to have a CO₂content

equaling 80% of the range of compositions being measured.

EXAMPLE: If the application is to measure between 0 ppm and 500 ppm, an appropriate

Span Gas would be 400 ppm. If the application is to measure between 0 ppm and 100

ppm, an appropriate Span Gas would be 80 ppm.

•

Span Gas can be purchased in pressurized canisters or created using Dynamic Dilution

Calibrator such as the Teledyne Analytical Instruments Model 700 and a source of dried

air scrubbed of CO₂such as a Teledyne Analytical Instruments Model 701 Zero Air

Generator in combination with a canister of indicating soda-lime.

•

Zero Air is similar in chemical composition to the earths atmosphere but scrubbed of all

components that might affect the analyzer’s readings.

In the case of CO₂measurements this means CO₂less than 0.1 ppm of CO₂and Water

Vapor. Zero Air can be purchased in pressurized canisters or created using a Teledyne

Instruments Model 701 Zero Air Generator in combination with a canister of indicating

soda-lime.

3. Attach an exhaust line to the exhaust outlet port.

•

The exhaust from the pump and vent lines should be vented to atmospheric pressure using

maximum of 10 meters of ¼” PTEF tubing.

CAUTION

Venting should be outside the shelter or immediate area surrounding the

instrument.

4. Attach a source of dried air scrubbed of CO₂to the purge inlet port

NOTE

The source of purge air should be at 20-25 psig and capable of maintaining a flow of at

least 0.5 liters/min.

Purge source air pressure should not exceed 35 pisg

5. Once the appropriate pneumatic connections have been made, check all pneumatic fittings for

leaks using a procedure similar to that defined in Section 9.3.3.

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3.1.2.2. Connections with Internal Valve Options Installed

Figures 3-5 through 3-8 show the proper pneumatic connections for MGFC7000E’s with various

optional internal valve sets installed.

Source of

SAMPLE Gas

VENT if input is pressurized

Certified

CO₂Gas

Sample

Needle

Exhaust

valve to

control

flow

MODEL

GFC7000E

VENT

Vent Span

Pressure Span

MODEL 701

Zero Air

Generator

IZS

VENT

Purge In

Indicating

soda-lime

Figure 3-5:

Pneumatic Connections–MGFC7000E with Zero/Span/Shutoff Valves (OPT

50)

Source of

SAMPLE Gas

VENT if input is pressurized

Certified

CO₂Gas

Sample

Exhaust

MODEL 701

Zero Air

Generator

MODEL

GFC7000E

VENT

Vent Span

Pressure Span

IZS

External Zero

Air Scrubber

Purge In

Indicating

soda-lime

Figure 3-6

Pneumatic Connections–MGFC7000E with Zero/Span/Shutoff Valves and

External Zero Air Scrubber (OPT 51)

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Source of

SAMPLE Gas

VENT if input is pressurized

MODEL 700

Gas Dilution

Calibrator

Sample

Exhaust

Certified

CO₂Gas

Needle

valve to

control flow

MODEL

GFC7000E

Vent Span

VENT

Pressure Span

Indicating

soda-lime

IZS

Purge In

MODEL 701

Zero Air

Generator

Figure 3-7:

Pneumatic Connections–MGFC7000E with Zero/Span Valves (OPT 52)

Source of

SAMPLE Gas

VENT if input is pressurized

Certified

CO Gas

MODEL 700

Gas Dilution

Calibrator

Sample

Exhaust

Indicating

soda-lime

VENT

MODEL

GFC7000E

Vent Span

Pressure Span

External Zero

Air Scrubber

IZS

MODEL 701

Zero Air Generator

Purge In

Figure 3-8:

Pneumatic Connections–MGFC7000E with Zero/Span Valves with External

Zero air Scrubber (OPT 53)

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Some applications may require multipoint calibration checks where span gas of several different

concentrations is needed. We recommend using high-concentration, certified, calibration gas

supplied to the analyzer through a Gas Dilution Calibrator such as a Teledyne Instruments Model

700. This type of calibrator precisely mixes Span Gas and Zero Air to produce any concentration

level between 0 ppm and the concentration of the calibrated gas.

Figure 3-8 depicts the pneumatic set up in this sort of application of a Model GFC7000E CO₂

Analyzer with zero/span/shutoff valve option 50 installed (a common configuration for this type of

application).

Gas Pressure should

be regulated at

Source of

30 – 35 PSIG

SAMPLE Gas

VENT if input is pressurized

MODEL 700

Gas Dilution

Calibrator

Sample

VENT

Exhaust

MODEL

GFC7000E

VENT

Calibrated

CO₂Gas

Vent Span

Pressure Span

IZS

Indicating

soda-lime

VENT

Purge In

Needle

valve to

control flow

MODEL 701

Zero Air Generator

Figure 3-9:

Example of Pneumatic Set up for Multipoint Calibration of M360

3.2. Initial Operation

If you are unfamiliar with the MGFC7000E theory of operation, we recommend that you read

Chapter 10.

For information on navigating the analyzer’s software menus, see the menu trees described in

Appendix A.1.

NOTE

The analyzer’s cover must be installed to ensure that the temperatures of the GFC

wheel and absorption cell assemblies are properly controlled.

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3.2.1. Startup

After electrical and pneumatic connections are made, turn on the instrument and pump power.

The exhaust and PMT cooler fans should start. The display should immediately display a single,

horizontal dash in the upper left corner of the display. This will last approximately 30 seconds

while the CPU loads the operating system.

Once the CPU has completed this activity it will begin loading the analyzer firmware and

configuration data. During this process, string of messages will appear on the analyzer’s front

panel display:

System waits 3 seconds

then automatically begins

its initialization routine.

SELECT START OR REMOTE

START

No action required.

CHECKING FLASH STATUS

System is checking the format

of the instrument’s flash

memory chip.

If at this point,

STARTING INSTRUMENT CODE

STARTING INSTRUMENT W/FLASH

**FLASH FORMAT INVALID**

appears, contact T–API customer service

The instrument is loading

configuration and calibration

data from the flash chip

The instrument is

loading the analyzer

firmware.

M200E NOX ANALYZER

BOOT PROGRESS [XXXXX 50%_ _ _ _ _]

The revision level of the

firmware installed in your

analyzer is briefly displayed

SOFTWARE REVISION D.6

BOOT PROGRESS [XXXXXXXX 80% _ _]

SAMPLE

TEST

SYSTEM RESET

CO2=X.XXX

CLR SETUP

Firmware

fully booted

CAL

Press CLR to clear initial

warning messages.

(see Section 3.2.3)

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The analyzer should automatically switch to SAMPLE mode after completing the boot-up

sequence and start monitoring CO₂gas. Warm-Up

3.2.2. Warm Up

The MGFC7000E requires about 30 minutes warm-up time before reliable CO₂measurements can

be taken. During that time, various portions of the instrument’s front panel will behave as follows.

See Figure 3-10 for locations.

Table 3-5:

Front Panel Display During System Warm-Up

Name

Color

Behavior

Significance

Concentration

Field

N/A

Displays current,

compensated CO₂

Concentration

N/A

Mode Field

N/A

Displays blinking

“SAMPLE”

Instrument is in sample mode but is still in the

process of warming up.

STATUS LED’s

Sample

Green

Unit is operating in sample mode, front panel

display is being updated.

Flashes On/Off when adaptive filter is active

The instrument’s calibration is not enabled.

Cal

Yellow

Red

Off

Fault

Blinking

The analyzer is warming up and hence out of

specification for a fault-free reading. various warning

messages will appear.

MODE FIELD MESSAGE FIELD

CONCENTRATION FIELD STATUS LED’s

FASTENER

LOCKING SCREW

FASTENER

SAMPLE

CAL

CO2 = 400.0

SETUP

SAMPLE A

RANGE = 500.0 PPM

CAL

FAULT

POWER

GAS FILTER CORRELATION CO₂ANALYZER- MODEL GFC7000E

KEY DEFINITIONS KEYBOARD

ON / OFF SWITCH

Figure 3-10: Front Panel Layout

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3.2.3. Warning Messages

Because internal temperatures and other conditions may be outside be specified limits during the

analyzer’s warm-up period, the software will suppress most warning conditions for 30 minutes

after power up.

If warning messages persist after the 30 minutes warm up period is over, investigate their cause

using the troubleshooting guidelines in Chapter 11 of this manual. The following table includes a

brief description of the various warning messages that may appear.

Table 3-6:

Possible Warning Messages at Start-Up

MESSAGE

MEANING

The instruments A/D circuitry or one of its analog outputs is not calibrated.

The Temperature of the optical bench is outside the specified limits.

ANALOG CAL WARNING

BENCH TEMP WARNING

BOX TEMP WARNING

Remote span calibration failed while the dynamic span feature was set to

turned on

CANNOT DYN SPAN

CANNOT DYN ZERO

Remote zero calibration failed while the dynamic zero feature was set to

turned on

Configuration was reset to factory defaults or was erased.

Configuration storage was reset to factory configuration or erased.

CONFIG INITIALIZED

Concentration alarm 1 is enabled and the measured CO₂level is ≥ the set

point.

CONC ALRM1 WARNING

Concentration alarm 2 is enabled and the measured CO₂level is ≥ the set

point.

CONC ALRM2 WARNING

iDAS data storage was erased.

DATA INITIALIZED

FRONT PANEL WARN

Firmware is unable to communicate with the front panel.

The temperature of the IR photometer is outside the specified limits.

PHOTO TEMP WARNING

REAR BOARD NOT DET

The CPU is unable to communicate with the motherboard.

The firmware is unable to communicate with the relay board.

The flow rate of the sample gas is outside the specified limits.

Sample gas pressure outside of operational parameters.

RELAY BOARD WARN

SAMPLE FLOW WARN

SAMPLE PRESS WARN

The temperature of the sample gas is outside the specified limits.

The IR source may be faulty.

SAMPLE TEMP WARN

SOURCE WARNING

The instrument is not properly tracking the rotation of the Gas Filter

Correlation wheel.

SYNC WARNING

The computer was rebooted.

SYSTEM RESET

The Gas Filter Correlation wheel temperature is outside the specified limits.

WHEEL TEMP WARNING

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To View and Clear the various warning messages press:

SAMPLE

HVPS WARNING

CAL MSG

CO2 = 0.00

TEST deactivates warning

TEST

CLR SETUP

messages

MSG activates warning

SAMPLE

RANGE=500.000 PPM

MSG

CO2 = 0.00

messages.

<TST TST> keys replaced with

< TST TST > CAL

CLR SETUP

TEST key

SAMPLE

HVPS WARNING

CO2 = 0.00

Press CLR to clear the current

message.

TEST

CAL

MSG

CLR SETUP

NOTE:

If more than one warning is active, the

next message will take its place

If the warning message persists

after several attempts to clear it,

the message may indicate a

real problem and not an artifact

of the warm-up period

Once the last warning has been

cleared, the analyzer returns to

SAMPLE mode

Make sure warning messages are

not due to real problems.

3.2.4. Functional Check

1. After the analyzer’s components has warmed up for at least 30 minutes, verify that the

software properly supports any hardware options that were installed.

2. Check to make sure that the analyzer is functioning within allowable operating parameters.

Appendix C includes a list of test functions viewable from the analyzer’s front panel as well as

their expected values. These functions are also useful tools for diagnosing performance

problems with your analyzer (Section 11.1.2). The enclosed Final Test and Validation Data

sheet (part number 04307) lists these values before the instrument left the factory.

To view the current values of these parameters press the following key sequence on the

analyzer’s front panel. Remember until the unit has completed its warm up these parameters

may not have stabilized.

SAMPLE

RANGE = 500.000 PPM

CO2 = XXX.X

SETUP

< TST TST > CAL

RANGE

RANGE1¹

RANGE2¹

STABIL

Toggle <TST TST> keys to

scroll through list of functions

CO2 MEAS

CO2 REF

MR RATIO

PRES

SAMP FL

SAMP TEMP

BENCH TEMP

WHEEL TEMP

BOX TEMP

PHT DRIVE

SLOPE

Refer to

Section

6.X.X for

definitions

of these

test

functions.

¹Only appears instrument is set

for DUAL or AUTO reporting

range modes

OFFSET

TEST

TIME

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3. If your analyzer has a Ethernet card (Option 63) installed and your network is running a

dynamic host configuration protocol (DHCP) software package, the Ethernet option will

automatically configure its interface with your LAN. However, it is a good idea to check these

settings to make sure that the DHCP has successfully downloaded the appropriate network

settings from your network server (See Section 6.10.9.2).

If your network is not running DHCP, you will have to configure the analyzer’s interface

manually (See Section 6.10.9.3).

3.3. Initial Calibration Procedure

The next task is to calibrate the analyzer.

To perform the following calibration you must have sources for zero air and span gas available for

input into the sample port on the back of the analyzer. See Section 3.1.2 for instructions for

connecting these gas sources.

While it is possible to perform this procedure with any range setting we recommend that you

perform this initial checkout using the 50 ppm range.

NOTE

The following procedure assumes that the instrument does not have any of

the available Zero/Span Valve Options installed.

See Section 7.4 for instructions for calibrating instruments possessing Z/S

valve options.

1. Set the Analog Output Range of the MGFC7000E

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SAMPLE

RANGE = 500.000 PPM

CO2 =X.XXX

< TST TST > CAL

SETUP

SAMPLE

ENTER SETUP PASS : 818

ENTR EXIT

SETUP X.X

CFG DAS RNGE PASS CLK MORE

EXIT

SETUP X.X

RANGE CONTROL MENU

MODE SET UNIT

EXIT

Press this button to select the

concentration units of measure:

Press this button to set

the analyzer for SNGL

DUAL or AUTO ranges

PPB, PPM, UGM, MGM

SETUP X.X

RANGE: 500.000 CONC

ENTR EXIT

EXIT ignores the new setting and

returns to the RANGE CONTROL

MENU.

To change the value of the

reporting range span, enter the

number by pressing the key under

each digit until the expected value

appears.

ENTR accepts the new setting and

returns to the

SETUP X.X

RANGE: 500.000 Conc

RANGE CONTROL MENU.

ENTR EXIT

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2. Set the expected CO₂span gas concentration

SAMPLE*

RANGE = 500.000 PPM

CO2 =X.XXX

SETUP

< TST TST > CAL

This sequence causes the

analyzer to prompt for the

expected CO₂span

concentration.

M-P CAL

RANGE = 500.000 PPM

CO2 =X.XXX

EXIT

< TST TST > ZERO

CONC

The CO₂span

concentration values

automatically default to

400.0 Conc.

EXIT ignores the new setting

and returns to the previous

display.

M-P CAL

CO2 SPAN CONC: 400.000 Conc

To change this value to

the actual concentration of

the span gas, enter the

number by pressing the

key under each digit until

the expected value

ENTR accepts the new setting

ENTR EXIT

and returns to the

previous display..

appears.

NOTE

For this Initial Calibration it is important to independently verify the precise CO₂

Concentration Value of the SPAN gas.

If the source of the Span Gas is from a Calibrated Bottle, use the exact concentration

value printed on the bottle.

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3. Perform the Zero/Span Calibration Procedure

SAMPLE*

RANGE = 500.000 PPM

CO2 =XXX.X

SETUP

Set the Display to show the

STABIL test function.

This function calculates the

stability of the CO_x

< TST TST > CAL

measurement

SAMPLE

STABIL=XXX.X PPM

CO2 =XXX.X

SETUP

< TST TST > CAL

ACTION:

Allow zero gas to enter the sample port at the

rear of the instrument.

Wait until STABIL

falls below 1.0 ppm.

This may take several

minutes.

M-P CAL

STABIL=XXX.X PPM

CO2 =XXX.X

< TST TST > CAL

SETUP

M-P CAL

STABIL=XXX.X PPM

CONC

CO2 =XXX.X

EXIT

< TST TST > ZERO

Press ENTR to changes the

OFFSET & SLOPE values for the

CO₂measurements.

M-P CAL

STABIL=XXX.X PPM

CO2 =XXX.X

< TST TST > ENTR

CONC

EXIT

Press EXIT to leave the calibration

unchanged and return to the

previous menu.

ACTION:

Allow span gas to enter the sample port at the

rear of the instrument.

The value of

STABIL may jump

significantly.

Wait until it falls back

below 1.0 ppm

The SPAN key now

appears during the

transition from zero to

span.

This may take several

minutes.

M-P CAL

STABIL=XXX.X PPM

CO2 =XXX.X

EXIT

< TST TST >

M-P CAL

SPAN CONC

You may see both keys.

If either the ZERO or

SPAN buttons fail to

appear see Section 11

for troubleshooting tips.

Press ENTR to change the

OFFSET & SLOPE values for the

CO₂measurements.

RANGE = 500.000 PPM CO2 =XXX.X

EXIT

Press EXIT to leave the calibration

unchanged and return to the

previous menu.

< TST TST > ENTR SPAN CONC

M-P CAL

RANGE = 500.000 PPM CO2 =XXX.X

CONC EXIT

EXIT returns to the main

SAMPLE display

< TST TST > ENTR

The Model GFC7000E Analyzer is now ready for operation

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NOTE

Once you have completed the above set-up procedures, please fill out the Quality

Questionnaire that was shipped with your unit and return it to Teledyne Instruments.

This information is vital to our efforts in continuously improving our service and our

products.

THANK YOU.

Front Panel

IR Source

On/Off Switch &

Circuit Breaker

Particulate Filter

GFC Wheel

Housing Purge

Gas Inlet & Flow

Control Orifice

Optical Bench

Gas Inlet

Optional

Sample/Cal

Valve

GFC Motor

GFC Wheel Housing

& IR Source Heat

Sample Gas

Critical

Flow Orifice

Optional

Zero/Span

Valve

Gas Flow

Sensor Assy

Flow Sensor

Optional

Shutoff

Valve

Purge Gas

Pressure

Control Assy

Pump Assy

Sample Gas

Pressure Sensor

Optical Bench

Gas Outlet

Sample Gas

Temperature

Sensor

Optional

Ethernet Card

CPU Card

Mother

Board

Power

Receptacle

Rear Panel

Fan

Figure 3-11: Assembly Layout

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Sample Gas Outlet

fitting

Sample Gas Flow

Sensor

Sample Chamber

Sync/Demod PCA

Housing

Pressure Sensor(s)

Bench

Temperature

Thermistor

Shock Absorbing

Mounting Bracket

Opto-Pickup

PCA

Purge Gas

Pressure Regulator

IR Source

GFC Wheel

Heat Sync

GFC Wheel Motor

GFC Temperature

Sensor

Purge Gas

Inlet

GFC Heater

Figure 3-12: Optical Bench Layout

INSTRUMENT CHASSIS

SAMPLE GAS

INLET

PUMP

GFC Wheel

Motor

Purge Gas

Flow Rate

Control

EXHAUST GAS

OUTLET

Orifice

GFC Motor

Heat Sync

Purge Gas

Pressure

Control Assy

GFC Wheel

Housing

PURGE GAS

INLET

FLOW / PRESSURE

SENSOR PCA

SAMPLE

PRESSURE

SENSOR

SAMPLE CHAMBER

FLOW

SENSOR

VENT SPAN

OUTLET

PRESSURE

SPAN INLET

PARTICULATE

FILTER

IZS INLET

Figure 3-13: Internal Pneumatic Flow – Basic Configuration

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User Notes

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Frequently Asked Questions

4. FREQUENTLY ASKED QUESTIONS

4.1. FAQ’s

The following is a list from the Teledyne Instruments’ Customer Service Department of the most

commonly asked questions relating to the Model CO₂Analyzer.

Q: How do I get the instrument to zero / Why is the zero key not displayed?

A: See Section 11.2.4 Inability to zero.

Q: How do I get the instrument to span / Why is the span key not displayed?

A: See Section 11.2.3 Inability to span.

Q: Why does the ENTR key sometimes disappear on the Front Panel Display?

A: During certain types of adjustments or configuration operations, the ENTR key will disappear if

you select a setting that is nonsensical (such as trying to set the 24-hour clock to 25:00:00) or

out of the allowable range for that parameter (such as selecting an iDAS Holdoff period of more

than 20 minutes).

Once you adjust the setting in question to an allowable value, the ENTR key will re-appear.

Q: Is there an optional midpoint calibration?

A: There is an optional mid point linearity adjustment, however, midpoint adjustment is applicable

only to applications where CO₂measurements are expected above 100 ppm. Call Teledyne

Instruments’ Service Department for more information on this topic.

Q: How do I make the display and datalogger analog input agree?

A: This most commonly occurs when an independent metering device is used besides the

datalogger/recorded to determine gas concentration levels while calibrating the analyzer. These

disagreements result from the analyzer, the metering device and the datalogger having slightly

different ground levels.

If the only difference is a DC offset then it is possible to enter a compensating value in the analog

outputs. This procedure is described in Section 6.9.4.3 of this manual.

Alternately, use the datalogger itself as the metering device during calibrations procedures.

Q: How do I perform a leak check?

See Section 9.3.3.

Q: How do I measure the sample flow?

A: Sample flow is measured by attaching a calibrated rotameter, wet test meter, or other flow-

measuring device to the sample inlet port when the instrument is operating. The sample flow

should be 800 cm³/min ±10%. See Section 9.3.4.

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Q: How long does the IR source last?

A: Typical lifetime is about 2-3 years.

Q: Where is the sintered filter/sample flow control orifice?

A: These components are located inside the flow control assembly that is attached to the inlet side

of the sample pump, see Figure 3-13. See Section 11.5.1 for instructions on disassembly and

replacement.

Q: How do I set up a SEQUENCE to run a nightly calibration check?

A: The setup of this option is located in Section 7.6.

Q: How do I set the analog output signal range and offset?

A: Instructions for this can be found in Section 6.9.4 which describes analog I/O configuration.

Q: What is the averaging time for an GFC7000E?

A: The default averaging time, optimized for ambient pollution monitoring, is 150 seconds for

stable concentrations and 10 seconds for rapidly changing concentrations; see Section 10.5.1 for

more information. However, it is adjustable over a range of 0.5 second to 200 seconds (please

contact customer service for more information).

4.2. Glossary

ASSY - acronym for Assembly

DAS - acronym for data acquisition system, the old acronym of iDAS.

DIAG - acronym for diagnostics, the diagnostic settings of the analyzer

DHCP: acronym for dynamic host configuration protocol. A protocol used by LAN or Internet

servers to automatically set up the interface protocols between themselves and any other

addressable device connected to the network.

DOC - Disk On Chip, the analyzer’s central storage area for analyzer firmware, configuration

settings and data. This is a solid state device without mechanically moving parts that acts as a

computer hard disk drive under Æ DOS with disk label “C”. DOC chips come with 8 mb in the E-

series analyzer standard configuration but are available in larger sizes.

DOS - Disk Operating System. The E-series analyzers uses DR DOS

EEPROM - also referred to as a FLASH chip.

FLASH - flash memory is non-volatile, solid-state memory.

GFC – Acronym for Gas Filter Correlation.

I²C bus - a clocked, bi-directional, serial bus for communication between individual analyzer

components

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iDAS - acronym for internal data acquisition system

IP – acronym for internet protocol

LAN - acronym for local area network

LED - acronym for light emitting diode

PCA - acronym for printed circuit assembly, the Æ PCB with electronic components, ready to use.

PCB - acronym for printed circuit board, the bare board without electronic components

RS-232 - an electronic communications type of a serial communications port

RS-485 - an electronic communications type of a serial communications port

TCP/IP - acronym for transfer control protocol / internet protocol, the standard communications

protocol for Ethernet devices.

VARS - acronym for variables, the variables settings of the analyzer

User Notes

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Optional Hardware and Software

5. OPTIONAL HARDWARE AND SOFTWARE

This section includes a brief description of the hardware and software options available for the

Model GFC7000E Gas Filter Correlation Carbon Dioxide Analyzer. For assistance with ordering

these options please contact the Sales department of Teledyne – Advanced Pollution Instruments

at:

TEL: 626-961-9221

TEL: 626-934-1500

FAX: 626-961-2538

WEB SITE: www.teledyne-ai.com

5.1. Rack Mount Kits (Options 20a, 20b & 21)

Option Number

Description

OPT 20A

OPT 20B

OPT 21

Rack mount brackets with 26 in. chassis slides.

Rack mount brackets with 24 in. chassis slides.

Rack mount brackets only

Each of these options, permits the Analyzer to be mounted in a standard 19" x 30" RETMA rack.

5.2. Current Loop Analog Outputs (Option 41)

This option adds isolated, voltage-to-current conversion circuitry to the analyzer’s analog outputs.

This option may be ordered separately for any of the analog outputs, it can be installed at the

factory or added later. Call Teledyne Instruments sales for pricing and availability.

The current loop option can be configured for any output range between 0 and 20 mA.

Information on calibrating or adjusting these outputs can be found in Section 6.9.4.9.

Figure 5-1:

Current Loop Option Installed on the Motherboard

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Optional Hardware and Software

5.3. Expendable Kits (Options 42C, 42D and 43)

OPTION NUMBER

OPT 42C

DESCRIPTION

1 year’s supply of replacement of 47mm dia. particulate filters

OPT 42D

1 full replacement’s volume of indicating soda-lime for the external CO₂

scrubber included with options 51 & 53 ( approximate active lifetime: 1

year)

OPT 43

Options 42 C & 42D

5.4. Calibration Valves Options

There are four available options involving Zero/Span/Shutoff valves. From an operational and

software standpoint, all of the options are the same, only the source of the span and zero gases

are different.

5.4.1. Zero/Span/Shutoff Valve (Option 50)

This option requires that both zero air and span gas be supplied from external sources. It is

specifically designed for applications where span gas will be supplied from a pressurized bottle of

calibrated CO₂gas. A critical flow control orifice, internal to the instrument ensures that the

proper flow rate is maintained. An internal vent line, isolated by a shutoff valve ensures that the

gas pressure of the span gas is reduced to ambient atmospheric pressure. normally zero air would

be supplied from zero air module such as a Teledyne Instruments Model 701.

In order to ensure that span gas does not migrate backwards through the vent line and alter the

concentration of the span gas, a gas line not less than 2 meters in length should be attached to

the vent span outlet on the rear panel of the analyzer. To prevent the buildup of back pressure,

this vent line should not be greater than 10 meters in length.

The following table describes the state of each valve during the analyzer’s various operational

modes.

Table 5-1:

Zero/Span Valve Operating States for Options 50 & 51

MODE

VALVE

CONDITION

VALVE PORT CONNECTION

(Fig. 5-2)

Sample/Cal

Zero/Span

Open to SAMPLE inlet

Open to ZERO AIR inlet

Closed

3 Æ 2

N/A

SAMPLE

(Normal State)

Shutoff Valve

Sample/Cal

Zero/Span

Open to zero/span inlet

Open to ZERO AIR inlet

Closed

1 Æ 2

3 Æ 2

N/A

ZERO CAL

SPAN CAL

Shutoff Valve

Sample/Cal

Zero/Span

Open to ZERO/SPAN inlet

Open to SPAN GAS inlet

1 Æ 2

Shutoff Valve

Open to PRESSURE SPAN

Inlet

1 Æ 2

The minimum span gas flow rate required for this option is 800 cm³/min.

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The state of the zero/span valves can also be controlled:

•

Manually from the analyzer’s front panel by using the SIGNAL I/O controls located under

the DIAG Menu (Section 6.9.2),

•

By activating the instrument’s AutoCal feature (Section 7.6),

Remotely by using the external digital control inputs (Section 6.13.1.2 and Section 7.5.2),

•

Remotely through the RS-232/485 serial I/O ports (see Appendix A-6 for the appropriate

commands).

INSTRUMENT CHASSIS

SAMPLE GAS

INLET

PUMP

GFC Wheel

Motor

EXHAUST GAS

Purge Gas

OUTLET

Flow Control

Orifice

GFC Motor

Heat Sync

Purge Gas

Pressure

Control Assy

GFC Wheel

Housing

PURGE GAS

INLET

FLOW / PRESSURE

SENSOR PCA

SAMPLE

PRESSURE

SENSOR

SAMPLE CHAMBER

FLOW

SENSOR

VENT SPAN

OUTLET

PRESSURE

SPAN INLET

ZERO/SPAN

VALVE

SAMPLE /CAL

VALVE

SHUT OFF

VALVE

PARTICULATE

FILTER

IZS INLET

Figure 5-2:

Internal Pneumatic Flow – Zero/Span/Shutoff Valves OPT 50 & 51

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5.4.2. Zero/Span/Shutoff with External CO₂Scrubber

(Option 51)

Option 51 is operationally and pneumatically identical to Option 50 above (see section 5.4.1),

except that the zero air is generated by an externally mounted zero air scrubber filled with

indicating soda-lime that changes color from white to pink as it becomes saturated.

5.4.3. Zero/Span Valve (Option 52)

This valve option is intended for applications where zero air is supplied by a zero air generator like

the Teledyne Instruments Model 701 and span gas are being supplied by Gas Dilution Calibrator

Like the Teledyne Instruments Model 700 or 702. Internal zero/span and sample/cal valves

control the flow of gas through the instrument, but because the calibrator limits the flow of span

gas no shutoff valve is required.

In order to ensure that span gas does not migrate backwards through the vent line and alter the

concentration of the span gas, a gas line not less than 2 meters in length should be attached to

the vent span outlet on the rear panel of the analyzer. To prevent the buildup of back pressure,

this vent line should not be greater than 10 meters in length.

The following table describes the state of each valve during the analyzer’s various operational

modes.

Table 5-2:

Zero/Span Valve Operating States for Options 52 & 53

Mode

Valve

Condition

Valve Port Connection

(Fig. 5-2)

Sample/Cal

Zero/Span

Sample/Cal

Zero/Span

Sample/Cal

Zero/Span

Open to SAMPLE inlet

Open to ZERO AIR inlet

Open to zero/span inlet

Open to ZERO AIR inlet

Open to ZERO/SPAN inlet

Open to SPAN GAS inlet

3 Æ 2

1 Æ 2

3 Æ 2

1 Æ 2

SAMPLE

(Normal State)

ZERO CAL

SPAN CAL

The minimum span gas flow rate required for this option is 800 cm³/min.

The state of the zero/span valves can also be controlled:

•

Manually from the analyzer’s front panel by using the SIGNAL I/O controls located under

the DIAG Menu (Section 6.9.2),

•

By activating the instrument’s AutoCal feature (Section 7.6),

Remotely by using the external digital control inputs (Section 6.13.1.2 and Section 7.5.2),

•

Remotely through the RS-232/485 serial I/O ports (see Appendix A-6 for the appropriate

commands).

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INSTRUMENT CHASSIS

SAMPLE GAS

INLET

PUMP

GFC Wheel

Motor

EXHAUST GAS

OUTLET

Purge Gas

Flow Control

Orifice

GFC Motor

Heat Sync

Purge Gas

Pressure

Control Assy

GFC Wheel

Housing

PURGE GAS

INLET

FLOW / PRESSURE

SENSOR PCA

SAMPLE

PRESSURE

SENSOR

SAMPLE CHAMBER

FLOW

SENSOR

VENT SPAN

OUTLET

PRESSURE

SPAN INLET

ZERO/SPAN

VALVE

SAMPLE /CAL

VALVE

PARTICULATE

FILTER

IZS INLET

Figure 5-3:

Internal Pneumatic Flow – Zero/Span OPT 52 & 53

5.4.4. Zero/Span Valve with External CO₂Scrubber (Option 53)

Option 53 is operationally and pneumatically identical to Option 52 above (see Section 5.4.3),

except that the zero air is generated by an externally mounted zero air scrubber filled with

indicating soda-lime that changes color from white to pink as it becomes saturated.

5.5. Communication Options

5.5.1. RS232 Modem Cable (Option 60)

This option consists of a cable to connect the analyzer’s COM1 port to a computer, a code

activated switch or any other communications device that is equipped with a DB-9 male

connector. The cable is terminated with two DB-9 female connectors, one of which fits the

analyzer’s COM1 port.

Some older computers or code activated switches with a DB-25 serial connector will need a

different cable or an appropriate adapter.

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5.5.2. RS-232 Multidrop (Option 62)

The multidrop option is used with any of the RS-232 serial ports to enable communications of

several analyzers with the host computer over a chain of RS-232 cables. The option consists of a

small box, which can be attached to the analyzer, with a termination switch, a power connector

and two serial ports, one incoming from the analyzer (cable supplied) and one outgoing (requires

additional cable) to the next analyzer’s multi-drop box. One Option 62 is required per analyzer.

The first incoming port on the first box connects to the host computer and the outgoing port on

the last multi-drop box needs to be terminated. Setup and user instructions are covered in the

Teledyne Instruments’ multi-drop manual, part number 021790000.

5.5.3. Ethernet (Option 63)

The Ethernet option allows the analyzer to be connected to any Ethernet local area network (LAN)

running TCP/IP. The local area network must have routers capable of operating at 10BaseT. If

Internet access is available through the LAN, this option also allows communication with the

instrument over the public Internet.

When installed, this option is electronically connected to the instrument’s COM2 serial port making

that port no longer available for RS-232/RS-485 communications through the COM2 connector on

the rear panel. The option consists of a Teledyne Instruments designed Ethernet card (Figure 5-

4), which is mechanically attached to the instrument’s rear panel. A 7-foot long, CAT-5 network

cable terminated at both ends with standard RJ-45 connectors is included as well. Maximum

communication speed is limited by the RS-232 port to 115.2 kBaud.

Figure 5-4:

MGFC7000E Ethernet Card and rear panel With Ethernet Installed

5.6. Additional Manuals

5.6.1. Printed Manuals (Option 70)

Additional printed copies of this manual are available from Teledyne Instruments

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5.6.2. Manual on CD (Part number 045840200)

This operators manual is also available on CD. The electronic document is stored in Adobe

Systems Inc. Portable Document Format (PDF) and is viewable with Adobe Acrobat Reader^®

software, downloadable for free at http://www.adobe.com/

The CD version of the manual has many advantages:

•

Fully searchable text.

Hypertext links for figures, tables, table of contents and embedded references for quick

access of individual manual portions.

•

A list of thumbnails, chapters and sections displayed at the left of the text.

Internet links embedded in the manual will take you to the corresponding web site

(requires an internet connection).

5.7. Extended Warranty (Options 92 & 93)

Two options are available for extending Teledyne Instruments’ standard warranty (Section 2.3).

Both options have to be specified upon ordering the analyzer.

Option Number

OPT 92

OPT 93

Description

Extends warranty to cover a two (2) year period from the date of

purchase.

Extends warranty to cover a five (5) year period from the date of

purchase.

5.8. Dilution Ratio Option

The Dilution Ration Option is a software option that is designed for applications where the Sample

gas is diluted before being analyzed by the Model GFC7000E. Typically this occurs in Continuous

Emission Monitoring (CEM) applications where the quality of gas in a smoke stack is being tested

and the sampling method used to remove the gas from the stack dilutes the gas.

Once the degree of dilution is known, this feature allows the user to add an appropriate scaling

factor to the analyzer’s CO₂concentration calculation so that the Measurement Range and

concentration values displayed on the instrument’s Front Panel Display and reported via the

Analog and Serial Outputs reflect the undiluted values.

Instructions for using the dilution ratio option can be found in Section 6.7.7..

5.9. Maintenance Mode Switch

API’s instruments can be equipped with an switch that places the instrument in maintenance

mode. When present, the switch accessed by opening the hinged front panel and is located on

the rearward facing side of the display/keyboard driver PCA; on the left side; near the particulate

filter.

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When in maintenance mode the instrument ignores all commands received via the COMM ports

that alter the operation state of the instrument This includes all calibration commands, diagnostic

menu commands and the reset instrument command. the instrument continues to measure

concentration and send data when requested.

This option is of particular use for instruments connected to multidrop or Hessen protocol

networks.

5.10. Second Language Switch

API’s instruments can be equipped with switch that activates an alternate set of display message

in a language other than the instruments default language. When present, the switch accessed by

opening the hinged front panel and is located on the rearward facing side of the display/keyboard

driver PCA; on the right side.

To activate this feature, the instrument must also have a specially programmed Disk on Chip

containing the second language.

User Notes

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6. OPERATING INSTRUCTIONS

To assist in navigating the analyzer’s software, a series of menu trees can be found in Appendix

A-1 of this manual.

NOTES

The flow charts appearing in this section contain typical representations of the

analyzer’s display during the various operations being described. These representations

may differ slightly from the actual display of your instrument.

The ENTR key may disappear if you select a setting that is invalid or out of the allowable

range for that parameter, such as trying to set the 24-hour clock to 25:00:00. Once you

adjust the setting to an allowable value, the ENTR key will re-appear.

6.1. Overview of Operating modes

The MGFC7000E software has a variety of operating modes. Most commonly, the analyzer will be

operating in SAMPLE mode. In this mode, a continuous read-out of the CO₂concentration is

displayed on the front panel and output as an analog voltage from rear panel terminals,

calibrations can be performed, and TEST functions and WARNING messages can be examined.

The second most important operating mode is SETUP mode. This mode is used for performing

certain configuration operations, such as for the iDAS system, the reporting ranges, or the serial

(RS-232/RS-485/Ethernet) communication channels. The SET UP mode is also used for

performing various diagnostic tests during troubleshooting.

Mode Field

SAMPLE A

RANGE = 500.00 PPM

CO2 400.00

SETUP

<TST TST> CAL

Figure 6-1:

Front Panel Display

The mode field of the front panel display indicates to the user which operating mode the unit is

currently running.

Besides SAMPLE and SETUP, other modes the analyzer can be operated in are:

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Table 6-1:

Analyzer Operating modes

MEANING

MODE

DIAG

One of the analyzer’s diagnostic modes is being utilized (see Section 6.9).

M-P CAL

This is the basic, multi-point calibration mode of the instrument and is activated

by pressing the CAL key.

SAMPLE

SAMPLE A

SETUP¹

Sampling normally, flashing indicates adaptive filter is on.

Indicates that unit is in SAMPLE Mode and AUTOCAL feature is activated.

SETUP mode is being used to configure the analyzer (CO₂sampling will continue

during this process).

SPAN CAL A

Unit is performing span cal procedure initiated automatically by the analyzer’s

AUTOCAL feature.

SPAN CAL M

SPAN CAL R

Unit is performing span cal procedure initiated manually by the user.

Unit is performing span cal procedure initiated remotely via the RS-232, RS-4485

or digital i/o control inputs.

ZERO CAL A

Unit is performing zero cal procedure initiated automatically by the analyzer’s

AUTOCAL feature.

ZERO CAL M

ZERO CAL R

Unit is performing zero cal procedure initiated manually by the user.

Unit is performing zero cal procedure initiated remotely via the RS-232, RS-4485

or digital I/O control inputs.

The revision of the Teledyne Instruments software installed in this analyzer will be displayed

following the word SETUP. E.g. “SETUP E.0”

Finally, the various CAL modes allow calibration of the analyzer. Because of its importance, this

mode is described separately in Chapter 7.

6.2. Sample Mode

This is the analyzer’s standard operating mode. In this mode the instrument is analyzing the gas

in the sample chamber, calculating CO₂concentration and reporting this information to the user

via the front panel display, the analog outputs and, if set up properly, the RS-232/485/Ethernet

ports.

NOTE

A value of “XXXX” displayed in the CO2 Concentration field means that the M/R ratio is

invalid because CO2 REF is either too high(> 4950 mVDC) or too low (< 1250 VDC).

6.2.1. Test Functions

A series of test functions is available at the front panel while the analyzer is in SAMPLE mode.

These parameters provide information about the present operating status of the instrument and

are useful during troubleshooting (Section 11.1.2 ). They can also be recorded in one of the iDAS

channels (Section 6.12) for data analysis. To view the test functions, press one of the <TST TST>

keys repeatedly in either direction.

Table 6-2:

Units

Test Functions Defined

Meaning

Parameter

Display

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Title

The full scale limit at which the reporting range of the

analyzer is currently set.

THIS IS NOT the Physical Range of the instrument. See

Section 6.7 for more information.

Range

RANGE

PPB, PPM,

UGM,

RANGE1¹

RANGE2¹

MGM

Standard deviation of CO₂concentration readings. Data

points are recorded every ten second. The calculation uses

the last 25 data points.

Stability

STABIL

PPB, PPM

UGM,

MGM

The demodulated, peak IR detector output during the

measure portion of the CFG Wheel cycle.

CO₂Measure

CO₂

MEAS

The demodulated, peak IR detector output during the

reference portion of the CFG wheel cycle.

CO₂Reference

CO₂REF

The result of CO2 MEAS divided by CO2 REF. This ratio is

the primary value used to compute CO₂concentration. The

value displayed is not linearized.

Measurement / MR Ratio

Reference

Ratio

The absolute pressure of the Sample gas as measured by a

solid state pressure sensor located inside the sample

chamber.

Sample

Pressure

PRES

In-Hg-A

cc/min

Sample mass flow rate. This is computed from the differential

between the pressures measured up-stream and down-

stream of the sample critical flow orifice pressures.

Sample Flow

SAMPLE

The temperature of the gas inside the sample chamber.

Sample

Temperature

SAMP

TEMP

°C

Optical bench temperature.

Bench

Temperature

BENCH

TEMP

Filter wheel temperature.

Wheel

Temperature

WHEEL

TEMP

°C

The temperature inside the analyzer chassis.

Box

BOX

°C

Temperature

TEMP

The drive voltage being supplied to the thermoelectric coolers

of the IR photo-detector by the sync/demod Board.

Photo-detector

Temp. Control

Voltage

PHT

DRIVE

The sensitivity of the instrument as calculated during the last

calibration activity. The SLOPE parameter is used to set the

span calibration point of the analyzer.

Slope

SLOPE

The overall offset of the instrument as calculated during the

last calibration activity. The OFFSET parameter is used to

set the zero point of the analyzer response.

Offset

OFFSET

Displays the signal level of the TEST analog output channel.

Only appears when the TEST channel has been activated.

Test channel

output signal

TEST

TIME

mV, mA

The current time. This is used to create a time stamp on

iDAS readings, and by the AUTOCAL feature to trigger

calibration events.

Current Time

Only appears when the instrument’s reporting range mode is set for DUAL or AUTO

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To view the TEST Functions press the following Key sequence:

SAMPLE

RANGE = 500.000 PPM

CO2 = XXX.X

SETUP

< TST TST > CAL

RANGE

RANGE1¹

RANGE2¹

STABIL

Toggle <TST TST> keys to

scroll through list of functions

CO2 MEAS

CO2 REF

MR RATIO

PRES

SAMP FL

SAMP TEMP

BENCH TEMP

WHEEL TEMP

BOX TEMP

PHT DRIVE

SLOPE

Refer to

Table 6-2

for

definitions

of these

test

functions.

¹Only appears instrument is set

for DUAL or AUTO reporting

range modes

OFFSET

TEST

TIME

Figure 6-2

Viewing MGFC7000E TEST Functions

NOTE

A value of “XXXX” displayed for any of the TEST functions indicates an out-of-range

reading or the analyzer’s inability to calculate it.

All pressure measurements are represented in terms of absolute pressure. Absolute,

atmospheric pressure is 29.92 in-Hg-A at sea level. It decreases about 1 in-Hg per 300

m gain in altitude. A variety of factors such as air conditioning and passing storms can

cause changes in the absolute atmospheric pressure.

6.2.2. Warning Messages

The most common instrument failures will be reported as a warning on the analyzer’s front panel

and through the COM ports. Section 11.1.1 explains how to use these messages to troubleshoot

problems. Section 3.2.3 shows how to view and clear warning messages.

Table 6-3 lists all warning messages for the current version of software.

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Table 6-3:

List of Warning Messages

MESSAGE

MEANING

ANALOG CAL WARNING

The instruments A/D circuitry or one of its analog outputs is not calibrated.

The Temperature of the optical bench is outside the specified limits.

BENCH TEMP WARNING

BOX TEMP WARNING

Remote span calibration failed while the dynamic span feature was set to

turned on

CANNOT DYN SPAN

CANNOT DYN ZERO

Remote zero calibration failed while the dynamic zero feature was set to

turned on

Configuration was reset to factory defaults or was erased.

Concentration alarm 1 is enabled and the measured CO₂level is ≥ the set

point.

CONC ALRM1 WARNING

CONC ALRM2 WARNING

Concentration alarm 2 is enabled and the measured CO₂level is ≥ the set

point.

CONFIG INITIALIZED

DATA INITIALIZED

FRONT PANEL WARN

Configuration storage was reset to factory configuration or erased.

iDAS data storage was erased.

Firmware is unable to communicate with the front panel.

The temperature of the IR photometer is outside the specified limits.

The CPU is unable to communicate with the motherboard.

PHOTO TEMP WARNING

REAR BOARD NOT DET

RELAY BOARD WARN

SAMPLE FLOW WARN

SAMPLE PRESS WARN

The firmware is unable to communicate with the relay board.

The flow rate of the sample gas is outside the specified limits.

Sample gas pressure outside of operational parameters.

SAMPLE TEMP WARN

SOURCE WARNING

The temperature of the sample gas is outside the specified limits.

The IR source may be faulty.

SYNC WARNING

The instrument is not properly tracking the rotation of the Gas Filter

Correlation wheel.

SYSTEM RESET

The computer was rebooted.

WHEEL TEMP WARNING

The Gas Filter Correlation wheel temperature is outside the specified limits.

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To view and clear warning messages

SAMPLE

HVPS WARNING

CAL MSG

CO2 = 0.00

TEST deactivates warning

TEST

CLR SETUP

messages

MSG activates warning

SAMPLE

RANGE=500.000 PPM

MSG

CO2 = 0.00

messages.

<TST TST> keys replaced with

< TST TST > CAL

CLR SETUP

TEST key

SAMPLE

HVPS WARNING

CO2 = 0.00

Press CLR to clear the current

message.

TEST

CAL

MSG

CLR SETUP

NOTE:

If more than one warning is active, the

next message will take its place

If the warning message persists

after several attempts to clear it,

the message may indicate a

real problem and not an artifact

of the warm-up period

Once the last warning has been

cleared, the analyzer returns to

SAMPLE mode

Make sure warning messages are

not due to real problems.

Figure 6-3

Viewing and Clearing MGFC7000E WARNING Messages

6.3. Calibration Mode

Pressing the CAL key switches the MGFC7000E into multi-point calibration mode. In this mode,

the user can calibrate the instrument or check the instruments calibration with the use of

calibrated zero or span gases.

If the instrument includes either the zero/span valve option or IZS option, the display will also

include CALZ and CALS keys. Pressing either of these keys also puts the instrument into

multipoint calibration mode.

•

The CALZ key is used to initiate a calibration of the zero point.

The CALS key is used to calibrate the span point of the analyzer. It is recommended that

this span calibration is performed at 90% of full scale of the analyzer’s currently selected

reporting range.

Because of their critical importance and complexity, calibration operations are described in detail

in Chapter 7 of this manual. For more information concerning the zero/span, zero/span/shutoff

and IZS valve options, see Section 5.4.

6.3.1. SETUP – PASS: Calibration Password Security

The MGFC7000E calibration functions may be password protected for to prevent inadvertent

adjustments. When the calibration password has been enabled using the PASS menu item found

under the Setup Menu (see below), the system will prompt the user for a password anytime CAL,

CALZ, CALS activated.

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The default status of the calibration password is OFF. To enable the calibration password press:

SAMPLE

RANGE = 500.000 PPM

CO2 =X.XXX

< TST TST > CAL

SETUP

ENTR accepts

displayed

SAMPLE

ENTER SETUP PASS : 818

password value

ENTR EXIT

EXIT returns to

SAMPLE display

SETUP X.X

PRIMARY SETUP MENU

CFG DAS RNGE PASS CLK MORE

EXIT

SETUP X.X

CAL. PASSWORD ENABLE: OFF

CAL. PASSWORD

default state is

OFF

Toggles

password

status On/Off

OFF

ENTR EXIT

SETUP X.X

PASSWORD ENABLE: ON

ENTR EXIT

ENTR accepts

the change

SETUP X.X

PASSWORD ENABLE: ON

ENTR EXIT

EXIT ignores

the change

If the calibration password (101) is enabled, the following keypad sequence will be required to

enter one of the calibration modes:

SAMPLE*

RANGE = 500.000 PPM

CO2 =X.XXX

SETUP

< TST TST > CAL CALZ CALS

SAMPLE

ENTER SETUP PASS : 0

Prompts

password

number

ENTR EXIT

SAMPLE

ENTER SETUP PASS : 0

Press

individual

keys to set

101

M-P CAL

RANGE = 500.000 PPM

CO2 =X.XXX

EXIT

< TST TST > ZERO

CONC

Continue calibration process …

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6.4. SETUP Mode

The SETUP mode contains a variety of choices that are used to configure the analyzer’s hardware

and software features, perform diagnostic procedures, gather information on the instruments

performance and configure or access data from the internal data acquisition system (iDAS). For a

visual representation of the software menu trees, refer to Appendix A-1.

The areas access under the Setup mode are:

Table 6-4:

Primary Setup Mode Features and Functions

KEYPAD

LABEL

MANUAL

SECTION

MODE OR FEATURE

DESCRIPTION

Lists key hardware and software configuration

information

Analyzer Configuration

Auto Cal Feature

CFG

6.5

Used to set up an operate the AutoCal feature.

Only appears if the analyzer has one of the internal

valve options installed

ACAL

7.6

Internal Data Acquisition

(iDAS)

DAS

RNGE

PASS

CLK

Used to set up the iDAS system and view recorded data

6.12

6.7

Analog Output Reporting

Range Configuration

Used to configure the output signals generated by the

instruments Analog outputs.

Calibration Password

Security

Turns the calibration password feature ON/OFF

6.3.1

6.6

Internal Clock

Configuration

Used to Set or adjust the instrument’s internal clock

This button accesses the instruments secondary setup

See

Table 6-5

Advanced SETUP features

Table 6-5:

Secondary Setup Mode Features and Functions

KEYPAD

LABEL

MANUAL

SECTION

MODE OR FEATURE

DESCRIPTION

Used to set up and operate the analyzer’s various

external I/O channels including RS-232; RS 485,

modem communication and/or Ethernet access.

External Communication

Channel Configuration

6.10 &

6.13

COMM

Used to view various variables related to the

instruments current operational status

System Status Variables

VARS

DIAG

6.8

6.9

Used to access a variety of functions that are used to

configure, test or diagnose problems with a variety of

the analyzer’s basic systems

System Diagnostic

Features

Used to activate the analyzer’s two gas concentration

status alarms and set the alarm limits

CO₂Concentration Alarms

ALRM

6.11

NOTE

Any changes made to a variable during one of the following procedures is not

acknowledged by the instrument until the ENTR Key is pressed

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If the EXIT key is pressed before the ENTR key, the analyzer will beep alerting the user

that the newly entered value has been lost.

6.4.1. SETUP Mode Password Security

Whenever the Model GFC7000E’s SETUP mode is activated the instrument will prompt the user to

enter a security password. The default password is 818. This allows access to all of the

instruments basic functions and operating modes as well as some of its more powerful diagnostic

tools and variables.

The analyzer will automatically insert 818 into the password prompt field. Simply press ENTR to

proceed.

Other password levels exist allowing access to special diagnostic tools and variables used only for

specific and rarely needed troubleshooting and adjustment procedures. They may be made

available as needed by Teledyne Instruments’ Customer Service department.

6.5. SETUP – CFG: Viewing the Analyzer’s

Configuration Information

Pressing the CFG key displays the instrument configuration information. This display lists the

analyzer model, serial number, firmware revision, software library revision, CPU type and other

information. Use this information to identify the software and hardware when contacting customer

service. Special instrument or software features or installed options may also be listed here.

SAMPLE*

RANGE = 500.000 PPB

CO2 =X.XXX

< TST TST > CAL

SETUP

SAMPLE

ENTER SETUP PASS : 818

ENTR EXIT

Press NEXT of PREV to move back

and forth through the following list

of Configuration information:

• MODEL NAME

SAMPLE

PRIMARY SETUP MENU

Press EXIT at

any time to

return to the

• SERIAL NUMBER

• SOFTWARE REVISION

• LIBRARY REVISION

CFG DAS RNGE PASS CLK MORE

EXIT

•

iCHIP SOFTWARE REVISION¹

SAMPLE display

•

HESSEN PROTOCOL REVISION¹

•

ACTIVE SPECIAL SOFTWARE

SAMPLE

GFC7000E CO2 ANALYZER

OPTIONS¹

Press EXIT at

any time to

return to

• CPU TYPE

• DATE FACTORY CONFIGURATION

SAVED

NEXT PREV

EXIT

SETUP menu

¹Only appears if relevant option of Feature is active.

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6.6. SETUP – CLK: Setting the Internal Time-of-Day

Clock

The MGFC7000E has a time of day clock that supports the AutoCal timer, time of day TEST

function, and time stamps on most COM port messages. To set the time-of-day, press:

SAMPLE

RANGE = 500.000 PPM

CO2 =X.XXX

< TST TST > CAL

SETUP

SAMPLE

ENTER SETUP PASS : 818

ENTR EXIT

SETUP X.X

PRIMARY SETUP MENU

CFG DAS RNGE PASS CLK MORE

EXIT

SETUP X.X

TIME-OF-DAY CLOCK

Enter Current

Time-of-Day

Enter Current

Date-of-Year

TIME DATE

EXIT

SETUP X.X

DATE: 01-JAN-02

SETUP X.X

TIME: 12:00

JAN

ENTR EXIT

: 0

ENTR EXIT

SETUP X.X

JAN

DATE: 01-JAN-02

SETUP X.X3

: 0

TIME: 12:00

ENTR EXIT

SETUP X.X

TIME-OF-DAY CLOCK

TIME DATE

SETUP X.X

EXIT

EXIT returns

to the main

SAMPLE display

PRIMARY SETUP MENU

CFG DAS RNGE PASS CLK MORE

EXIT

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In order to compensate for CPU clocks which run faster or slower, you can adjust a variable called

CLOCK_ADJ to speed up or slow down the clock by a fixed amount every day. To change this

variable, press:

SAMPLE

RANGE = 500.000 PPM

CO2 =X.XXX

SETUPX.X

1 ) CONC_PRECISION = 3

EDIT PRNT EXIT

< TST TST > CAL

SETUP

PREV NEXT JUMP

SAMPLE

ENTER SETUP PASS : 818

Continue to press NEXT until …

ENTR EXIT

SETUP X.X

4) CLOCK_ADJ=0 Sec/Day

JUMP EDIT PRNT EXIT

SETUP X.X

PRIMARY SETUP MENU

CFG DAS RNGE PASS CLK MORE

EXIT

SETUP X.X

CLOCK_ADJ:0 Sec/Day

ENTR EXIT

SETUP X.X

SECONDARY SETUP MENU

COMM VARS DIAG

EXIT

Enter sign and number of seconds per

day the clock gains (-) or loses (+).

SETUP X.X

0 ) DAS_HOLD_OFF=15.0 Minutes

SETUP X.X

4) CLOCK_ADJ=0 Sec/Day

NEXT JUMP

EDIT PRNT EXIT

PREV NEXT JUMP

EDIT PRNT EXIT

3x EXIT returns

to the main SAMPLE display

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6.7. SETUP – RNGE: Analog Output Reporting Range

Configuration

The analyzer has three active analog output signals, accessible through a connector on the rear

panel.

ANALOG OUT

SO₂concentration

Test Channel

outputs

Not Used

LOW range when

DUAL mode is selected

HIGH range when

DUAL mode is selected

Figure 6-4:

Analog Output Connector Pin Out

All three outputs can be configured either at the factory or by the user for full scale outputs of 0.1

VDC, 1VDC, 5VDC or 10VDC. Additionally A1 and A2 may be equipped with optional 0-20 mADC

current loop drivers and configured for any current output within that range (e.g. 0-20, 2-20, 4-

20, etc.). The user may also adjust the signal level and scaling of the actual output voltage or

current to match the input requirements of the recorder or datalogger (see Section 6.9.4).

The A1 and A2 channels output a signal that is proportional to the CO₂concentration of the

sample gas. Several modes are available which allow them to operate independently or be slaved

together (see Section 6.7). The user may also select between a variety of reporting range spans

(see Sections 6.7.3, 6.7.4 and 6.7.5).

EXAMPLE:

A1 OUTPUT: Output Signal = 0-5 VDC representing 0-1000 ppm concentration values

A2 OUTPUT: Output Signal = 0 – 10 VDC representing 0-500 ppm concentration values.

The output, labeled A3 is special. It can be set by the user (see Section 6.9.9) to output several

of the test functions accessible through the <TST TST> keys of the units sample display.

Output A4 is not available on the Model GFC7000E analyzer.

6.7.1. Physical Range versus Analog Output Reporting Ranges

Functionally, the Model GFC7000E Gas Filter Correlation CO₂Analyzer has one hardware Physical

Range that is capable of determining CO₂concentrations between 50 ppb and 2 000 ppm. This

architecture improves reliability and accuracy by avoiding the need for extra, switchable, gain-

amplification circuitry. Once properly calibrated, the analyzer’s front panel will accurately report

concentrations along the entire span of its 50 ppb and 2 000 ppm physical range.

Because, most applications use only a small part of the analyzer’s physical range, the width of the

Model GFC7000E’s physical range can create data resolution problems for most analog recording

devices. For example, in an application where the expected concentration of CO₂is typically less

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than 500 ppm, the full scale of expected values is only 25% of the instrument’s 2 000 ppm

physical range. Unmodified, the corresponding output signal would also be recorded across only

25% of the range of the recording device.

The MGFC7000E solves this problem by allowing the user to select a scaled reporting range for the

analog outputs that only includes that portion of the physical range relevant to the specific

application. Only the reporting range of the analog outputs is scaled, the physical range of the

analyzer and the readings displayed on the front panel remain unaltered.

6.7.2. Reporting Range Modes

The MGFC7000E provides three analog output range modes to choose from.

•

Single range (SNGL) mode sets a single maximum range for the analog output. If single

range is selected (see Section 6.7.3) both outputs are slaved together and will represent

the same measurement span (e.g. 0-50 ppm), however their electronic signal levels may

be configured for different ranges (e.g. 0-10 VDC vs. 0-.1 VDC – See Section 6.9.4.1).

Dual range (DUAL) allows the A1 and A2 outputs to be configured with different

measurement spans (see Section 6.7.4) as well as separate electronic signal levels (see

Section 6.9.4.1).

•

Auto range (AUTO) mode gives the analyzer to ability to output data via a low range and

high range. When this mode is selected (see Section 6.7.5) the MGFC7000E will

automatically switch between the two ranges dynamically as the concentration value

fluctuates.

Range status is also output via the External Digital I/O Status Bits (see Section 6.13.1.1).

To select the Analog Output Range Type press:

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SAMPLE*

RANGE = 500.000 PPM

CO2 =X.XXX

< TST TST > CAL

SETUP

SAMPLE

ENTER SETUP PASS : 818

8 ENTR EXIT

SETUP X.X

CFG DAS RNGE PASS CLK MORE

EXIT

SETUP X.X

RANGE CONTROL MENU

MODE SET UNIT

EXIT

SETUP X.X

RANGE MODE: SNGL

EXIT Returns

to the Main

SNGL DUAL AUTO

ENTR EXIT

SAMPLE Display

Only one of the

range modes may

be active at any

time.

Go To

Section

6.7.3

Go To

Section

6.7.4

Go To

Section

6.7.5

NOTE

Upper span limit setting for the individual range modes are shared. Resetting the span

limit in one mode also resets the span limit for the corresponding range in the other

modes as follows:

SNGL

Range

DUAL

AUTO

ÅÆ Range1 ÅÆ Low Range

Range2 ÅÆ High Range

6.7.3. Single Range mode (SNGL)

This is the default reporting range mode for the analyzer. In single range mode both A1 and A2

are set to the same reporting range. This reporting range can be any value between 50 ppb and 2

000 ppm.

While the two outputs always have the same reporting range, the span, signal offset and scaling

of their electronic signals may be configured for differently (e.g., A1 = 0-10 V; A2 = 0-0.1 V).

See Section 6.9.4 for instructions on adjusting these parameters.

To select SNGLE range mode and to set the upper limit of the range, press:

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SAMPLE*

RANGE = 500.000 PPM

CO2 X.XXX

< TST TST > CAL

SETUP

SETUP C.3

RANGE MODE: SNGL

SAMPLE

ENTER SETUP PASS : 818

SNGL DUAL AUTO

ENTR EXIT

SETUP C.3

RANGE CONTROL MENU

SETUP C.3

PRIMARY SETUP MENU

MODE SET UNIT

EXIT

CFG DAS RNGE PASS CLK MORE

EXIT

SETUP C.3

RANGE CONTROL MENU

SETUP C.3

RANGE: 500.0 Conc

MODE SET UNIT

EXIT

ENTR EXIT

SETUP C.3

RANGE MODE: SNGL

SETUP C.3

MODE SET UNIT

RANGE CONTROL MENU

EXIT x 2 returns

to the main

SAMPLE display

SNGL DUAL AUTO

ENTR EXIT

EXIT

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6.7.4. Dual Range Mode (DUAL)

Selecting Dual Range mode allows the A1 and A2 outputs to be configured with different

reporting ranges. The analyzer software calls these two ranges low and high. The low range

setting corresponds with the analog output labeled A1 on the Rear Panel of the instrument. The

high Range Setting corresponds with the A2 output. While the software names these two ranges

low and high, they do not have to be configured that way. For example: The low range can be set

for a span of 0-1000 ppm while the high range is set for 0-500 ppm.

In DUAL range mode the RANGE test function displayed on the front panel will be replaced by

two separate functions:

•

RANGE1: The range setting for the A1 output.

RANGE2: The range setting for the A2 output.

To set the ranges press following keystroke sequence

SAMPLE*

RANGE = 500.000 PPM

CO2 =X.XXX

SETUP X.X

RANGE MODE: DUAL

< TST TST > CAL

SETUP

SNGL DUAL AUTO

ENTR EXIT

SAMPLE

ENTER SETUP PASS : 818

SETUP X.X

RANGE CONTROL MENU

ENTR EXIT

MODE SET UNIT

EXIT

SETUP X.X

PRIMARY SETUP MENU

SETUP X.X

LOW RANGE: 500.0 Conc

.0 ENTR EXIT

CFG DAS RNGE PASS CLK MORE

EXIT

Toggle the

Numeral Keys

to set the upper

limit of each

range.

SETUP X.X

RANGE CONTROL MENU

SETUP X.X

HIGH RANGE: 500.0 Conc

.0 ENTR EXIT

MODE SET UNIT

SETUP X.X

RANGE MODE: SNGL

SETUP X.X

RANGE CONTROL MENU

EXIT Returns

to the Main

SAMPLE Display

SNGL DUAL AUTO

ENTR EXIT

MODE SET UNIT

EXIT

When the instrument’s range mode is set to DUAL the concentration field in the upper right hand

corner of the display alternates between displaying the low range value and the high range value.

The concentration currently being displayed is identified as follows: C1 = Low (or A1) and C2 =

High (or A2).

NOTE

In DUAL range mode the LOW and HIGH ranges have separate slopes and offsets for

computing CO₂concentration.

The two ranges must be independently calibrated.

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6.7.5. Auto Range Mode (AUTO)

In AUTO range mode, the analyzer automatically switches the reporting range between two user-

defined ranges (low and high). The unit will switch from low range to high range when the CO₂

concentration exceeds 98% of the low range span. The unit will return from high range back to

low range once both the CO₂concentration falls below 75% of the low range span.

In AUTO Range mode the instrument reports the same data in the same range on both the A1

and A2 outputs and automatically switches both outputs between ranges as described above.

Also, the RANGE test function displayed on the front panel will automatically switch to show

which range is in effect.

The high/low range status is also reported through the external, digital status bits (Section

6.13.1.1).

To set individual ranges press the following keystroke sequence.

SAMPLE*

RANGE = 500.000 PPM

CO2 =X.XXX

SETUP X.X

RANGE MODE: AUTO

< TST TST > CAL

SETUP

SNGL DUAL AUTO

ENTR EXIT

SAMPLE

ENTER SETUP PASS : 818

ENTR EXIT

SETUP X.X

RANGE CONTROL MENU

EXIT x 2 returns

to the main

SAMPLE display

MODE SET UNIT

EXIT

SETUP X.X

PRIMARY SETUP MENU

CFG DAS RNGE PASS CLK MORE

EXIT

SETUP X.X

LOW RANGE: 500.0 Conc

.0 ENTR EXIT

Toggle the numeral

keys to set the

LOW and HIGH

range value.

SETUP X.X

RANGE CONTROL MENU

MODE SET UNIT

ENTR accepts the

new setting, EXIT

ignores the new

setting.

SETUP X.X

RANGE MODE: SNGL

SETUP X.X

HIGH RANGE: 500.0 Conc

.0 ENTR EXIT

SNGL DUAL AUTO

ENTR EXIT

CAUTION

In AUTO range mode the LOW and HIGH ranges have separate slopes and offsets for

computing CO2 concentration.

The two ranges must be independently calibrated.

NOTE

Avoid accidentally setting the low range of the instrument with a higher span limit than

the high range. This will cause the unit to stay in the low reporting range perpetually

and defeat the function of the AUTO range mode.

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6.7.6. Range Units

The MGFC7000E can display concentrations in parts per billion (10⁹mols per mol, PPB), parts per

million (10⁶mols per mol, PPM), micrograms per cubic meter (µg/m³, UG), milligrams per cubic

meter (mg/m³, MG) or percent (volume CO₂/volume sample gas, %). Changing units affects all of

the display, analog outputs, COM port and iDAS values for all reporting ranges regardless of the

analyzer’s range mode.

NOTE

Concentrations displayed in mg/m3 and ug/m3 use 0°C, 760 mmHg for Standard

Temperature and Pressure (STP). Consult your local regulations for the STP used by

your agency.

Conversion factors from volumetric to mass units are:

CO₂: ppb x 1.96 = µg/m3; ppm x 1.96 = mg/m3

To change the concentration units:

SAMPLE

RANGE = 500.00 PPB

CO2=X.XXX

< TST TST > CAL

SETUP

SAMPLE

ENTER SETUP PASS : 818

ENTR EXIT

SETUP X.X

PRIMARY SETUP MENU

CFG DAS RNGE PASS CLK MORE

EXIT

EXIT returns

to the main menu.

SETUP X.X

RANGE CONTROL MENU

MODE SET UNIT

SETUP X.X

CONC UNITS: PPM

Select the preferred

concentration unit.

PPM PPB UGM MGM

ENTER EXIT

ENTR accepts

the new unit,

EXIT returns

to the SETUP

menu.

SETUP X.X

CONC UNITS: %

PPM PPB UGM MGM

NOTE

Once the units of measurement have been changed the unit MUST be recalibrated, as

the “expected span values” previously in effect will no longer be valid. Simply entering

new expected span values without running the entire calibration routine is not

sufficient.

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6.7.7. Dilution Ratio

The dilution ratio is a software option that allows the user to compensate for any dilution of the

sample gas before it enters the sample inlet. Using the dilution ratio option is a 4-step process:

1. Select reporting range units: Follow the procedure in Section 6.7.6.

2. Select the range: Use the procedures in Section 6.7.2 – 6.7.5. Make sure that the SPAN value

entered is the maximum expected concentration of the undiluted calibration gas and that the

span gas is either supplied through the same dilution inlet system as the sample gas or has an

appropriately lower actual concentration. For example, with a dilution set to 100, a 10 ppm

gas can be used to calibrate a 1000 ppm sample gas if the span gas is not routed through the

dilution system. On the other hand, if a 1000 ppm span gas is used, it needs to pass through

the same dilution steps as the sample gas.

3. Set the dilution factor as a gain (e.g., a value of 20 means 20 parts diluting gas and 1 part of

sample gas):

SAMPLE*

RANGE = 500.000 PPM

CO2 =X.XXX

< TST TST > CAL

SETUP

SAMPLE

ENTER SETUP PASS : 818

ENTR EXIT

SETUP C.3

PRIMARY SETUP MENU

CFG DAS RNGE PASS CLK MORE

EXIT

SETUP C.3

RANGE CONTROL MENU

DIL only appears

if the dilution ratio

option has been

installed

MODE SET UNIT DIL

EXIT ignores the

new setting.

SETUP C.3

DIL FACTOR: 1.0 GAIN

.0 ENTR

ENTR accepts the

Toggle these keys to set the dilution

factor.

new setting.

This is the number by which the

analyzer will multiply the CO₂

concentrations of the gas passing

through the reaction cell.

SETUP C.3

DIL FACTOR: 20.0 GAIN

.0 ENTR

The analyzer multiplies the measured gas concentrations with this dilution factor and displays the

result.

NOTE

Once the above settings have been entered, the instrument needs to be recalibrated

using one of the methods discussed in Chapter 7.

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6.8. SETUP – VARS: Using the Internal Variables

The MGFC7000E has several-user adjustable software variables, which define certain operational

parameters. Usually, these variables are automatically set by the instrument’s firmware, but can

be manually re-defined using the VARS menu. Table 6-6 lists all variables that are available within

the 818 password protected level.

Table 6-6:

Variable Names (VARS) Revision B.3

Description

No.

Variable

Allowed Values

Changes the internal data acquisition system (iDAS)

hold-off time, which is the duration when data are

not stored in the iDAS because the software

considers the data to be questionable. That is the

case during warm-up or just after the instrument

returns from one of its calibration modes to SAMPLE

mode. DAS_HOLD_OFF can be disabled entirely in

each iDAS channel.

Can be between

0.5 and 20

minutes

DAS_HOLD_OFF

Default=15 min.

Allows the user to set the number of significant digits

CONC_PRECISION to the right of the decimal point display of

AUTO, 1, 2, 3, 4

Default=AUTO

concentration and stability values.

Dynamic zero automatically adjusts offset and slope

of the CO₂response when performing a zero point

calibration during an AutoCal (Chapter 7).

DYN_ZERO

DYN_SPAN

CLOCK_ADJ

ON/OFF

Dynamic span automatically adjusts slope and slope

of the CO₂response when performing a zero point

calibration during an AutoCal (Chapter 7).

Note that the DYN_ZERO and DYN_SPAN features

are not allowed for applications requiring EPA

equivalency.

Adjusts the speed of the analyzer’s clock. Choose the

+ sign if the clock is too slow, choose the - sign if

the clock is too fast.

-60 to +60 s/day

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To access and navigate the VARS menu, use the following key sequence.

SAMPLE*

RANGE = 500.000 PPM

CO2 =X.XXX

< TST TST > CAL

SETUP

SAMPLE

ENTER SETUP PASS : 818

ENTR EXIT

SETUP X.X

PRIMARY SETUP MENU

CFG DAS RNGE PASS CLK MORE

EXIT

EXIT ignores the new setting.

ENTR accepts the new setting.

SETUP X.X

SECONDARY SETUP MENU

COMM VARS DIAG ALRM

SETUP X.X

0 ) DAS_HOLD_OFF=15.0 Minutes

SETUP X.X

DAS_HOLD_OFF=15.0 Minutes

ENTR EXIT

NEXT JUMP

EDIT PRNT EXIT

Toggle this keys to change setting

SETUP X.X

6) CONC_PRECUISION : 3

SETUP X.X

CONC_PRECUISION : 3

PREV NEXT JUMP

EDIT PRNT EXIT

AUTO

ENTR EXIT

Toggle these keys to change setting

SETUP X.X

4 ) DYN_ZERO=ON

SETUP X.X

DYN_ZERO=ON

PREV NEXT JUMP

EDIT PRNT EXIT

ENTR EXIT

Toggle this keys to change setting

SETUP X.X

5) DYN_SPAN=ON

PREV NEXT JUMP

EDIT PRNT EXIT

SETUP X.X

DYN_SPAN=ON

ENTR EXIT

Toggle this keys to change setting

SETUP X.X

7) CLOCK_ADJ=0 Sec/Day

SETUP X.X

CLOCK_ADJ=0 Sec/Day

ENTR EXIT

PREV NEXT JUMP

EDIT PRNT EXIT

Toggle tese keys to change setting

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6.9. SETUP – DIAG: Using the Diagnostics Functions

A series of diagnostic tools is grouped together under the SETUPÆMOREÆDIAG menu. As these

parameters are dependent on firmware revision (see Menu Tree A-6 in Appendix A). The individual

parameters, however, are explained in more detail in the section indicated in Table 6-7. These

tools can be used in a variety of troubleshooting and diagnostic procedures and are referred to in

many places of the maintenance and trouble-shooting sections.

Table 6-7:

GFC7000E Diagnostic (DIAG) Functions

Front Panel

Mode

DIAGNOSTIC FUNCTION AND MEANING

SECTION

Indicator

SIGNAL I/O: Allows observation of all digital and analog

signals in the instrument. Allows certain digital signals

such as valves and heaters to be toggled ON and OFF.

DIAG I/O

6.9.2

ANALOG OUTPUT: When entered, the analyzer performs

an analog output step test. This can be used to calibrate

a chart recorder or to test the analog output accuracy.

DIAG AOUT

DIAG AIO

6.9.3

6.9.4

ANALOG I/O CONFIGURATION: the signal levels of the

instruments analog outputs may be calibrated (either

individually or as a group). Various electronic

parameters such as signal span, and offset are available

for viewing and configuration.

ELECTRIC TEST: The analyzer is performing an electric

test. This test simulates IR detector signal in a known

manner so that the proper functioning of the

sync/demod board can be verified.

DIAG

OPTIC

6.9.5

6.9.6

6.9.7

DARK CALIBRATION: The analyzer is performing a dark

calibration procedure. This procedure measures and

stores the inherent dc offset of the sync/demod board

electronics.

DIAG ELEC

DIAG PCAL

PRESSURE CALIBRATION: The analyzer records the

current output of the sample gas pressure sensor. This

value is used by the CPU to compensate the CO₂

concentration.

FLOW CALIBRATION: This function is used to calibrate

the gas flow output signals of sample gas and ozone

supply. These settings are retained when exiting DIAG.

DIAG FCAL

DIAG TCHN

6.9.8

6.9.9

TEST CHAN OUTPUT: Configures the A4 analog output

channel.

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6.9.1. Accessing the Diagnostic Features

To access the DIAG functions press the following keys:

SAMPLE*

RANGE = 500.00 PPM

CO2 =X.XXX

DIAG

ANALOG I / O CONFIGURATION

< TST TST > CAL

SETUP

ENTR EXIT

SAMPLE

ENTER SETUP PASS : 818

DIAG

ELECTRICAL TEST

DARK CALIBRATION

ENTR EXIT

SETUP X.X

PRIMARY SETUP MENU

EXIT returns

to the main

SAMPLE

display

DIAG

CFG DAS RNGE PASS CLK MORE

EXIT

SETUP X.X

SECONDARY SETUP MENU

EXIT returns

to the PRIMARY

SETUP MENU

DIAG

PRESSURE CALIBRATION

COMM VARS DIAG ALRM

DIAG

SIGNAL I / O

From this point

forward, EXIT returns

to the

SECONDARY

SETUP MENU

DIAG

FLOW CALIBRATION

TEST CHAN OUTPUT

ENTR EXIT

DIAG

ANALOG OUTPUT

DIAG

6.9.2. Signal I/O

The signal I/O diagnostic mode allows to review and change the digital and analog input/output

functions of the analyzer. See Appendix A-4 for a complete list of the parameters available for

review under this menu.

NOTE

Any changes of signal I/O settings will remain in effect only until the signal I/O menu is

exited. Exceptions are the ozone generator override and the flow sensor calibration,

which remain as entered when exiting.

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Model GFC7000E Instruction Manual

Operating Instructions

To enter the signal I/O test mode, press:

SAMPLE

RANGE = 500.000 PPM

CO2 =X.XXX

DIAG

SIGNAL I / O

Use the

NEXT PREV

keys to move between

signal types.

< TST TST > CAL

SETUP

PREV NEXT JUMP

ENTR EXIT

Use the JUMP key to

go directly to a

DIAG I / O

Test Signals Displayed Here

SAMPLE

ENTER SETUP PASS : 818

specific signal

PREV NEXT JUMP

PRNT EXIT

ENTR EXIT

See Appendix A-4 for

a complete list of

EXIT returns

to the main

SAMPLE display

available SIGNALS

EXAMPLE

DIAG I / O

JUMP TO: 12

SETUP X.X

PRIMARY SETUP MENU

EXAMPLE:

ENTR EXIT

Enter 12 to Jump to

12) ST_CONC_VALID

CFG DAS RNGE PASS CLK MORE

EXIT

DIAG I / O

ST_CONC_VALID = ON

Exit to return

to the

SETUP X.X

SECONDARY SETUP MENU

DIAG menu

PREV NEXT JUMP

ON PRNT EXIT

COMM VARS DIAG ALRM

EXIT

Pressing the PRNT key will send a formatted printout to the serial port and can be

captured with a computer or other output device.

6.9.3. Analog Output Step Test

This test can be used to check the accuracy and proper operation of the analog outputs. The test

forces all four analog output channels to produce signals ranging from 0% to 100% of the full

scale range in 20% increments. This test is useful to verify the operation of the data

logging/recording devices attached to the analyzer.

To begin the Analog Output Step Test press:

SAMPLE

RANGE = 500.000 PPM

CO2 =X.XXX

DIAG

SIGNAL I / O

< TST TST > CAL

SETUP

ENTR EXIT

SAMPLE

ENTER SETUP PASS : 818

DIAG

ANALOG OUTPUT

ENTR EXIT

Performs

analog output

step test.

DIAG AOUT

ANALOG OUTPUT

SETUP X.X

PRIMARY SETUP MENU

0% - 100%

EXIT

CFG DAS RNGE PASS CLK MORE

EXIT

Exit-Exit

returns to the

DIAG AOUT

SETUP X.X

SECONDARY SETUP MENU

DIAG menu

[0%]

EXIT

COMM VARS DIAG ALRM

EXIT

Pressing the key under “0%” while performing the test will

pause the test at that level. Brackets will appear around

the value: example: [20%] Pressing the same key again

will resume the test.

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Model GFC7000E Instruction Manual

Operating Instructions

6.9.4. Analog I/O Configuration

The analog I/O functions that are available in the MGFC7000E are:

Table 6-8:

DIAG - Analog I/O Functions

Function

Sub Menu

AOUTS CALIBRATED: Shows the status of the analog output calibration (YES/NO) and initiates a

calibration of all analog output channels.

CONC_OUT_1

Sets the basic electronic configuration of the A1 analog output (CO₂) . There are

three options:

Range: Selects the signal type (voltage or current loop) and full scale level of the

output.

REC_OFS: Allows to set a voltage offset (not available when RANGE is set to

CURRent loop.

Auto_CAL: Performs the same calibration as AOUT CALIBRATED, but on this one

channel only.

NOTE: Any change to RANGE or REC_OFS requires recalibration of this output.

CONC_OUT_2

TEST OUTPUT

Same as for CONC_OUT_1 but for analog channel 2 (CO₂)

Same as for CONC_OUT_1 but for analog channel 4 (TEST)

AIN CALIBRATED

Shows the calibration status (YES/NO) and initiates a calibration of the analog to

digital converter circuit on the motherboard.

To configure the analyzer’s three analog outputs, set the electronic signal type of each channel

and calibrate the outputs. This consists of:

•

Selecting an output type (voltage or current, if an optional current output driver has been

installed) and the signal level that matches the input requirements of the recording device

attached to the channel, see Sections 6.9.4.1.

•

Calibrating the output channel. This can be done automatically or manually for each

channel, see Sections 6.9.4.2 and 6.9.4.3.

Adding a bipolar recorder offset to the signal, if required (Section 6.9.4.2.)

In its standard configuration, the analyzer’s outputs can be set for the following DC voltages. Each

range is usable from -5% to + 5% of the nominal range.

Table 6-9:

Analog Output Voltage Ranges

RANGE

0-0.1 V

0-1 V

MINIMUM OUTPUT

-5 mV

MAXIMUM OUTPUT

+105 mV

-0.05 V

+1.05 V

0-5 V

-0.25 V

+5.25 V

0-10 V

-0.5 V

+10.5 V

The default offset for all ranges is 0 VDC.

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Operating Instructions

The following DC current output limits apply to the current loop modules:

Table 6-10: Analog Output Current Loop Range

RANGE

MINIMUM OUTPUT

MAXIMUM OUTPUT

0-20 mA

0 mA

20 mA

These are the physical limits of the current loop modules, typical

applications use 2-20 or 4-20 mA for the lower and upper limits.

Please specify desired range when ordering this option.

The default offset for all ranges is 0 mA.

Pin assignments for the output connector at the rear panel of the instrument are shown in Table

6-11.

ANALOG OUT

Table 6-11: Analog Output Pin Assignments

ANALOG

OUTPUT

VOLTAGE

SIGNAL

CURRENT

SIGNAL

V Out

I Out +

Ground

I Out -

V Out

I Out +

I Out -

Ground

V Out

I Out +

I Out -

Ground

7 & 8

Not Used

See Figure 3-2 for a the location of the analog output connector on the instruments rear panel.

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Operating Instructions

6.9.4.1. Analog Output Signal Type and Range Span Selection

To select an output signal type (DC Voltage or current) and level for one output channel, activate

the ANALOG I/O CONFIGURATION MENU (see Section 6.9.1) then press:

FROM ANALOG I/O CONFIGURATION MENU

DIAG

ANALOG I / O CONFIGURATION

ENTR

EXIT

DIAG AIO

AOUTS CALIBRATED: NO

Press SET> to select the

analog output channel to be

configured. Press EDIT to

continue

< SET SET> CAL

DIAG AIO

CONC_OUT_2:5V, CAL

< SET SET> EDIT

EXIT

DIAG AIO

CONC_OUT_2 RANGE: 5V

SET> EDIT

DIAG AIOOUTPUT RANGE: 5V

These keys set

the signal level

and type of the

selected channel

0.1V 1V 5V 10V CURR

ENTR EXIT

Pressing ENTR records the new setting

and returns to the previous menu.

Pressing EXIT ignores the new setting and

returns to the previous menu.

DIAG AIOOUTPUT RANGE: 10V

0.1V 1V 5V 10V CURR

ENTR EXIT

6.9.4.2. Analog Output Calibration Mode

The analog outputs can be calibrated automatically or manually. In its default mode, the

instrument is configured for automatic calibration of all channels. Manual calibration should be

used for the 0.1V range or in cases where the outputs must be closely matched to the

characteristics of the recording device. Outputs configured for automatic calibration can be

calibrated as a group or individually. Calibration of the analog outputs needs to be carried out on

first startup of the analyzer (performed in the factory as part of the configuration process) or

whenever re-calibration is required.

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Operating Instructions

To calibrate the outputs as a group, activate the ANALOG I/O CONFIGURATION MENU (see

Section 6.9.1), then press:

STARTING FROM DIAGNOSTIC MENU

(see Section 6.7.1)

DIAG

ANALOG I / O CONFIGURATION

ENTR EXIT

Exit at any time

to return to the

main DIAG

DIAG AIO

AOUTS CALIBRATED: NO

If AutoCal has been

turned off for any

channel, the message

for that channel will be

similar to:

< SET SET> CAL

EXIT

DIAG AIO AUTO CALIBRATING CONC_OUT_1

AUTO CALIBRATING CONC_OUT_2

NOT AUTO CAL

CONC_OUT_1

AUTO CALIBRATING TEST_OUTPUT

If any of the channels have

not been calibrated this

message will read NO.

Exit to return to

the I/O

configuration

DIAG AIO

AOUTS CALIBRATED:

YES

< SET SET> CAL

EXIT

To automatically calibrate a single analog channel, activate the ANALOG I/O

CONFIGURATION MENU (see Section 6.9.1), then press:

DIAG

ANALOG I / O CONFIGURATION

NEXT ENTR EXIT

EXIT to Return

to the main

Sample Display

DIAG AIO

AOUTS CALIBRATED: NO

SET> CAL

EXIT

Press SET> to select the

Analog Output channel to

be configured. Then Press

EDIT to continue

DIAG AIO

CONC_OUT_2:5V, CAL

< SET SET> EDIT

EXIT

DIAG AIO

CONC_OUT_2 RANGE: 5V

DIAG AIO

CONC_OUT_2 CALIBRATED: NO

CAL EXIT

SET> EDIT

<SET

DIAG AIO

CONC_OUT_2 REC OFS: 0 mV

DIAG AIO

AUTO CALIBRATING CONC_OUT_2

< SET SET> EDIT

EXIT

DIAG AIO

CONC_OUT_2 AUTO CAL: ON

DIAG AIO

<SET

CONC_OUT_2 CALIBRATED: YES

CAL EXIT

< SET SET> EDIT

EXIT

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Operating Instructions

To select manual output calibration for a particular channel, activate the ANALOG I/O

CONFIGURATION MENU (see Section 6.9.1), then press:

DIAG

ANALOG I / O CONFIGURATION

ENTR EXIT

DIAG AIO

CONC_OUT_2 REC OFS: 0 mV

Exit to return to

the main

sample display

< SET SET> EDIT

EXIT

DIAG AIO

AOUTS CALIBRATED: NO

DIAG AIO

CONC_OUT_2 AUTO CAL: ON

< SET SET> CAL

EXIT

< SET SET> EDIT

EXIT

Press SET> to select the analog output channel to

be configured. Then press EDIT to continue

DIAG AIO

CONC_OUT_2 AUTO CAL: ON

DIAG AIO

CONC_OUT_2:5V, CAL

ENTR EXIT

< SET SET> EDIT

EXIT

Toggles the

auto cal mode

ON/ OFF for

this analog

output channel

only.

ENTR accepts the new setting

and returns to the previous menu.

EXIT ignores the new setting and

returns to the previous menu.

DIAG AIO

CONC_OUT_2 RANGE: 5V

SET> EDIT

Now the analog output channels should either be automatically calibrated or they should be set to

manual calibration, which is described next.

6.9.4.3. Manual Analog Output Calibration and Voltage Adjustment

For highest accuracy, the voltages of the analog outputs can be manually calibrated. Calibration is

done through the instrument software with a voltmeter connected across the output terminals

(Figure 6-5). Adjustments are made using the front panel keys by setting the zero-point first and

then the span-point (Table 6-12).

The software allows this adjustment to be made in 100, 10 or 1 count increments.

Table 6-12: Voltage Tolerances for Analog Output Calibration

Full Scale

0.1 VDC

1 VDC

Zero Tolerance

±0.0005V

±0.001V

Span Voltage

90 mV

Span Tolerance

±0.001V

900 mV

±0.001V

5 VDC

±0.002V

4500 mV

±0.003V

10 VDC

±0.004V

±0.006V

NOTE

Outputs configured for 0.1V full scale should always be calibrated manually

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Model GFC7000E Instruction Manual

Operating Instructions

See Table 3-1 for

pin assignments

of Analog Out

connector on the

rear panel

+DC Gnd

V OUT +

V OUT -

V IN +

V IN -

Recording

Device

ANALYZER

Figure 6-5:

Setup for Calibrating Analog Voltage Outputs

To make these adjustments, the AOUT auto-calibration feature must be turned off (Section

6.9.4.2). Activate the ANALOG I/O CONFIGURATION MENU (see Section 6.9.1), then press:

FROM ANALOG I/O CONFIGURATION MENU

DIAG AIO

CONC_OUT_1 RANGE: 5V

DIAG

ANALOG I / O CONFIGURATION

ENTR EXIT

SET> EDIT

EXIT

DIAG AIO

CONC_OUT_1 REC OFS: 0 mV

DIAG AIO

AOUTS CALIBRATED: NO

< SET SET> EDIT

EXIT

If AutoCal is ON, go to

Section 6.7.3

< SET SET> CAL

EXIT

DIAG AIO

CONC_OUT_1 AUTO CAL: OFF

Press SET> to select the analog output channel to be

< SET SET> EDIT

configured:

DISPLAYED AS=

CONC_OUT_1 =

CONC_OUT_2 =

TEST OUTPUT =

CHANNEL

DIAG AIO

< SET

CONC_OUT_2 CALIBRATED: NO

CAL

EXIT

DIAG AIO

CONC_OUT_1 :5V, NO CAL

DIAG AIO CONC_OUT_1 VOLT–Z : 0 mV

< SET SET> EDIT

EXIT

U100 UP10 UP DOWN DN10 D100 ENTR EXIT

These keys increase / decrease the analog

output by 100, 10 or 1 counts.

EXIT ignores the

new setting.

ENTR accepts the

Continue adjustments until the voltage measured

at the output of the analyzer and/or the input of

the recording device matches the value in the

upper right hand corner of the display to the

tolerance listed in Table 6-10.

DIAG AIO CONC_OUT_1 VOLT–S : 4500 mV

U100 UP10 UP DOWN DN10 D100 ENTR EXIT

new setting.

The concentration display will not change. Only

the voltage reading of your voltmeter will change.

DIAG AIO

< SET

CONC_OUT_1 CALIBRATED: YES

CAL EXIT

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Operating Instructions

6.9.4.4. Current Loop Output Adjustment

A current loop option is available and can be installed as a retrofit for each of the analog outputs

of the analyzer (Sections 5.2). This option converts the DC voltage analog output to a current

signal with 0-20 mA output current. The outputs can be scaled to any set of limits within that 0-20

mA range. However, most current loop applications call for either 2-20 mA or 4-20 mA range. All

current loop outputs have a +5% over-range. Ranges with the lower limit set to more than 1 mA

(e.g., 2-20 or 4-20 mA) also have a -5% under-range.

To switch an analog output from voltage to current loop after installing the current output printed

circuit assembly, follow the instructions in Section 6.9.4.4 and select CURR from the list of

options on the RANGE menu.

Adjusting the signal zero and span values of the current loop output is done by raising or lowering

the voltage of the respective analog output. This proportionally raises or lowers the current

produced by the current loop option.

Similar to the voltage calibration, the software allows this current adjustment to be made in 100,

10 or 1 count increments. Since the exact current increment per voltage count varies from output

to output and from instrument to instrument, you will need to measure the change in the current

with a current meter placed in series with the output circuit (Figure 6-6).

See Table 3-2 for

pin assignments of

the Analog Out

connector on the

rear panel.

OUT

V OUT +

V OUT -

I IN +

I IN -

Recording

Device

Analyzer

Figure 6-6:

Setup for Calibrating Current Outputs

NOTE

Do not exceed 60 V between current loop outputs and instrument ground.

To adjust the zero and span values of the current outputs, activate the ANALOG I/O

CONFIGURATION MENU (see Section 6.9.1), then press:

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Operating Instructions

FROM ANALOG I/O CONFIGURATION MENU

The instrument attempt to automatically calibrate

the channel … then beep.

DIAG

ANALOG I / O CONFIGURATION

NEXT ENTR EXIT

DIAG AIO CONC_OUT_2 D/A/ CAL ERROR

EXIT

DIAG AIO

AIN CALIBRATED: NO

SET> EDIT

EXIT

DIAG AIO

CONC_OUT_2 CURR-Z: 0 mV

U100 UP10 UP DOWN DN10 D100 ENTR EXIT

Press SET> to select the analog output channel

to be configured:.

DIAG AIO

CONC_OUT_2 ZERO: 27 mV

Increase or decrease the current

output by 100, 10 or 1 counts.

The resulting change in output

voltage is displayed in the upper

line.

U100 UP10 UP DOWN DN10 D100 ENTR EXIT

DIAG AIO CONC_OUT_2:CURR, NO CAL

< SET SET> EDIT

EXIT

Continue adjustments until the

correct current is measured with

the current meter.

DIAG AIO

CONC_OUT_2 SPAN: 10000 mV

DIAG AIO CONC_OUT_2 RANGE: CURR

U100 UP10 UP DOWN DN10 D100 ENTR EXIT

<SET SET> EDIT

EXIT

DIAG AIO

CONC_OUT_2 ZERO: 9731 mV

EXIT ignores the

new setting, ENTR

accepts the new

setting.

DIAG AIO CONC_OUT_2 CALIBRATED: NO

< SET CAL EXIT

U100 UP10 UP DOWN DN10 D100 ENTR EXIT

DIAG AIO CONC_OUT_2 CALIBRATED: YES

DIAG AIO AUTO CALIBRATING CONC_OUT_2

< SET

CAL

EXIT

If a current meter is not available, an alternative method for calibrating the current loop outputs

is to connect a 250 Ω ± 1% resistor across the current loop output. Using a voltmeter connected

across the resistor, follow the procedure above but adjust the output to the following values:

Table 6-13: Current Loop Output Calibration with Resistor

Voltage for 2-20 mA

(measured across resistor)

Voltage for 4-20 mA

(measured across resistor)

Full scale

0.5 V

5.0 V

1.0 V

5.0 V

100%

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Operating Instructions

6.9.4.5. AIN Calibration

This is the sub-menu to conduct the analog input calibration. This calibration should only be

necessary after major repair such as a replacement of CPU, motherboard or power supplies.

Activate the ANALOG I/O CONFIGURATION MENU (see Section 6.9.1), then press:

STARTING FROM ANALOG I / O CONFIGURATION MENU

Exit at any time to

return to the main

DIAG menu

DIAG

ANALOG I / O CONFIGURATION

ENTR EXIT

Continue pressing SET? until …

DIAG AIO

AIN CALIBRATED: NO

< SET SET> CAL

EXIT

DIAG AIO

CALIBRATING A/D ZERO

Instrument

calibrates

automatically

CALIBRATING A/D SPAN

Exit to return to the

ANALOG I/O

CONFIGURATION

DIAG AIO

AIN CALIBRATED: YES

< SET SET> CAL

EXIT

6.9.5. Electric Test

The electric test function substitutes simulated signals for CO₂MEAS and CO₂REF, generated by

circuitry on the sync/demod board, for the output of the IR photo-detector. While in this mode the

user can also view the same test functions viewable from the main SAMPLE display. When the

test is running, the concentration reported on the front panel display should be 40.0 ppm.

SAMPLE

RANGE = 500.000 PPM

CO2 =X.XXX

DIAG

SIGNAL I / O

< TST TST > CAL

SETUP

ENTR

EXIT

SAMPLE

ENTER SETUP PASS : 818

Repeat Pressing NEXT unti . . .

ENTR EXIT

DIAG

ELECTRIC TEST

SETUP X.X

PRIMARY SETUP MENU

PREV NEXT

ENTR

EXIT

CFG DAS RNGE PASS CLK MORE

EXIT

DIAG ELEC

RANGE=50.000 PPM

CO2= 40.0

EXIT

Exit returns

to the

DIAG Menu

SETUP X.X

SECONDARY SETUP MENU

COMM VARS DIAG ALRM

EXIT

Press <TST TST> to view Test Functions

NOTE: CO MEAS and CO REF will be artificially altered to

enforce a CO₂reading of 40.0 ppm.

All other Test Functions will report the correct operational

value

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Operating Instructions

6.9.6. Dark Calibration Test

The dark calibration test interrupts the signal path between the IR photo-detector and the

remainder of the sync/demod board circuitry. This allows the instrument to compensate for any

voltage levels inherent in the sync/demod circuitry that might effect the calculation of CO₂

concentration. Performing this calibration returns two offset voltages, One for CO₂MEAS and on

for CO₂REF that are automatically added to the CPU’s calculation routine. The two offset voltages

from the last calibration procedure may be reviewed by the user via the front panel display.

To activate the dark calibration procedure or review the results of a previous calibration, press:

SAMPLE

RANGE = 500.000 PPM

CO2 =X.XXX

< TST TST > CAL

SETUP

SAMPLE

ENTER SETUP PASS : 818

ENTR EXIT

DIAG

SIGNAL I / O

ENTR

EXIT

SETUP X.X

PRIMARY SETUP MENU

CFG DAS RNGE PASS CLK MORE

EXIT

Repeat Pressing NEXT until . . .

SETUP X.X

SECONDARY SETUP MENU

DIAG

DARK CALIBRATION

COMM VARS DIAG ALRM

EXIT

PREV NEXT

ENTR

EXIT

DIAG DARK

CO DARK CALIBRATION

Exit returns

to the

previous menu

VIEW CAL

EXIT

Calibration runs automatically

Electric offset for Reference signal

Display

tracks %

complete

DIAG DARK

REF DARK OFFSET: 0.0 mV

DIAG DARK

DARK CAL 1% COMPLETE

EXIT

Electric offset for Measurement signal

DIAG DARK

MEAS DARK OFFSET: 0.0 mV

DIAG DARK

DARK CALIBRATION ABORTED

6.9.7. Pressure Calibration

A sensor at the exit of the sample chamber continuously measures the pressure of the sample

gas. This data is used to compensate the final CO₂concentration calculation for changes in

atmospheric pressure and is stored in the CPU’s memory as the test function PRES (also viewable

via the front panel).

NOTE

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This calibration must be performed when the pressure of the sample gas is equal to

ambient atmospheric pressure.

Before performing the following pressure calibration procedure, disconnect the sample

gas pump and the sample gas-line vent from the sample gas inlet on the instrument’s

rear panel.

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To cause the analyzer to measure and record a value for PRES, press.

SAMPLE

RANGE = 500.000 PPM

CO2 =X.XXX

DIAG

SIGNAL I / O

< TST TST > CAL

SETUP

ENTR

EXIT

SAMPLE

ENTER SETUP PASS : 818

DIAG

SIGNAL I / O

ENTR EXIT

Exit at

any time

to return

to main

the

SETUP X.X

PRIMARY SETUP MENU

Repeat Pressing NEXT until . . .

SETUP

CFG DAS RNGE PASS CLK MORE

EXIT

ENTR accepts the

new value and

returns to the

previous menu

EXIT ignores the

new value and

returns to the

DIAG FCAL ACTUAL PRESS : 27.20 IN-HG-A

SETUP X.X

SECONDARY SETUP MENU

ENTR EXIT

COMM VARS DIAG ALRM

EXIT

Adjust these values until

the displayed flow rate

equals the flow rate being

measured by the

previous menu

independent flow meter.

6.9.8. Flow Calibration

The flow calibration allows the user to adjust the values of the sample flow rates as they are

displayed on the front panel and reported through COM ports to match the actual flow rate

measured at the sample inlet. This does not change the hardware measurement of the flow

sensors, only the software calculated values.

To carry out this adjustment, connect an external, sufficiently accurate flow meter to the sample

inlet (see Chapter 11 for more details). Once the flow meter is attached and is measuring actual

gas flow, press:

SAMPLE

RANGE = 500.000 PPM

CO2 =X.XXX

< TST TST > CAL

SETUP

DIAG

SIGNAL I / O

SAMPLE

ENTER SETUP PASS : 818

ENTR

EXIT

ENTR EXIT

Exit at

any time

to return

to main

the

SETUP X.X

PRIMARY SETUP MENU

Repeat Pressing NEXT until . . .

CFG DAS RNGE PASS CLK MORE

EXIT

SETUP

DIAG

FLOW CALIBRATION

SETUP X.X

SECONDARY SETUP MENU

PREV NEXT

ENTR EXIT

COMM VARS DIAG ALRM

EXIT

ENTR accepts the

new value and

returns to the

previous menu

EXIT ignores the

new value and

returns to the

DIAG FCAL

ACTUAL FLOW: 607 CC / M

ENTR EXIT

Adjust these values until

the displayed flow rate

equals the flow rate being

measured by the

independent flow meter.

previous menu

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Operating Instructions

6.9.9. Test Channel Output

When activated, output channel A3 can be used to report one of the test functions viewable from

the SAMPLE mode display. To activate the A3 channel and select a test function, follow this key

sequence:

SAMPLE*

RANGE = 500.000 PPM

CO2 =X.XXX

Continue to press NEXT until …

< TST TST > CAL

SETUP

DIAG

TEST CHAN OUTPUT

SAMPLE

ENTER SETUP PASS : 818

EXIT returns

to the main

SAMPLE

display

ENTR

EXIT

ENTR EXIT

SETUP X.X

PRIMARY SETUP MENU

DIAG TCHN

TEST CHANNEL: NONE

CFG DAS RNGE PASS CLK MORE

EXIT

ENTR

EXIT

SETUP X.X

SECONDARY SETUP MENU

DIAG TCHN TEST CHANNEL: CO2 MEASURE

PREV NEXT ENTR

COMM VARS DIAG ALRM

EXIT

DIAG

SIGNAL I / O

ENTR EXIT

Press PREV or NEXT

to move through the

list of available

parameters

Press ENTR to select

Press EXIT to

return to the

DIAG menu

DIAG

ANALOG OUTPUT

the displayed

parameter activating

the test channel.

PREV NEXT

(Table 6-13)

Table 6-14: Test Parameters Available for Analog Output A3

Test Channel

Zero

Full Scale

NONE

Test Channel is turned off

CO₂MEASURE

CO₂REFERENCE

SAMPLE PRESS

SAMPLE FLOW

SAMPLE TEMP

BENCH TEMP

WHEEL TEMP

CHASSIS TEMP

PHT DRIVE

0 mV

0 "Hg

0 cc/m

0°C

5000 mV*

40 "Hg

1000 cc/m

70°C

0°C

70°C

0°C

70°C

0°C

70°C

0 mV

5000 mV

* This refers to the internal voltage level of the function NOT the output

signal level of the Test channel itself.

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6.10. SETUP – COMM: Using the Analyser’s

Communication Ports

The MGFC7000E is equipped with two serial communication ports located on the rear panel

(Figure 3-2). Both ports operate similarly and give the user the ability to communicate with, issue

commands to, and receive data from the analyzer through an external computer system or

terminal. By default, both ports operate on the RS-232 protocol. The COM2 port, however, can be

configured for half-duplex RS-485 communication or can be used for the Teledyne Instruments

Ethernet interface card (optional equipment, Section 5.5.3).

Multidrop Communications

There are two options to connect multiple analyzers to a single computer terminal or data logging

device over a single serial communications line. Either port can be equipped with an optional RS-

232 multidrop assembly (Section 5.5.2), or up to eight analyzers can be connected using COM2

configured for RS-485 operation (contact the factory for further information). A third option is to

use a code-activated switch (CAS), which can connect typically between 2 and 16 analyzers to one

communications hub. Contact Teledyne Instruments sales for more information on CAS systems.

Ethernet Communications

When equipped with the optional Ethernet interface, the analyzer can be connected to any

standard 10BaseT Ethernet network via low-cost network hubs, switches or routers. The interface

operates as a standard TCP/IP device on port 3000. This allows a remote computer to connect

through the internet to the analyzer using APIcom, terminal emulators or other programs.

6.10.1. Analyzer ID Code

The first entry in the COMM menu is for configuration of the analyzer ID code, a numerical value

of up to 4 digits. Each type of Teledyne Instruments analyzer is configured with a default ID code.

The MGFC7000E default ID code is 360. When more than one Teledyne Instruments analyzer of

the same model type is connected to the same communications channel , such as two Model

GFC7000E’s operating on the same Hessen Protocol network, each analyzer needs to be

addressed with a unique ID number.

To edit the instrument’s ID code, press:

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SAMPLE*

RANGE = 500.000 PPM

CO2 =X.XXX

< TST TST > CAL

SETUP

SAMPLE

ENTER SETUP PASS : 818

ENTR EXIT

SETUP X.X

PRIMARY SETUP MENU

CFG DAS RNGE PASS CLK MORE

EXIT

SETUP X.X SECONDARY SETUP MENU

COMM VARS DIAG ALRM

EXIT

SETUP X.X

COMMUNICATIONS MENU

EXIT

ID COM1 COM2

Toggle these keys to

cycle through the

available character set:

0-9

ENTR key accepts the

SETUP X.

MACHINE ID: 360 ID

new settings

EXIT key ignores the

ENTR EXIT

new settings

The ID number is only important if more than one analyzer is connected to the same

communications channel (e.g., a multi-drop setup). Different models of Teledyne Instruments

analyzers have different default ID numbers, but if two analyzers of the same model type are

used on one channel (for example, two MGFC7000E’s), the ID of one instrument needs to be

changed.

The ID can also be used for to identify any one of several analyzers attached to the same network

but situated in different physical locations.

6.10.2. COMM Port Default Settings

Received from the factory, the analyzer is set up to emulate a DCE or modem, with pin 3 of the

DB-9 connector designated for receiving data and pin 2 designated for sending data.

•

COM1: RS-232 (fixed), DB-9 male connector.

o Baud rate: 19200 bits per second (baud).

o Data Bits: 8 data bits with 1 stop bit.

o Parity: None.

•

COM2: RS-232 (configurable), DB-9 female connector.

o Baud rate: 115000 bits per second (baud).

o Data Bits: 8 data bits with 1 stop bit.

o Parity: None.

NOTE

Cables that appear to be compatible because of matching connectors may incorporate

internal wiring that make the link inoperable. Check cables acquired from sources other

than Teledyne Instruments for pin assignments before using.

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6.10.3. COMM Port Cable Connections

There are two DB-9 connectors on the MGFC7000E rear panel. COM1 is a male connector, COM2

a female connector (Table 6-15 lists pin assignments). Teledyne Instruments offers two mating

cables, one of which should be applicable for your use.

Part number WR000077, a DB-9 female to DB-9 female cable, 6 feet long, allows connection of

COM1 with the serial port of most personal computers. Also available as Option 60 (Section

5.5.1).

Part number WR0000024, a DB-9 female to DB-25 male cable. Allows connection to the most

common styles of modems (e.g. Hayes-compatible) and code activated switches.

Both cables are configured with straight-through wiring and should require no additional adapters.

To assist in properly connecting the serial ports to either a computer or a modem, there are

activity indicators just above each COM port. When power is applied to the analyzer, the red LED

should be illuminated. If this LED is dark, it indicates a communications error between serial port

and CPU.

Once a cable is connected between the analyzer and a computer or modem, both the red and

green LEDs should be on. If not, COM1 can be switched between DTE and DCE modes using a

small switch on the rear panel to exchange the receive and transmit lines (emulating a cross-over

or null-modem cable). If both LEDs are still not illuminated, check the cable for proper wiring. For

COM2 it may be necessary to install a null-modem cable (contact customer service for

information).

6.10.4. RS-485 Configuration of COM2

As delivered from the factory, COM2 is configured for RS-232 communications. This port can be

re-configured for operation as a non-isolated, half-duplex RS-485 port with a 150 Ω termination

resistor (Table 6-15 shows the pin assignments of the DB-9 connector).

For RS-485 operation, jumper JP3 on the CPU board should be installed and switch 6 of SW1

should be set to the ON position. For RS-232, remove the jumper and set the switch to OFF

(default). JP3 is just to the right of the third connector from the left on the top of the CPU board

(as seen from the inside of the analyzer). SW1 is in the middle of the CPU board between disk-on-

chip and BIOS. For non-terminated RS-485 operation, remove the jumper on JP3 but leave switch

6 in the ON position. Refer to Figure 3-11 to locate the CPU board.

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Table 6-15: COM1 and COM2 DB-9 Pin Assignments

Pin #

COM1 (RS-232)

Not used

COM2 (RS-232)

Not used

COM2 (RS-485)

Not used

Transmit Data*

Receive Data*

Not used

Receive Data

Transmit Data

Not used

DATA -

Data +

Not used

Signal Ground

Not used

Signal Ground

Not used

Signal Ground

Not used

DATA SET READY*

DATA SET READY

REQUEST TO SEND

Not used

REQUEST TO SEND*

(=DTE Ready)

Not used

* Configurable for COM1 at rear panel using the DTE-DCE switch

6.10.5. DTE and DCE Communication

RS-232 was developed for allowing communications between data terminal equipment (DTE) and

data communication equipment (DCE). Basic terminals always fall into the DTE category whereas

modems are always considered DCE devices. The difference between the two is the pin

assignment of the Data Receive and Data Transmit functions. DTE devices receive data on pin 2

and transmit data on pin 3, DCE devices receive data on pin 3 and transmit data on pin 2.

To allow the analyzer to be used with terminals (DTE), modems (DCE) and computers (which can

be either), a switch mounted below the serial ports on the rear panel allows the user to switch

between the two functions.

6.10.6. COMM Port Communication Modes

Each of the analyzer’s serial ports can be configured to operate in a number of different modes,

listed in Table 6-16, which can be combined by adding the mode ID numbers. For example, quiet

mode, computer mode and internet-enabled mode would carry a combined mode ID of 11, the

standard configuration on the MGFC7000E COM2 port. Note that each COM port needs to be

configured independently.

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Table 6-16: COMM Port Communication modes

MODE¹

QUIET

DESCRIPTION

Quiet mode suppresses any feedback from the analyzer (iDAS reports, and

warning messages) to the remote device and is typically used when the port

is communicating with a computer program such as APICOM. Such feedback

is still available but a command must be issued to receive them.

COMPUTER

SECURITY

Computer mode inhibits echoing of typed characters and is used when the

port is communicating with a computer program, such as APICOM.

When enabled, the serial port requires a password before it will respond.

The only command that is active is the help screen (? CR).

HESSEN

PROTOCOL

The Hessen communications protocol is used in some European countries.

Teledyne Instruments part number 02252 contains more information on this

protocol.

E, 7, 1

When turned on this mode switches the COMM port settings

from

No parity; 8 data bits; 1 stop bit

2048

Even parity; 7 data bits; 1 stop bit

RS-485

Configures the COM2 Port for RS-485 communication. RS-485 mode has

precedence over multidrop mode if both are enabled.

1024

MULTIDROP

PROTOCOL

Multidrop protocol allows a multi-instrument configuration on a single

communications channel. Multidrop requires the use of instrument IDs.

ENABLE

MODEM

Enables to send a modem initialization string at power-up. Asserts certain

lines in the RS-232 port to enable the modem to communicate.

ERROR

Fixes certain types of parity errors at certain Hessen protocol installations.

128

256

CHECKING²

XON/XOFF

Disables XON/XOFF data flow control also known as software handshaking.

HANDSHAKE²

HARDWARE

HANDSHAKE

Enables CTS/RTS style hardwired transmission handshaking. This style of

data transmission handshaking is commonly used with modems or terminal

emulation protocols as well as by Teledyne Instrument’s APICOM software.

HARDWARE

FIFO²

Improves data transfer rate when on of the COMM ports.

512

COMMAND

PROMPT

Enables a command prompt when in terminal mode.

4096

Modes are listed in the order in which they appear in the

SETUP Æ MORE Æ COMM Æ COM[1 OR 2] Æ MODE menu

The default sting for this feature is ON. Do not disable unless instructed to by Teledyne Instruments

Customer Service personnel.

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Press the following keys to select a communication mode for a one of the COMM Ports, such as the

following example where HESSEN PROTOCOL mode is enabled:

SAMPLE*

RANGE = 500.000 PPM

CO2 =X.XXX

< TST TST > CAL

SETUP

SAMPLE

ENTER SETUP PASS : 818

ENTR EXIT

SETUP X.X

PRIMARY SETUP MENU

CFG DAS RNGE PASS CLK MORE

EXIT

EXIT returns

to the

SETUP X.X

SECONDARY SETUP MENU

COMM VARS DIAG ALRM

SETUP X.X

COMMUNICATIONS MENU

Select which COM

port to configure

ID COM1 COM2

The sum of the mode

IDs of the selected

modes is displayed

here

SETUP X.X

SET> EDIT

COM1 MODE:0

SETUP X.X

COM1 QUIET MODE: OFF

ENTR EXIT

NEXT OFF

Continue pressing next until …

SETUP X.X COM1 HESSEN PROTOCOL : OFF

Use PREV and NEXT

keys to move between

available modes.

PREV NEXT OFF

ENTR EXIT

A mode is enabled by

toggling the ON/OFF

key.

ENTR key accepts the

SETUP X.X COM1 HESSEN PROTOCOL : ON

new settings

EXIT key ignores the

PREV NEXT ON

ENTR EXIT

new settings

Continue pressing the NEXT and PREV keys to select any other

modes you which to enable or disable

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6.10.7. COM Port Baud Rate

To select the baud rate of one of the COM Ports, press:

SAMPLE*

RANGE = 500.000 PPM

CO2 =X.XXX

< TST TST > CAL

SETUP

SAMPLE

ENTER SETUP PASS : 818

ENTR EXIT

SETUP X.X

PRIMARY SETUP MENU

CFG DAS RNGE PASS CLK MORE

EXIT

EXIT returns

to the

SETUP X.X

SECONDARY SETUP MENU

COMM VARS DIAG ALRM

SETUP X.X

COMMUNICATIONS MENU

Select which COM

port to configure.

ID COM1 COM2

SETUP X.X

SET> EDIT

COM1 MODE:0

Press SET> until you

reach COM1 BAUD

RATE

EXAMPLE

SETUP X.X

COM1 BAUD RATE:19200

Use PREV and NEXT

keys to move

between available

baud rates.

EXIT key

ignores

the new

setting

<SET SET> EDIT

300

1200

SETUP X.X

COM1 BAUD RATE:19200

ENTR

4800

9600

19200

38400

57600

115200

ENTR key

accepts

the new

setting

PREV NEXT

SETUP X.X

COM1 BAUD RATE:9600

ENTR

NEXT ON

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6.10.8. COM Port Testing

The serial ports can be tested for correct connection and output in the COMM menu. This test

sends a string of 256 ‘w’ characters to the selected COM port. While the test is running, the red

LED on the rear panel of the analyzer should flicker.

To initiate the test press the following key sequence.

SAMPLE

RANGE = 500.000 PPM

CO2 =X.XXX

SETUP X.X

COMMUNICATIONS MENU

Select which

COM port to

test.

< TST TST > CAL

SETUP

ID COM1 COM2

EXIT

SAMPLE

ENTER SETUP PASS : 818

SETUP X.X

SET> EDIT

COM1 MODE:0

ENTR EXIT

SETUP X.X

PRIMARY SETUP MENU

SETUP X.X

COM1 BAUD RATE:19200

CFG DAS RNGE PASS CLK MORE

EXIT

<SET SET> EDIT

EXIT

SETUP X.X

SECONDARY SETUP MENU

SETUP X.X

<SET

COM1 : TEST PORT

TEST

COMM VARS DIAG ALRM

EXIT

SETUP X.X

<SET

TRANSMITTING TO COM1

TEST

Test runs

automatically

EXIT returns to

COMM menu

EXIT

6.10.9. Ethernet Card Configuration

The optional Ethernet card (Option 63) allows the analyzer to communicate via standard 10BaseT

Ethernet protocol through the COM2 serial port. Refer to Figure and 5-4 for the physical location

of this option.

The card has four LEDs that are visible on the rear panel of the analyzer, indicating its current

operating status.

Table 6-17: Ethernet Status Indicators

LED

LNK (green)

ACT (yellow)

TxD (green)

FUNCTION

ON when connection to the LAN is valid.

Flickers on any activity on the LAN.

Flickers when the RS-232 port is transmitting

data.

RxD (yellow)

Flickers when the RS-232 port is receiving data.

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6.10.9.1. Ethernet Card COM2 Communication Modes and Baud Rate

The firmware on board the Ethernet card automatically sets the communication modes and baud

rate (115 200 kBaud ) for the COM2 port. Once the Ethernet option is installed and activated,

the COM2 submenu is replaced by a new submenu, INET. This submenu is used to manage and

configure the Ethernet interface with your LAN or Internet Server(s).

6.10.9.2. Configuring the Ethernet Interface Option using DHCP

The Ethernet option for you MGFC7000E uses Dynamic Host Configuration Protocol (DHCP) to

automatically configure its interface with your LAN. This requires your network servers also be

running DHCP. The analyzer will do this the first time you turn the instrument on after it has been

physically connected to your network. Once the instrument is connected and turned on it will

appear as an active device on your network without any extra set up steps or lengthy procedures.

Should you need to, the following Ethernet configuration properties are viewable via the analyzer’s

front panel.

Table 6-18: LAN/Internet Configuration Properties

PROPERTY

DEFAULT STATE

DESCRIPTION

This displays whether the DHCP is turned ON or

OFF.

DHCP

STATUS

Editable

EDIT key

disabled

when DHCP

This string of four packets of 1 to 3 numbers each

(e.g. 192.168.76.55.) is the address of the

analyzer itself.

INSTRUMENT

IP ADDRESS

Configured

by DHCP

is ON

EDIT key

disabled

when DHCP

is ON

A string of numbers very similar to the Instrument

IP address (e.g. 192.168.76.1.)that is the address

of the computer used by your LAN to access the

Internet.

GATEWAY IP

ADDRESS

Configured

by DHCP

Also a string of four packets of 1 to 3 numbers

each (e.g. 255.255.252.0) that defines that

identifies the LAN the device is connected to.

All addressable devices and computers on a LAN

must have the same subnet mask. Any

transmissions sent devices with different assumed

to be outside of the LAN and are routed through

gateway computer onto the Internet.

EDIT key

disabled

when DHCP

is ON

SUBNET

MASK

Configured

by DHCP

This number defines the terminal control port by

which the instrument is addressed by terminal

emulation software, such as Internet or Teledyne

Instruments’ APICOM.

TCP PORT

3000

Editable

The name by which your analyzer will appear

when addressed from other computers on the LAN

or via the Internet. While the default setting for

all Teledyne Instruments MGFC7000E analyzers is

“mGFC7000E” the host name may be changed to

fit customer needs.

HOST NAME

MGFC7000E

¹Do not change the setting for this property unless instructed to by Teledyne Instruments

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Customer Service personnel.

NOTE

It is a good idea to check these settings the first time you power up your analyzer after

it has been physically connected to the LAN/Internet to make sure that the DHCP has

successfully downloaded the appropriate information from you network server(s).

If the gateway IP, instrument IP and the subnet mask are all zeroes (e.g. “0.0.0.0”),

the DCHP was not successful.

You may have to manually configure the analyzer’s Ethernet properties.

See your network administrator.

To view the above properties, press:

SAMPLE*

RANGE = 500.000 PPM

CO2 =X.XXX

SETUP X.X

DHCP: ON

< TST TST > CAL

SETUP

SET> EDIT

EXIT

SAMPLE

ENTER SETUP PASS : 818

SETUP X.X

INST IP: 0.0.0.0

ENTR EXIT

SETUP X.X

PRIMARY SETUP MENU

SETUP X.X GATEWAY IP: 0.0.0.0

EDIT Key

Disabled

CFG DAS RNGE PASS CLK MORE

EXIT

SETUP X.X SECONDARY SETUP MENU

SETUP X.X

SUBNET MASK: 0.0.0.0

COMM VARS DIAG ALRM

SETUP X.X

INET

COMMUNICATIONS MENU

SETUP X.X

TCP PORT: 3000

COM1

<SET SET> EDIT

From this point on,

EXIT returns to

COMMUNICATIONS

SETUP X.X HOSTNAME: M360E

<SET

EDIT

Don not alter unless

directed to by Teledyne

Instruments Customer

Service personnel

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6.10.9.3. Manually Configuring the Network IP Addresses

There are several circumstances when you may need to manually configure the interface settings

of the analyzer’s Ethernet card. The INET sub-menu may also be used to edit the Ethernet card’s

configuration properties

•

Your LAN is not running a DHCP software package,

The DHCP software is unable to initialize the analyzer’s interface;

You wish to program the interface with a specific set of IP addresses that may not be the

ones automatically chosen by DHCP.

Editing the Ethernet Interface properties is a two step process.

STEP 1: Turn DHCP OFF: While DHCP is turned ON, the ability to manually set INSTRUMENT IP,

GATEWAY IP and SUBNET MASK is disabled

SAMPLE*

RANGE = 500.000 PPM

CO2 =X.XXX

SETUP X.X

INET

COMMUNICATIONS MENU

< TST TST > CAL

SETUP

COM1

EXIT

SAMPLE

ENTER SETUP PASS : 818

SETUP X.X

DHCP: ON

ENTR EXIT

<SET SET> EDIT

SETUP X.X

DHCP: ON

SETUP X.X

PRIMARY SETUP MENU

ENTR EXIT

CFG DAS RNGE PASS CLK MORE

EXIT

SETUP X.X

DHCP: ON

SETUP X.X SECONDARY SETUP MENU

OFF

COMM VARS DIAG ALRM

Continue with editing of Ethernet interface

properties (see Step 2, below).

ENTR accept

new settings

EXIT ignores

new settings

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STEP 2: Configure the INSTRUMENT IP, GATEWAY IP and SUBNET MASK addresses by

pressing:

Internet Configuration Keypad Functions

From Step 1 above)

KEY

[0]

FUNCTION

Press this key to cycle through the range of

numerals and available characters (“0 – 9” & “ . ”)

<CH CH>

DEL

Moves the cursor one character left or right.

Deletes a character at the cursor location.

SETUP X.X

DHCP: OFF

Accepts the new setting and returns to the previous

menu.

ENTR

EXIT

SET> EDIT

EXIT

Ignores the new setting and returns to the previous

menu.

Some keys only appear as needed.

SETUP X.X INST IP: 000.000.000.000

<SET SET> EDIT

Cursor

location is

indicated by

brackets

SETUP X.X INST IP: [0] 00.000.000

<CH CH>

DEL [0]

ENTR EXIT

SETUP X.X GATEWAY IP: 000.000.000.000

<SET SET> EDIT

EXIT

SETUP X.X GATEWAY IP: [0] 00.000.000

<CH CH> DEL [?] ENTR EXIT

SETUP X.X SUBNET MASK:255.255.255.0

<SET SET> EDIT

EXIT

SETUP X.X SUBNET MASK:[2]55.255.255.0

<CH CH> DEL [?] ENTR EXIT

SETUP X.X TCP PORT 3000

<SET

EDIT

EXIT

The PORT number needs to remain at 3000.

Do not change this setting unless instructed to by

Teledyne Instruments Customer Service personnel.

Pressing EXIT from

any of the above

display menus

causes the Ethernet

option to reinitialize

its internal interface

firmware

SETUP X.X

INITIALIZING INET 0%

…

INITIALIZING INET 100%

SETUP X.X

INITIALIZATI0N SUCCEEDED

SETUP X.X

INITIALIZATION FAILED

Contact your IT

Network Administrator

SETUP X.X

COMMUNICATIONS MENU

INET

COM1

EXIT

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6.10.9.4. Changing the Analyzer’s HOSTNAME

The HOSTNAME is the name by which the analyzer appears on your network. The default name

for all Teledyne Instruments Model GFC7000E analyzers is MGFC7000E. To change this name

(particularly if you have more than one Model GFC7000E analyzer on your network), press.

SAMPLE*

RANGE = 500.000 PPM

CO2 =X.XXX

SETUP X.X

DHCP: ON

< TST TST > CAL

SETUP

SET> EDIT

EXIT

Continue pressing SET> UNTIL …

SAMPLE

ENTER SETUP PASS : 818

ENTR EXIT

SETUP X.X

PRIMARY SETUP MENU

SETUP X.X HOSTNAME: M360E

<SET EDIT

CFG DAS RNGE PASS CLK MORE

EXIT

SETUP X.X SECONDARY SETUP MENU

SETUP X.X HOSTNAME: [M]360E

COMM VARS DIAG ALRM

<CH CH> INS DEL [?]

ENTR EXIT

SETUP X.X

ID INET

COMMUNICATIONS MENU

SETUP X.X HOSTNAME: M360E-FIELD1

COM1

<SET

EDIT

EXIT

SETUP X.X

INITIALIZING INET 0%

…

INITIALIZING INET 100%

SETUP X.X

INITIALIZATI0N SUCCEEDED

SETUP X.X

INITIALIZATION FAILED

SETUP X.X

COMMUNICATIONS MENU

Contact your IT

Network Administrator

INET

COM1

EXIT

Table 6-19: Internet Configuration Keypad Functions

FUNCTION

KEY

<CH

CH>

INS

DEL

[?]

Moves the cursor one character to the left.

Moves the cursor one character to the right.

Inserts a character before the cursor location.

Deletes a character at the cursor location.

Press this key to cycle through the range of numerals and characters available

for insertion. 0-9, A-Z, space ’ ~ ! © # $ % ^ & * ( ) - _ = +[ ] { } <

>\ | ; : , . / ?

ENTR

EXIT

Accepts the new setting and returns to the previous menu.

Ignores the new setting and returns to the previous menu.

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Some keys only appear as needed.

6.11. SETUP – ALRM: Using the Gas Concentration

Alarms

The Model GFC7000E includes two CO₂concentration alarms Each alarm has a user settable

limit, and is associated with an opto-isolated TTL relay accessible via the status output connector

on the instrument’s back panel (see Section 6.13.1.1). If the CO₂concentration measured by the

instrument rises above that limit, the alarm‘s status output relay is closed.

The default settings for ALM1 and ALM2 are:

Table 6-20: CO₂Concentration Alarm Default Settings

ALARM

STATUS

LIMIT SET POINT

100 ppm

ALM1

ALM2

Disabled

300 ppm

Set points listed are for PPM. Should the reporting range units of measure be changed (see Section

6.7.6) the analyzer will automatically scale the set points to match the new range unit setting.

Note

To prevent the concentration alarms from activating during span calibration operations

make sure to press CAL or CALS button prior to introducing span gas into the analyzer.

To enable either of the CO₂concentration alarms and set the Limit points, press:

SAMPLE*

RANGE = 500.000 PPM

CO2 =X.XXX

< TST TST > CAL

SETUP

SAMPLE

ENTER SETUP PASS : 818

ENTR EXIT

SETUP X.X

ALARM MENU

SETUP X.X

PRIMARY SETUP MENU

ALM1 ALM2

EXIT

CFG DAS RNGE PASS CLK MORE

EXIT

SETUP X.

ALARM 1 LIMIT: OFF

SETUP X.X SECONDARY SETUP MENU

OFF

ENTR EXIT

COMM VARS DIAG ALRM

EXIT

SETUP X.

ALARM 1 LIMIT: ON

ENTR EXIT

Toggle these keys to

cycle through the

available character set:

0-9

SETUP X.

ALARM 1 LIMIT: 200,00 PPM

.0 ENTR EXIT

ENTR key accepts the

new settings

EXIT key ignores the

new settings

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6.12. SETUP – DAS: Using the Data Acquisition System

(iDAS)

The MGFC7000E analyzer contains a flexible and powerful, internal data acquisition system (iDAS)

that enables the analyzer to store concentration and calibration data as well as a host of

diagnostic parameters. The iDAS of the MGFC7000E can store up to about one million data points,

which can, depending on individual configurations, cover days, weeks or months of valuable

measurements. The data are stored in non-volatile memory and are retained even when the

instrument is powered off. Data are stored in plain text format for easy retrieval and use in

common data analysis programs (such as spreadsheet-type programs).

The iDAS is designed to be flexible, users have full control over the type, length and reporting

time of the data. The iDAS permits users to access stored data through the instrument’s front

panel or its communication ports. Using APICOM, data can even be retrieved automatically to a

remote computer for further processing.

The principal use of the iDAS is logging data for trend analysis and predictive diagnostics, which

can assist in identifying possible problems before they affect the functionality of the analyzer. The

secondary use is for data analysis, documentation and archival in electronic format.

To support the iDAS functionality, Teledyne Instruments offers APICOM, a program that provides

a visual interface for remote or local setup, configuration and data retrieval of the iDAS (Section

6.12). The APICOM manual, which is included with the program, contains a more detailed

description of the iDAS structure and configuration, which is briefly described in this section.

The MGFC7000E is configured with a basic iDAS configuration, which is enabled by default. New

data channels are also enabled by default but each channel may be turned off for later or

occasional use. Note that iDAS operation is suspended while its configuration is edited through the

front panel. To prevent such data loss, it is recommended to use the APICOM graphical user

interface for iDAS changes.

The green SAMPLE LED on the instrument front panel, which indicates the analyzer status, also

indicates certain aspects of the iDAS status:

Table 6-21: Front Panel LED Status Indicators for iDAS

LED STATE

OFF

iDAS Status

System is in calibration mode. Data logging can be enabled or disabled for this

mode. Calibration data are typically stored at the end of calibration periods,

concentration data are typically not sampled, diagnostic data should be collected.

BLINKING

Instrument is in hold-off mode, a short period after the system exits calibrations.

IDAS channels can be enabled or disabled for this period. Concentration data are

typically disabled whereas diagnostic should be collected.

Sampling normally.

The iDAS can be disabled only by disabling or deleting its individual data channels.

6.12.1. iDAS Structure

The iDAS is designed around the feature of a “record”. A record is a single data point of one

parameter, stored in one (or more) data channels and generated by one of several triggering

event. The entire iDAS configuration is stored in a script, which can be edited from the front panel

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or downloaded, edited and uploaded to the instrument in form of a string of plain-text lines

through the communication ports.

iDAS data are defined by the PARAMETER type and are stored through different triggering EVENTS

in data CHANNELS, which relate triggering events to data parameters and define certain

operational functions related to the recording and reporting of the data.

6.12.1.1. iDAS Channels

The key to the flexibility of the iDAS is its ability to store a large number of combinations of

triggering events and data parameters in the form of data channels. Users may create up to 20

data channels and each channel can contain one or more parameters. For each channel one

triggering event is selected and up to 50 data parameters, which can be the same or different

between channels. Each data channel has several properties that define the structure of the

channel and allow the user to make operational decisions regarding the channel (Table 6-22).

Table 6-22: iDAS Data Channel Properties

PROPERTY

NAME

DESCRIPTION

DEFAULT

“NONE”

SETTING RANGE

The name of the data channel.

Up to 6 letters and

digits (more with

APICOM, but only the

first six are displayed

on the front panel).

TRIGGERIN

G EVENT

The event that triggers the data channel to

measure and store its data parameters. See

APPENDIX A-5 for a list of available triggering

events.

ATIMER

See Appendix A-5 For

a complete list.

NUMBER &

A User-configurable list of data types to be

1 – DETMES See Appendix A-5 For

PARAMETER recorded in any given channel. See APPENDIX

a complete list.

LIST

A-5 for a list of available parameters

STARTING

DATE

The starting date when a channel starts

collecting data

01-JAN-03

000:01:00

Any actual date in the

past or future.

SAMPLE

PERIOD

The amount of time between each data point

that is averaged into one mean reported every

REPORT PERIOD.

000:00:01 to

366:23:59

(Days:Hours:Minutes)

REPORT

PERIOD

The amount of time between each channel

data point.

000:01:00

100

000:00:01 to

366:23:59

(Days:Hours:Minutes)

NUMBER OF The number of reports that will be stored in

RECORDS

1 to 1 million, limited

by available storage

space.

the data file. Once the specified limit has been

exceeded, the oldest data are over-written to

make space for new data.

RS-232

REPORT

Enables the analyzer to automatically report

channel values to the RS-232 ports.

OFF

OFF or ON

CHANNEL

ENABLED

Enables or disables the channel. Provides a

convenient means to temporarily disable a

data channel.

CAL HOLD

OFF

Disables sampling of data parameters while

instrument is in calibration mode.

OFF

OFF or ON

(Section 6.12.2.11.)

When enabled here – there is also a length of

the DAS HOLD OFF after calibration mode,

which is set in the VARS menu

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6.12.1.2. iDAS Parameters

Data parameters are types of data that may be measured and stored by the iDAS. For each

Teledyne Instruments analyzer model, the list of available data parameters is different, fully

defined and not customizable. Appendix A-5 lists firmware specific data parameters for the

MGFC7000E. iDAS parameters include things like CO₂concentration measurements, temperatures

of the various heater placed around the analyzer, pressures and flows of the pneumatic

subsystem and other diagnostic measurements as well as calibration data such as slope and

offset.

Most data parameters have associated measurement units, such as mV, ppb, cm³/min, etc.,

although some parameters have no units. With the exception of concentration readings, none of

these units of measure can be changed. To change the units of measure for concentration

readings see Section 6.7.6.

Note

iDAS does not keep track of the unit of each concentration value and iDAS data files

may contain concentrations in multiple units if the unit was changed during data

acquisition.

Each data parameter has user-configurable functions that define how the data are recorded:

Table 6-23: iDAS Data Parameter Functions

FUNCTION

EFFECT

PARAMETER

Instrument-specific parameter name.

SAMPLE MODE INST: Records instantaneous reading.

AVG: Records average reading during reporting interval.

MIN: Records minimum (instantaneous) reading during reporting interval.

MAX: Records maximum (instantaneous) reading during reporting interval.

PRECISION

Decimal precision of parameter value(0-4).

STORE NUM.

SAMPLES

OFF: stores only the average (default).

ON: stores the average and the number of samples in each average for a

parameter. This property is only useful when the AVG sample mode is used. Note

that the number of samples is the same for all parameters in one channel and

needs to be specified only for one of the parameters in that channel.

Users can specify up to 50 parameters per data channel (the MGFC7000E provides about 30

parameters). However, the number of parameters and channels is ultimately limited by available

memory.

6.12.1.3. iDAS Triggering Events

Triggering events define when and how the iDAS records a measurement of any given data

channel. Triggering events are firmware-specific and a complete list of Triggers for this model

analyzer can be found in Appendix A-5. The most commonly used triggering events are:

•

ATIMER: Sampling at regular intervals specified by an automatic timer. Most

trending information is usually stored at such regular intervals, which can be

instantaneous or averaged.

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•

EXITZR, EXITSP, SLPCHG (exit zero, exit span, slope change): Sampling at the

end of (irregularly occurring) calibrations or when the response slope changes.

These triggering events create instantaneous data points, e.g., for the new slope

and offset (concentration response) values at the end of a calibration. Zero and

slope values are valuable to monitor response drift and to document when the

instrument was calibrated.

•

WARNINGS: Some data may be useful when stored if one of several warning

messages appears such as WTEMPW (GFC wheel temperature warning) or

PPRESW (purge pressure warning). This is helpful for trouble-shooting by

monitoring when a particular warning occurred.

6.12.2. Default iDAS Channels

A set of default Data Channels has been included in the analyzer’s software for logging CO₂

concentration and certain predictive diagnostic data. These default channels include but are not

limited to:

CONC: Samples CO₂concentration 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. By default, the last 800 hourly averages are stored.

PNUMTC: 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.

CALDAT: Logs new slope and offset every time a zero or span calibration is performed. This Data

Channel also records the instrument readings just prior to performing a calibration. This

information is useful for performing predictive diagnostics as part of a regular maintenance

schedule (see Section 9.1).

STBZRO: Logs the concentration stability, the electronic output of the IR detector of the most

recent measure phase and the measure/reference ratio every time the instrument exits zero

calibration mode. Data from the last 200 zero calibrations is stored. A time and date stamp is

recorded for every data point logged. This information is useful for performing predictive

diagnostics as part of a regular maintenance schedule (see Section 9.1).

STBSPN: Logs the electronic output of the IR detector of the most recent measure phase and the

measure/reference ratio every time the instrument exits span calibration mode. Data from the

last 200 zero calibrations is stored. A time and date stamp is recorded for every data point logged.

This information is useful for performing predictive diagnostics as part of a regular maintenance

schedule (see Section 9.1).

TEMP: Samples the analyzer’s bench temperature, box temperature and PHT cooler drive voltage

every five minutes and records a average once every six hours. Data from the last 400

averaging periods is recorded. A time and date stamp is recorded for every data point logged.

This information is useful for performing predictive diagnostics as part of a regular maintenance

schedule (see Section 9.1).

Note

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The CALDAT, STBZRO and STBSPN channels collect data based on events (e.g. a

calibration operation) rather than a timed interval. This does not represent any specific

length of time since it is dependent on how often calibrations are performed.

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Triggering Events and Data Parameters/Functions for these default channels are:

LIST OF CHANNELS

LIST OF PARAMETERS

NAME: CONC

EVENT: ATIMER

PARAMETER:

CONC1

REPORT PERIOD: 000:01:00

MODE:

AVG

NO. OF RECORDS: 800

RS-232 REPORT: OFF

CHANNEL ENABLED: ON

CAL HOLD OFF: ON

PRECISION:

STORE NUM SAMPLES

OFF

PARAMETER:

SMPLFLW

MODE:

AVG

NAME: PNUMTC

PRECISION:

EVENT: ATIMER

STORE NUM SAMPLES

OFF

REPORT PERIOD: 001:00:00

NO. OF RECORDS: 360

RS-232 REPORT: OFF

CHANNEL ENABLED: ON

CAL HOLD OFF: OFF

PARAMETER:

SMPLPRS

MODE:

AVG

PRECISION:

STORE NUM SAMPLES

OFF

PARAMETER:

SLOPE1

MODE:

INST

PRECISION:

STORE NUM SAMPLES

NAME: CALDAT

EVENT: SLPCHG

PARAMETER:

OFSET1

REPORT PERIOD: N/A

NO. OF RECORDS:200

RS-232 REPORT: OFF

CHANNEL ENABLED: ON

CAL HOLD OFF: OFF

MODE:

INST

PRECISION:

STORE NUM SAMPLES

OFF

PARAMETER:

ZSCNC1

MODE:

INST

PRECISION:

STORE NUM SAMPLES

PARAMETER:

STABIL

MODE:

INST

PRECISION:

STORE NUM SAMPLES

NAME: STBZRO

EVENT: EXITZR

PARAMETER:

DETMES

REPORT PERIOD: N/A

NO. OF RECORDS:200

RS-232 REPORT: OFF

CHANNEL ENABLED: ON

CAL HOLD OFF: OFF

MODE:

INST

PRECISION:

STORE NUM SAMPLES

OFF

PARAMETER:

RATIO

MODE:

INST

PRECISION:

STORE NUM SAMPLES

PARAMETER:

DETMES

MODE:

INST

NAME: STBSPN

PRECISION:

EVENT: EXITSP

STORE NUM SAMPLES

REPORT PERIOD: N/A

NO. OF RECORDS:200

RS-232 REPORT: OFF

CHANNEL ENABLED: ON

CAL HOLD OFF: OFF

PARAMETER:

RATIO

MODE:

INST

PRECISION:

STORE NUM SAMPLES

OFF

PARAMETER:

BNTEMP

MODE:

AVG

PRECISION:

STORE NUM SAMPLES

NAME: TEMP

EVENT: ATIMER

PARAMETER:

BOXTMP

REPORT PERIOD: 000:06:00

NO. OF RECORDS:400

RS-232 REPORT: OFF

CHANNEL ENABLED: ON

CAL HOLD OFF: OFF

MODE:

AVG

PRECISION:

STORE NUM SAMPLES

OFF

PARAMETER:

PHTDRV

MODE:

AVG

PRECISION:

STORE NUM SAMPLES

OFF

Figure 6-7:

Default iDAS Channels Setup

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These default Data Channels can be used as they are, or they can be customized from the front

panel to fit a specific application. They can also be deleted to make room for custom user-

programmed Data Channels.

Appendix A-5 lists the firmware-specific iDAS configuration in plain-text format. This text file can

either be loaded into APICOM and then modified and uploaded to the instrument or can be copied

and pasted into a terminal program to be sent to the analyzer.

NOTE

Sending an iDAS configuration to the analyzer through its COM ports will replace the

existing configuration and will delete all stored data. Back up any existing data and the

iDAS configuration before uploading new settings.

These default Data Channels can be used as they are, or they can be customized from the front

panel to fit a specific application. They can also be deleted to make room for custom user-

programmed Data Channels.

Appendix A-5 lists the firmware-specific iDAS configuration in plain-text format. This text file can

either be loaded into APICOM and then modified and uploaded to the instrument or can be copied

and pasted into a terminal program to be sent to the analyzer.

NOTE

Sending an iDAS configuration to the analyzer through its COM ports will replace the

existing configuration and will delete all stored data. Back up any existing data and the

iDAS configuration before uploading new settings.

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6.12.2.1. Viewing iDAS Data and Settings

iDAS data and settings can be viewed on the front panel through the following keystroke

sequence.

SAMPLE*

RANGE = 500.000 PPM

CO2 =X.XXX

< TST TST > CAL

SETUP

VIEW KEYPAD FUNCTIONS

KEY

FUNCTION

SAMPLE

ENTER SETUP PASS : 818

<PRM

PRM>

Moves to the next Parameter

ENTR EXIT

Moves to the previous

Parameter

SETUP X.X

PRIMARY SETUP MENU

NX10

PV10

Moves the view forward 10

data points/channels

CFG DAS RNGE PASS CLK MORE

EXIT

Moves to the next data

point/channel

Moves to the previous data

point/channel

SETUP X.X

DATA ACQUISITION

Moves the view back 10 data

points/channels

VIEW EDIT

EXIT

Keys only appear as needed

SETUP X.X

CONC : DATA AVAILABLE

NEXT VIEW

EXIT

SETUP X.X

00:00:00 NXCNC1=0.0 PPM

PV10 PREV NEXT NX10 <PRM PRM>

EXIT

SETUP X.X

PNUMTC: DATA AVAILABLE

PREV NEXT VIEW

EXIT

SETUP X.X

00:00:00 SMPFLW=000.0 cc / m

<PRM

PRM>

EXIT

SETUP X.X

CALDAT: DATA AVAILABLE

PREV NEXT VIEW

EXIT

SETUP X.X

00:00:00 NXSLP1=0.000

<PRM

PRM>

PV10 PREV

EXIT

SETUP X.X

STBZRO: DATA AVAILABLE

PREV NEXT VIEW

EXIT

SETUP X.X

00:00:00 STABIL=0.000

PV10 PREV

EXIT

SETUP X.X

STBSPN: DATA AVAILABLE

PREV NEXT VIEW

EXIT

SETUP X.X

00:00:00 DETMES=0.000

<PRM

PRM>

PV10 PREV

SETUP X.X

TEMP: DATA AVAILABLE

PREV NEXT VIEW

EXIT

SETUP X.X

00:00:00 BOXTMP=0.000

<PRM

PRM>

PV10 PREV

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6.12.2.2. Editing iDAS Data Channels

IDAS configuration is most conveniently done through the APICOM remote control program. The

following list of key strokes shows how to edit using the front panel.

SAMPLE*

RANGE = 500.000 PPM

CO2 =X.XXX

< TST TST > CAL

SETUP

SAMPLE

ENTER SETUP PASS : 818

EXIT will return to the

previous SAMPLE

display.

ENTR EXIT

SETUP X.X

PRIMARY SETUP MENU

CFG DAS RNGE PASS CLK MORE

EXIT

Main Data Acquisition Menu

SETUP X.X

DATA ACQUISITION

VIEW EDIT

EXIT

Edit Data Channel Menu

Moves the

display up &

down the list of

Data Channels

SETUP X.X

0) CONC: ATIMER, 1,

900

Exits to the Main

Data Acquisition

PREV NEXT

INS DEL EDIT PRNT EXIT

Exports the

Inserts a new Data

Channel into the list

BEFORE the Channel

configuration of all

data channels to

RS-232 interface.

currently being displayed

Deletes The Data

Channel currently

being displayed

Moves the display

between the

SETUP X.X

NAME:CONC

Exits returns to the

previous Menu

PROPERTIES for this

data channel.

<SET SET> EDIT PRNT

EXIT

Reports the configuration of current

data channels to the RS-232 ports.

Allows to edit the channel name, see next key sequence.

When editing the data channels, the top line of the display indicates some of the configuration

parameters. For example, the display line:

0) CONC : ATIMER, 4, 800

translates to the following configuration:

Channel No.: 0

NAME: CONC

TRIGGER EVENT: ATIMER

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PARAMETERS: Four parameters are included in this channel

EVENT: This channel is set up to record 800 data points.

To edit the name of a data channel, follow the above key sequence and then press:

From the end of the previous key sequence …

SETUP X.X

NAME:CONC

<SET SET> EDIT PRINT

EXIT

ENTR accepts the new string

and returns to the previous

menu.

SETUP X.X

NAME:CONC

ENTR

EXIT

EXIT ignores the new string

and returns to the previous

menu.

Press each key repeatedly to cycle through the

available character set:

0-9, A-Z, space ’ ~ ! © # $ % ^ & * ( ) - _ = +[ ]

{ } < >\ | ; : , . / ?

6.12.2.3. Trigger Events

To edit the list of data parameters associated with a specific data channel, press:

From the DATA ACQUISITION menu

(see Section 6.12.2.2)

Edit Data Channel Menu

SETUP X.X

0) CONC: ATIMER, 1,

900

Exits to the Main

Data Acquisition

PREV NEXT

INS DEL EDIT PRNT EXIT

SETUP X.X

NAME:CONC

<SET SET> EDIT PRINT

EXIT

SETUP X.X

EVENT:ATIMER

<SET SET> EDIT PRINT

EXIT

ENTR accepts the new string

and returns to the previous

menu.

EXIT ignores the new string

and returns to the previous

menu.

SETUP X.X

EVENT:ATIMER

ENTR

EXIT

Press each key repeatedly to cycle through the

list of available trigger events.

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6.12.2.4. Editing iDAS Parameters

Data channels can be edited individually from the front panel without affecting other data

channels. However, when editing a data channel, such as during adding, deleting or editing

parameters, all data for that particular channel will be lost, because the iDAS can store only data

of one format (number of parameter columns etc.) for any given channel. In addition, an iDAS

configuration can only be uploaded remotely as an entire set of channels. Hence, remote update

of the iDAS will always delete all current channels and stored data.

To modify, add or delete a parameter, follow the instruction shown in section 6.12.2.2 then press:

From the DATA ACQUISITION menu

(see Section 6.12.2.2)

Edit Data Channel Menu

SETUP X.X

0) CONC: ATIMER, 1,

900

Exits to the main

Data Acquisition

PREV NEXT

INS DEL EDIT PRNT EXIT

SETUP X.X

NAME:CONC

<SET SET> EDIT PRINT

EXIT

Press SET> key until…

SETUP X.X

PARAMETERS:1

<SET SET> EDIT PRINT

EXIT

SETUP X.X

EDIT PARAMS (DELETE DATA)

YES will delete

all data in that

entire channel.

NO returns to

the previous

menu and

YES NO

retains all data.

Edit Data Parameter Menu

Moves the

display between

existing

SETUP X.X 0) PARAM=CONC1, MODE=AVG

PREV NEXT INS DEL EDIT

Exits to the main

Data Acquisition

EXIT

Parameters

Inserts a new Parameter

before the currently

displayed Parameter

Use to configure

the functions for

this Parameter.

Deletes the Parameter

currently displayed.

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To configure a specific data parameter, press:

FROM THE EDIT DATA PARAMETER MENU

(see previous section)

SETUP X.X 0) PARAM=CONC1, MODE=AVG

PREV NEXT

INS DEL EDIT

EXIT

SETUP X.X PARAMETERS:CONC!

SET> EDIT

EXIT

SETUP X.X PARAMETERS: PMTDET

PREV NEXT ENTR

EXIT

If more than on parameter is active for

this channel, these cycle through list of

existing Parameters.

SETUP X.X SAMPLE MODE:AVG

<SET SET> EDIT

EXIT

SETUP X.X SAMPLE MODE: INST

INST AVG MIN MAX

EXIT

Press the key for the desired mode

ENTR accepts the new

setting and returns to the

previous menu.

SETUP X.X PRECISION: 1

EXIT ignores the new setting

and returns to the previous

<SET SET> EDIT

EXIT

SETUP X.X PRECISION: 1

EXIT

Set for 0-4

<SET Returns to

SETUP X.X STORE NUM. SAMPLES: OFF

Functions

<SET

EDIT

EXIT

SETUP X.X STORE NUM. SAMPLES: OFF

OFF

ENTR EXIT

Turn ON or OFF

6.12.2.5. Sample Period and Report Period

The iDAS defines two principal time periods by which sample readings are taken and permanently

recorded:

•

SAMPLE PERIOD: Determines how often iDAS temporarily records a sample reading of

the parameter in volatile memory. The SAMPLE PERIOD is set to one minute by default

and generally cannot be accessed from the standard iDAS front panel menu, but is

available via the instruments communication ports by using APICOM or the analyzer’s

standard serial data protocol.

SAMPLE PERIOD is only used when the iDAS parameter’s sample mode is set for AVG,

MIN or MAX.

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•

REPORT PERIOD: Sets how often the sample readings stored in volatile memory are

processed, (e.g. average, minimum or maximum are calculated) and the results stored

permanently in the instruments Disk-on-Chip as well as transmitted via the analyzer’s

communication ports. The REPORT PERIOD may be set from the front panel.

If the INST sample mode is selected the instrument stores and reports an instantaneous

reading of the selected parameter at the end of the chosen REPORT PERIOD

In AVG, MIN or MAX sample modes, the settings for the SAMPLE PERIOD and the REPORT

PERIOD determine the number of data points used each time the average, minimum or

maximum is calculated, stored and reported to the COMM ports. The actual sample readings are

not stored past the end of the of the chosen REPORT PERIOD.

Also, the SAMPLE PERIOD and REPORT PERIOD intervals are synchronized to the beginning

and end of the appropriate interval of the instruments internal clock.

•

If SAMPLE PERIOD were set for one minute the first reading would occur at the beginning

of the next full minute according to the instrument’s internal clock.

•

If the REPORT PERIOD were set for of one hour the first report activity would occur at

the beginning of the next full hour according to the instrument’s internal clock.

EXAMPLE: Given the above settings, if iDAS were activated at 7:57:35 the first sample

would occur at 7:58 and the first report would be calculated at 8:00 consisting of data

points for 7:58. 7:59 and 8:00.

During the next hour (from 8:01 to 9:00) the instrument will take a sample reading every

minute and include 60 sample readings.

When the STORE NUM. SAMPLES feature is turned on the instrument will also store how many

sample readings were used for the AVG, MIN or MAX calculation but not the readings

themselves.

REPORT PERIODS IN PROGRESS WHEN INSTRUMENT IS POWERED OFF

If the instrument is powered off in the middle of a REPORT PERIOD, the samples accumulated so

far during that period are lost. Once the instrument is turned back on, the iDAS restarts taking

samples and temporarily them in volatile memory as part of the REPORT PERIOD currently

active at the time of restart. At the end of this REPORT PERIOD only the sample readings taken

since the instrument was turned back on will be included in any AVG, MIN or MAX calculation.

Also, the STORE NUM. SAMPLES feature will report the number of sample readings taken since

the instrument was restarted.

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To define the REPORT PERIOD, follow the instruction shown in section 6.12.2.2 then press:

From the DATA ACQUISITION menu

(see Section 6.12.2.2)

Edit Data Channel Menu

Use the PREV and NEXT

keys to scroll to the data

channel to be edited.

SETUP X.X

0) CONC: ATIMER, 1,

900

Exits to the main

Data Acquisition

menu.

PREV NEXT

INS DEL EDIT PRNT EXIT

SETUP X.X

NAME:CONC

<SET SET> EDIT PRINT

EXIT

Press SET> key until you reach REPORT PERIOD …

SETUP X.X

REPORT PERIOD:000:01:00

<SET SET> EDIT PRINT

EXIT

SETUP X.X

REPORT PERIODD:DAYS:0

Set the number of days

between reports (0-366).

ENTR EXIT

Press keys to set hours

between reports in the format :

HH:MM (max: 23:59). This is a

24 hour clock . PM hours are 13

thru 23, midnight is 00:00.

SETUP X.X

REPORT PERIODD:TIME:01:01

ENTR EXIT

ENTR accepts the new string and

returns to the previous menu.

EXIT ignores the new string and

returns to the previous menu.

IIf at any time an illegal entry is selected (e.g., days > 366)

the ENTR key will disappear from the display.

Example 2:15 PM = 14:15

6.12.2.6. Number of Records

The number of data records in the MGFC7000E is limited to about a cumulative one million data

points in all channels (one megabyte of space on the disk-on-chip). However, the actual number

of records is also limited by the total number of parameters and channels and other settings in the

iDAS configuration. Every additional data channel, parameter, number of samples setting etc. will

reduce the maximum amount of data points somewhat. In general, however, the maximum data

capacity is divided amongst all channels (max: 20) and parameters (max: 50 per channel).

The iDAS will check the amount of available data space and prevent the user from specifying too

many records at any given point. If, for example, the iDAS memory space can accommodate 375

more data records, the ENTR key will disappear when trying to specify more than that number of

records. This check for memory space may also make an upload of an iDAS configuration with

APICOM or a Terminal program fail, if the combined number of records would be exceeded. In this

case, it is suggested to either try from the front panel what the maximum number of records can

be or use trial-and-error in designing the iDAS script or calculate the number of records using the

DAS or AICOM manuals. To set the number of records for one channel from the front panel, press

SETUP-DAS-EDIT-ENTR and the following key sequence.

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From the DATA ACQUISITION menu

(see Section 6.12.2.2)

Edit Data Channel Menu

SETUP X.X

0) CONC: ATIMER, 1 2,

900

Exits to the main

Data Acquisition

PREV NEXT

INS DEL EDIT PRNT EXIT

SETUP X.X

NAME:CONC

<SET SET> EDIT PRINT

EXIT

Press SET> key until…

SETUP X.X

NUMBER OF RECORDS:000

<SET SET> EDIT PRINT

EXIT

SETUP X.X

EDIT RECOPRDS (DELET DATA)

NO returns to the

previous menu.

YES will delete all data

in this channel.

YES

ENTR accepts the new

setting and returns to the

previous menu.

EXIT ignores the new setting

and returns to the previous

menu.

Toggle keys to set

number of records

(1-99999)

SETUP X.X

REPORT PERIODD:DAYS:0

ENTR EXIT

6.12.2.7. RS-232 Report Function

The MGFC7000E iDAS can automatically report data to the communications ports, where they can

be captured with a terminal emulation program or simply viewed by the user.

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To enable automatic COM port reporting, follow the instruction shown in section 6.12.2.2 then

press:

From the DATA ACQUISITION menu

(see Section 6.12.2.2)

Edit Data Channel Menu

SETUP X.X

0) CONC: ATIMER, 1,

900

Exits to the main

Data Acquisition

PREV NEXT

INS DEL EDIT PRNT EXIT

SETUP X.X

NAME:CONC

<SET SET> EDIT PRINT

EXIT

Press SET> key until…

SETUP X.X

RS-232 REPORT: OFF

<SET SET> EDIT PRINT

EXIT

ENTR accepts the new

setting and returns to the

previous menu.

EXIT ignores the new setting

and returns to the previous

menu.

SETUP X.X

RS-232 REPORT: OFF

Toggle key to turn

reporting ON or OFF

OFF

ENTR EXIT

6.12.2.8. Compact Report

When enabled, this option avoids unnecessary line breaks on all RS-232 reports. Instead of

reporting each parameter in one channel on a separate line, up to five parameters are reported in

one line.

6.12.2.9. Starting Date

This option allows to specify a starting date for any given channel in case the user wants to start

data acquisition only after a certain time and date. If the Starting Date is in the past, the iDAS

ignores this setting.

6.12.2.10. Disabling/Enabling Data Channels

Data channels can be temporarily disabled, which can reduce the read/write wear on the disk-on-

chip. The ALL_01 channel of the MGFC7000E, for example, is disabled by default.

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To disable a data channel, follow the instruction shown in section 6.12.2.2 then press:

From the DATA ACQUISITION menu

(see Section 6.12.2.2)

Edit Data Channel Menu

SETUP X.X

0) CONC: ATIMER, 1,

900

Exits to the main

Data Acquisition

PREV NEXT

INS DEL EDIT PRNT EXIT

SETUP X.X

NAME:CONC

<SET SET> EDIT PRINT

EXIT

Press SET> key until…

SETUP X.X

CHANNEL ENABLE:ON

<SET SET> EDIT PRINT

EXIT

ENTR accepts the new

setting and returns to the

previous menu.

EXIT ignores the new setting

and returns to the previous

menu.

SETUP X.X

CHANNEL ENABLE:ON

Toggle key to turn

channel ON or OFF

OFF

ENTR EXIT

6.12.2.11. HOLDOFF Feature

The iDAS HOLDOFF feature allows to prevent data collection during calibrations and during the

DAS_HOLDOFF period enabled and specified in the VARS (Section 6.8). To enable or disable the

HOLDOFF, follow the instruction shown in section 6.12.2.2 then press:

From the DATA ACQUISITION menu

(see Section 6.12.2.2)

Edit Data Channel Menu

SETUP X.X

0) CONC: ATIMER, 1,

900

Exits to the main

Data Acquisition

PREV NEXT

INS DEL EDIT PRNT EXIT

SETUP X.X

NAME:CONC

<SET SET> EDIT PRINT

EXIT

Press SET> key until…

SETUP X.X

CAL HOLD OFF:ON

SET> EDIT PRINT

EXIT

ENTR accepts the new

setting and returns to the

previous menu.

EXIT ignores the new setting

and returns to the previous

menu.

SETUP X.X

CAL HOLD OFF:ON

Toggle key to turn

HOLDOFF ON or OFF

ENTR EXIT

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6.12.3. Remote iDAS Configuration

Editing channels, parameters and triggering events as described in this section can be performed

via the APICOM remote control program using the graphic interface shown in Figure 6-8. Refer to

Section 6.13 for details on remote access to the MGFC7000E analyzer.

Figure 6-8:

APICOM user interface for configuring the iDAS.

Once an iDAS configuration is edited (which can be done offline and without interrupting DAS data

collection), it is conveniently uploaded to the instrument and can be stored on a computer for

later review, alteration or documentation and archival. Refer to the APICOM manual for details on

these procedures. The APICOM user manual (Teledyne Instruments part number 039450000) is

included in the APICOM installation file, which can be downloaded at http://www.teledyne-

api.com/software/apicom/.

Although Teledyne Analytical Instruments recommends the use of APICOM, the iDAS can also be

accessed and configured through a terminal emulation program such as HyperTerminal (Figure

6-9). However, all configuration commands must be created following a strict syntax or be pasted

in from of a text file, which was edited offline and then uploaded through a specific transfer

procedure.

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Figure 6-9:

iDAS Configuration Through a Terminal Emulation Program.

Both procedures are best started by downloading the default iDAS configuration, getting familiar

with its command structure and syntax conventions, and then altering a copy of the original file

offline before uploading the new configuration.

CAUTION

Whereas the editing, adding and deleting of iDAS channels and parameters of one

channel through the front-panel keyboard can be done without affecting the other

channels, uploading an iDAS configuration script to the analyzer through its

communication ports will erase all data, parameters and channels by replacing them

with the new iDAS configuration. Backup of data and the original iDAS configuration is

advised before attempting any iDAS changes.

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6.13. Remote Operation of the Analyzer

6.13.1. Remote Operation Using the External Digital I/O

6.13.1.1. Status Outputs

The status outputs report analyzer conditions via optically isolated NPN transistors, which sink up

to 50 mA of DC current. These outputs can be used interface with devices that accept logic-level

digital inputs, such as programmable logic controllers (PLC’s). Each Status bit is an open collector

output that can withstand up to 40 VDC. All of the emitters of these transistors are tied together

and available at D.

NOTE

Most PLC’s have internal provisions for limiting the current that the input will draw from

an external device. When connecting to a unit that does not have this feature, an

external dropping resistor must be used to limit the current through the transistor

output to less than 50 mA. At 50 mA, the transistor will drop approximately 1.2V from

its collector to emitter.

The status outputs are accessed via a 12-pin connector on the analyzer’s rear panel labeled

STATUS. The function of each pin is defined in Table 6–24.

STATUS

Figure 6-10: Status Output Connector

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The pin assignments for the Status Outputs are:

Table 6-24: Status Output Pin Assignments

Status

Definition

Output #

Condition

SYSTEM OK

On if no faults are present.

On if CO₂concentration measurement is valid.

If the CO₂concentration measurement is invalid, this bit is OFF.

CONC VALID

HIGH RANGE

ZERO CAL

On if unit is in high range of DUAL or AUTO range modes.

On whenever the instruments zero point is being calibrated.

On whenever the instruments span point is being calibrated.

On whenever the instrument is in diagnostic mode.

SPAN CAL

DIAG MODE

On whenever the measured CO₂concentration is above the set

point for ALM1

ALARM1

ALARM2

On whenever the measured CO₂concentration is above the set

point for ALM2

EMITTER BUSS

DC POWER

The emitters of the transistors on pins 1-8 are bussed together.

+ 5 VDC

Digital Ground

The ground level from the analyzer’s internal DC power supplies.

6.13.1.2. Control Inputs

These inputs allow the user to remotely initiate Zero and Span calibrations. Two methods for

energizing the inputs is provided below; the first using the internal +5V available on the CONTROL

IN connector and the second, if an external, isolated supply is employed.

Table 6-25: Control Input Pin Assignments

Input

Status

Condition when enabled

EXTERNAL ZERO

CAL

Zero calibration mode is activated. The mode field of the

display will read ZERO CAL R.

EXTERNAL SPAN

CAL

Span calibration mode is activated. The mode field of the

display will read SPAN CAL R.

Unused

DIGITAL GROUND Provided to ground an external device (e.g., recorder).

DC power for

Input pull ups

Input for +5 VDC required to activate inputs A - F. This voltage

can be taken from an external source or from the “+” pin.

Internal +5V

Supply

Internal source of +5V which can be used to activate inputs

when connected to pin U.

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There are two methods to activate control inputs. The internal +5V available from the “+” pin is

the most convenient method (Figure 6.11). However, to ensure that these inputs are truly

isolated, a separate, external 5 VDC power supply should be used (Figure 6.11).

CONTROL IN

U +

5 VDC Power

Supply

External Power Connections

Local Power Connections

Figure 6-11: Control Inputs

6.13.2. Remote Operation Using the External Serial I/O

6.13.2.1. Terminal Operating Modes

The Model GFC7000E can be remotely configured, calibrated or queried for stored data through

the serial ports. As terminals and computers use different communication schemes, the analyzer

supports two communicate modes specifically designed to interface with these two types of

devices.

•

Computer mode is used when the analyzer is connected to a computer with a dedicated

interface program such as APICOM. More information regarding APICOM can be found in

later in this section or on the Teledyne Instruments website at http://www.teledyne-

api.com/software/apicom/.

•

Interactive mode is used with a terminal emulation programs such as HyperTerminal or a

“dumb” computer terminal. The commands that are used to operate the analyzer in this

mode are listed in Table 6-26.

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6.13.2.2. Help Commands in Terminal Mode

Table 6-26: Terminal Mode Software Commands

COMMAND

Control-T

Function

Switches the analyzer to terminal mode (echo, edit). If mode flags 1 & 2 are OFF,

the interface can be used in interactive mode with a terminal emulation program.

Control-C

Switches the analyzer to computer mode (no echo, no edit).

A carriage return is required after each command line is typed into the

terminal/computer. The command will not be sent to the analyzer to be executed

until this is done. On personal computers, this is achieved by pressing the ENTER

key.

(carriage return)

Erases one character to the left of the cursor location.

(backspace)

ESC

Erases the entire command line.

(escape)

? [ID] CR

This command prints a complete list of available commands along with the

definitions of their functionality to the display device of the terminal or computer

being used. The ID number of the analyzer is only necessary if multiple analyzers

are on the same communications line, such as the multi-drop setup.

Control-C

Control-P

Pauses the listing of commands.

Restarts the listing of commands.

6.13.2.3. Command Syntax

Commands are not case-sensitive and all arguments within one command (i.e. ID numbers,

keywords, data values, etc.) must be separated with a space character.

All Commands follow the syntax:

X [ID] COMMAND <CR>

Where

is the command type (one letter) that defines the type of command. Allowed

designators are listed in Table 6-27 and Appendix A-6.

[ID]

is the analyzer identification number (Section 6.10.1.). Example: the Command

“? 200” followed by a carriage return would print the list of available commands

for the revision of software currently installed in the instrument assigned ID

Number 200.

COMMAND is the command designator: This string is the name of the command being

issued (LIST, ABORT, NAME, EXIT, etc.). Some commands may have additional

arguments that define how the command is to be executed. Press ? <CR> or

refer to Appendix A-6 for a list of available command designators.

<CR>

is a carriage return. All commands must be terminated by a carriage return

(usually achieved by pressing the ENTER key on a computer).

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Table 6-27: Command Types

Operating Instructions

COMMAND

COMMAND TYPE

Calibration

Diagnostic

Logon

Test measurement

Variable

Warning

6.13.2.4. Data Types

Data types consist of integers, hexadecimal integers, floating-point numbers, Boolean expressions

and text strings.

•

Integer data are used to indicate integral quantities such as a number of records, a filter

length, etc. They consist of an optional plus or minus sign, followed by one or more digits.

For example, +1, -12, 123 are all valid integers.

•

Hexadecimal integer data are used for the same purposes as integers. They consist of the

two characters “0x,” followed by one or more hexadecimal digits (0-9, A-F, a-f), which is

the ‘C’ programming language convention. No plus or minus sign is permitted. For

example, 0x1, 0x12, 0x1234abcd are all valid hexadecimal integers.

•

Floating-point numbers are used to specify continuously variable values such as

temperature set points, time intervals, warning limits, voltages, etc. They consist of an

optional plus or minus sign, followed by zero or more digits, an optional decimal point, and

zero or more digits. (At least one digit must appear before or after the decimal point.)

Scientific notation is not permitted. For example, +1.0, 1234.5678, -0.1, 1 are all valid

floating-point numbers.

•

Boolean expressions are used to specify the value of variables or I/O signals that may

assume only two values. They are denoted by the keywords ON and OFF.

Text strings are used to represent data that cannot be easily represented by other data

types, such as data channel names, which may contain letters and numbers. They consist

of a quotation mark, followed by one or more printable characters, including spaces,

letters, numbers, and symbols, and a final quotation mark. For example, “a”, “1”,

“123abc”, and “()[]<>” are all valid text strings. It is not possible to include a quotation

mark character within a text string.

•

Some commands allow you to access variables, messages, and other items, such as iDAS

data channels, by name. When using these commands, you must type the entire name of

the item; you cannot abbreviate any names.

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6.13.2.5. Status Reporting

Reporting of status messages as an audit trail is one of the three principal uses for the RS-232

interface (the other two being the command line interface for controlling the instrument and the

download of data in electronic format). You can effectively disable the reporting feature by setting

the interface to quiet mode (Section 6.10.6., Table 6-16).

Status reports include iDAS data (when reporting is enabled), warning messages, calibration and

diagnostic status messages. Refer to Appendix A-3 for a list of the possible messages, and this

section for information on controlling the instrument through the RS-232 interface.

General Message Format

All messages from the instrument (including those in response to a command line request) are in

the format:

X DDD:HH:MM [Id] MESSAGE<CRLF>

Where:

is a command type designator, a single character indicating the message

type, as shown in the Table 6-27.

DDD:HH:MM is the time stamp, the date and time when the message was issued. It

consists of 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.

[ID]

is the analyzer ID, a number with 1 to 4 digits.

MESSAGE

is the message content that may contain warning messages, test

measurements, iDAS reports, variable values, etc.

<CRLF>

is a carriage return / line feed pair, which terminates the message.

The uniform nature of the output messages makes it easy for a host computer to parse them into

an easy structure. Keep in mind that the front panel display does not give any information on the

time a message was issued, hence it is useful to log such messages for trouble-shooting and

reference purposes. Terminal emulation programs such as HyperTerminal can capture these

messages to text files for later review.

6.13.2.6. Remote Access by Modem

The MGFC7000E can be connected to a modem for remote access. This requires a cable between

the analyzer’s COM port and the modem, typically a DB-9F to DB-25M cable (available from

Teledyne Instruments with part number WR0000024).

Once the cable has been connected, check to make sure the DTE-DCE is in the correct position.

Also make sure the MGFC7000E COM port is set for a baud rate that is compatible with the

modem, which needs to operate with an 8-bit word length with one stop bit.

The first step is to turn on the MODEM ENABLE communication mode (Mode 64, Section 6.10.6).

Once this is completed, the appropriate setup command line for your modem can be entered into

the analyzer. The default setting for this feature is

AT Y0 &D0 &H0 &I0 S0=2 &B0 &N6 &M0 E0 Q1 &W0

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This string can be altered to match your modem’s initialization and can be up to 100 characters

long.

To change this setting press:

SAMPLE*

RANGE = 500.000 PPM

CO2 =X.XXX

< TST TST > CAL

SETUP

SETUP X.X

SET> EDIT

COM1 MODE:0

EXIT

SAMPLE

ENTER SETUP PASS : 818

ENTR EXIT

SETUP X.X

COM1 BAUD RATE:19200

<SET SET> EDIT

SETUP X.X

PRIMARY SETUP MENU

CFG DAS RNGE PASS CLK MORE

EXIT

SETUP X.X

COM1 MODEM INIT:AT Y∅ &D∅ &H

EXIT

EXIT returns

to the

<SET SET> EDIT

SETUP X.X

SECONDARY SETUP MENU

ENTR accepts the

new string and returns

to the previous menu.

EXIT ignores the new

string and returns to

the previous menu.

COMM VARS DIAG ALRM

EXIT

SETUP X.X

COM1 MODEM INIT:[A]T Y∅ &D∅ &H

ENTR EXIT

<CH CH> INS DEL [A]

SETUP X.X

COMMUNICATIONS MENU

Select which

COM Port is

tested

ID COM1 COM2

Press the [?]

key repeatedly to cycle through the

available character set:

0-9

The INS key

inserts a character

before the cursor

location.

The DEL key

deletes a character

at the cursor

location.

A-Z

The <CH and CH> keys move

the [ ] cursor left and right

along the text string

space ’ ~ ! © # $ % ^ & * ( ) - _ =

+[ ] { } < >\ | ; : , . / ?

To Initialize the modem press:

SAMPLE*

RANGE = 500.000 PPM

CO2 =X.XXX

SETUP

< TST TST > CAL

SETUP X.X

SET> EDIT

COM1 MODE:0

EXIT

SAMPLE

ENTER SETUP PASS : 818

ENTR EXIT

SETUP X.X

COM1 BAUD RATE:19200

<SET SET> EDIT

SETUP X.X

PRIMARY SETUP MENU

CFG DAS RNGE PASS CLK MORE

EXIT

EXIT returns

to the

SETUP X.X

COM1 MODEM INIT:AT Y∅ &D∅ &H

SETUP X.X

SECONDARY SETUP MENU

<SET SET> EDIT

EXIT

COMM VARS DIAG ALRM

EXIT

SETUP X.X

COM1 INITIALIZE MODEM

EXIT

SETUP X.X

COMMUNICATIONS MENU

Select which

COM Port is

tested

<SET SET> INIT

ID COM1 COM2

EXIT

SETUP X.X

INITIALIZING MODEM

<SET SET> INIT

EXIT

EXIT returns to the

Communications Menu.

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6.13.2.7. COM Port Password Security

In order to provide security for remote access of the MGFC7000E, a LOGON feature can be

enabled to require a password before the instrument will accept commands. This is done by

turning on the SECURITY MODE (Mode 4, Section 6.10.6). Once the SECURITY MODE is

enabled, the following items apply.

•

A password is required before the port will respond or pass on commands.

If the port is inactive for one hour, it will automatically logoff, which can also be achieved

with the LOGOFF command.

•

Three unsuccessful attempts to log on with an incorrect password will cause subsequent

logins to be disabled for 1 hour, even if the correct password is used.

•

If not logged on, the only active command is the '?' request for the help screen.

The following messages will be returned at logon:

•

LOGON SUCCESSFUL - Correct password given

LOGON FAILED - Password not given or incorrect

LOGOFF SUCCESSFUL - Connection terminated successfully

To log on to the model GFC7000E analyzer with SECURITY MODE feature enabled, type:

LOGON 940331

940331 is the default password. To change the default password, use the variable RS232_PASS

issued as follows:

V RS232_PASS=NNNNNN

Where N is any numeral between 0 and 9.

6.13.2.8. APICOM Remote Control Program

APICOM is an easy-to-use, yet powerful interface program that allows to access and control any of

Teledyne Instruments’ main line of ambient and stack-gas instruments from a remote connection

through direct cable, modem or Ethernet. Running APICOM, a user can:

Establish a link from a remote location to the MGFC7000E through direct cable connection via RS-

232 modem or Ethernet.

•

View the instrument’s front panel and remotely access all functions that could be accessed

when standing in front of the instrument.

•

Remotely edit system parameters and set points.

Download, view, graph and save data for predictive diagnostics or data analysis.

Retrieve, view, edit, save and upload iDAS configurations.

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•

Check on system parameters for trouble-shooting and quality control.

APICOM is very helpful for initial setup, data analysis, maintenance and trouble-shooting. Figure

6-8 shows an example of APICOM being used to remotely configuration the instruments iDAS

feature. Figure 6-12 shows examples of APICOM’s main interface, which emulates the look and

functionality of the instruments actual front panel

Figure 6-12: APICOM Remote Control Program Interface

APICOM is included free of cost with the analyzer and the latest versions can also be downloaded

for free at http://www.teledyne-api.com/software/apicom/.

6.13.3. Additional Communications Documentation

Table 6-28: Serial Interface Documents

INTERFACE / TOOL

DOCUMENT TITLE

PART

NUMBER

AVAILABLE

ONLINE*

APICOM

Multi-drop

DAS Manual

APICOM User Manual

039450000

021790000

028370000

YES

RS-232 Multi-drop Documentation

Detailed description of the iDAS.

* These documents can be downloaded at http://www.teledyne-api.com/manuals/

6.13.4. Using the GFC7000E with a Hessen Protocol Network

6.13.4.1. General Overview of Hessen Protocol

The Hessen protocol is a multidrop protocol, in which several remote instruments are connected

via a common communications channel to a host computer. The remote instruments are regarded

as slaves of the host computer. The remote instruments are unaware that they are connected to

a multidrop bus and never initiate Hessen protocol messages. They only respond to commands

from the host computer and only when they receive a command containing their own unique ID

number.

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The Hessen protocol is designed to accomplish two things: to obtain the status of remote

instruments, including the concentrations of all the gases measured; and to place remote

instruments into zero or span calibration or measure mode. API’s implementation supports both of

these principal features.

The Hessen protocol is not well defined, therefore while API’s application is completely compatible

with the protocol itself, it may be different from implementations by other companies.

The following subsections describe the basics for setting up your instrument to operate over a

Hessen Protocol network. for more detailed information as well as a list of host computer

commands and examples of command and response message syntax, download the Manual

Addendum for Hessen Protocol from the Teledyne Instruments web site: http://www.teledyne-

ai.com/manuals/index.asp .

6.13.4.2. Hessen COMM Port Configuration

Hessen protocol requires the communication parameters of the MGFC7000E’s COMM ports to be

set differently than the standard configuration as shown in the table below.

Table 6-29: RS-232 Communication Parameters for Hessen Protocol

Parameter

Data Bits

Stop Bits

Parity

Standard

Hessen

None

Full

Even

Half

Duplex

To change the rest of the COMM port parameters. see Section 6.10.6.

To change the baud rate of the GFC7000E’s COMM ports, see Section 6.10.7.

NOTE

Make sure that the communication parameters of the host computer are also properly

set.

Also, the instrument software has a 200 ms. latency before it responds to commands

issued by the host computer. This latency should present no problems, but you should

be aware of it and not issue commands to the instrument too frequently.

6.13.4.3. Activating Hessen Protocol

The first step in configuring the GFC7000E to operate over a Hessen protocol network is to

activate the Hessen mode for COMM ports and configure the communication parameters for the

port(s) appropriately. Press:

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Operating Instructions

SAMPLE*

RANGE = 500.000 PPM

CO2 =X.XXX

SETUP X.X

COM1 QUIET MODE: OFF

ENTR EXIT

Repeat the

entire process to

set up the

< TST TST > CAL

SETUP

NEXT OFF

COM2 port

SAMPLE

ENTER SETUP PASS : 818

Continue pressing next until …

ENTR EXIT

SETUP X.X COM1 HESSEN PROTOCOL : OFF

SETUP X.X

PRIMARY SETUP MENU

PREV NEXT OFF

ENTR EXIT

CFG DAS RNGE PASS CLK MORE

EXIT

Toggle OFF/ON keys

to change

SETUP X.X COM1 HESSEN PROTOCOL : ON

SETUP X.X SECONDARY SETUP MENU

activate/deactivate

selected mode.

PREV NEXT ON

ENTR EXIT

COMM VARS DIAG

ALRM

SETUP X.X

COMMUNICATIONS MENU

SETUP X.X

COM1 E,7,1 MODE: OFF

Select which COMM

port to configure

ID COM1 COM2

PREV NEXT OFF

ENTR EXIT

The sum of the mode

IDs of the selected

modes is displayed

here

SETUP X.X

SET> EDIT

COM1 MODE:0

SETUP X.X

COM1 E,7,1 MODE: ON

ENTR key accepts the

new settings

PREV NEXT ON

ENTR EXIT

EXIT key ignores the

new settings

6.13.4.4. Selecting a Hessen Protocol Type

Currently there are two versions of Hessen Protocol in use. The original implementation, referred

to as TYPE 1, and a more recently released version, TYPE 2 that has more flexibility when

operating with instruments that can measure more than one type of gas. For more specific

information about the difference between TYPE 1and TYPE 2 download the Manual Addendum for

Hessen Protocol from the Teledyne Instruments web site: http://www.teledyne-

ai.com/manuals/index.asp .

To select a Hessen Protocol Type press:

SAMPLE*

RANGE = 500.000 PPM

CO2 =X.XXX

< TST TST > CAL

SETUP

SETUP X.X

COMMUNICATIONS MENU

SAMPLE

ENTER SETUP PASS : 818

ID HESN COM1 COM2

EXIT

ENTR EXIT

SETUP X.

HESSEN VARIATION: TYPE 1

SETUP X.X

PRIMARY SETUP MENU

SET> EDIT

EXIT

CFG DAS RNGE PASS CLK MORE

EXIT

ENTR key accepts the

new settings

SETUP X.X HESSEN VARIATION: TYPE 1

TYE1 TYPE 2 ENTR EXIT

EXIT key ignores the

SETUP X.X

SECONDARY SETUP MENU

new settings

COMM VARS DIAG ALRM

SETUP X.X HESSEN VARIATION: TYPE 2

PREV NEXT OFF ENTR EXIT

Press to change

protocol type.

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Operating Instructions

NOTE

While Hessen Protocol Mode can be activated independently for COM1 and COM2, The

TYPE selection affects both Ports.

6.13.4.5. Setting The Hessen Protocol Response Mode

The Teledyne Instruments implementation of Hessen Protocol allows the user to choose one of

several different modes of response for the analyzer.

Table 6-30: Teledyne Instruments Hessen Protocol Response Modes

MODE ID

CMD

MODE DESCRIPTION

This is the Default Setting. Reponses from the instrument are encoded as the traditional

command format. Style and format of responses depend on exact coding of the initiating

command.

Responses from the instrument are always delimited with <STX> (at the beginning of the

response, <ETX> (at the end of the response followed by a 2 digit Block Check Code

(checksum), regardless of the command encoding.

BCC

Responses from the instrument are always delimited with <CR> at the beginning and the end

of the string, regardless of the command encoding.

TEXT

To Select a Hessen response mode, press:

SAMPLE*

RANGE = 500.000 PPM

CO2 =X.XXX

< TST TST > CAL

SETUP

SAMPLE

ENTER SETUP PASS : 818

ENTR EXIT

SETUP X.X

COMMUNICATIONS MENU

ID HESN COM1 COM2

EXIT

SETUP X.X

PRIMARY SETUP MENU

CFG DAS RNGE PASS CLK MORE

EXIT

SETUP X.X

HESSEN VARIATION: TYPE 1

SET> EDIT

SETUP X.X

SECONDARY SETUP MENU

ENTR key accepts the

new settings

COMM VARS DIAG ALRM

EXIT key ignores the

SETUP X.X

HESSEN RESPONSE MODE :CMD

new settings

<SET SET> EDIT

EXIT

Press to

change

response

mode.

SETUP X.X

HESSEN RESPONSE MODE :CMD

BCC TEXT EDIT

ENTR EXIT

6.13.4.6. Hessen Protocol Gas ID

The Model GFC7000E Analyzer is a single gas instrument that measures CO₂. As such it’s default

gas ID has already been set to 310. There is no need to change this setting.

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Operating Instructions

6.13.4.7. Setting Hessen Protocol Status Flags

Teledyne Instruments’ implementation of Hessen protocols includes a set of status bits that the

instrument includes in responses to inform the host computer of its condition. Each bit can be

assigned to one operational and warning message flag. The default settings for these bit/flags

are:

Table 6-31: Default Hessen Status Bit Assignments

STATUS FLAG NAME

DEFAULT BIT

ASSIGNMENT

WARNING FLAGS

SAMPLE FLOW WARNING

BENCH TEMP WARNING

SOURCE WARNING

0001

0002

0004

0008

0010

0020

0040

0080

BOX TEMP WARNING

WHEEL TEMP WARNING

SAMPLE TEMP WARNING

SAMPLE PRESSURE WARNING

INVALID CONC

(The Instrument’s Front Panel Display Will Show

The Concentration As “XXXX”)

OPERATIONAL FLAGS

Instrument Off

0100

0200

0400

0800

In Manual Calibration Mode

In Zero Calibration Mode

In Span Calibration Mode

UNITS OF MEASURE FLAGS

UGM

0000

2000

MGM

PPB

4000

PPM

6000

SPARE/UNUSED BITS

UNASSIGNED FLAGS (0000)

100, 1000, 8000

Sync Warning

Relay Board Warning

Front Panel Warning

Conc Alarm 1

Conc Alarm 2

Analog Cal Warning

Cannot Dyn Zero

Cannot Dyn Span

Invalid Conc

Photo Temp Warning

System Reset

Rear Board Not Detected

NOTES:

It is possible to assign more than one flag to the same Hessen status bit. This allows

the grouping of similar flags, such as all temperature warnings, under the same status

bit.

Be careful not to assign conflicting flags to the same bit as each status bit will be

triggered if any of the assigned flags is active.

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Operating Instructions

To assign or reset the status flag bit assignments, press:

SAMPLE*

RANGE = 500.000 PPM

CO2 =X.XXX

< TST TST > CAL

SETUP

SAMPLE

ENTER SETUP PASS : 818

ENTR EXIT

SETUP X.X

PRIMARY SETUP MENU

CFG DAS RNGE PASS CLK MORE

EXIT

SETUP X.X

SECONDARY SETUP MENU

COMM VARS DIAG ALRM

EXIT

SETUP X.X

COMMUNICATIONS MENU

ID HESN COM1 COM2

Repeat pressing SET> until …

SETUP X.

HESSEN STATUS FLAGS

<SET SET> EDIT

EXIT

SETUP X.

SYNC WARNING: 0000

PREV NEXT

EDIT PRNT EXIT

Repeat pressing NEXT or PREV until the desired

message flag is displayed. See Table 6-27.

For xxample …

SETUP X.

SYSTEM RESET: 0000

EDIT PRNT EXIT

PREV NEXT

The <CH and

CH> keys move

the [ ] cursor left

and right along

the bit string.

SETUP X.

SYSTEM RESET: [0]000

[0]

ENTR key accepts the

new settings

<CH CH>

ENTR EXIT

EXIT key ignores the

new settings

Press the [?] key repeatedly to cycle through the available character set: 0-9

Note: Values of A-F can also be set but are meaningless.

6.13.4.8. Instrument ID Code

Each instrument on a Hessen Protocol network must have a unique ID code. The MGFC7000E is

programmed with a default ID code of 360. To change this code see Section 6.10.1

User Notes

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Calibration Procedures

7. CALIBRATION PROCEDURES

This section contains a variety of information regarding the various methods for calibrating a

Model GFC7000E CO₂Analyzer as well as other supporting information.

NOTE

The procedures in this section assume that the calibration password feature is disabled

(the instruments default state). If it is enabled a password prompt screen (see Section

6.3.1) will appear after the CAL, CALZ or CALS buttons are pushed but before the

instrument enters the associated calibration mode.

7.1. Before Calibration

The calibration procedures in this section assume that the Range Type, Range Span and units of

measure have already been selected for the analyzer. If this has not been done, please do so

before continuing (see Section 6.7 for instructions).

All Gas lines should be PTFE (Teflon), FEP, glass, stainless steel or brass.

NOTE

If any problems occur while performing the following calibration procedures, refer to

Chapter 11 of this manual for troubleshooting tips.

7.1.1. Zero Air and Span Gas

To perform the following calibration you must have sources for zero air and span gas available.

Zero Air is similar in chemical composition to the Earth’s atmosphere but scrubbed of all

components that might affect the analyzer’s readings. Zero air should contain less than 25 ppb of

CO₂and other major interfering gases such as CO and Water Vapor. It should have a dew point

of -5°C or less

Span Gas is a gas specifically mixed to match the chemical composition of the type of gas being

measured at near full scale of the desired measurement range. It is recommended that the span

gas used have a concentration equal to 80% of the full measurement range.

If Span Gas is sourced directly from a calibrated, pressurized tank, the gas mixture should be CO₂

mixed with Zero Air or N₂at the required ratio.

Zero air generators that condition ambient air by drying and removal of pollutants are available on

the commercial market such as the Teledyne Instruments Model 701 Zero Air Generator. We

recommend this type of device, in conjunction with a CO₂scrubber such as soda-lime, for

generating zero air.

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Calibration Procedures

7.1.2. Calibration Gas Traceability

All equipment used to produce calibration gases should be verified against standards of the

National Institute for Standards and Technology (NIST). To ensure NIST traceability, we

recommend to acquire cylinders of working gas that are certified to be traceable to NIST Standard

Reference Materials (SRM). These are available from a variety of commercial sources.

7.1.3. Data Recording Devices

A strip chart recorder, data acquisition system or digital data acquisition system should be used to

record data from the MGFC7000E’s serial or analog outputs. If analog readings are used, the

response of the recording system should be checked against a NIST traceable voltage source or

meter. Data recording device should be capable of bi-polar operation so that negative readings

can be recorded. For electronic data recording, the MGFC7000E provides an internal data

acquisition system (iDAS), which is described in detail in Section 6.12.

7.2. Manual Calibration without Zero/Span Valves

This is the basic method for manually calibrating the Model GFC7000E CO₂Analyzer without

functioning zero/span valve options. It is identical to the method described in the GETTING

STARTED (Chapter 3) of this manual and is repeated her for you convenience.

STEP ONE: Connect the Sources of Zero Air and Span Gas as shown below.

Calibrated CO₂

gas at desired

VENT

Source of

SAMPLE Gas

Removed

during

Calibration

span gas

concentration

Needle

valve to

control

flow

Indicating

soda-lime

Sample

Exhaust

MODEL

GFC7000E

Valve

Vent Span

Pressure Span

MODEL 701

Zero Air

IZS

Generator

Purge In

Figure 7-1:

Pneumatic Connections–Basic Configuration–Using Bottled Span Gas

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Calibration Procedures

Source of

SAMPLE Gas

Removed

during

Calibrated

CO₂Gas

MODEL 700

Gas Dilution

Calibrator

Calibration

Indicating

soda-lime

VENT

Sample

Exhaust

Vent Span

Pressure Span

IZS

MODEL

GFC7000E

MODEL 701

Zero Air Generator

Purge In

Figure 7-2:

Pneumatic Connections–Basic Configuration–Using Gas Dilution Calibrator

STEP TWO: Set the expected CO₂Span Gas concentration:

SAMPLE*

RANGE = 500.000 PPM

CO2 =X.XXX

SETUP

< TST TST > CAL

This sequence causes the

analyzer to prompt for the

expected CO_xspan

concentration.

M-P CAL

RANGE = 500.000 PPM

CO2 =X.XXX

EXIT

< TST TST > ZERO

CONC

The SO₂span

concentration values

automatically default to

400.0 Conc.

EXIT ignores the new setting

and returns to the previous

display.

M-P CAL

SO2 SPAN CONC: 400.000 Conc

To change this value to

the actual concentration of

the span gas, enter the

number by pressing the

key under each digit until

the expected value

ENTR accepts the new setting

ENTR EXIT

and returns to the

previous display..

appears.

NOTE

For this Initial Calibration it is important to independently verify the PRECISE CO₂

Concentration Value of the SPAN gas.

If the source of the Span Gas is from a Calibrated Bottle, use the exact concentration

value printed on the bottle.

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Calibration Procedures

STEP THREE: Perform the Zero/Span Calibration Procedure:

SAMPLE*

RANGE = 500.000 PPM

CO2 =XXX.X

SETUP

Set the Display to show the

STABIL test function.

This function calculates the

stability of the CO_x

< TST TST > CAL

measurement

SAMPLE

STABIL=XXX.X PPM

CO2 =XXX.X

SETUP

< TST TST > CAL

ACTION:

Allow zero gas to enter the sample port at the

rear of the instrument.

Wait until STABIL

falls below 1.0 ppb.

This may take several

minutes.

M-P CAL

STABIL=XXX.X PPM

CO2 =XXX.X

< TST TST > CAL

SETUP

M-P CAL

STABIL=XXX.X PPM

CONC

CO2 =XXX.X

EXIT

< TST TST > ZERO

Press ENTR to changes the

OFFSET & SLOPE values for the

CO₂measurements.

M-P CAL

STABIL=XXX.X PPM

CO2 =XXX.X

< TST TST > ENTR

CONC

EXIT

Press EXIT to leave the calibration

unchanged and return to the

previous menu.

ACTION:

Allow span gas to enter the sample port at the

rear of the instrument.

The value of

STABIL may jump

significantly.

Wait until it falls back

below 1.0 ppb.

The SPAN key now

appears during the

transition from zero to

span.

This may take several

minutes.

M-P CAL

STABIL=XXX.X PPM

CO2 =XXX.X

EXIT

< TST TST >

M-P CAL

SPAN CONC

You may see both keys.

If either the ZERO or

SPAN buttons fail to

appear see Section 11

for troubleshooting tips.

Press ENTR to change the

OFFSET & SLOPE values for the

CO₂measurements.

RANGE = 500.000 PPM CO2 =XXX.X

EXIT

Press EXIT to leave the calibration

unchanged and return to the

previous menu.

< TST TST > ENTR SPAN CONC

M-P CAL

RANGE = 500.000 PPM CO2 =XXX.X

CONC

EXIT

EXIT returns to the main

SAMPLE display

< TST TST > ENTR

If the ZERO or SPAN keys are not displayed, this means that the measurement made during that

part of the procedure is too far out of the allowable range to do allow a reliable calibration. The

reason for this must be determined before the analyzer can be calibrated. See Chapter 11 for

troubleshooting tips.

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Calibration Procedures

7.3. Manual Calibration Checks

Informal calibration checks, which only evaluate but do not alter the analyzer’s response curve,

are recommended as a regular maintenance item and in order to monitor the analyzer’s

performance. To carry out a calibration check rather than a full calibration, follow these steps.

STEP ONE: Connect the sources of zero air and span gas as shown in Figures 7.1 or 7.2.

STEP TWO: Perform the zero/span calibration check procedure:

ACTION:

Supply the instrument with zero gas.

SAMPLE

RANGE = 500.0 PPM

CO2=X.XXX

SETUP

Scroll the display to the

STABIL test function.

< TST TST > CAL

SAMPLE

STABIL=XXX.X PPM

CO2=X.XXX

SETUP

< TST TST > CAL

Wait until

STABIL is

below 1.0 ppb.

This may take

several minutes.

ACTION:

Record the CO₂

concentration

reading.

SAMPLE

STABIL=XXX.X PPM

CO2=X.XXX

< TST TST > CAL

SETUP

The value of

STABIL may jump

significantly.

ACTION:

Supply span gas to the instrument

Wait until it falls

below 1.0 ppb. This

may take several

minutes.

ACTION:

Record the CO₂

concentration

reading.

SAMPLE

STABIL=XXX.X PPM

CO2=X.XXX

SETUP

< TST TST > CAL

The SPAN key appears during the transition from zero to

span. You may see both keys.

7.4. Manual Calibration with Zero/Span Valves

There are four different zero/span valve option configurations (see Section 5.4). They all operate

identically, differing only in the method used to supply calibration gas to the Analyzer.

STEP ONE: Connect the sources of Zero Air and Span Gas as shown below.

Figures 7-3 through 7-6 show the proper pneumatic connections for GFC7000E’s with various

optional internal valve sets installed.

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Calibration Procedures

Source of

SAMPLE Gas

VENT if input is pressurized

Certified

CO₂Gas

Sample

Exhaust

Needle

valve to

control

MODEL

GFC7000E

VENT

Vent Span

flow

MODEL 701

Zero Air

Pressure Span

Generator

IZS

VENT

Purge In

Indicating

soda-lime

Figure 7-3:

Pneumatic Connections–MGFC7000E with Zero/Span/Shutoff Valves (OPT

50)

Source of

SAMPLE Gas

VENT if input is pressurized

Certified

CO₂Gas

Sample

Exhaust

MODEL 701

Zero Air

Generator

MODEL

GFC7000E

VENT

Vent Span

Pressure Span

IZS

External Zero

Air Scrubber

Purge In

Indicating

soda-lime

Figure 7-4

Pneumatic Connections–MGFC7000E with Zero/Span/Shutoff Valves and

External Zero Air Scrubber (OPT 51)

Source of

SAMPLE Gas

VENT if input is pressurized

MODEL 700

Gas Dilution

Calibrator

Sample

Certified

CO₂Gas

Needle

valve to

Exhaust

MODEL

GFC7000E

control flow

Vent Span

VENT

Pressure Span

Indicating

soda-lime

IZS

VENT

Purge In

MODEL 701

Zero Air

Generator

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Calibration Procedures

Figure 7-5:

Pneumatic Connections–MGFC7000E with Zero/Span Valves (OPT 52)

Source of

SAMPLE Gas

VENT if input is pressurized

Certified

CO Gas

MODEL 700

Gas Dilution

Calibrator

Sample

Exhaust

Indicating

soda-lime

VENT

MODEL

GFC7000E

Vent Span

Pressure Span

External Zero

Air Scrubber

IZS

MODEL 701

Zero Air Generator

Purge In

Figure 7-6:

Pneumatic Connections–MGFC7000E with Zero/Span Valves with External

Zero air Scrubber (OPT 53)

STEP TWO: Set the expected CO₂Span Gas concentration:

SAMPLE*

RANGE = 500.000 PPM

CO2 =X.XXX

SETUP

< TST TST > CAL CALZ CALS

This sequence causes the

analyzer to prompt for the

expected CO_xspan

concentration.

M-P CAL

RANGE = 500.000 PPM

CONC

CO2 =X.XXX

EXIT

< TST TST > ZERO

The SO₂span

concentration values

automatically default to

400.0 Conc.

EXIT ignores the new setting

and returns to the previous

display.

M-P CAL

SO2 SPAN CONC: 450.000 Conc

To change this value to

the actual concentration of

the span gas, enter the

number by pressing the

key under each digit until

the expected value

ENTR accepts the new setting

ENTR EXIT

and returns to the

previous display..

appears.

NOTE

For this Initial Calibration it is important to independently verify the PRECISE CO₂

Concentration Value of the SPAN gas.

If the source of the Span Gas is from a Calibrated Bottle, use the exact concentration

value printed on the bottle.

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Calibration Procedures

STEP THREE: Perform the zero/span calibration. Zero and span checks using the zero/span

valve option are similar to that described in Section 3.3, except that zero air and span gas is

supplied to the analyzer through the zero/span valves rather than through the sample inlet port.

The zero and cal operations are initiated directly and independently with dedicated keys (CALZ &

CALS).

SAMPLE*

RANGE = 500.000 PPM

CO2 =XXX.X

Set the Display to show the

STABIL test function.

This function calculates the

stability of the CO_x

<TST TST> CAL CALZ CALS SETUP

measurement

SAMPLE

STABIL=XXX.X PPM

CO2 =XXX.X

< TST TST > CAL CALZ CALS SETUP

ACTION:

Allow zero gas to enter the sample port at the

rear of the instrument.

Wait until STABIL

falls below1.0 ppb.

This may take several

minutes.

M-P CAL

STABIL=XXX.X PPM

CO2 =XXX.X

SETUP

< TST TST > CAL CALZ CALS

M-P CAL

STABIL=XXX.X PPM

CONC

CO2 =XXX.X

EXIT

< TST TST > ZERO

Press ENTR to changes the

OFFSET & SLOPE values for the

CO₂measurements.

M-P CAL

STABIL=XXX.X PPM

CO2 =XXX.X

< TST TST > ENTR

CONC

EXIT

Press EXIT to leave the calibration

unchanged and return to the

previous menu.

ACTION:

Allow span gas to enter the sample port at the

rear of the instrument.

The value of

STABIL may jump

significantly.

Wait until it falls back

below 1.0 ppb.

The SPAN key now

appears during the

transition from zero to

span.

This may take several

minutes.

M-P CAL

STABIL=XXX.X PPM

CO2 =XXX.X

EXIT

< TST TST >

M-P CAL

SPAN CONC

You may see both keys.

If either the ZERO or

SPAN buttons fail to

appear see Section 11

for troubleshooting tips.

Press ENTR to change the

OFFSET & SLOPE values for the

CO₂measurements.

RANGE = 500.000 PPM CO2 =XXX.X

EXIT

Press EXIT to leave the calibration

unchanged and return to the

previous menu.

< TST TST > ENTR SPAN CONC

M-P CAL

RANGE = 500.000 PPM CO2 =XXX.X

CONC

EXIT

EXIT returns to the main

SAMPLE display

< TST TST > ENTR

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Calibration Procedures

7.5. Manual Calibration Checks with Zero/Span Valves

Zero and span checks using the VARIOUS zero/span valve options available for the MGFC7000E

are similar to that described in Section 7.3, except that the zero and calibration operations are

initiated directly and independently with dedicated keys CALZ and CALS.

To perform a manual calibration check of an analyzer with a valve option installed, use the

following method.

STEP ONE: Connect the sources of Zero Air and Span Gas as shown in figures 7-3 through 7-6.

STEP TWO: Perform the zero/span check.

SAMPLE*

RANGE = 500.000 PPM

CO2 =X.XXX

Scroll to the STABIL test

< TST TST > CAL CALZ CALS

SETUP

function.

SAMPLE

STABIL=XXX.X PPM

CO2 =X.XXX

SETUP

Wait until STABIL

falls below 1.0

ppb.

< TST TST > CAL CALZ CALS

ACTION:

Record the

CO2 readings

presented in the

upper right corner of

the display.

This may take

several minutes.

ZERO CAL M

STABIL=XXX.X PPM CO2 =X.XXX

CONC EXIT

< TST TST > ZERO

SAMPLE

STABIL=XXX.X PPM CO2 =X.XXX

ACTION:

Record the

CO2 readings

presented in the

upper right corner of

the display.

The value of STABIL

may jump

significantly. Wait

until STABIL falls

below 1.0 ppb. This

may take several

minutes.

< TST TST > CAL CALZ CALS

SETUP

SPAN CAL M

STABIL=XXX.X PPM

CO2 =X.XXX

EXIT

EXIT returns to the main

< TST TST > ZERO SPAN CONC

SAMPLE display

7.5.1. Zero/Span Calibration on Auto Range or Dual Ranges

If the analyzer is being operated in dual range mode or auto range mode, then the high and low

ranges must be independently calibrated.

When the analyzer is in either dual or auto range modes the user must run a separate calibration

procedure for each range. After pressing the CAL, CALZ or CALS keys the user is prompted for

the range that is to be calibrated as seen in the CALZ example below:

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Calibration Procedures

SAMPLE*

RANGE = 500.000 PPM

CO2 =XXX.X

SETUP

Set the Display to show the

STABIL test function.

This function calculates the

stability of the CO_x

<TST TST> CAL CALZ CALS

measurement

SAMPLE

STABIL=XXX.X PPM

CO2 =XXX.X

SETUP

< TST TST > CAL CALZ CALS

ACTION:

Allow zero gas to enter the sample port at the

rear of the instrument.

Wait until STABIL

falls below 1.0 ppb.

This may take several

minutes.

M-P CAL

STABIL=XXX.X PPM

CO2 =XXX.X

< TST TST > CAL CALZ CALS

SETUP

SAMPLE

RANGE TO CAL: LOW

ENTR

LOW HIGH

SETUP

SAMPLE

RANGE TO CAL: HIGH

ENTR

LOW HIGH

ANALYZER ENTERS

ZERO CAL MODE

ZERO CAL M

RANGE = 500.000 PPB SO2 =X.XXX

< TST TST > ZERO SPAN CONC

EXIT

Continue Calibration as per

Standard Procedure

Once this selection is made, the calibration procedure continues as previously described in Section

7.2. The other range may be calibrated by starting over from the main SAMPLE display.

7.5.2. Use of Zero/Span Valves with Remote Contact Closure

Contact closures for controlling calibration are located on the rear panel CONTROL IN connector.

Instructions for setup and use of these contacts are found in Section 6.11.1.2. When the contacts

are closed for at least 5 seconds, the instrument switches into zero or span mode. The remote

calibration contact closures may be activated in any order. It is recommended that contact

closures remain closed for at least 10 minutes to establish a reliable reading.

The instrument will stay in the selected mode for as long as the contacts remain closed. If

calibration is enabled, the MGFC7000E will re-calibrate when the contact is opened, then go into

SAMPLE mode. If calibration is disabled, the instrument will return to SAMPLE mode, leaving the

calibration unchanged.

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Calibration Procedures

7.6. Automatic Zero/Span Cal/Check (AutoCal)

The AutoCal system allows unattended periodic operation of the ZERO/SPAN valve options by

using the MGFC7000E’s internal time of day clock. AutoCal operates by executing SEQUENCES

programmed by the user to initiate the various calibration modes of the analyzer and open and

close valves appropriately. It is possible to program and run up to 3 separate sequences (SEQ1,

SEQ2 and SEQ3). Each sequence can operate in one of 3 Modes, or be disabled.

Table 7-1:

AUTOCAL Modes

MODE NAME

DISABLED

ZERO

ACTION

Disables the Sequence

Causes the Sequence to perform a zero calibration/check

ZERO-SPAN

Causes the Sequence to perform a zero and span

concentration calibration/check

SPAN

Causes the Sequence to perform a span concentration

calibration/check

For each mode there are seven parameters that control operational details of the SEQUENCE.

They are:

Table 7-2:

AutoCal ATTRIBUTE Setup Parameters

ATTRIBUTE NAME

TIMER ENABLED

STARTING DATE

STARTING TIME

DELTA DAYS

ACTION

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

Enable to do a calibration – Disable to do a cal check only

DELTA TIME

DURATION

CALIBRATE

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Calibration Procedures

The following example sets Sequence #2 to do a Zero-Span Calibration every other day starting

at 1 am on September 4, 2001, lasting 15 minutes, without calibration. This will start ½ hour later

each iteration.

MODE AND

ATTRIBUTE

VALUE

COMMENT

Define Sequence #2

Sequence

ZERO-SPAN

Mode

Select Zero and Span Mode

Enable the timer

Timer Enable

Starting Date

Starting Time

Delta Days

Delta Time

Duration

Sept. 4, 2001

01:00

Start after Sept 4, 2001

First Span starts at 1:00AM

Do Sequence #2 every other day

Do Sequence #2 ½ hr later each day

Operate Span valve for 15 min

Do not calibrate at end of Sequence

00:30

15.0

Calibrate

NOTE

The programmed STARTING_TIME must be a minimum of 5 minutes later than the real

time clock (See Section 6.6 for setting real time clock).

NOTE

Avoid setting two or more sequences at the same time of the day. Any new sequence

which is initiated whether from a timer, the COM ports, or the contact closure inputs

will override any sequence which is in progress.

NOTE

If at any time an illegal entry is selected (Example: Delta Days > 367) the ENTR key will

disappear from the display.

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Calibration Procedures

To program the Sequence:

SAMPLE*

RANGE = 500.000 PPM

CO2 =X.XXX

SETUP

SETUP X.X STARTING TIME:14:15

< TST TST > CAL CALZ CALS

<SET SET> EDIT

EXIT

SAMPLE

ENTER SETUP PASS : 818

SETUP X.X

DELTA DAYS: 1

ENTR EXIT

<SET SET> EDIT

Toggle keys

to set

SETUP X.X

PRIMARY SETUP MENU

number of

days

between

procedures

(1-367)

SETUP X.X DELTA DAYS: 1

CFG ACAL DAS RNGE PASS CLK MORE

EXIT

ENTR EXIT

SETUP X.X SEQ 1) DISABLED

SETUP X.X DELTA DAYS:2

NEXT MODE

EXIT

<SET SET> EDIT

EXIT

SETUP X.X SEQ 2) DISABLED

PREV NEXT MODE

EXIT

SETUP X.X DELTA TIME00:00

<SET SET> EDIT

EXIT

SETUP X.X MODE: DISABLED

Toggle keys

to set

delay time for

each iteration

of the

sequence:

HH:MM

ENTR EXIT

EXIT

SETUP X.X DELTA TIME: 00:00

ENTR EXIT

SETUP X.X MODE: ZERO

(0 – 24:00)

PREV NEXT

SETUP X.X DELTA TIEM:00:30

<SET SET> EDIT

EXIT

SETUP X.X MODE: ZERO–SPAN

PREV NEXT

SETUP X.X DURATION:15.0 MINUTES

Toggle keys

to set

duration for

each

iteration of

the

sequence:

Set in

<SET SET> EDIT

EXIT

ENTR EXIT

EXIT

SETUP X.X SEQ 2) ZERO–SPAN, 1:00:00

PREV NEXT MODE SET

SETUP X.X DURATION 15.0MINUTES

Default

value is

SETUP X.X TIMER ENABLE: ON

Decimal

minutes

from

SET> EDIT

EXIT

0.1 – 60.0

SETUP X.X DURATION:30.0 MINUTES

<SET SET> EDIT

SETUP X.X STARTING DATE: 01–JAN–02

<SET SET> EDIT

EXIT

Toggle keys

to set

day, month &

year:

SETUP X.X

CALIBRATE: OFF

SETUP X.X STARTING DATE: 01–JAN–02

<SET SET> EDIT

EXIT

ENTR EXIT

EXIT

SEP

ENTR EXIT

Format :

DD-MON-YY

Toggle key

between

Off and

SETUP X.X

CALIBRATE: OFF

SETUP X.X STARTING DATE: 04–SEP–03

<SET SET> EDIT

EXIT

SETUP X.X

CALIBRATE: ON

SETUP X.X STARTING DATE: 04–SEP–03

<SET SET> EDIT

EXIT

Toggle keys to

set time:

SETUP X.X SEQ 2) ZERO–SPAN, 2:00:30

EXIT returns

to the SETUP

SETUP X.X STARTING TIME:00:00

Format : HH:MM

PREV NEXT MODE SET

EXIT

<SET SET> EDIT

EXIT

This is a 24 hr

clock .

PM hours are

13 – 24.

Sequence

Delta Time

MODE

Delta Days

SETUP X.X STARTING TIME:00:00

Example

2:15 PM = 14:15

: 1

ENTR EXIT/

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Calibration Procedures

7.6.1. AutoCal with Auto or Dual Reporting Ranges Modes

Selected

SETUP C.4

<SET

RANGE TO CAL: LOW

EDIT

EXIT

SETUP C.4

RANGE TO CAL: LOW

RANGE TO CAL: HIGH

LOW HIGH

ENTR SETUP

SETUP C.4

<SET

EDIT

EXIT

SETUP C.4 SEQ 2) ZERO–SPAN, 2:00:30

EXIT returns to the

PRIMARY SETUP

PREV NEXT MODE SET

NOTE

In order to automatically calibrate both the HIGH and LOW ranges, you must set up a

separate sequence for each.

7.7. Calibration Quality

After completing one of the calibration procedures described above, it is important to evaluate the

analyzer’s calibration SLOPE and OFFSET parameters. These values describe the linear response

curve of the analyzer. The values for these terms, both individually and relative to each other,

indicate the quality of the calibration. To perform this quality evaluation, you will need to record

the values of both test functions (Section 6.2.1 or Appendix A-3), all of which are automatically

stored in the iDAS channel CALDAT for data analysis, documentation and archival.

Make sure that these parameters are within the limits listed in Table 7-3.

Table 7-3:

Calibration Data Quality Evaluation

FUNCTION

SLOPE

MINIMUM VALUE

OPTIMUM VALUE

1.000

MAXIMUM VALUE

0.700

1.300

0.500

OFFS

-0.500

0.000

These values should not be significantly different from the values recorded on the Teledyne

Instruments Final Test and Validation Data sheet that was shipped with your instrument. If

they are, refer to the troubleshooting Chapter 11.

User Notes

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EPA Protocol Calibration

8. EPA PROTOCOL CALIBRATION

At the writing of this manual there is no EPA requirements for the monitoring of CO₂or published

calibration protocols.

User Notes

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MAINTENANCE SCHEDULE & PROCEDURES

9. MAINTENANCE SCHEDULE & PROCEDURES

Predictive diagnostic functions including failure warnings and alarms built into the analyzer’s

firmware allow the user to determine when repairs are necessary without performing painstaking

preventative maintenance procedures. There are, however, a minimal number of simple

procedures that when performed regularly will ensure that the analyzer continues to operate

accurately and reliably over its the lifetime. Repairs and troubleshooting are covered in Chapter 11

of this manual.

9.1. Maintenance Schedule

Table 9-1 shows a typical maintenance schedule for the analyzer. Please note that in certain

environments (i.e. dusty, very high ambient pollutant levels) some maintenance procedures may

need to be performed more often than shown.

NOTE

A Span and Zero Calibration Check (see CAL CHECK REQ’D Column of Table 9-1) must be

performed following certain of the maintenance procedure listed below.

See Sections 7.3, 7.5 and 7.6 for instructions on performing checks.

CAUTION

Risk of electrical shock. Disconnect power before performing any of the

following operations that require entry into the interior of the analyzer.

NOTE

The operations outlined in this chapter are to be performed by qualified

maintenance personnel only.

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Table 9-1:

Cal

Check

Req’d.

GFC7000E Maintenance Schedule

Date Performed

Manual

Section

Item

Action

Freq

Particulate

Filter

Weekly or as

needed

Replace

Yes

Weekly or

after any

Maintenance

or Repair

Verify Test Record and

Functions

analyze

Pump

Diaphragm

Every 2

years

Replace

Yes

Perform

Flow Check

Every 6

Months

Check Flow

Annually or

after any

Maintenance

Perform

Leak Check

Verify Leak

Tight

Yes

or Repair

Pneumatic

lines

Examine

and clean

Yes if

cleaned

As needed

Only if

cover

Cleaning

Clean

remv’d

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Table 9-2:

GFC7000E Test Function Record

Date Recorded

Operating

Function

Mode*

ZERO CAL

STABILITY

ZERO CAL

CO2 MEAS

Zero CAL

MR RATIO

SPAN CAL

SAMPLE

PRES

SAMPLE After

Warn-up

PHT DRIVE

SLOPE

SPAN CAL

ZERO CAL

OFFSET

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9.2. Predicting Failures Using the Test Functions

The Test Functions can be used to predict failures by looking at how their values change over

time. Initially it may be useful to compare the state of these Test Functions to the values recorded

on the printed record of the final calibration performed on your instrument at the factory, p/n

04307. Table 9-3 can be used as a basis for taking action as these values change with time. The

internal data acquisition system (iDAS) is a convenient way to record and track these changes.

Use APIcom to download and review this data from a remote location.

Table 9-3:

Predictive uses for Test Functions

Function

Stability

Condition

Behavior

Interpretation

ƒ Pneumatic Leaks – instrument & sample

system

ƒ Detector deteriorating

ƒ Source Aging

ƒ Detector deteriorating

ƒ Optics getting dirty or contaminated

ƒ Source Aging

ƒ Detector deteriorating

ƒ Contaminated zero gas (H2O)

ƒ Source Aging

ƒ Detector deteriorating

ƒ GFC Wheel Leaking

ƒ Pneumatic Leaks

Zero Cal

Increasing

CO2 MEAS

Decreasing

Increasing

Zero Cal

Decreasing

Increasing

MR Ratio

ƒ Contaminated zero gas (CO₂)

ƒ Source Aging

ƒ Pneumatic Leaks – instrument & sample

system

Span Cal

Sample

ƒ Calibration system deteriorating

ƒ Source Aging

ƒ GFC Wheel Leaking

Decreasing

ƒ Calibration system deteriorating

ƒ Pneumatic Leak between sample inlet

and Sample Cell

ƒ Change in sampling manifold

ƒ Dirty particulate filter

ƒ Pneumatic obstruction between sample

inlet and Sample Cell

ƒ Obstruction in sampling manifold

ƒ Mechanical Connection between IR-

Detector and Sample Cell deteriorating

ƒ IR-Photodetector deteriorating

ƒ See MR Ratio - Zero Cal Decreasing

above

ƒ See MR Ratio - Zero Cal Increasing above

ƒ See MR Ratio - Span Cal Decreasing

above

Increasing > 1”

Pres

Decreasing > 1”

Increasing

Any, but with

Bench Temp

at 48°C

PHT Drive

Offset

Increasing

Decreasing

Increasing

Zero Cal

Slope

Span Cal

ƒ See MR Ratio – Span Cal Increasing

above

Decreasing

9.3. Maintenance Procedures

The following procedures are to be performed periodically as part of the standard maintenance of

the Model GFC7000E.

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9.3.1. Replacing the Sample Particulate Filter

The particulate filter should be inspected often for signs of plugging or contamination. We

recommend that when you change the filter, handle it and the wetted surfaces of the filter

housing as little as possible. Do not touch any part of the housing, filter element, PTFE retaining

ring, glass cover and the o-ring.

To change the filter:

1. Turn OFF the analyzer to prevent drawing debris into the instrument.

2. Open the MGFC7000E’s hinged front panel and unscrew the knurled retaining ring on the filter

assembly.

Figure 9-1:

Sample Particulate Filter Assembly

3. Carefully remove the retaining ring, PTFE o-ring, glass filter cover and filter element.

4. Replace the filter, being careful that the element is fully seated and centered in the bottom of

the holder.

5. Re-install the PTFE o-ring with the notches up, the glass cover, then screw on the retaining

ring and hand tighten. Inspect the seal between the edge of filter and the o-ring to assure a

proper seal.

6. Re-start the Analyzer.

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9.3.2. Rebuilding the Sample Pump

The diaphragm in the sample pump periodically wears out and must be replaced. A sample

rebuild kit is available – see Appendix B of this manual for the part number of the pump rebuild

kit. Instructions and diagrams are included with the kit.

Always perform a Flow and Leak Check after rebuilding the Sample Pump.

9.3.3. Performing Leak Checks

Leaks are the most common cause of analyzer malfunction; Section 9.3.3.1 presents a simple leak

check procedure. Section 9.3.3.2 details a more thorough procedure.

9.3.3.1. Vacuum Leak Check and Pump Check

This method is easy and fast. It detects, but does not locate most leaks, it also verifies that the

sample pump is in good condition.

1. Turn the analyzer ON, and allow enough time for flows to stabilize.

2. Cap the sample inlet port.

3. After several minutes, when the pressures have stabilized, note the following. In the TEST

menu, note the SAMPLE PRESSURE reading.

4. If the reading is < 10 in-Hg, the pump is in good condition and there are no large leaks.

5. If both readings are equal within 10%, the instrument is free of large leaks.

9.3.3.2. Pressure Leak Check

If you can’t locate the leak by the above procedure, use the following procedure. Obtain a leak

checker similar to the Teledyne Instruments part number 01960, which contains a small pump,

shut-off valve, and pressure gauge. Alternatively, a convenient source of low-pressure gas is a

tank of span gas, with the two-stage regulator adjusted to less than 15 psi with a shutoff valve

and pressure gauge.

CAUTION

Do not use bubble solution with vacuum applied to the analyzer. The

solution may contaminate the instrument. Do not exceed 15 PSIG

pressure.

1. Turn OFF power to the instrument.

2. Install a leak checker or tank of gas as described above on the sample inlet at the rear panel.

3. Remove the instrument cover and locate the inlet side of the sample pump. Remove the flow

assembly from the pump and plug it with the appropriate gas-tight fitting.

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4. Pressurize the instrument with the leak checker, allowing enough time to fully pressurize the

instrument through the critical flow orifice. Check each fitting with soap bubble solution,

looking for bubbles. Once the fittings have been wetted with soap solution, do not re-apply

vacuum, as it will suck soap solution into the instrument and contaminate it. Do not exceed

15 psi pressure.

5. If the instrument has one of the zero and span valve options, the normally closed ports on

each valve should also be separately checked. Connect the leak checker to the normally closed

ports and check with soap bubble solution.

6. Once the leak has been located and repaired, the leak-down rate should be < 1 in-Hg (0.4 psi)

in 5 minutes after the pressure is shut off.

9.3.4. Performing a Sample Flow Check

CAUTION

Always use a separate calibrated flow meter capable of measuring flows

in the 0 – 1000 cc/min range to measure the gas flow rate though the

analyzer.

DO NOT use the built in flow measurement viewable from the Front Panel

of the instrument. This measurement is only for detecting major flow

interruptions such as clogged or plugged gas lines.

See Figure 3-2 for sample port location.

1. Turn off power.

2. Attach the Flow Meter to the sample inlet port on the rear panel. Ensure that the inlet to the

Flow Meter is at atmospheric f.

3. Turn on instrument power.

4. Sample flow should be 800 cc/min ± 10%.

5. Once an accurate measurement has been recorded by the method described above, adjust the

analyzer’s internal flow sensors (see Section 6.9.8)

Low flows indicate blockage somewhere in the pneumatic pathway. High flows indicate leaks

downstream of the Flow Control Assembly.

9.3.5. Cleaning the Optical Bench

The MGFC7000E sensor assembly and optical bench is complex and delicate. Disassembly and

cleaning is not recommended. Please check with the factory before disassembling the optical

bench.

9.3.6. Cleaning Exterior Surfaces of the MGFC7000E

If necessary, the exterior surfaces of the MGFC7000E can be cleaned with a clean damp cloth. Do

not submerge any part of the instrument in water or cleaning solution.

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User Notes

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THEORY OF OPERATION

10. THEORY OF OPERATION

The Model GFC7000E Gas Filter Correlation Carbon Dioxide Analyzer is a microprocessor-

controlled analyzer that determines the concentration of carbon dioxide (CO₂) in a sample gas

drawn through the instrument. It requires that sample and calibration gasses be supplied at

ambient atmospheric pressure in order to establish a stable gas flow through the sample chamber

where the gases ability to absorb infrared radiation is measured.

Calibration of the instrument is performed in software and does not require physical adjustments

to the instrument. During calibration the microprocessor measures the current state of the IR

Sensor output and various other physical parameters of the instrument and stores them in

memory.

The microprocessor uses these calibration values, the ir absorption measurements made on the

sample gas along with data regarding the current temperature and pressure of the gas to

calculate a final co₂concentration.

This concentration value and the original information from which it was calculated are stored in

one of the unit’s internal data acquisition system (iDAS - see Sections 6.12) as well as reported to

the user via a vacuum florescent display or a variety of digital and analog signal outputs.

10.1. Measurement Method

10.1.1. Beer’s Law

The basic principle by which the analyzer works is called Beer’s Law. It defines the how light of a

specific wavelength is absorbed by a particular gas molecule over a certain distance. The

mathematical relationship between these three parameters is:

-αLc

I = I_oe

Where:

I_o

is the intensity of the light if there was no absorption.

is the intensity with absorption.

is the absorption path, or the distance the light travels as it is being absorbed.

is the concentration of the absorbing gas. In the case of the Model GFC7000E,

carbon dioxide (CO₂).

is the absorption coefficient that tells how well CO₂absorbs light at the specific

wavelength of interest.

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THEORY OF OPERATION

10.1.2. Measurement Fundamentals

In the most basic terms, the Model GFC7000E uses a high energy heated element to generate a

beam of broad-band IR light with a known intensity (measured during Instrument calibration.

This beam is directed through multi-pass cell filled with sample gas. The sample cell uses mirrors

at each end to reflect the IR beam back and forth through the sample gas to generate a 2.5 meter

absorption path (see Figure 10–1). This length was chosen to give the analyzer maximum

sensitivity to fluctuations in CO₂density.

Band-Pass

Filter

Sample Chamber

Source

Photo-Detector

IR Beam

Figure 10-1: Measurement Fundamentals

Upon exiting the sample cell, the beam shines through a band-pass filter that allows only light at

a wavelength of 4.3 µm to pass. Finally, the beam strikes a solid-state photo-detector that

converts the light signal into a modulated voltage signal representing the attenuated intensity of

the beam.

10.1.3. Gas Filter Correlation

Unfortunately, water vapor absorbs light at 4.3 µm too. To overcome the interfering effects of

water vapor the Model GFC7000E adds another component to the IR light path called a gas filter

correlation (GFC) wheel (see Figure 10-2).

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THEORY OF OPERATION

Measurement

Cell

(Pure N₂)

Reference Cell

(N₂with CO₂)

Figure 10-2: GFC Wheel

A GFC wheel is a metallic wheel into which two chambers are carved. The chambers are sealed on

both sides with material transparent to 4.3 µm IR radiation creating two airtight cavities. Each

cavity is filled with specially composed gases. One cell is filled with pure N₂(the measure cell)_.

The other is filled with a combination of N₂and a high concentration of CO₂(the reference cell).

IR unaffected by N₂in Measurement Cell

Δ H

IR IS affected by CO in Reference Cell

Source

Photo-Detector

GFC Wheel

Figure 10-3: Measurement Fundamentals with GFC Wheel

As the GFC wheel spins, the IR light alternately passes through the two cavities. When the beam

is exposed to the reference cell, the CO₂in the gas filter wheel strips the beam of most of the IR

at 4.3μm. When the light beam is exposed to the measurement cell, the N₂in the filter wheel

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does not absorb IR light. This results in a fluctuation in the intensity of the IR light striking the

photo-detector (See Figure 10-3) that results in the output of the detector resembling a square

wave.

The Model GFC7000E determines the amount of CO₂in the sample chamber by computing the

ratio between the peak of the measurement pulse (CO2 MEAS) and the peak of the reference

pulse (CO2 REF).

IR unaffected by N₂in Measurement

Cell of the GDC Wheel and no

additional CO₂in the Sample Chamber

CO2 MEAS

CO2 REF

IR affected by CO₂in Reference

Cell with no interfering gas in the

Sample Chamber

IR shinning through Measurement Cell

of the GDC Wheel is reduced by

additional CO₂in the Sample Chamber

M/R

is reduced

IR shining through Reference Cell

is also reduced by additional CO₂

in the Sample Chamber, but to a

lesser extent

Figure 10-4: Affect of CO₂in the Sample on CO2 MEAS & CO2 REF

If no gases exist in the sample chamber that absorb light at 4.3μm, the high concentration of CO₂

in the gas mixture of the reference cell will attenuate the intensity of the IR beam by 60% giving

a M/R ratio of approximately 2.4:1.

Adding CO₂to the sample chamber causes the peaks corresponding to both cells to be attenuated

by a further percentage. Since the intensity of the light passing through the measurement cell is

greater, the effect of this additional attenuation is greater. This causes CO2 MEAS to be more

sensitive to the presence of CO₂in the sample chamber than CO2 REF and the ratio between

them (M/R) to move closer to 1:1 as the concentration of CO₂in the sample chamber increases.

Once the Model GFC7000E has computed this ratio, a look-up table is used, with interpolation, to

linearize the response of the instrument. This linearized concentration value is combined with

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THEORY OF OPERATION

calibration SLOPE and OFFSET values to produce the CO₂concentration which is then normalized

for changes in sample pressure.

M/R

is Shifted

IR shining through both cells is

effected equally by interfering gas

in the Sample Chamber

Figure 10-5: Effects of Interfering Gas on CO2 MEAS & CO2 REF

If an interfering gas, such as H₂O vapor is introduced into the sample chamber, the spectrum of

the IR beam is changed in a way that is identical for both the reference and the measurement

cells, but without changing the ratio between the peak heights of CO₂MEAS and CO₂REF. In

effect, the difference between the peak heights remains the same.

Thus, the difference in the peak heights and the resulting M/R ratio is only due to CO₂and not to

interfering gases. In this way, Gas filter correlation rejects the effects of interfering gases and so

that the analyzer responds only to the presence of CO₂.

To improve the signal-to-noise performance of the IR photo-detector, the GFC wheel also

incorporates an optical mask that chops the IR beam into alternating pulses of light and dark at

six times the frequency of the measure/reference signal. This limits the detection bandwidth

helping to reject interfering signals from outside this bandwidth improving the signal to noise

ration.

The IR Signal as the Photo-Detector

sees it after being chopped by the GFC

Wheel Screen

CO MEAS

CO REF

Figure 10-6: Chopped IR Signal

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10.1.4. Ambient CO₂Interference Rejection

CO₂absorbs IR light very well. So well that even the narrow volume of ambient air between the

IR source and the sample chamber is enough to alter the analyzer’s measured concentration of

CO₂. Also, ambient air, which averages around 350 ppm to 400 ppm, will vary significantly over

the course of the day. The ambient CO₂concentration can rise as high as 1 000 ppm during the

time of the day when people are present. It can fluctuate ± 300 ppm as the photosynthesis of

plant life in the nearby area increases during the day and decreases at night.

The basic design of the GFC7000E rejects most of this interference at a 100:1 ratio, however this

still can allow small fluctuations in CO₂concentration during the course of the day. To completely

remove all effects of ambient CO₂from the analyzer’s measurement of CO₂, dried air, scrubbed of

all CO₂is pumped into the GFC wheel housing to purge all ambient CO₂(see Figure 10-7)

10.2. Pneumatic Operation

Caution

It is important that the sample airflow system is both leak tight and

not pressurized over ambient pressure.

Regular leak checks should be performed on the analyzer as described

in the maintenance schedule, Table 9-1.

Procedures for correctly performing leak checks can be found in

Section 9.3.3.

An internal pump evacuates the sample chamber creating a small vacuum that draws sample gas

into the analyzer. Normally the analyzer is operated with its inlet near ambient pressure either

because the sample is directly drawn at the inlet or a small vent is installed at the inlet. There are

several advantages to this “pull through” configuration.

•

By placing the pump down stream from the sample chamber several problems are avoided.

First the pumping process heats and compresses the sample air complicating the

measurement process.

•

Additionally, certain physical parts of the pump itself are made of materials that might

chemically react with the sample gas.

Finally, in certain applications where the concentration of the target gas might be high

enough to be hazardous, maintaining a negative gas pressure relative to ambient means

that should a minor leak occur, no sample gas will be pumped into the atmosphere

surrounding analyzer.

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10.2.1. Sample Gas Flow

INSTRUMENT CHASSIS

SAMPLE GAS

INLET

PUMP

GFC Wheel

Motor

Purge Gas

EXHAUST GAS

OUTLET

Flow Rate

Control

Orifice

GFC Motor

Heat Sync

Purge Gas

Pressure

Control Assy

GFC Wheel

Housing

PURGE GAS

INLET

FLOW / PRESSURE

SENSOR PCA

SAMPLE

PRESSURE

SENSOR

SAMPLE CHAMBER

FLOW

SENSOR

VENT SPAN

OUTLET

PRESSURE

SPAN INLET

PARTICULATE

FILTER

IZS INLET

Figure 10-7: Internal Pneumatic Flow – Basic Configuration

10.2.1.1. Critical Flow Orifice

The most important component of this flow control assembly is the critical flow orifice.

Critical flow orifices are a remarkably simple way to regulate stable gas flow rates. They operate

without moving parts by taking advantage of the laws of fluid dynamics. By restricting the flow of

gas though the orifice, a pressure differential is created. This pressure differential combined with

the action of the analyzer’s external pump draws the gas through the orifice.

As the pressure on the downstream side of the orifice (the pump side) continues to drop, the

speed that the gas flows though the orifice continues to rise. Once the ratio of upstream pressure

to downstream pressure is greater than 2:1, the velocity of the gas through the orifice reaches

the speed of sound. As long as that ratio stays at least 2:1 the gas flow rate is unaffected by any

fluctuations, surges, or changes in downstream pressure because such variations only travel at

the speed of sound themselves and are therefore cancelled out by the sonic shockwave at the

downstream exit of the critical flow orifice.

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CRITICAL

FLOW

ORIFICE

AREA OF

LOW

AREA OF

HIGH

PRESSURE

Sonic

Shockwave

O-RINGS

SPRING

FILTER

Figure 10-8: Flow Control Assembly & Critical Flow Orifice

The actual flow rate of gas through the orifice (volume of gas per unit of time), depends on the

size and shape of the aperture in the orifice. The larger the hole, the more gas molecules, moving

at the speed of sound, pass through the orifice. Also, because the flow rate of gas through the

orifice is only related to the minimum 2:1 pressure differential and not absolute pressure:

•

Pressure wave created by the pump’s action are filtered out.

The flow rate of gas through the sample chamber will be the same regardless of whether

the analyzer is at the bottom of Death Valley or on top of Pikes Peak.

•

The flow rate of the gas is also unaffected by degradations in pump efficiency due to age.

The critical flow orifice used in the Model GFC7000E is designed to provide a flow rate of 800

cm³/min.

10.2.1.2. Sample Pressure Sensor

An absolute value pressure transducer plumbed to the outlet of the sample chamber is used to

measure sample pressure. The output of the sensor is used to compensate the concentration

measurement for changes in air pressure. This sensor is mounted to a printed circuit board with

the sample flow sensor on the sample chamber; see following section and Figure 3-11.

10.2.1.3. Sample Flow Sensor

A thermal-mass flow sensor is used to measure the sample flow through the analyzer. The sensor

is calibrated at the factory with ambient air or N₂, but can calibrated to operate with samples

consisting of other gases such as CO₂, see Section 9.3.4. This sensor is mounted to a printed

circuit board with the Sample Pressure sensor on the sample chamber; see previous section and

Figure 3-11.

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Particulate Filter

The Model GFC7000E Analyzer comes equipped with a 47 mm diameter, Teflon, particulate filter

with a 5 micron pore size. The filter is accessible through the front panel, which folds down to

allow access, and should be changed according to the suggested maintenance schedule described

in Table 9-1.

10.2.1.4. Valve Options

A variety of optional valve sets can be purchased for the analyzer which allow the user to more

easily supply and manipulate various calibration gases, such as zero air and span gas during

various calibration procedures. For more information of these options see Section 5.4.

10.2.2. Purge Gas Pressure and Flow Control

In order to ensure that all of the ambient CO₂is purged from the GFC Wheel housing a adequate

supply of dried air, scrubbed of CO₂must be supplied to the PURGE AIR inlet at the back of the

instrument. The source of purge air must be capable of maintaining a pressure of 20-25 psig at a

flow rate of at least 0.5 liters/min. Purge source air pressure should not exceed 35 pisg.

In order to maintain the proper pressure differential between the inside of the GFC wheel housing

and ambient air, the M360 design includes a manually settable pressure regulator that maintains

the pressure of the purge air feed at 7.5 psig and a flow control orifice that ensures a 0.5 liter/min

flow though the GFC wheel housing.

10.3. Electronic Operation

10.3.1. Overview

Figure 10-9 shows a block diagram of the major electronic components of the Model GFC7000E.

At its heart the analyzer is a microcomputer (CPU) that controls various internal processes,

interprets data, makes calculations, and reports results using specialized firmware developed by

Teledyne Instruments. It communicates with the user as well as receives data from and issues

commands to a variety of peripheral devices via a separate printed circuit assembly called the

Mother Board.

The mother board collects data, performs signal conditioning duties and routs incoming and

outgoing signals between the cpu and the analyzer’s other major components.

Data is generated by a gas-filter-correlation optical bench which outputs an analog signal

corresponding to the concentration of CO₂in the sample gas. This analog signal is transformed

into two, pre-amplified, DC voltages (CO2 MEAS and CO2 REF) by a synchronous demodulator

printed circuit assembly. CO2 MEAS and CO2 REF are converted into digital data by a unipolar,

analog-to-digital converter, located on the mother board.

A variety of sensors report the physical and operational status of the analyzer’s major

components, again through the signal processing capabilities of the mother board. These status

reports are used as data for the CO₂concentration calculation and as trigger events for certain

control commands issued by the CPU. They are stored in memory by the CPU and in most cases

can be viewed but the user via the front panel display.

The CPU communicates with the user and the outside world in a variety of manners:

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•

Through the analyzer’s keyboard and vacuum florescent display over a clocked, digital,

serial I/O bus (using a protocol called I2C);

RS 232 & RS485 Serial I/O channels;

•

Via an optional Ethernet communications card:

Various DCV and DCA analog outputs, and

Several sets of Digital I/O channels.

Finally, the CPU issues commands via a series of relays and switches (also over the I²C bus)

located on a separate printed circuit assembly to control the function of key electromechanical

devices such as heaters, motors and valves.

Back Panel

Connectors

Analog Outputs

Optional

4-20 mA

Control Inputs:

1 – 8

COM-A COM-B

Optional

Ethernet

Interface

Status Outputs:

1 – 8

Analog

Outputs

(D/A)

External

Digital I/O)

PC 104

CPU Card

A/D

Converter

(V/F)

RS–232

or RS-485

Power-Up

Circuit

Disk On

Chip

RS – 232

MOTHER

BOARD

Flash Chip

Box

Temp

PC 104 Bus

Zero/Span

Valve

Options

PUMP

Thermistor

Interface

I²C

Bus

Internal

Digital I/O

Sensor Inputs

SAMPLE

TEMP

O₂

RELAY

BOARD

Sample

Flow &

Pressure

Keyboard &

Display

CPU Status

Sensors

LED

BENCH

TEMP

Sensor

Status

TEC Control

Source

Control

PHT

WHEEL

TEMP

Photo-

detector

SYNC

DEMOD

Drive

Detector

Output

GFC

Motor

GFC

Wheel

Optical

Bench

Schmidt

Trigger

Wheel

Heater

Segment Sensor

Bench Heater

M / R Sensor

Figure 10-9: GFC7000E Electronic Block Diagram

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10.3.2. CPU

The Model GFC7000E’s CPU is a, low power (5 VDC, 0.8A max), high performance, 386-based

microcomputer running MS-DOS. Its operation and assembly conform to the PC/104 Specification

version 2.3 for embedded PC and PC/AT applications. It has 2 MB of DRAM on board and operates

at 40MHz over an internal 32-bit data and address bus. Chip to chip data handling is performed

by two 4-channel DMA devices over data busses of either 8-bit or 16-bit configuration. The CPU

supports both RS-232 and RS-485 serial I/O.

The CPU includes two types of non-volatile data storage.

Disk On Chip

While technically an EEPROM, the Disk –on-Chip (DOC), this device appears to the CPU as,

behaves as, and performs the same function in the system as an 8MB disk drive. It is used to

store the operating system for the computer, the Teledyne Instruments Firmware, and most of

the operational data generated by the analyzer’s internal data acquisition system (iDAS - see

Section 6.12).

Flash Chip

Another, smaller EEPROM used to store critical calibration and configuration data. Segregating

this data on a separate, less heavily accessed chip significantly decreases the chance of this key

data being corrupted.

10.3.3. Optical Bench & GFC Wheel

Electronically, the Model GFC7000E’s optical bench, GFC wheel and associated components do

more than simply measure the amount of CO₂present in the sample chamber. A variety of other

critical functions are performed here as well.

10.3.3.1. Sample Gas and GFC Temperature Control

Because the temperature of a gas affects its density and therefore the amount of light absorbed

by that gas it is important to reduce the effect of fluctuations in ambient temperature on the

Model GFC7000E’s measurement of CO₂. To accomplish this both the temperature of the sample

chamber and the GFC Wheel are maintained at constant temperatures above their normal

operating ranges.

Bench Temperature : To minimize the effects of ambient temperature variations on the sample

measurement, the sample chamber is heated to 48°C (8 degrees above the maximum suggested

ambient operating temperature for the analyzer). A strip heater attached to the underside of the

chamber housing is the heat source. The temperature of the sample chamber is sensed by a

thermistor, also attached to the sample chamber housing.

Wheel Temperature: To minimize the effects of temperature variations caused by the near

proximity of the IR Source to the GFC wheel on the gases contained in the wheel, it is also raised

to a high temperature level. Because the IR Source itself is very hot, the set point for this heat

circuit is 68°C. A cartridge heater is implanted into the heat sync on the motor is the heat source.

The temperature of the wheel/motor assembly is sensed by a thermistor also inserted into the

heat sync.

Both heaters operate off of the AC line voltage supplied to the instrument.

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10.3.3.2. IR Source

The light used to detect CO₂in the sample chamber is generated by a element heated to

approximately 1100^oC producing infrared radiation across a broad band. This radiation is optically

filtered after it has passed through the GFC Wheel and the sample chamber and just before it

reaches the photo-detector to eliminate all black body radiation and other extraneous IR emitted

by the various components of those components.

10.3.3.3. GFC Wheel

A synchronous AC motor turns the GFC wheel motor. For analyzers operating on 60Hz line power

this motor turns at 1800 rpm. For those operating on 50Hz line power the spin rate is 1500 rpm.

The actual spin rate is unimportant within a large rate since a phase lock loop circuit is used to

generate timing pulses for signal processing.

In order to accurately interpret the fluctuations of the IR beam after it has passed through the

sample gas, the GFC wheel several other timing signals are produced by other photo

emitters/detectors. These devices consist of a combination LED and detector mounted so that the

light emitted by the LED shines through the same mask on the GFC wheel that chops the IR

beam.

KEY:

Detection Beam shining

through MEASUREMENT

side of GFC Wheel

Detection Beam shining

through REFERENCE

side of GFC Wheel

IR Detection Ring

Segment Sensor Ring

M/R Sensor Ring

Figure 10-10: GFC Light Mask

M/R Sensor

The emitter/detector assembly that produces this signal shines through a portion of the mask that

allows light to pass for half of a full revolution of the wheel. The resulting light signal tells the

analyzer whether the IR beam is shining through the measurement or the reference side of the

GFC wheel.

Segment Sensor

This emitter/detector shines through a portion of the mask that is divided into the same number

of segments as the portion of the mask through which the IR beam passes. It is used by the

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synchronous / demodulation circuitry of the analyzer to latch onto the most stable part of each

measurement and reference IR pulse.

Measurement

Pulses

Reference

Pulses

IR Beam

Pulses

Segment Sensor

Pulses

MR Sensor

Pulses

Figure 10-11: Segment Sensor and M/R Sensor Output

Schmidt Triggers

To ensure that the waveforms produced by the Segment Sensor and the M/R Sensor are properly

shaped and clean, these signals are passed through a set of Schmidt Triggers circuits.

10.3.3.4. IR Photo-Detector

The IR beam is converted into an electrical signal by a cooled solid-state photo-conductive

detector The detector is composed of a narrow-band optical filter, a piece of lead-salt crystal

whose electrical resistance changes with temperature, and a two-stage thermo-electric cooler.

When the analyzer is on, a constant electrical current is directed through the detector, The IR

beam is focused onto the detector surface, raising its temperature and lowering its electrical

resistance that results in a change in the voltage drop across the detector.

During those times that the IR beam is bright, the temperature of the detector is high; the

resistance of the detector is correspondingly low and the its output voltage output is low. During

those times when the IR beam intensity is low or completely blocked by the GFC Wheel mask, the

temperature of the detector is lowered by the two-stage thermo-electric cooler, increasing the

detectors resistance and raising the output voltage.

10.3.4. Synchronous Demodulator (Sync/Demod) Assembly

10.3.4.1. Overview

While the photo-detector converts fluctuations of the IR beam into electronic signals, the Sync /

Demod Board amplifies these signals and converts them into usable information. Initially the

output by the photo-detector is a complex and continuously changing waveform made up of

Measure and Reference pulses. The sync/demod board demodulates this waveform and outputs

two analog DC voltage signals, corresponding to the peak values of these pulses. CO2 MEAS and

CO2 REF are converted into digital signals by circuitry on the Motherboard then used by the CPU

to calculate the CO₂concentration of the sample gas.

Additionally the synch/demod board contains circuitry that controls the photo-detector’s

thermoelectric cooler as well as circuitry for performing certain diagnostic tests on the analyzer.

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56V

Bias

CO₂MEAS

Variable

Gain Amp

Dark

Switch

Sample

Pre

Amp

Photo-

detector

Signal

Conditioner

Hold

Circuits

TEC Control

PHT DRIVE

E-Test

Generator

CO₂Reference

Signal

Amplifiers

Conditioner

(x4)

Thermo-Electric

Cooler

Control Circuit

E Test A Gate

E Test B Gate

Dark Test Gate

Measure Gate

Compact

Measure Dark Gate

Reference Gate

Programmable

Logic Device

Reference Dark Gate

Phase Lock Warning

M/R Sensor

From GFC

Wheel

Segment

Sensor

Segment Clock

X1 Reference

E Test Control

Phase

Lock

Loop

x10

From CPU

via Mother

Board

÷10

Dark Switch

Control

X10 Clock

M/R

Segment

Status LED

Phase Lock

Figure 10-12: GFC7000E Sync / Demod Block Diagram

10.3.4.2. Signal Synchronization and Demodulation

The signal emitted by the IR photo-detector goes through several stages of amplification before it

can be accurately demodulated. The first is a pre-amplification stage that raises the signal to

levels readable by the rest of the synch/demod board circuitry. The second is a variable

amplification stage that is adjusted at the factory to compensate for performance variations of

mirrors, detectors, and other components of the optical bench from instrument to instrument.

The workhorses of the sync/demod board are the four sample-and-hold circuits that capture

various voltage levels found in the amplified detector signal needed to determine the value of CO2

MEAS and CO2 REF. They are activated by logic signals under the control of a compact

programmable logic device (PLD), which in turn responds to the output of the Segment Sensor

and M/R Sensor described in Figure 10–11.

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The four sample and hold circuits are:

DESIGNATION

ACTIVE WHEN:

IR BEAM PASSING THROUGH

SEGMENT SENSOR PULSE IS:

Measure Gate

Measure Dark Gate

Reference Gate

MEASUREMENT cell of GFC Wheel

MEASUREMENT Cell of GFC Wheel

REFERENCE cell of GFC Wheel

HIGH

LOW

HIGH

LOW

Reference Dark Gate

Timing for activating the Sample and Hold circuits is provided by a phase lock loop circuit (PLL).

Using the segment sensor output as a reference signal the PLL generates clock signal at ten times

that frequency. This faster clock signal is used by the PLD to make the sample and hold circuits

capture the signal during the center portions of the detected waveform, ignore the rising and

falling edges of the detector signal.

Sample & Hold

Active

Detector

Output

Sample & Hold

Inactive

Figure 10-13: Sample & Hold Timing

10.3.4.3. Phase Lock Warning

In order to detect critical fault conditions such as a failure of either the segment sensor or the GFC

wheel motor, the synch/demod board also performs a simple check of the above signal

synchronization to make sure everything is operation. The PLD divides the X10 clock signal by ten

and sends this signal back to the PLL circuit which compares it to the original segment sensor

reference signal.

If these two signals match, the PLL sends a status level to the PLD that the phase lock is OK. If

for some reason the two signals do not match, the PLL alerts the PLD that phase lock has been

lost and the PLD issues a phase lock warning to the CPU. Should this occur, A SYNC warning will

appear on the analyzer’s front panel display (see Section 11.1.1 for more information).

10.3.4.4. Sync/Demod Status LED’s

The following two status LED’s located on the synch/demod board provide additional diagnostic

tools for checking the GFC wheel rotation.

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Table 10-1: Sync/Demod Status LED Activity

LED

FUNCTION

STATUS OK

FAULT STATUS

M/R Sensor Status

LED flashes approximately

2/second

LED is stuck

ON or OFF

Segment Sensor

Status

LED flashes approximately

6/second

LED is stuck

ON or OFF

See Section 11.1.4 for more information.

10.3.4.5. Photo-Detector Temperature Control

The synch/demod board also contains circuitry that controls the IR photo-detector’s thermoelectric

coolers. A drive voltage, PHT DRIVE, is supplied to the coolers by the synch/demod board which

is adjusted by the synch/demod board based on a return signal called TEC control which alerts

informs the synch/demod board of the detector’s temperature. The warmer the detector, the

harder the coolers are driven.

PHT DRIVE is one of the Test Functions viewable by the user via the form panel. Press <TST or

TST> until it appears on the display.

10.3.4.6. Dark Calibration Switch

This switch initiates the Dark Calibration procedure. When initiated by the user (see Section 6.9.6

for more details), the dark calibration process opens this switch, interrupting the signal from the

IR photo-detector. This allows the analyzer to measure any offset caused by the synch/demod

board circuitry.

10.3.4.7. Electric Test Switch

When active this circuit generates a specific waveform intended to simulate the function of the IR

photo-detector but with a known set of value which is substituted for the detector’s actual signal

via the dark switch. It may also be initiated by the user (see Section 6.9.5 for more details).

10.3.5. Relay Board

By actuating various switches and relays located on this board, the CPU controls the status of

other key components. The relay board receives instructions in the form of digital signals over

the I²C bus, interprets these digital instructions and activates its various switches and relays

appropriately.

Heater Control

The two heaters attached to the sample chamber housing and the GFC wheel motor are controlled

by solid state relays located on the relay board.

The GFC wheel heater is simply turned on or off, however control of the bench heater also

includes circuitry that selects which one of its two separate heating elements is activated

depending on whether the instrument is running on 100 VAC, 115 VAC or 230 VAC line power.

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GFC Wheel Motor Control:

The GFC wheel operates from a AC voltage supplied by a multi-input transformer located on the

relay board. The step-down ratio of this transformer is controlled by factory-installed jumpers to

adjust for 100 VAC, 115 VAC or 230 VAC line power. Other circuitry slightly alters the phase of the

AC power supplied to the motor during start up based on whether line power is 50Hz or 60 Hz.

Normally, the GFC Wheel Motor is always turning while the analyzer is on. A physical switch

located on the relay board can be used to turn the motor off for certain diagnostic procedures.

Zero/Span Valve Options

Any zero/span/shutoff valve options installed in the analyzer are controlled by a set of electronic

switches located on the relay board. These switches, under CPU control, supply the +12VDC

needed to activate each valve’s solenoid.

IR Source

The Relay board supplies a constant 11.5VDC to the IR Source. Under normal operation the IR

source is always on.

10.3.5.1. Status LED’s

Eight LED’s are located on the analyzer’s relay board to show the current status on the various

control functions performed by the relay board (see Figure 10-14). They are:

Table 10-2: Relay Board Status LED’s

LED

COLOR

FUNCTION

STATUS WHEN LIT

STATUS WHEN UNLIT

RED

Watchdog Circuit Cycles On/Off Every 3 Seconds under direct control of the

analyzer’s CPU.

YELLOW

GREEN

Wheel Heater

Bench Heater

Spare

HEATING

N/A

NOT HEATING

N/A

Sample/Cal Gas

Valve Option

Valve Open to CAL GAS

FLOW

Valve Open to SAMPLE GAS

FLOW

GREEN

Zero/Span Gas

Valve Option

Valve Open to SPAN GAS

FLOW

Valve Open to ZERO GAS

FLOW

Shutoff Valve

Option

Valve Open to CAL GAS

FLOW

Valve CLOSED to CAL GAS

FLOW

IR SOURCE

Source ON

Source OFF

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DC VOLTAGE TEST

POINTS

STATUS LED’s

RELAY PCA

PN 04135

Figure 10-14: Location of relay board Status LED’s

10.3.5.2. I²C Watch Dog Circuitry

Special circuitry on the relay board monitors the activity on the I²C bus and drives LED D1.

Should this LED ever stay ON or OFF for 30 seconds, the watchdog circuit will automatically shut

of all valves as well as turn off the IR Source and all heaters. The GFC wheel motor will still be

running as will the Sample Pump, which is not controlled by the relay board.

10.3.6. Mother Board

This printed circuit assembly provides a multitude of functions including, A/D conversion, digital

input/output, PC-104 to I2C translation, temperature sensor signal processing and is a pass

through for the RS-232 and RS-485 signals.

10.3.6.1. A to D Conversion

Analog signals, such as the voltages received from the analyzer’s various sensors, are converted

into digital signals that the CPU can understand and manipulate by the analog to digital converter

(A/D). Under the control of the CPU, this functional block selects a particular signal input (e.g.

BOX TEMP, CO2 MEAS, CO2 REF, etc.) and then coverts the selected voltage into a digital word.

The A/D consists of a voltage-to-frequency (V-F) converter, a programmable logic device (PLD),

three multiplexers, several amplifiers and some other associated devices. The V-F converter

produces a frequency proportional to its input voltage. The PLD counts the output of the V-F

during a specified time period, and sends the result of that count, in the form of a binary number,

to the CPU.

The A/D can be configured for several different input modes and ranges but in the MGFC7000E is

used in uni-polar mode with a +5 V full scale. The converter includes a 1% over and under-

range. This allows signals from –0.05 V to +5.05 V to be fully converted.

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For calibration purposes, two reference voltages are supplied to the A/D converter: Reference

Ground and +4.096 VDC. During calibration, the device measures these two voltages, outputs

their digital equivalent to the CPU. The CPU uses these values to compute the converter’s offset

and slope and uses these factors for subsequent conversions.

See Section 6.9.4 for instructions on performing this calibration.

10.3.6.2. Sensor Inputs

The key analog sensor signals are coupled to the A/D through the master multiplexer from two

connectors on the motherboard. 100K terminating resistors on each of the inputs prevent cross

talk from appearing on the sensor signals.

Co₂Measure And Reference

These are the primary signals that are used in the computation of the CO₂concentration. They

are the demodulated IR-sensor signals from the sync demodulator board.

Sample Pressure And Flow

These are analog signals from two sensors that measure the pressure and flow rate of the gas

stream at the outlet of the sample chamber. This information is used in two ways. First, the

sample pressure is used by the CPU to calculate CO₂Concentration. Second, the pressure and

flow rate are monitored as a test function to assist the user in predicting and troubleshooting

failures.

10.3.6.3. Thermistor Interface

This circuit provides excitation, termination and signal selection for several negative-coefficient,

thermistor temperature sensors located inside the analyzer. They are:

Sample Temperature Sensor

The source of this signal is a thermistor located inside the sample chamber of the Optical Bench.

It measures the temperature of the sample gas in the chamber. This data is used to during the

calculation of the CO₂concentration value.

Bench Temperature Sensor

This thermistor, attached to the sample chamber housing, reports the current temperature of the

chamber housing to the CPU as part of the bench heater control loop.

Wheel Temperature Sensor

This thermistor attached a the heat-sync on the GFC wheel motor assembly reports the current

temperature of the wheel/motor assembly to the cpu as part of the Wheel Heater control loop.

Box Temperature Sensor

A thermistor is attached to the mother board. It measures the analyzer’s inside temperature.

This information is stored by the CPU and can be viewed by the user for troubleshooting purposes

via the front panel display (see Section 11.1.2).

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10.3.6.4. Analog Outputs

The analyzer comes equipped with four analog outputs: A1, A2, A3 and a fourth that is a spare.

A2 and A1 Output

The first two, A2 and A1 are normally set up to operate in parallel so that the same data can be

sent to two different recording devices. While the names imply that one should be used for

sending data to a chart recorder and the other for interfacing with a datalogger, either can be

used for both applications.

Both of these channels output a signal that is proportional to the CO₂concentration of the sample

gas. The A1 and A2 outputs can be slaved together or set up to operated independently. A variety

of scaling factors are available, See Section 6.9.4 for information on setting the range type and

scaling factors for these output channels.

A3 Output

The third analog output, labeled A3 is special. It can be set by the user (see Section 6.9.9) to

carry the current signal level of any one of the parameters accessible through the A3 menu of the

unit’s software.

Spare Output

The fourth analog output, termed SPARE is not used in the MGFC7000E.

In its standard configuration, the analyzer comes with all four of these channels set up to output a

DC voltage. However, 4-20mA current loop drivers can be purchased for the first three of these

outputs: A2, A2 & A3.

Output Loop-back

All four analog outputs are connected back to the A/D converter through a Loop-back circuit. This

permits the voltage outputs to be calibrated by the CPU without need for any additional tools or

fixtures.

10.3.6.5. Internal Digital I/O

This channel is used to communicate digital status and control signals about the operation of key

components of the Optical Bench. The CPU sends signals to the synch/demod board that initiate

the ELECTRICAL TEST and DARK CALIBRATION procedures. Likewise, the synch/demod board

uses this interface to send the SYNC warning signal to the CPU (see Sections 6.9.5, 6.9.6 and

11.1.1).

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10.3.6.6. External Digital I/O

This External Digital I/O performs two functions.

Status Outputs

Logic-Level voltages are output through an optically isolated 8-pin connector located on the rear

panel of the analyzer. These outputs convey good/bad and on/off information about certain

analyzer conditions. They can be used to interface with certain types of programmable devices

(see Section 6.13.1.1).

Control Inputs

By applying +5VDC power supplied from an external source such as a PLC or Datalogger (see

Section 6.13.1.2), Zero and Span calibrations can be initiated by contact closures on the rear

panel.

10.3.7. I²C Data Bus

An I²C data bus is used to communicate data and commands between the cpu and the

keyboard/display interface and the relay board. I²C is a two-wire, clocked, digital serial i/o bus

that is used widely in commercial and consumer electronic systems. A transceiver on the

motherboard converts data and control signals from the PC-104 bus to I²C. The data is then fed

to the keyboard/display interface and finally onto the relay board.

Interface circuits on the keyboard/display interface and relay boards convert the i²c data to

parallel inputs and outputs. An additional, interrupt line from the keyboard to the motherboard

allows the CPU to recognize and service key presses on the keyboard.

Power up Circuit

This circuit monitors the +5V power supply during start-up and sets the Analog outputs, external

digital I/O ports, and I²C circuitry to specific values until the CPU boots and the instrument

software can establish control.

10.3.8. Power Supply/ Circuit Breaker

The analyzer operates on 100 VAC, 115 VAC or 230 VAC power at either 50Hz or 60Hz. Individual

units are set up at the factory to accept any combination of these five attributes. As illustrated in

Figure 10-15, power enters the analyzer through a standard IEC 320 power receptacle located on

the rear panel of the instrument. From there it is routed through the On/Off switch located in the

lower right corner of the Front Panel. A 6.75 Amp circuit breaker is built into the ON/OFF Switch.

AC power is distributed directly to the sample gas pump. The bench and GFC wheel heaters as

well as the GFC wheel receive AC power via the relay board.

AC Line power is converted stepped down and converted to DC power by two DC power supplies.

One supplies +12 VDC, for valves and the IR source, while a second supply provides +5 VDC and

±15 VDC for logic and analog circuitry. All DC voltages are distributed via the relay board.

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CAUTION

Should the AC power circuit breaker trip, investigate and correct the

condition causing this situation before turning the analyzer back on.

ON/OFF

SWITCH

AC POWER

Pressure

Sensors

ENTRANCE

Display

Keypad

CPU

PS 1 (+5 VDC; ±15 VDC)

RELAY

BOARD

KEY

AC POWER

DC POWER

Mother

Board

PS 2 (+12 VDC)

Sync/Demod

IR Source

Cooling Fan

Pump

M/R &

Segment

Sensors

GFC

Wheel

Motor

Valve

Options

Heaters

Figure 10-15: Power Distribution Block Diagram

10.4. Interface

The analyzer has several ways to communicate the outside world, see Figure 10-16. Users can

input data and receive information directly via the Front panel keypad and display. Direct

communication with the CPU is also available by way of the analyzer’s RS232 & RS485 I/O ports

or an optional Ethernet port. The analyzer can also send and receive different kinds of information

via its external digital I/O connectors and the three analog outputs located on the rear panel.

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COMM A

Male

RS–232 ONLY

RS-232 or RS–485

COMM B

Female

CPU

Mother

Board

Control Inputs:

ETHERNET

OPTION

1 – 6

Status Outputs:

1 – 8

PC/104 BUS

Analog Outputs

KEYBOARD

Optional

4-20 mA

I²C BUS

A4ST

FRONT PANEL DISPLAY

RELAY

BOARD

Figure 10-16: Interface Block Diagram

10.4.1. Front Panel Interface

MODE FIELD MESSAGE FIELD

CONCENTRATION FIELD STATUS LED’s

LOCKING SCREW

FASTENER

SAMPLE

CAL

CO2 = 400.0

SETUP

RANGE = 500.0 PPM

SAMPLE A

<TST TST> CAL

FAULT

POWER

GAS FILTER CORRELATION CO₂ANALYZER- MODEL GFC7000E

KEY DEFINITIONS KEYBOARD

ON / OFF SWITCH

Figure 10-17: GFC7000E Front Panel Layout

The most commonly used method for communicating with the MGFC7000E Analyzer is via the

instrument’s front panel which includes a set of three status LEDs, a vacuum florescent display

and a keyboard with 8 context sensitive keys.

10.4.1.1. Analyzer Status LED’s

Three LEDS are used to inform the user of the instruments basic operating status

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Table 10-3: Front Panel Status LED’s

NAME

COLOR STATE

DEFINITION

SAMPLE

Green

Off

Unit is not operating in sample mode, iDAS is disabled.

Sample Mode active; Front Panel Display being updated, iDAS data being stored.

Unit is operating in sample mode, front panel display being updated, iDAS hold-off

mode is ON, iDAS disabled

Blinking

CAL

Yellow

Red

Off

Auto Cal disabled

Auto Cal enabled

Blinking

Unit is in calibration mode

FAULT

Off

CO₂warnings exist

Warnings exist

Blinking

10.4.1.2. Keyboard

A row of eight keys just below the vacuum florescent display (see Figure 10-17) is the main

method by which the user interacts with the analyzer. As the software is operated, labels appear

on the bottom row of the display directly above each active key, defining the function of that key

as it is relevant for the operation being performed. Pressing a key causes the associated

instruction to be performed by the analyzer.

Note that the keys do not auto-repeat. In circumstances where the same key must be activated

for two consecutive operations, it must be released and re-pressed.

10.4.1.3. Display

The main display of the analyzer is a vacuum florescent display with two lines of 40 text

characters each. Information is organized in the following manner (see Figure 10-17):

Mode Field: Displays the name of the analyzer’s current operating mode.

Message Field: Displays a variety of informational messages such as warning messages, operation

data and response messages during interactive tasks.

Concentration Field: Displays the actual concentration of the sample gas currently being measured

by the analyzer

Keypad Definition Field: Displays the definitions for the row of keys just below the display. These

definitions dynamic, context sensitive and software driven.

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10.4.1.4. Keyboard/Display Interface Electronics

I²C to Relay Board

Key Press

Detect

Display Data

Decoder

Display

Controller

Display Power

Watchdog

Keypad

Decoder

I²C Interface

Serial

Data

From 5 VDC

Power Supply

Optional

Maintenance

LED

Sample LED

(Green)

Maint.

Switch

2^ndLang.

Switch

Cal LED

(Yellow)

2 x 40 CHAR. VACUUM

FLUORESCENT DISPLAY

Fault LED

(Red)

KEYBOARD

Beeper

FRONT PANEL

Figure 10-18: Keyboard and Display Interface Block Diagram

The keyboard/display interface electronics of the MGFC7000E Analyzer watches the status of the

eight front panel keys, alerts the CPU when keys are depressed, translates data from parallel to

serial and back and manages communications between the keyboard, the CPU and the front panel

display. Except for the Keyboard interrupt status bit, all communication between the CPU and the

keyboard/display is handle by way of the instrument’s I²C buss. The CPU controls the clock signal

and determines when the various devices on the bus are allowed to talk or required to listen. Data

packets are labeled with addresses that identify for which device the information is intended.

Keypad Decoder

Each key on the front panel communicates with a decoder IC via a separate analog line. When a

key is depressed the decoder chip notices the change of state of the associated signal; latches and

holds the state of all eight lines (in effect creating an 8-bit data word); alerts the key-depress-

detect circuit (a flip-flop IC); translates the 8-bit word into serial data and; sends this to the I²C

interface chip.

Key-Depress-Detect Circuit

This circuit flips the state of one of the inputs to the I²C interface chip causing it to send an

interrupt signal to the CPU

I²C Interface Chip

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This IC performs several functions:

•

Using a dedicated digital status bit, it sends an interrupt signal alerting the CPU that new

data from the keyboard is ready to send.

Upon acknowledgement by the CPU that it has received the new keyboard data, the I²C

interface chip resets the key-depress-detect flip-flop.

In response to commands from the CPU, it turns the front panel status LEDs on and off and

activates the beeper.

Informs the CPU when the optional maintenance and second language switches have been

opened or closed (see Chapter 5 for information on these options).

Display Data Decoder

This decoder the serial translates the data sent by the CPU (in TTY format) into a bitmapped

image which is sent over a parallel data bus to the display.

Display Controller

This circuit manages the interactions between the display data decoder and the display itself. It

generates a clock pulse that keeps the two devices synchronized. It can also, in response to

commands from the CPU turn off and/or reset the display.

Additionally, for analyzers with the optional maintenance switch is installed (See Chapter 5), the

display controller turns on an LED located on the back of the keyboard interface PCA whenever

the instrument is placed in maintenance mode.

Display Power Watchdog

The Model GFC7000E’s display can begin to show garbled information or lock-up if the DC voltage

supplied to it falls too low, even momentarily. To alleviate this, a brown-out watchdog circuit

monitors the level of the power supply and in the event that the voltage level falls below a certain

level, turns the display off, then on resetting it

I²C Link To The Relay PCA

While the CPU’s I²C communication with the relay board is also routed through the

keyboard/display interface, information passed to and from the relay board via this channel is not

recognized by, acted upon or affected by the circuitry of the keyboard/display interface.

10.5. Software Operation

The Model GFC7000E Gas Filter Correlation Carbon Dioxide Analyzer is at its heart a high

performance, 386-based microcomputer running MS-DOS. Inside the DOS shell, special software

developed by Teledyne Instruments interprets user commands via the various interfaces,

performs procedures and tasks, stores data in the CPU’s various memory devices and calculates

the concentration of the sample gas.

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DOS Shell

AI FIRMWARE

Analyzer Operations

Calibration Procedures

Configuration Procedures

Autonomic Systems

Memory Handling

IDAS Records

Calibration Data

System Status Data

PC/104 BUS

Diagnostic Routines

ANALYZER

HARDWARE

Interface Handling

Sensor input Data

Display Messages

Keypad

Measurement

Algorithm

Analog Output Data

RS232 & RS485

External Digital I/O

PC/104 BUS

Linearization Table

Figure 10-19: Basic Software Operation

10.5.1. Adaptive Filter

The MGFC7000E software processes the CO2 MEAS and CO2 REF signals, after they are

digitized by the motherboard, through an adaptive filter built into the software. Unlike other

analyzers that average the output signal over a fixed time period, the MGFC7000E averages over

a set number of samples, where each sample is 0.2 seconds. This is technique is known as

boxcar averaging. During operation, the software automatically switches between two different

length filters based on the conditions at hand. Once triggered, the short filter remains engaged

for a fixed time period to prevent chattering.

During conditions of constant or nearly constant concentration the software, by default, computes

an average of the last 750 samples, or approximately 150 seconds. This provides the calculation

portion of the software with smooth stable readings. If a rapid change in concentration is detected

the filter includes, by default, the last 48 samples, approximately 10 seconds of data, to allow the

analyzer to more quickly respond. If necessary, these boxcar lengths can be changed between 1

and 1000 samples but with corresponding tradeoffs in rise time and signal-to-noise ratio (contact

customer service for more information).

Two conditions must be simultaneously met to switch to the short filter. First the instantaneous

concentration must exceed the average in the long filter by a fixed amount. Second the

instantaneous concentration must exceed the average in the long filter by a portion, or

percentage, of the average in the long filter.

10.5.2. Calibration - Slope and Offset

Calibration of the analyzer is performed exclusively in software.

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During instrument calibration (see Chapter 7) the user enters expected values for zero and span

via the front panel keypad and commands the instrument to make readings of calibrated sample

gases for both levels. The readings taken are adjusted, linearized, and compared to the expected

values, With this information the software computes values for instrument slope and offset and

stores these values in memory for use in calculating the CO₂concentration of the sample gas.

The instrument slope and offset values recorded during the last calibration can be viewed by

pressing the following keystroke sequence:

SAMPLE

RANGE = 50.0 MGM

CO =XX.XX

SETUP

< TST TST > CAL

SAMPLE

OFFSET = 0.000

CO =XX.XX

SETUP

< TST TST > CAL

SAMPLE

TIME = 16:23:34

CO =XX.XX

SETUP

< TST TST > CAL

SAMPLE

SLOPE = 1.000

CO =XX.XX

SETUP

< TST TST > CAL

10.5.3. Measurement Algorithm

Once the IR photo-detector is signal is demodulated into CO2 MEAS and CO2 REF by the

sync/demod board and converted to digital data by the mother board the MGFC7000E analytical

software calculates the ratio between CO2 MEAS and CO2 REF. this value is compared to a look-

up table is used, with interpolation, to linearize the response of the instrument. The linearized

concentration value is combined with calibration slope and offset values, then normalized for

changes in sample gas pressure to produce the final CO₂concentration. This is the value that is

displayed on the instrument front panel display and is stored in memory by the analyzer’s iDAS

system.

10.5.4. Temperature and Pressure Compensation

Changes in pressure can have a noticeable, effect on the CO₂concentration calculation. To

account for this, the Model GFC7000E software includes a feature which allows the instrument to

compensation of the CO₂calculations based on changes in ambient pressure.

The TPC feature multiplies the analyzer’s CO₂concentration by a factor which is based on the

difference between the ambient pressure of the sample gas normalized to standard atmospheric

pressure. As ambient pressure increases, the compensated CO₂concentration is increased.

10.5.5. Internal Data Acquisition System (iDAS)

The iDAS is designed to implement predictive diagnostics that stores trending data for users to

anticipate when an instrument will require service. Large amounts of data can be stored in non-

volatile memory and retrieved in plain text format for further processing with common data

analysis programs. The iDAS has a consistent user interface in all Teledyne Instruments

analyzers. New data parameters and triggering events can be added to the instrument as needed.

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Depending on the sampling frequency and the number of data parameters the iDAS can store

several months of data, which are retained even when the instrument is powered off or a new

firmware is installed. The iDAS permits users to access the data through the instrument’s front

panel or the remote interface. The latter can automatically download stored data for further

processing. For information on using the iDAS, refer to Sections 6.12.

User Notes

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TROUBLESHOOTING & REPAIR PROCEDURES

11. TROUBLESHOOTING & REPAIR PROCEDURES

This section contains a variety of methods for identifying the source of performance problems with

the analyzer. Also included in this section are procedures that are used in repairing the

instrument.

CAUTION

The operations outlined in this chapter are to be performed by qualified

maintenance personnel only.

CAUTION

Risk of electrical shock. Disconnect power before performing the

following operations.

11.1. General Troubleshooting Hints

The analyzer has been designed so that problems can be rapidly detected, evaluated and

repaired. During operation, the analyzer continuously performs self-check diagnostics and

provides the ability to monitor the key operating parameters of the instrument without disturbing

monitoring operations.

A systematic approach to troubleshooting will generally consist of the following four steps:

1. Note any WARNING MESSAGES and take corrective action as required.

2. Examine the values of all TEST functions and compare to factory values. Note any major

deviations from the factory values and take correction action as required.

3. Use the internal electronic status LED’s to determine whether the CPU and I²C buses are

running, and if the sync/demodulator and relay board are operating properly. Verify that the

DC power supplies are operating properly by checking the voltage test points on the relay

board. Please note that the analyzer’s DC power wiring is color-coded and these colors match

the color of the corresponding test points on the relay board.

4. SUSPECT A LEAK FIRST! Data from Teledyne Instruments’ service department indicates

that 50% of all problems are eventually traced to leaks in the pneumatic connections and gas

lines of the analyzer itself, the source of zero air, span gases or sample gas delivery system.

Check for gas flow problems such as clogged or blocked internal/external gas lines, damaged

seals, punctured gas lines, a damaged pump diaphragm, etc.

5. Follow the procedures defined in Section 11.4 for confirming that the analyzer’s basic

components are working (power supplies, CPU, relay board, sync/demod board, keypad, GFC

wheel motor, etc.). See Figure 3-11 for general layout of components and sub-assemblies in

the analyzer. See the wiring Interconnect Drawing and Interconnect List, documents 04216

and 04217.

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11.1.1. Interpreting WARNING Messages

The most common and/or serious instrument failures will result in a warning message being

displayed on the front panel. Table 11-1 lists warning messages, along with their meaning and

recommended corrective action.

It should be noted that if more than two or three warning messages occur at the same time, it is

often an indication that some fundamental analyzer sub-system (power supply, relay board,

motherboard) has failed rather than indication of the of the specific failures referenced by the

warnings. In this case, it is recommended that proper operation of power supplies (see Section

11.4.2), the relay board (see Section 11.4.5), and the A/D Board (see Section11.4.7.1) be

confirmed before addressing the specific warning messages.

The analyzer will alert the user that a Warning Message is active by displaying the keypad label

MSG on the Front Panel. In this case the Front panel display will look something like the

following:

SAMPLE

RANGE=500.0 PPM

CO2 = 00.00

CLR SETUP

<TST TST> CAL

MSG

The analyzer will also alert the user via the Serial I/O COM port(s) and cause the FAULT LED on

the front panel to blink.

To view or clear the various warning messages press:

SAMPLE

WHEEL TEMP WARNING

CAL MSG

CO2 = XX.XX

CLR SETUP

TEST deactivates Warning

Messages until New warning(s)

are activated

TEST

MSG activates Warning

SAMPLE

RANGE=500.00 PPM

MSG

CO2 = XX.XX

CLR SETUP

Messages.

<TST TST> keys replaced with

< TST TST > CAL

TEST key

SAMPLE

WHEEL TEMP WARNING

CO2 = XX.XX

Press CLR to clear the

message currently being

Displayed.

< TST TST > CAL

MSG

CLR SETUP

If more than one warning is

active the next message will

take its place

Once the last warning has been

cleared, the analyzer returns to

SAMPLE Mode

Make sure warning messages

are not due to

legitimate problems..

Figure 11-1: Viewing and Clearing Warning Messages

NOTE: A failure of the analyzer’s CPU or mother board can result in any or all of the following

messages.

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Table 11-1: Warning Messages - Indicated Failures

WARNING

MESSAGE

FAULT CONDITION

The optical bench temp Bad bench heater

POSSIBLE CAUSES

BENCH TEMP

WARNING

is controlled at 48 ± 5

Bad bench temperature sensor

^°C.

Bad relay controlling the bench heater

Entire relay board is malfunctioning

I²C buss malfunction

BOX TEMP

WARNING

Box Temp is < 5 ^°C or

> 48 ^°C.

NOTE: Box temperature typically runs ~7^oc warmer than

ambient temperature.

Poor/blocked ventilation to the analyzer.

Stopped exhaust-fan

Ambient temperature outside of specified range

Measured concentration value is too high or low.

Concentration slope value to high or too low

Measured concentration value is too high.

Concentration offset value to high.

Failed disk on chip

CANNOT DYN

SPAN

CANNOT DYN

ZERO

CONFIG

INITIALIZED

Dynamic Span

operation failed

Dynamic Zero

operation failed

Configuration and

Calibration data reset

to original Factory

state.

User erased data

Concentration alarm 1

is enabled and the

measured CO₂level is

≥ the set point.

CONC ALRM1

WARNING

Concentration alarm 2

is enabled and the

measured CO₂level is

≥ the set point.

CONC ALRM2

WARNING

DATA

Data Storage in iDAS

was erased

The CPU is unable to

Communicate with the

Front Panel Display

/Keyboard

Failed disk on chip

User cleared data

INITIALIZED

FRONT PANEL

WARN

Warning only appears on serial I/O com port(s)

Front panel display will be frozen, blank or will not respond.

Failed keyboard

I²C buss failure

Loose connector/wiring

PHOTO TEMP

WARNING

PHT DRIVE is >2500

mVDC

Failed IR photo-detector

Failed sync/demod board

IR photo-detector improperly attached to the sample

chamber

Bench temp too high.

REAR BOARD

NOT DET

Mother Board not

detected on power up.

Warning only appears on serial i/o com port(s)

Front panel display will be frozen, blank or will not respond.

Massive failure of mother board

I²C buss failure

RELAY BOARD

WARN

The CPU cannot

communicate with the

Relay Board.

Failed relay board

Loose connectors/wiring

SAMPLE FLOW

WARN

Sample flow rate is <

500 cc/min or > 1000

cc/min.

Failed sample pump

Blocked sample inlet/gas line

Dirty particulate filter

Leak downstream of critical flow orifice

Failed flow sensor/circuitry

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Table 11-1: Warning Messages – Indicated Failures (cont.)

WARNING

MESSAGE

FAULT CONDITION

POSSIBLE CAUSES

SAMPLE PRES

WARN

Sample Pressure is

<10 in-Hg or

> 35 in-Hg

Normally 29.92 in-Hg

at sea level decreasing

at 1 in-Hg per 1000 ft

of altitude (with no

flow – pump

If sample pressure is < 10 in-hg:

o Blocked particulate filter

o Blocked sample inlet/gas line

o Failed pressure sensor/circuitry

If sample pressure is > 35 in-hg:

o Blocked vent line on pressurized sample/zero/span gas

supply

o Bad pressure sensor/circuitry

disconnected).

SAMPLE TEMP

WARN

Sample temperature is Ambient temperature outside of specified range

< 10^oC or > 100^oC.

Failed bench heater

Failed bench temperature sensor

Relay controlling the bench heater

Failed relay board

I²C buss

SOURCE

WARNING

Occurs when CO₂Ref

is <1250 mVDC or

>4950 mVDC.

GFC wheel stopped

Failed sync/demod board

If status LED’s on the sync/demod board ARE flashing the

cause is most likely a failed:

IR source

Either of these

conditions will result in Relay board

I²C buss

IR photo-detector

an invalid M/R ratio.

SYNC WARNING Phase Lock Loop (PLL)

has lost lock on wheel

GFC wheel stopped

GFC wheel rotation very slow/dragging

Failed sync/demod board

rotation.

If status LED’s on the sync/demod board ARE flashing the

cause is most likely an a problem with the analyzer’s main

power:

Intermittent loss of the power supply too short to cause a

SYSTEM RESET warning;

Frequency problem with the AC mains.

This message occurs at power on.

If it is confirmed that power has not been interrupted:

Failed +5 VDC power,

SYSTEM RESET

The computer has

rebooted.

Fatal error caused software to restart

Loose connector/wiring

WHEEL TEMP

WARNING

The filter wheel

Blocked Cooling Vents below GFC Assembly

Analyzer’s top cover removed

Wheel heater

temperature is

controlled at 68 ± 5 ^°C

Wheel temperature sensor

Relay controlling the wheel heater

Entire relay board

I²C buss

11.1.2. Fault Diagnosis with TEST Functions

Besides being useful as predictive diagnostic tools, the test functions viewable from the front

panel can be used to isolate and identify many operational problems when combined with a

thorough understanding of the analyzer’s theory of operation (see Chapter 10).

The acceptable ranges for these test functions are listed in the “Nominal Range” column of the

analyzer Final Test and Validation Data Sheet (p/n 04307) shipped with the instrument. Values

outside these acceptable ranges indicate a failure of one or more of the analyzer’s subsystems.

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Functions whose values are still within the acceptable range but have significantly changed from

the measurement recorded on the factory data sheet may also indicate a failure. A worksheet has

been provided in Appendix C to assist in recording the value of these test functions.

The following table contains some of the more common causes for these values to be out of

range.

Table 11-2: Test Functions - Indicated Failures

TEST

FUNCTIONS

(As Displayed)

INDICATED FAILURE(S)

Time of day clock is too fast or slow

To adjust see Section 6.6.

TIME

Battery in clock chip on CPU board may be dead.

Incorrectly configured measurement range(s) could cause response problems with a

Datalogger or chart recorder attached to one of the analog output.

If the Range selected is too small, the recording device will over range.

If the Range is too big, the device will show minimal or no apparent change in readings.

Indicates noise level of instrument or CO₂concentration of sample gas (see Section 11.3.2

for causes).

RANGE

STABIL

If the value displayed is too high the IR Source has become brighter. Adjust the variable

gain potentiometer on the sync/demod board

If the value displayed is too low or constantly changing and the CO₂REF is OK:

Failed multiplexer on the mother board

Failed sync/demod board

Loose connector or wiring on sync/demod board

Flow of purge gas to the GFC wheel housing may have stopped

If the value displayed is too low or constantly changing and the CO₂REF is BAD:

GFC wheel stopped or rotation is too slow

Failed sync/demod board IR source

CO2 MEAS

CO2 REF

Failed IR source

Failed relay board

Failed I²C buss

Failed IR photo-detector

When the analyzer is sampling zero air and the ratio is too low:

The reference cell of the GFC wheel is contaminated or leaking.

The alignment between the GFC wheel and the segment sensor, the M/R sensor or both

is incorrect.

MR RATIO

Failed sync/demod board

Flow of purge gas to the GFC wheel housing may have stopped

When the analyzer is sampling zero air and the ratio is too high:

Zero air is contaminated

Failed IR photo-detector

See Table 11-1 for SAMPLE PRES WARN

PRES

Check for gas flow problems. see Section 11.1.6

SAMPLE FL

SAMPLE TEMP should be close to BENCH TEMP. Temperatures outside of the specified

range or oscillating temperatures are cause for concern

SAMPLE

TEMP

Bench temp control improves instrument noise, stability and drift. Temperatures outside of

the specified range or oscillating temperatures are cause for concern. See Table 11-1 for

BENCH TEMP WARNING

BENCH

TEMP

Wheel temp control improves instrument noise, stability and drift. Outside of set point or

oscillating temperatures are cause for concern. See Table 11-1 for WHEEL TEMP

WARNING

WHEEL

TEMP

If the box temperature is out of range, check fan in the power supply module. Areas to the

side and rear of instrument should allow adequate ventilation. See Table 11-1 for BOX

TEMP WARNING.

BOX TEMP

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Table 11-2: Test Functions - Indicated Failures (cont.)

TEST

FUNCTIONS

(As Displayed)

INDICATED FAILURE(S)

If this drive voltage is out of range it may indicate one of several problems:

- A poor mechanical connection between the various components in inside the detector

housing

- An electronic failure of the IR Photo-Detector’s built-in cooling circuitry, or;

- A temperature problem inside the analyzer chassis. In this case other temperature

warnings would also be active such as BENCH TEMP WARNING or BOX TEMP

WARNING.

PHT DRIVE

Values outside range indicate

Contamination of the zero air or span gas supply

Instrument is miss-calibrated

Blocked gas flow

Contaminated or leaking GFC wheel (either chamber)

Faulty IR photo-detector

SLOPE

Faulty sample faulty IR photo-detector pressure sensor (P1) or circuitry

Invalid M/R ratio (see above)

Bad/incorrect span gas concentration due.

Values outside range indicate

Contamination of the zero air supply

Contaminated or leaking GFC wheel (either chamber)

Faulty IR photo-detector

OFFSET

11.1.3. Using the Diagnostic Signal I/O Function

The Signal I/O parameters found under the DIAG Menu (see Section 6.9.2 and Appendix A)

combined with a thorough understanding of the instruments theory of operation (found in Chapter

10) are useful for troubleshooting in three ways:

•

The technician can view the raw, unprocessed signal level of the analyzer’s critical inputs

and outputs.

All of the components and functions that are normally under algorithmic control of the CPU

can be manually exercised.

The technician can directly control the signal level Analog and Digital Output signals.

This allows the technician to systematically observe the effect of directly controlling these signals

on the operation of the analyzer. Below in Figure 11-2 is an example of how to use the signal I/O

menu to view the raw voltage of an input signal or to control the state of an output voltage or

control signal. The specific parameter will vary depending on the situation.

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SAMPLE*

RANGE = 500.000 PPM

CO2 =X.XXX

< TST TST > CAL

SETUP

SAMPLE

ENTER SETUP PASS : 818

ENTR EXIT

SETUP X.X

PRIMARY SETUP MENU

CFG DAS RNGE PASS CLK MORE

EXIT

SETUP X.X

SECONDARY SETUP MENU

COMM VARS DIAG

DIAG

SIGNAL I/O

PREV NEXT

ENTR

DIAG I/O

0 ) EXT_ZERO_CAL=ON

PREV NEXT JUMP

PRNT EXIT

If parameter is an

input signal

If parameter is an output

signal or control

DIAG I/O

28) SAMPLE_PRESSURE=2540 MV

DIAG I/O

22) WHEEL_HTR=ON

PREV NEXT JUMP

PRNT EXIT

PREV NEXT JUMP

ON PRNT EXIT

Toggles parameter

ON/OFF

DIAG I/O

22 ) WHEEL_HTR=OFF

PREV NEXT JUMP

OFF PRNT EXIT

Exit returns to

DIAG display & all values

return to software control

Figure 11-2: Example of Signal I/O Function

11.1.4. Internal Electronic Status LED’s

Several LED’s are located inside the instrument to assist in determining if the analyzer’s CPU, I²C

buss and relay board, GFC wheel and the sync/demodulator board are functioning properly.

11.1.4.1. CPU Status Indicator

DS5, a red LED, that is located on upper portion of the motherboard, just to the right of the CPU

board, flashes when the CPU is running the main program loop. After power-up, approximately

30 to 60 seconds, DS5 should flash on and off. If characters are written to the front panel display

but DS5 does not flash then the program files have become corrupted, contact customer service

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because it may be possible to recover operation of the analyzer. If after 30 – 60 seconds neither

the DS5 is flashing or no characters have been written to the front panel display then the CPU is

bad and must be replaced.

Mother Board

P/N 04069

CPU Status LED

Figure 11-3: CPU Status Indicator

11.1.4.2. Sync Demodulator Status LED’s

Two LED’s located on the Sync/Demod Board and are there to make it obvious that the GFC

Wheel is spinning and the synchronization signals are present:

Table 11-3: Sync/Demod Board Status Failure Indications

LED

Function

M/R Sensor

Status

Fault Status

LED is stuck

ON or OFF

Indicated Failure(s)

GFC Wheel is not turning

M/R Sensor on Opto-Pickup Board failed

Sync/Demod Board failed

JP 4 Connector/Wiring faulty

Failed/Faulty +5 VDC Power Supply (PS1)

Segment

Sensor Status

LED is stuck

ON or OFF

GFC Wheel is not turning

Segment Sensor on Opto-Pickup Board failed

Sync/Demod Board failed

JP 4 Connector/Wiring faulty

Failed/Faulty +5 VDC Power Supply (PS1)

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D1 – M/R Sensor Status

JP4 Connector to Opto-Pickup

Board

D2 – Segment Sensor Status

Figure 11-4: Sync/Demod Board Status LED Locations

11.1.4.3. Relay Board Status LED’s

There are eight LED’s located on the Relay Board. The most important of which is D1, which

indicates the health of the I²C buss. If D1 is blinking the other faults following LED’s can be used

in conjunction with DIAG menu signal I/O to identify hardware failures of the relays and switches

on the relay (see Section 6.9.2 and Appendix D).

Table 11-4: I²C Status LED Failure Indications

LED

FUNCTION

FAULT STATUS

INDICATED FAILURE(S)

Failed/Halted CPU

Faulty Mother Board, Keyboard or Relay

Board

Faulty Connectors/Wiring between Mother

Board, Keyboard or Relay Board

Failed/Faulty +5 VDC Power Supply (PS1)

I2C buss

Health

(Watchdog

Continuously ON

Continuously OFF

(Red)

Circuit)

DC VOLTAGE TEST

POINTS

STATUS LED’s

RELAY PCA

PN 04135

Figure 11-5: Relay Board Status LEDs

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Table 11-5: Relay Board Status LED Failure Indications

SIGNAL I/O PARAMETER

LED

FUNCTION

DIAGNOSTIC TECHNIQUE

ACTIVATED BY

VIEW RESULT

Voltage displayed should change. If not:

Failed Heater

WHEEL_TEMP Faulty Temperature Sensor

Yellow

WHEEL

HEATER

WHEEL_HEATER

Failed AC Relay

Faulty Connectors/Wiring

Voltage displayed should change. If not:

Failed Heater

Yellow

BENCH

HEATER

BENCH_HEATER

N/A

BENCH_TEMP Faulty Temperature Sensor

Failed AC Relay

Faulty Connectors/Wiring

N/A

Yellow

SPARE

N/A

Sample/Cal Valve should audibly change

states. If not:

Failed Valve

Failed Relay Drive IC on Relay Board

Failed Relay Board

Faulty +12 VDC Supply (PS2)

Faulty Connectors/Wiring

Zero/Span Valve should audibly change

states. If not:

Failed Valve

Failed Relay Drive IC on Relay Board

Failed Relay Board

Faulty +12 VDC Supply (PS2)

Faulty Connectors/Wiring

Shutoff Valve should audibly change

states. If not:

Failed Valve

Failed Relay Drive IC on Relay Board

Failed Relay Board

Faulty +12 VDC Supply (PS2)

Faulty Connectors/Wiring

Voltage displayed should change. If not:

Failed IR Source

SAMPLE/CAL

GAS VALVE

OPTION

Green

CAL_VALVE

SPAN_VALVE

SHUTOFF_VALVE

IR_SOURCE

ZERO/SPAN

GAS VALVE

OPTION

Green

N/A

Green

SHUTOFF

VALVE OPTION

Faulty +12 VDC Supply (PS2)

Green

IR SOURCE

CO₂_MEASURE Failed Relay Board

Failed IR Photo-Detector

Failed Sync/Demod Board

Faulty Connectors/Wiring

11.1.5. Gas Flow Problems

In general, flow problems can be divided into three categories:

1. Flow is too high

2. Flow is greater than zero, but is too low, and/or unstable

3. Flow is zero (no flow)

When troubleshooting flow problems, it is a good idea to first confirm that the actual flow and not

the analyzer’s flow sensor and software are in error, or the flow meter is in error. Use an

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independent flow meter to perform a flow check as described in Section 9.3.4. If this test shows

the flow to be correct, check the pressure sensors as described in Section 11.4.6.5.

11.1.6. Typical Sample Gas Flow Problems

11.1.6.1. Flow is Zero

The unit displays a SAMPLE FLOW warning message on the front panel display or the SAMPLE

FLOW test function reports a zero or very low flow rate.

Confirm that the sample pump is operating (turning). If not, use an AC voltmeter to make sure

that power is being supplied to the pump. If no power is present at the electrical leads of the

pump.

1. If AC power is being supplied to the pump, but it is not turning, replace the pump.

2. If the pump is operating but the unit reports no gas flow, perform a flow check as described in

Section 9.3.4.

3. If no independent flow meter is available:

•

Disconnect the gas lines from both the sample inlet and the exhaust outlet on the rear

panel of the instrument.

•

Make sure that the unit is in basic SAMPLE Mode.

Place a finger over an Exhaust outlet on the rear panel of the instrument.

If gas is flowing through the analyzer, you will feel pulses of air being expelled from the

Exhaust outlet.

4. If gas flows through the instrument when it is disconnected from its sources of zero air, span

gas or sample gas, the flow problem is most likely not internal to the analyzer. Check to make

sure that:

•

All calibrators/generators are turned on and working correctly.

Gas bottles are not empty or low.

Valves, regulators, and gas lines are not clogged or dirty.

11.1.6.2. Low Flow

1. Check if the pump diaphragm is in good condition. If not, rebuild the pump (see Section

9.3.2). Check the Spare Parts List for information of pump rebuild kits.

2. Check for leaks as described in Section 9.3.3. Repair the leaking fitting, line or valve and re-

check.

3. Check for the sample filter and the orifice filter for dirt. Replace filters (see Sections 9.3.1 and

11.5.1 respectively).

4. Check for partially plugged pneumatic lines, orifices, or valves. Clean or replace them.

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5. If an IZS option is installed in the instrument, press CALZ and CALS. If the flow increases

then suspect a bad sample/cal valve.

11.1.6.3. High Flow

The most common cause of high flow is a leak in the sample flow control assembly or between

there and the pump. If no leaks or loose connections are found in the fittings or the gas line

between the orifice and the pump, rebuild/clean the sample flow control assembly as described in

Section 11.5.1.

11.1.6.4. Displayed Flow = “XXXX”

This warning means that there is inadequate gas flow. There are four conditions that might cause

this:

1. A leak upstream or downstream of the flow sensor

2. A flow obstruction upstream or downstream of the flow sensor

3. Bad Flow Sensor Board

4. Bad pump

To determine which is the case, view the sample pressure and sample flow functions on the front

panel. If the sample pressure is reading abnormally low, then the cause is likely a flow obstruction

upstream of the flow sensor. First, check the sample filter and make sure it is not plugged and

then systematically check all the other components upstream of the orifice to ensure that they are

not obstructed.

If the sample pressure is reading normal but the sample flow is reading low then it is likely that

the pump diaphragm is worn or there is an obstruction downstream of the flow sensor.

11.1.6.5. Actual Flow Does Not Match Displayed Flow

If the actual flow measured does not match the displayed flow, but is within the limits of 720-880

cc/min, adjust the calibration of the flow measurement as described in Section 6.9.8.

11.1.6.6. Sample Pump

The sample pump should start immediately after the front panel power switch is turned ON. With

the Sample Inlet plugged, the test function PRES should read about 10”-Hg for a pump in good

condition. Readings above 15”-Hg indicate that the pump needs rebuilding. If the test function

SAMP FL is greater than 10 cc the instrument’s there is a leak in the pneumatic lines.

11.1.7. Poor or Stopped Flow of Purge Gas

If sufficient purge gas is not supplied to the GFC wheel housing, cyclical fluctuations in readings

at zero or low CO₂concentrations, such as < 100 ppm, may occur. These fluctuations are the

result of changes in the CO₂concentration of the ambient atmosphere throughout the course of

the day and night. In isolated areas with relatively few people working nearby the ambient CO₂

concentration will fall during the day and rise during the night as rate of photosynthesis of the

plants in the surrounding area decreases and increases. In a lab environment with a relatively

high human occupancy the ambient CO₂concentration will increase during those parts of the day

when the highest number of workers are present. If the GFC wheel housing is allowed to fill with

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ambient air, these natural, diurnal fluctuations might be detected by the instrument and cause its

in its calculation of the CO₂concentration of the sample gas to drift.

Another possible symptom of poor or stopped purge gas flow would be the inability to measure

zero concentrations accurately at the end of a work day on a system that was calibrated at the

beginning of a workday. Again this could be due to local fluctuations in ambient CO₂

concentration between the time of the day when the calibration was performed and other times

during the day.

11.2. Calibration Problems

11.2.1. Miss-Calibrated

There are several symptoms that can be caused by the analyzer being miss-calibrated. This

condition is indicated by out of range Slopes and Offsets as displayed through the test functions

and is frequently caused by the following:

1. BAD SPAN GAS. This can cause a large error in the slope and a small error in the offset.

Delivered from the factory, the MGFC7000E’s slope is within ±15% of nominal. Bad span gas

will cause the analyzer to be calibrated to the wrong value. If in doubt have the span gas

checked by and independent lab.

2. CONTAMINATED ZERO GAS. Excess H₂O can cause a positive or negative offset and will

indirectly affect the slope.

3. Dilution calibrator not set up correctly or is malfunctioning. This will also cause the slope, but

not the zero to be incorrect. Again the analyzer is being calibrated to the wrong value.

4. Too many analyzers on the manifold. This can cause either a slope or offset error because

ambient gas with its pollutants will dilute the zero or span gas.

11.2.2. Non-Repeatable Zero and Span

As stated earlier, leaks both in the MGFC7000E and in the external system are a common source

of unstable and non-repeatable readings.

1. Check for leaks in the pneumatic systems as described in Section 9.3.3. Don’t forget to

consider pneumatic components in the gas delivery system outside the MGFC7000E. Such as:

•

A change in zero air source such as ambient air leaking into zero air line, or;

A change in the span gas concentration due to zero air or ambient air leaking into the

span gas line.

2. Once the instrument passes a leak check, do a flow check (see Section 9.3.4) to make sure

adequate sample is being delivered to the sensor assembly.

3. A failing IR photo-detector may be at fault. Check the CO2 MEAS and CO2 REF test

functions via the front panel display to make sure the signal levels are in the normal range

(See Appendix A) and are quiet.

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4. Confirm the sample pressure, wheel temperature, bench temperature, and sample flow

readings are correct and have steady readings.

5. Disconnect the exhaust line from the optical bench near the rear of the instrument and plug

this line into the SAMPLE inlet creating a pneumatic loop. The CO₂concentration (either zero

or span) now must be constant. If readings become quiet, the problem is in the external

pneumatics supplies for sample gas, span gas or zero air.

6. If pressurized span gas is being used with a zero/span valve option, make sure that the

venting is adequate (See Section 3.1.2 and 5.4)

7. If it is the zero point that is non-repeatable, and if that non-repeatability seems to only occur

at a certain time of day, such as when worker occupancy is highest or lowest, make sure the

flow of purge gas to the GFC wheel housing has not stopped (see Sections 10.2.2 and 11.1.7.

for more information).

11.2.3. Inability to Span – No SPAN Key

1. Confirm that the carbon dioxide span gas source is accurate; this can be done by switching

between two span-gas tanks. If the CO₂concentration is different, there is a problem with

one of the tanks.

2. Check for leaks in the pneumatic systems as described in Section 9.3.3.

3. Make sure that the expected span gas concentration entered into the instrument during

calibration is the correct span gas concentration and not too different from expected span

value. This can be viewed via the RNG Menu (see Section 6.7).

4. Check to make sure that there is no ambient air or zero air leaking into span gas line.

11.2.4. Inability to Zero – No ZERO Key

1. Confirm that there is a good source of zero air. Dilute a tank of span gas with the same

amount of zero air from two different sources. If the CO₂Concentration of the two

measurements is different, there is a problem with one of the sources of zero air.

2. Check for leaks in the pneumatic systems as described in Section 9.3.3.

3. The Internal zero air scrubber may need maintenance. This device is only present if the

analyzer has had zero/span valve options 51 or 53 installed this.

4. Check to make sure that there is no ambient air leaking into zero air line.

11.3. Other Performance Problems

Dynamic problems (i.e. problems which only manifest themselves when the analyzer is monitoring

sample gas) can be the most difficult and time consuming to isolate and resolve. The following

section provides an itemized list of the most common dynamic problems with recommended

troubleshooting checks and corrective actions.

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11.3.1. Temperature Problems

Individual control loops are used to maintain the set point of the absorption bench, filter wheel,

and IR photo-detector temperatures. If any of these temperatures are out of range or are poorly

controlled, the MGFC7000E will perform poorly.

11.3.1.1. Box or Sample Temperature

Box Temperature

The box temperature sensor is mounted to the motherboard and cannot be disconnected to check

its resistance. Rather check the BOX TEMP signal using the SIGNAL I/O function under the

DIAG Menu (see Section 11.1.3). This parameter will vary with ambient temperature, but at

~30^oC (6-7° above room temperature) the signal should be ~1450 mV.

Sample Temperature

The Sample Temperature should closely track the bench temperature. If it does not, locate the

sensor, which is located at the midpoint of the optical bench in a brass fitting. Unplug the

connector labeled “Sample”, and measure the resistance of the thermistor; at room temperature

(25°C) it should be ~30K Ohms, at operating temperature, 48°C, it should be ~ 12K Ohms

11.3.1.2. Bench Temperature

There are three possible failures that could cause the Bench temperature to be incorrect.

1. The heater mounted to the bottom of the Absorption bench is electrically shorted or open.

Check the resistance of the two heater elements by measuring between pin 2 and 4 (~76

Ohms), and pin 3 and 4 (~330 Ohms), of the white five-pin connector just below the sample

temperature sensor on the Bench (pin 1 is the pointed end).

2. Assuming that the I²C buss is working and that there is no other failure with the relay board,

the solid-state relay (K2) on the relay board may have failed. Using the BENCH_HEATER

parameter under the signal I/O function, as described above, turn on and off K2 (D3 on the

relay board should illuminate as the heater is turned on). Check the AC voltage present

between pin 2 and 4, for a 100 or 115 VAC model, and pins 3 and 4, for a 220-240 VAC

model.

WARNING:

HAZARDOUS VOLTAGES ARE PRESENT DURING THIS TEST

3. If the relay has failed there should be no change in the voltage across pins 2 and 4 or 3 and 4.

Note, K2 is in a socket for easy replacement.

4. If K2 checks out OK, the thermistor temperature sensor located on the optical bench near the

front of the instrument could be at fault. Unplug the connector labeled “Bench”, and measure

the resistance of the thermistor. At room temperature it should have approximately 30K

Ohms resistance, near the 48^oC set point it should have ~11K ohms.

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11.3.1.3. GFC Wheel Temperature

Like the bench heater above there are three possible causes for the GFC wheel temperature to

have failed.

1. The wheel heater has failed. Check the resistance between pins 1 and 4 on the white five-pin

connector just below the sample temperature sensor on the bench (pin 1 is the pointed end).

It should be approximately 275 ohms.

2. Assuming that the I²C buss is working and that there is no other failure with the relay board,

the solid-state relay (K1) on the relay board may have failed. Using the WHEEL_HEATER

parameter under the signal I/O function, as described above, turn on and off K1 (D2 on the

relay board should illuminate as the heater is turned on). Check the AC voltage present

between pin 1 and 4.

WARNING:

HAZARDOUS VOLTAGES ARE PRESENT DURING THIS TEST

3. If the relay has failed there should be no change in the voltage across pins 1 and 4. Note, K1

is socketed for easy replacement.

4. If K1 checks out OK, the thermistor temperature sensor located at the front of the filter wheel

assembly may have failed. Unplug the connector labeled “Wheel”, and measure the resistance

of the thermistor. The resistance near the 68^oC set point is ~5.7k ohms.

11.3.1.4. IR Photo-Detector TEC Temperature

If the PHT DRIVE test parameter described above in Table 11-2 is out of range there are two

four possible causes of failure.

1. The screws retaining the IR photo detector to the absorption bench have become loose.

Carefully tighten the screws, hand-tight and note whether, after the analyzer has come up to

operating temperature, whether the PHT DRIVE voltage has returned to an acceptable level.

2. The two large transistor-type devices mounted to the side of the Absorption Bench have come

loose from the bench. Tighten the retaining screws and note whether there is an improvement

in the PHT DRIVE voltage.

3. The photo-detector has failed. Contact the factory for instructions.

4. The sync demodulator circuit board has failed. Contact the factor for instructions.

11.3.2. Excessive Noise

Noise is continuously monitored in the TEST functions as the STABIL reading and only becomes

meaningful after sampling a constant gas concentration for at least 10 minutes. Compare the

current STABIL reading with that recorded at the time of manufacture (included in the

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MGFC7000E Final Test And Validation Data Sheet-p/n 04271 shipped with the unit from Teledyne

Instruments).

1. The most common cause of excessive noise is leaks. Leak check and flow check the

instrument described in Section 9.3.

2. Detector failure – caused by failure of the hermetic seal or over-temperature due to poor heat

sinking of the detector can to the optical bench. In addition to increased noise due to poor

signal-to-noise ratio, another indicator of detector failure is a drop in the signal levels of the

CO₂MEASURE signal and CO₂REFERENCE signal.

3. Sync/Demod Board failure. There are many delicate, high impedance parts on this board.

Check the CO2 MEAS and CO2 REF Test Functions via the Front Panel Display.

4. The detector cooler control circuit can fail for reasons similar to the detector itself failing.

Symptoms would be a change in MR RATIO Test Function when zero air is being sampled.

Also check the SIGNAL I/O parameter PHT DRIVE. After warm-up, and at 25^oC ambient, if

PHT DRIVE < 2500 mV, the cooler is working properly. If PHT DRIVE is > 2500 mV there is a

malfunction.

5. The +5 and ±15 VDC voltages in the MGFC7000E are provided by switching power supplies.

Switch mode supplies create DC outputs by switching the input AC waveform at high

frequencies. As the components in the switcher age and degrade, the main problem observed

is increased noise on the DC outputs. If a noisy switcher power supply is suspected, attach an

oscilloscope to the DC output test points located on the top right hand edge of the Relay

board. Look for short period spikes > 100 mV p-p on the DC output.

11.4. Subsystem Checkout

The preceding sections of this manual discussed a variety of methods for identifying possible

sources of failures or performance problems within the analyzer. In most cases this included a list

of possible causes. This section describes how to determine individually determine if a certain

component or subsystem is actually the cause of the problem being investigated.

11.4.1. AC Mains Configuration

The analyzer is correctly configured for the AC mains voltage in use if:

1. The Sample Pump is running.

2. The GFC wheel motor is spinning (a slight vibration should be apparent to the touch).

3. If incorrect power is suspected, check that the correct voltage and frequency is present at the

line input on the rear panel.

•

If the unit is set for 230 VAC and is plugged into 115VAC, or 100VAC the sample pump

will not start, and the heaters will not come up to temperature.

•

If the unit is set for 115 or 100 VAC and is plugged into a 230 VAC circuit, the circuit

breaker built into the ON/OFF Switch on the Front Panel will trip to the OFF position

immediately after power is switched on.

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11.4.2. DC Power Supply

If you have determined that the analyzer’s AC mains power is working, but the unit is still not

operating properly, there may be a problem with one of the instrument’s switching power

supplies. The supplies can have two faults, namely no DC output, and noisy output.

To assist tracing DC Power Supply problems, the wiring used to connect the various printed circuit

assemblies and DC Powered components and the associated test points on the relay board follow

a standard color-coding scheme as defined in Table.

Table 11-6: DC Power Test Point and Wiring Color Codes

NAME

Dgnd

+5V

TEST POINT#

TP AND WIRE COLOR

Black

Red

Agnd

+15V

-15V

Green

Blue

Yellow

Purple

Orange

+12V

+12R

A voltmeter should be used to verify that the DC voltages are correct per the values in Table

below, and an oscilloscope, in AC mode, with band limiting turned on, can be used to evaluate if

the supplies are producing excessive noise (> 100 mV p-p).

Table 11-7: DC Power Supply Acceptable Levels

CHECK RELAY BOARD TEST POINTS

POWER

VOLTAG

FROM TEST

POINT

SUPPLY

ASSY

MIN V

MAX V

TO TEST POINT

NAME

Dgnd

NAME

PS1

PS2

+15

4.8

5.25

16V

Agnd

+15

13.5

-15

Agnd

-15V

Dgnd

Chassis

+12V

Dgnd

-14V

-0.05

11.75

-0.05

-16V

0.05

12.5

0.05

Agnd

Chassis

+12

Agnd

Dgnd

N/A

+12V Ret

Dgnd

11.4.3. I²C Bus

Operation of the I²C buss can be verified by observing the behavior of D1 on the Relay Board in

conjunction with the performance of the front panel display. Assuming that the DC power

supplies are operating properly and the wiring from the Motherboard to the Keyboard, and the

wiring from the keyboard to the Relay board, is intact, the I²C buss is operating properly if:

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•

D1 on the relay board is flashing, or

D1 is not flashing but pressing a key on the front panel results in a change to the display.

11.4.4. Keyboard/Display Interface

The front panel keyboard, display and Keyboard Display Interface PCA (03975 or 04258) can be

verified by observing the operation of the display when power is applied to the instrument and

when a key is pressed on the front panel. Assuming that there are no wiring problems and that

the DC power supplies are operating properly:

1. The vacuum fluorescent display is good if on power-up a “-“ character is visible on the upper

left hand corner of the display.

2. The CPU Status LED, DS5, is flashing, see Section 11.1.4.1.

3. If there is a “-“ character on the display at power-up and D1 on the relay board is flashing

then the keyboard/display interface PCA is bad.

4. If the analyzer starts operation with a normal display but pressing a key on the front panel

does not change the display, then there are three possible problems:

•

One or more of the keys is bad,

The interrupt signal between the Keyboard Display interface and the motherboard is

broken, or

•

The Keyboard Display Interface PCA is bad.

11.4.5. Relay Board

The relay board PCA (04135) can be most easily checked by observing the condition of the its

status LEDs on the relay board, as described in Section 11.1.4.3, and the associated output when

toggled on and off through signal I/O function in the diagnostic menu, see Section 11.1.3.

1. If the front panel display responds to key presses and D1 on the relay board is NOT flashing

then either the wiring between the Keyboard and the relay board is bad, or the relay board is

bad.

2. If D1 on the relay board is flashing and the status indicator for the output in question (heater

power, valve drive, etc.) toggles properly using the signal I/O function, then the associated

control device on the relay board is bad. Several of the control devices are in sockets and can

be easily replaced. The table below lists the control device associated with a particular

function:

Table 11-8: Relay Board Control Devices

CONTROL

DEVICE

FUNCTION

IN SOCKET

Wheel Heater

Bench Heater

Spare AC Control

IZS Valves

Yes

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IR Source Drive

The IR source drive output can be verified by measuring the voltage at J16 with the IR source

disconnected. It should be 11.5± 0.5 VDC.

11.4.6. Sensor Assembly

11.4.6.1. Sync/Demodulator Assembly

To verify that the Sync/Demodulator Assembly is working follow the procedure below:

1. Verify that D1 and D2 are flashing.

•

If not check the opto pickup assembly, Section 11.4.6.2 and the GFC wheel drive, Section

11.4.6.3

•

If the wheel drive and opto pickup are working properly then verify that there is 2.4 ±0.1

VAC and 2.5 ±0.15 VDC between digital ground and TP 5 on the sync demod board. If not

then check the wiring between the sync/demod and opto pickup assembly (see

interconnect drawing 04216). If good then the sync/demod board is bad.

2. Verify that the IR source is operating, Section 11.4.6.4.

3. With the analyzer connected to zero air, measure between TP11 (measure) and analog

ground, and TP12 (reference) and analog ground.

•

If they are similar to values recorded on the Factory Data sheet then there is likely a

problem with the wiring or the A/D converter.

•

If they are not then either the sync demodulator board or the IR-photodetector are bad.

See also section 11.3.1.4 for problems with the IR-Photodetector TEC drive.

11.4.6.2. Opto Pickup Assembly

Operation of the opto pickup PCA (04088) can be verified with a voltmeter. Measure the AC and

DC voltage between digital ground on the Relay board, or Keyboard and TP1 and TP2 on the sync

pickup PCA. For a working board, with the GFC motor spinning, they should read 2.4 ±0.1 VAC

and 2.5 ±0.15 VDC.

Further confirmation that the pickups and motor are operating properly can be obtained by

measuring the frequency at TP1 and TP2 using a frequency counter, a digital volt meter with a

frequency counter, or an oscilloscope per the table below.

Table 11-9: Opto Pickup Board Nominal Output Frequencies

NOMINAL MEASURED FREQUENCY

AC MAINS FREQ.

50 Hz

TP1

TP2

300

360

60 Hz

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11.4.6.3. GFC Wheel Drive

If the D1 and D2 on the sync demodulator board are not flashing then:

1. Check for power to the motor by measuring between pins 1 and 3 on the connector feeding

the motor. For instruments configured for 120 or 220-240VAC there should be approximately

88 VAC for instruments configured for 100VAC, it should be the voltage of the AC mains,

approximately 100VAC.

2. Verify that the frequency select jumper, JP4, is properly set on the Relay Board. For 50 Hz

operation it should be installed. For 60 Hz operation may either be missing or installed in a

vertical orientation.

3. If there is power to the motor and the frequency select jumper is properly set then the motor

is likely bad. See Section 11.5.2 for instructions on removing and replacing the GFC assembly

that the motor is bolted to.

11.4.6.4. IR Source

The IR source can be checked using the following procedure:

1. Disconnect the source and check its resistance when cold. When new, the source should have

a cold resistance of more than 1.5 Ohms but less than 3.5 Ohms. If not, then the source is

bad.

2. With the source disconnected, energize the analyzer and wait for it to start operating.

Measure the drive Voltage between pins 1 and 2 on the jack that the source is normally

connected to, it should be 11.5 ± 0.25 VDC. If not, then there is a problem with either the

wiring, the Relay Board, or the +12V power supply.

3. If the drive voltage is correct in step 2, then remove the source from the heat sink assembly

(2 screws on top) and connect to its mating connector. Observe the light being emitted from

the source. It should be centered at the bottom of the U-shaped element. If there is either

no emission or a badly centered emission then the source is bad.

11.4.6.5. Pressure/Flow Sensor Assembly

The pressure/flow sensor PCA, located on the top of the absorption bench, can be checked with a

Voltmeter using the following procedure which, assumes that the wiring is intact, and that the

Motherboard and the power supplies are operating properly:

1. For Pressure related problems:

•

Measure the voltage across C1 it should be 5 ± 0.25 VDC. If not then the board is bad.

Measure the voltage across TP4 and TP1. With the sample pump disabled it should be

4500 mV ±250 mV. With the pump energized it should be approximately 200 mV less. If

not, then S1, the pressure transducer is bad, the board is bad, or there is a pneumatic

failure preventing the pressure transducer from sensing the absorption cell pressure

properly.

2. For flow related problems:

•

Measure the voltage across TP2 and TP1 it should be 10 ±0.25 VDC. If not then the board

is bad.

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•

Measure the voltage across TP3 and TP1. With proper flow (800 sccm at the sample inlet)

this should be approximately 4.5V (this voltage will vary with altitude). With flow stopped

(sample inlet blocked) the voltage should be approximately 1V. If the voltage is incorrect,

the flow sensor is bad, the board is bad or there is a leak upstream of the sensor.

11.4.7. Motherboard

11.4.7.1. A/D Functions

The simplest method to check the operation of the A-to-D converter on the motherboard is to use

the Signal I/O function under the DIAG Menu to check the two A/D reference Voltages and input

signals that can be easily measured with a voltmeter.

1. Use the Signal I/O function (see Section 11.1.3 and Appendix A) to view the value of

REF_4096_MV and REF_GND. If both are within 3 mV of nominal (4096 and 0), and are

stable, ±0.5 mV then the basic A/D is functioning properly. If not then the Motherboard is

Bad

2. Choose a parameter in the Signal I/O function such as SAMPLE_PRESSURE,

SAMPLE_FLOW, CO₂_MEASURE or CO₂_REFERENCE. Compare these Voltages at their

origin (see Interconnect drawing 04215 and Interconnect list 04216) with the voltage

displayed through the Signal I/O function. If the wiring is intact but there is a large difference

between the measured and displayed voltage (±10 mV) then the Motherboard is bad.

11.4.7.2. Analog Outputs: Voltage

To verify that the analog outputs are working properly, connect a voltmeter to the output in

question and perform an analog output step test as described in Section 6.9.3.

For each of the steps, taking into account any offset that may have been programmed into

channel (see Section 6.9.4), the output should be within 1% of the nominal value listed in the

table below except for the 0% step, which should be within 2 to 3 mV. If one or more of the steps

fails to be within this range then it is likely that there has been a failure of the either or both of

the DACs and their associated circuitry on the Motherboard.

Table 11-10: Analog Output Test Function - Nominal Values Voltage Outputs

FULL SCALE OUTPUT VOLTAGE

100MV

10V

STEP

NOMINAL OUTPUT VOLTAGE

100

20 mV

40 mV

60 mV

80 mV

100 mV

0.2

0.4

0.6

0.8

1.0

11.4.7.3. Analog Outputs: Current Loop

To verify that the analog outputs with the optional current mode output are working properly,

connect a 250 ohm resistor across the outputs and use a voltmeter to measure the output as

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described in Section 6.9.4.2 and then perform an Analog Output Step Test as described in Section

6.9.3.

For each step the output should be within 1% of the nominal value listed in the table below.

Table 11-11: Analog Output Test Function - Nominal Values Current Outputs

OUTPUT RANGE

2 -20

4 -20

NOMINAL OUTPUT VALUES

STEP

CURRENT

2 mA

5.6

V(250 OHMS)

CURRENT

V(250 OHMS)

0.5V

1.4

2.3

3.2

4.1

100

7.2

1.8

2.6

3.4

4.2

9.2

10.4

13.6

16.8

12.8

16.4

11.4.7.4. Status Outputs

The procedure below can be used to test the Status outputs:

Connect a jumper between the “D“ pin and the “V” pin on the status output connector.

Connect a 1000 ohm resistor between the “+” pin and the pin for the status output that is being

tested.

Connect a voltmeter between the “V” pin and the pin of the output being tested (see table

below).

Under the DIAGÆ SIGNAL I/O menu (see Section 11.1.3), scroll through the inputs and outputs

until you get to the output in question. Alternately turn on and off the output noting the voltage

on the Voltmeter, it should vary between 0 volts for ON and 5 volts for OFF.

Table 11-12: Status Outputs Check

PIN (LEFT TO RIGHT)

STATUS

SYSTEM OK

CONC VALID

HIGH RANGE

ZERO CAL

SPAN CAL

DIAG MODE

ALRM1

SALRM2

11.4.7.5. Control Inputs – Remote Zero, Span

The control input bits can be tested by the following procedure:

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Connect a jumper from the +5 pin on the Status connector to the x5V on the Control In

connector.

Connect a second jumper from the ‘-‘ pin on the Status connector to the A pin on the Control In

connector. The instrument should switch from SAMPLE mode to ZERO CAL R mode.

Connect a second jumper from the ‘-‘ pin on the Status connector to the B pin on the Control In

connector. The instrument should switch from SAMPLE mode to SPAN CAL R mode.

In each case, the MGFC7000E should return to SAMPLE mode when the jumper is removed.

11.4.8. CPU

There are two major types of failures associated with the CPU board: complete failure and a

failure associated with the Disk On Chip on the CPU board. If either of these failures occur,

contact the factory.

1. For complete failures, assuming that the power supplies are operating properly and the wiring

is intact, the CPU is bad if on powering the instrument:

•

The vacuum fluorescent display shows a dash in the upper left hand corner.

The CPU Status LED, DS5, is not flashing. (see Section 11.1.4.1.)

There is no activity from the primary RS-232 port (COM-A) on the rear panel even if “?

<ret>” is pressed.

•

In some rare circumstances this failure may be caused by a bad IC on the Motherboard,

specifically U57 the large, 44 pin device on the lower right hand side of the board. If this

is true, removing U57 from its socket will allow the instrument to startup but the

measurements will be incorrect.

2. If the analyzer stops part way through initialization (there are words on the vacuum

fluorescent display) then it is likely that the DOC has been corrupted.

11.4.9. RS-232 Communications

11.4.9.1. General RS-232 Troubleshooting

Teledyne Instruments analyzers use 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 as equipment has become more advanced, connections between various types of

hardware have become increasingly difficult. Generally, every manufacturer observes the signal

and timing requirements of the protocol very carefully.

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Problems with RS-232 connections usually center around 4 general areas:

1. Incorrect cabling and connectors. See Table 6-15 for connector and pin-out information.

2. The BAUD rate and protocol are incorrectly configured. See Section 6.10.7.

3. If a modem is being used, additional configuration and wiring rules must be observed. See

Section 6.13.2.6

4. Incorrect setting of the DTE – DCE Switch is set correctly See Section 6.10.5

5. Verify that cable (03596) that connects the serial COM ports of the CPU to J12 of the

Motherboard is properly seated

11.4.9.2. Troubleshooting Analyzer/Modem or Terminal Operation

These are the general steps for troubleshooting problems with a modem connected to a Teledyne

Instruments analyzer.

1. Check Cables for proper connection to the modem, terminal or computer.

2. Check to make sure the DTE-DCE is in the correct position as described in Section 6.10.5.

3. Check to make sure the set up command is correct (See Section 6.13.2.7)

4. Verify that the Ready to Send (RTS) signal is at logic high. The MGFC7000E sets pin 7 (RTS) to

greater than 3 volts to enable modem transmission.

5. Make sure the BAUD rate, word length, and stop bit settings between modem and analyzer

match, see Section 6.10.7.

6. Use the RS-232 test function to send “w” characters to the modem, terminal or computer; See

Section 6.10.8.

7. Get your terminal, modem or computer to transmit data to the analyzer (holding down the

space bar is one way); the green LED should flicker as the instrument is receiving data.

8. Make sure that the communications software or Terminal emulation software is functioning

properly.

Further help with serial communications is available in a separate manual “RS-232 Programming

Notes” Teledyne Instruments part number 013500000.

11.5. Repair Procedures

This section contains procedures that might need to be performed on rare occasions when a major

component of the analyzer requires repair or replacement.

11.5.1. Repairing Sample Flow Control Assembly

The Critical Flow Orifice is housed in the Flow Control Assembly (Teledyne Instruments part

number: 001760400) located on the top of the optical bench. A sintered filter protects the jewel

orifice so it is unusual for the orifice to need replacing, but if does, or the filter needs replacement

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please use the following procedure (see the Spare Parts list in Appendix B for part numbers and

kits):

1. Turn off power to the analyzer.

2. Locate the assembly attached to the sample pump, see Figure 3–11.

3. Disconnect the pneumatic connection from the flow assembly and the assembly from the

pump.

4. Remove the fitting and the components as shown in the exploded view in Figure 11.6.

5. Replace the o-rings (p/n:OR_01) and the sintered filter (p/n:FL_01).

6. If replacing the critical flow orifice itself (p/n:00094100), make sure that the side with the

colored window (usually red) is facing upstream to the flow gas flow.

7. Re-assemble in reverse order.

8. After reconnecting the power and pneumatic lines, flow check the instrument as described in

the Section 9.3.4.

Pneumatic Connector, Male 1/8”

(P/N FT_70

Spring

(P/N HW_20)

Sintered Filter

(P/N FL_01)

Critical Flow Orifice

(P/N 00094100)

O-Ring

(P/N OR_01)

Purge Housing

(P/N 000850000)

Figure 11-6: Critical Flow Restrictor Assembly Disassembly

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11.5.2. Removing/Replacing the GFC Wheel

When Removing or replacing the GFC Wheel it is important to perform the disassembly in the

following order to avoid damaging the components:

1. Turn off the analyzer.

2. Remove the top cover as described in “Getting Started” Section 3.1.

3. Open the Instrument’s hinged front panel.

4. Locate the GFC wheel/motor assembly (see Figure 3-11).

5. unplug the following electronic components:

•

The GFC wheel housing temperature sensor;

GFC wheel heater

GFC wheel motor power supply

IR source

6. Unscrew the purge gas line hex nut and remove the 1/8 inch FEP purge gas line.

Figure 11-7: Opening the GFC Wheel Housing

7. Remove the two (2) screws holding the opto-pickup printed circuit assembly to the GFC wheel

housing.

8. Carefully remove the opto-pickup printed circuit assembly.

9. Remove the four (4) screws holding the GFC wheel motor/heat sink assembly to the GFC

wheel housing.

10.Carefully remove the GFC Wheel motor/heat sink assembly from the GFC wheel housing.

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Figure 11-8: Removing the GFC Wheel

11.Remove the ONE (1) screw fastening the GFC wheel/mask assembly to the gfc motor hub.

12.Remove the GFC wheel/mask assembly.

13.Follow the previous steps in reverse order to put the GFC wheel/motor assembly back

together.

11.5.3. Disk-On-Chip Replacement Procedure

Replacing the Disk-on-Chip, may be necessary in certain rare circumstances or to load new

instrument software. This will cause all of the instrument configuration parameters and iDAS data

to be lost. However a backup copy of the operating parameters are stored in a second non-

volatile memory and will be loaded into the new the Disk-on-Chip on power-up. To change the

Disk-on-Chip follow this procedure.

1. Turn off power to the instrument.

2. Fold down the rear panel by loosening the thumbscrews on each side

3. Locate the Disk-on-Chip in the rightmost socket near the right hand side of the CPU assembly.

Remove the IC by gently prying it up from the socket.

4. Reinstall the new Disk-on-Chip, making sure the notch in the end of the chip is facing upward.

5. Close the rear panel and turn on power to the machine.

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A Primer on Electro-Static Discharge

12. A PRIMER ON ELECTRO-STATIC DISCHARGE

Teledyne Instruments considers the prevention of damage caused by the discharge of static

electricity to be extremely important part of making sure that your analyzer continues to provide

reliable service for a long time. This section describes how static electricity occurs, why it is so

dangerous to electronic components and assemblies as well as how to prevent that damage from

occurring.

12.1. How Static Charges are Created

Modern electronic devices such as the types used in the various electronic assemblies of your

analyzer, are very small, require very little power and operate very quickly. Unfortunately the

same characteristics that allow them to do these things also makes them very susceptible to

damage from the discharge of static electricity. Controlling electrostatic discharge begins with

understanding how electro-static charges occur in the first place.

Static electricity is the result of something called triboelectric charging which happens whenever

the atoms of the surface layers of two materials rub against each other. As the atoms of the two

surfaces move together and separate, some electrons from one surface are retained by the other.

Materials

Makes

Contact

Materials

Separate

PROTONS = 3

ELECTRONS = 2

PROTONS = 3

ELECTRONS = 4

PROTONS = 3

ELECTRONS = 3

PROTONS = 3

ELECTRONS = 3

NET CHARGE = -1

NET CHARGE = +1

NET CHARGE = 0

Figure 12-1: Triboelectric Charging

If one of the surfaces is a poor conductor or even a good conductor that is not grounded, the

resulting positive or negative charge can not bleed off and becomes trapped in place, or static.

The most common example of triboelectric charging happens when someone wearing leather or

rubber soled shoes walks across a nylon carpet or linoleum tiled floor. With each step electrons

change places and the resulting electro-static charge builds up, quickly reaching significant levels.

Pushing an epoxy printed circuit board across a workbench, using a plastic handled screwdriver or

even the constant jostling of Styrofoam pellets during shipment can also build hefty static charges

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Table 12-1: Static Generation Voltages for Typical Activities

65-90%

10-25%

MEANS OF GENERATION

Walking across nylon carpet

Walking across vinyl tile

Worker at bench

1,500V

250V

35,000V

12,000V

6,000V

100V

Poly bag picked up from

bench

1,200V

1,500V

20,000V

18,000V

Moving around in a chair

padded with urethane foam

12.2. How Electro-Static Charges Cause Damage

Damage to components occurs when these static charges come in contact with an electronic

device. Current flows as the charge moves along the conductive circuitry of the device and the

typically very high voltage levels of the charge overheat the delicate traces of the integrated

circuits, melting them or even vaporizing parts of them. When examined by microscope the

damage caused by electro-static discharge looks a lot like tiny bomb craters littered across the

landscape of the component’s circuitry.

A quick comparison of the values in Table 12-1 with the those shown in the Table 12-2, listing

device susceptibility levels, shows why Semiconductor Reliability News estimates that

approximately 60% of device failures are the result of damage due to electro-static discharge.

Table 12-2: Sensitivity of Electronic Devices to Damage by ESD

DAMAGE SUSCEPTIBILITY

VOLTAGE RANGE

DEVICE

DAMAGE BEGINS

OCCURRING AT

CATASTROPHIC

DAMAGE AT

MOSFET

VMOS

100

1800

100

NMOS

GaAsFET

EPROM

JFET

2000

100

140

150

190

200

7000

500

SAW

Op-AMP

CMOS

2500

3000

2500

3000

Schottky Diodes 300

Film Resistors

300

This Film

Resistors

300

7000

ECL

500

SCR

1000

2500

Schottky TTL

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Model GFC7000E Instruction Manual

A Primer on Electro-Static Discharge

Potentially damaging electro-static discharges can occur:

•

Any time a charged surface (including the human body) discharges to a device. Even

simple contact of a finger to the leads of an sensitive device or assembly can allow enough

discharge to cause damage. A similar discharge can occur from a charged conductive

object, such as a metallic tool or fixture.

When static charges accumulated on a sensitive device discharges from the device to

another surface such as packaging materials, work surfaces, machine surfaces or other

device. In some cases, charged device discharges can be the most destructive.

A typical example of this is the simple act of installing an electronic assembly into the

connector or wiring harness of the equipment in which it is to function. If the assembly is

carrying a static charge, as it is connected to ground a discharge will occur.

•

Whenever a sensitive device is moved into the field of an existing electro-static field, a

charge may be induced on the device in effect discharging the field onto the device. If the

device is then momentarily grounded while within the electrostatic field or removed from

the region of the electrostatic field and grounded somewhere else, a second discharge will

occur as the charge is transferred from the device to ground.

12.3. Common Myths About ESD Damage

•

I didn’t feel a shock so there was no electro-static discharge: The human nervous

system isn’t able to feel a static discharge of less than 3500 volts. Most devices are

damaged by discharge levels much lower than that.

I didn’t touch it so there was no electro-static discharge: Electro Static charges are

fields whose lines of force can extend several inches or sometimes even feet away from the

surface bearing the charge.

It still works so there was no damage: Sometimes the damaged caused by electro-

static discharge can completely sever a circuit trace causing the device to fail immediately.

More likely, the trace will be only partially occluded by the damage causing degraded

performance of the device or worse, weakening the trace. This weakened circuit may

seem to function fine for a short time, but even the very low voltage and current levels of

the device’s normal operating levels will eat away at the defect over time causing the

device to fail well before its designed lifetime is reached.

These latent failures are often the most costly since the failure of the equipment in which

the damaged device is installed causes down time, lost data, lost productivity, as well as

possible failure and damage to other pieces of equipment or property.

•

Static Charges can’t build up on a conductive surface: There are two errors in this

statement.

Conductive devices can build static charges if they are not grounded. The charge will be

equalized across the entire device, but without access to earth ground, they are still

trapped and can still build to high enough levels to cause damage when they are

discharged.

A charge can be induced onto the conductive surface and/or discharge triggered in the

presence of a charged field such as a large static charge clinging to the surface of a nylon

jacket of someone walking up to a workbench.

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A Primer on Electro-Static Discharge

•

As long as my analyzer is properly installed it is safe from damage caused by

static discharges: It is true that when properly installed the chassis ground of your

analyzer is tied to earth ground and its electronic components are prevented from building

static electric charges themselves. This does not, however, prevent discharges from static

fields built up on other things, like you and your clothing, from discharging through the

instrument and damaging it.

12.4. Basic Principles of Static Control

It is impossible to stop the creation of instantaneous static electric charges. It is not, however

difficult to prevent those charges from building to dangerous levels or prevent damage due to

electro-static discharge from occurring.

12.4.1. General Rules

Only handle or work on all electronic assemblies at a properly set up ESD station.

Setting up an ESD safe work station need not be complicated. A protective mat properly tied to

ground and a wrist strap are all that is needed to create a basic anti-ESD workstation (see figure

12-2).

Protective

Wrist Strap

Mat

Ground Point

Figure 12-2: Basic anti-ESD Work Station

For technicians that work in the field, special lightweight and portable anti-ESD kits are available

from most suppliers of ESD protection gear. These include everything needed to create a

temporary anti-ESD work area anywhere.

•

Always wear an Anti-ESD wrist strap when working on the electronic assemblies

of your analyzer. An anti-ESD wrist strap keeps the person wearing it at or near the

same potential as other grounded objects in the work area and allows static charges to

dissipate before they can build to dangerous levels. Anti-ESD wrist straps terminated with

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Model GFC7000E Instruction Manual

A Primer on Electro-Static Discharge

alligator clips are available for use in work areas where there is no available grounded

plug.

Also, anti-ESD wrist straps include a current limiting resistor (usually around one meg-

ohm) that protects you should you accidentally short yourself to the instrument’s power

supply.

•

Simply touching a grounded piece of metal is insufficient. While this may

temporarily bleed off static charges present at the time, once you stop touching the

grounded metal new static charges will immediately begin to re-build. In some conditions

a charge large enough to damage a component can rebuild in just a few seconds.

Always store sensitive components and assemblies in anti-ESD storage bags or

bins: Even when you are not working on them, store all devices and assemblies in a

closed anti-Static bag or bin. This will prevent induced charges from building up on the

device or assembly and nearby static fields from discharging through the it.

Use metallic anti-ESD bags for storing and shipping ESD sensitive components

and assemblies rather than pink-poly bags. The famous, pink-poly bags are made of

a plastic that is impregnated with a liquid (similar to liquid laundry detergent) which very

slowly sweats onto the surface of the plastic creating a slightly conductive layer over the

surface of the bag.

While this layer may equalizes any charges that occur across the whole bag, it does not

prevent the build up of static charges. If laying on a conductive grounded surface, these

bags will allow charges to bleed away but the very charges that build up on the surface of

the bag itself can be transferred through the bag by induction onto the circuits of your ESD

sensitive device. Also, the liquid impregnating the plastic is eventually used up after which

the bag is as useless for preventing damage from ESD as any ordinary plastic bag.

Anti-Static bags made of plastic impregnated with metal (usually silvery in color) provide

all of the charge equalizing abilities of the pink-poly bags but also, when properly sealed,

create a Faraday cage that completely isolates the contents from discharges and the

inductive transfer of static charges.

Storage bins made of plastic impregnated with carbon (usually black in color) are also

excellent at dissipating static charges and isolating their contents from field effects and

discharges.

•

Never use ordinary plastic adhesive tape near an ESD sensitive device or to close

an anti-ESD bag. The act of pulling a piece of standard plastic adhesive tape, such as

Scotch^®tape, from its roll will generate a static charge of several thousand or even tens of

thousands of volts on the tape itself and an associated field effect that can discharge

through or be induced upon items up to a foot away.

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A Primer on Electro-Static Discharge

12.4.2. Basic anti-ESD Procedures for Analyzer Repair and

Maintenance

12.4.2.1. Working at the Instrument Rack

When working on the analyzer while it is in the instrument rack and plugged into a properly

grounded power supply

1. Attach you anti-ESD wrist strap to ground before doing anything else.

•

Use a wrist strap terminated with an alligator clip and attach it to a bare metal portion of

the instrument chassis. This will safely connect you to the same ground level to which the

instrument and all of its components are connected.

2. Pause for a second or two to allow any static charges to bleed away.

3. Open the casing of the analyzer and begin work. Up to this point the closed metal casing of

your analyzer has isolated the components and assemblies inside from any conducted or

induces static charges.

4. If you must remove a component from the instrument, do not lay it down on a non-ESD

preventative surface where static charges may lie in wait.

5. Only disconnect your wrist strap after you have finished work and closed the case of the

analyzer.

12.4.2.2. Working at a Anti-ESD Work Bench.

When working on an instrument of an electronic assembly while it is resting on a anti-ESD work

bench

1. Plug you anti-ESD wrist strap into the grounded receptacle of the work station before touching

any items on the work station and while standing at least a foot or so away, This will allow

any charges you are carrying to bleed away through the ground connection of the work station

and prevent discharges due to field effects and induction from occurring.

2. Pause for a second or two to allow any static charges to bleed away.

3. Only open any anti-ESD storage bins or bags containing sensitive devices or assemblies after

you have plugged your wrist strap into the work station.

•

Lay the bag or bin on the workbench surface.

Before opening the container, wait several seconds for any static charges on the outside

surface of the container to be bled away by the work station’s grounded protective mat.

4. Do not pick up tools that may be carrying static charges while also touching or holding an ESD

Sensitive Device.

•

Only lay tools or ESD-sensitive devices and assemblies on the conductive surface of your

workstation. Never lay them down on a non-ESD preventative surfaces.

5. Place any static sensitive devices or assemblies in anti-static storage bags or bins and close

the bag or bin before unplugging your wrist strap.

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A Primer on Electro-Static Discharge

6. Disconnecting your wrist strap is always the last action taken before leaving the work bench.

12.4.2.3. Transferring Components from Rack To Bench and Back

When transferring a sensitive device from an installed Teledyne Instruments analyzer to a Anti-

ESD workbench or back:

1. Follow the instructions listed above for working at the instrument rack and work station.

2. Never carry the component or assembly without placing it in a anti-ESD bag or bin.

3. Before using the bag or container allow any surface charges on it to dissipate:

•

If you are at the instrument rack hold the bag in one hand while your wrist strap is

connected to a ground point.

If you are at a anti-ESD work bench, lay the container down on the conductive work

surface.

In either case wait several seconds.

4. Place the item in the container.

5. Seal the container. If using a bag, fold the end over and fastening it with anti-ESD tape.

Never use standard plastic adhesive tape as a sealer.

•

Folding the open end over isolates the component(s) inside from the effects of static fields.

Leaving the bag open or simply stapling it shut without folding it closed prevents the bag

from forming a complete protective envelope around the device.

6. Once you have arrived at your destination, allow any surface charges that may have built up

on the bag or bin during travel to dissipate:

•

Connect your wrist strap to ground.

If you are at the instrument rack hold the bag in one hand while your wrist strap is

connected to a ground point.

•

If you are at a anti-ESD work bench, lay the container down on the conductive work

surface

•

In either case wait several seconds

7. Open the container.

12.4.2.4. Opening Shipments from and Packing Components for Return to

Teledyne Instruments Customer Service.

Packing materials such as bubble pack and Styrofoam pellets are extremely efficient generators of

static electric charges. To prevent damage from ESD, Teledyne Instruments ships all electronic

components and assemblies in properly sealed ant-ESD containers.

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A Primer on Electro-Static Discharge

Static charges will build up on the outer surface of the anti-ESD container during shipping as the

packing materials vibrate and rub against each other. To prevent these static charges from

damaging the components or assemblies being shipped make sure that you:

•

Always unpack shipments from Teledyne Instruments Customer Service by:

•

Opening the outer shipping box away from the anti-ESD work area

Carry the still sealed ant-ESD bag, tube or bin to the anti-ESD work area

Follow steps 6 and 7 of Section 12.4.2.3 above when opening the anti-ESD container at

the work station

•

Reserve the anti-ESD container or bag to use when packing electronic components or

assemblies to be returned to Teledyne Instruments

•

Always pack electronic components and assemblies to be sent to Teledyne Instruments

Customer Service in anti-ESD bins, tubes or bags.

•

Do not use pink-poly bags.

If you do not already have an adequate supply of anti-ESD bags or containers

available, Teledyne Instruments’ Customer Service department) will supply them (see

Section 11.7 for contact information.

•

Always follow steps 1 through 5 of Section 12.4.1.3

User Notes

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Model GFC7000E Instruction ManualAPPENDIX A - Version Specific Software Documentation

APPENDIX A - Version Specific Software Documentation

APPENDIX A-1: Model GFC7000E Software Menu Trees

APPENDIX A-2: Model GFC7000E Setup Variables Available Via Serial I/O

APPENDIX A-3: Model GFC7000E Warnings and Test Measurements Via Serial I/O

APPENDIX A-4: Model GFC7000E Signal I/O Definitions

APPENDIX A-5: Model GFC7000E iDAS Functions

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APPENDIX A-1: MGFC7000E Software Menu Trees, Revision E.0

SAMPLE

TEST¹

CAL

MSG^1,2

CLR^1,3

SETUP

Only appear if

reporting range

is set for

AUTO range

mode.

ENTER SETUP PASS: 818

LOW

HIGH

(Primary Setup Menu)

CFG

DAS

RANG PASS

CLK

ZERO

SPAN CONC

RANGE

(Secondary Setup Menu)

STABIL

PRES

SAMP FL

PMT

NORM PMT

UV LAMP

LAMP RATIO

STR. LGT

DARK PMT

DARK LAMP

SLOPE

COMM VARS

DIAG

OFFSET

HVPS

RCELL TEMP

BOX TEMP

PMT TEMP

IZS TEMP¹

TEST²

TEST FUNCTIONS

Viewable by user while

instrument is in

SAMPLE Mode

(see Section 6.2.1)

Only appears when warning messages are activated

(see Section 6.2.2)

Press this key to cycle through list of active warning

messages.

Press this key to clear/erase the warning message

currently displayed

TIME

Figure A-1: Basic Sample Display Menu

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APPENDIX A-1: MGFC7000E Software Menu Trees, Revision E.0

SAMPLE

TEST¹

CAL

CALS

MSG^1,2

CLR^1,3

CALZ

SETUP

Only appear if

reporting range

is set for

LOW

HIGH

LOW

HIGH

LOW

HIGH

AUTO range

mode.

RANGE

RANGE1^*

RANGE2^*

STABIL

ZERO

SPAN CONC

ZERO

SPAN CONC

ENTER SETUP PASS: 818

CO2 MEAS

CO2 REF

MR RATIO

PRES

SAMP FL

(Primary Setup Menu)

SAMP TEMP

BENCH TEMP

WHEEL TEMP

BOX TEMP

PHT DRIVE

SLOPE

CFG

DAS

RANG PASS

CLK

OFFSET

TEST

TIME

(Secondary Setup Menu)

TEST FUNCTIONS

Viewable by user while

instrument is in SAMPLE Mode

(see Section 6.2.1)

Only appears when warning messages are activated

(see Section 6.2.2)

Press this key to cycle through list of active warning

messages.

Press this key to clear/erase the warning message

currently displayed

COMM VARS

DIAG

*Only appears instrument is set for

DUAL or AUTO reporting range

modes

Figure A-2: Sample Display Menu - Units with Z/S Valve or IZS Option installed

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Model GFC7000E Instruction Manual

APPENDIX A-1: MGFC7000E Software Menu Trees, Revision E.0

SETUP

ENTER SETUP PASS: 818

ACAL¹

CFG

DAS

RNGE

PASS

CLK

Go To iDAS

MENU TREE

(Fig. A-5)

MODE

SET²

OFF

• MODEL NAME

• SERIAL NUMBER

TIME

DATE

SEQ 1)

SEQ 2)

• SOFTWARE

REVISION

SEQ 3

)

• LIBRARY REVISION

•

MODE

SET

UNIT

iCHIP SOFTWARE

REVISION¹

•

HESSEN PROTOCOL

REVISION¹

•

ACTIVE

SPECIAL SOFTWARE

OPTIONS¹

CPU TYPE

SNGL

DUAL

AUTO

• DATE FACTORY

CONFIGURATION

SAVED

DISABLED

ZERO

ZERO/SPAN

SPAN

PPB

PPM

UGM

MGM

ENTR

TIMER ENABLE

STARTING DATE

STARTING TIME

DELTA DAYS

DELTA TIME

Go To

Only appears if a applicable

option/feature is installed

and activated.

Appears whenever the

currently displayed

sequence is not set for

DISABLED.

Only appears when

reporting range is set to

AUTO range mode.

SECONDARY SETUP MENU

LOW³HIGH³

EDIT

(Fig. A-4)

DURATION

CALIBRATE

RANGE TO CAL³

Figure A-3: Primary Setup Menu (Except iDAS)

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APPENDIX A-1: MGFC7000E Software Menu Trees, Revision E.0

SETUP

ENTER SETUP PASS: 818

ACAL¹

CFG

DAS

RNGE

PASS

CLK

VIEW

EDIT

PREV NEXT

CONC

PNUMTC

CALDAT

ZTBZRO

STBSPN

TEMP

PREV NEXT

INS

DEL

EDIT

PRNT

YES

CONC

VIEW

PREV NEXT

PNUMTC

CALDAT

ZTBZRO

STBSPN

TEMP

<SET

SET>

EDIT

PRNT

<PRM PRM> PV10

NX10

Selects data point to view.

Creates/changes name

(see Section 6.12.2).

Cycles through

lists of

parameters

chosen for this

iDAS channel

NAME

EVENT

PARAMETERS

REPORT PERIOD

NUMBER OF RECORDS

RS-232 REPORT

CHANNEL ENABLE

CAL. HOLD

Sets the

amount of time

between each

report.

YES

PREV NEXT

INS

DEL

EDIT

Cycles through

available trigger

events

(see Section 6.12.3).

YES

OFF

<SET

SET>

EDIT

Cycles through

already active

parameters

(see Section 6.12.4).

Selects max

no. of records

for this channel

PARAMETER

PREV NEXT

SAMPLE MODE

PRECISION

INST

AVG

MIN

MAX

Cycles through available/active parameters

(see Section 6.12.4).

Only appears if a valve option is installed.

Figure A-4: Primary Setup Menu (iDAS)

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APPENDIX A-1: MGFC7000E Software Menu Trees, Revision E.0

SETUP

ENTER SETUP PASS: 818

ACAL¹

CFG

DAS

RNGE

PASS

CLK

COMM

VARS

DIAG

COM1

COM2

PREV NEXT JUMP

EDIT PRINT

DAS_HOLD_OFF

CONC PRECISION

DYN_ZERO OFF

DYN_SPAN OFF

CLOCK_ADJ

<SET

SET>

EDIT

MODE

BAUD RATE TEST PORT

PREV NEXT

TEST

QUIET

COMPUTER

SECURITY

HESSEN PROTOCOL

COMx E,7,1

RS-485

MULTIDROP

ENABLE MODEM

ENABLE INTERNET

IGNORE ERRORS

DISABLE XON/XOFF

COMMAND PROMPT

300

1200

2400

4800

9600

Go To

DIAG MENU TREE

(Fig A-6)

19200

38400

57760

115200

Only appears if a valve is installed.

OFF

Figure A-5: Secondary Setup Menu (COMM & VARS)

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APPENDIX A-1: MGFC7000E Software Menu Trees, Revision E.0

SETUP

ENTER SETUP PASS: 818

ACAL¹

CFG

DAS

RNGE

PASS

CLK

COMM

VARS

DIAG

COM1

PREV NEXT JUMP

EDIT PRINT

INET²

DAS_HOLD_OFF

COMM - MENU TREE

CONC PRECISION

DYN_ZERO OFF

DYN_SPAN OFF

CLOCK_ADJ

(Fig A-5)

<SET

SET>

EDIT

DHCP

INSTRUMENT IP

GATEWAY IP

SUBNET MASK

TCP PORT³

HOSTNAME⁴

Go To

DIAG MENU TREE

(Fig A-6)

INSTRUMENT IP⁵

GATEWAY IP⁵

SUBNET MASK⁵

TCP PORT³

OFF

EDIT

Only appears if a valve option is installed.

Only appears when the Ethernet card (option 63) is installed.

Although TCP PORT is editable regardless of the DHCP state, do not change the setting for this property unless

instructed to by Teledyne Instruments Customer Service personnel.

HOST NAME is only editable when DHCP is ON.

INSTRUMENT IP, GATEWAY IP & SUBNET MASK are only editable when DHCP is OFF.

Figure A-6: Secondary Setup Menu (COMM Menu with Ethernet Card)

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APPENDIX A-1: MGFC7000E Software Menu Trees, Revision E.0

SETUP

ENTER SETUP PASS: 818

ACAL¹

CFG

DAS

RNGE

PASS

CLK

COMM

VARS

DIAG

HESSEN²

COM1 COM2

See

Fig A-5

Fig A-6

<SET

SET> EDIT

<SET

SET> EDIT

VARIATION RESPONSE MODE GAS LIST STATUS FLAGS

TYPE 1

TYPE 2

BCC

TEXT

CMD

MODE

BAUD RATE TEST PORT

PREV NEXT TEST

CO2, 310, REPORTED

PREV NEXT

INS

DEL

EDIT

PRNT

300

1200

2400

4800

SAMPLE FLOW WARNING

BENCH TEMP WARNING

SOURCE WARNING

QUIET

COMPUTER

SECURITY

HESSEN PROTOCOL

COM[1,2] E,7,1

RS-485

BOX TEMP WARNING

WHEEL TEMP WARNING

SAMPLE TEMP WARNING

SAMPLE PRESSURE WARNING

INVALID CONC

9600

19200

38400

57760

115200

MULTIDROP

INSTRUMENT OFF

ENABLE MODEM

ENABLE INTERNET

IGNORE ERRORS

DISABLE XON/XOFF

COMMAND PROMPT

IN MANUAL CALIBRATION MODE

IN ZERO CALIBRATION MODE

IN SPAN CALIBRATION MODE

UGM

Only appears if a valve is installed.

Only appears when the HESSEN

mode is enabled for either COM1

or COM2.

MGM

See Table 6-27 for

Flag Assignments

PPB

PPM

OFF

Figure A-7: Secondary Setup Menu (COMM Menu with HESSEN)

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APPENDIX A-1: MGFC7000E Software Menu Trees, Revision E.0

SETUP

ENTER SETUP PASS: 818

ACAL¹

DAS

RNGE

PASS

CLK

CFG

DIAG

COMM

VARS

PREV NEXT

SIGNAL

I/O

ANALOG

OUTPUT

ANALOG I/O

CONFIGURATION

ELECTRICAL

DARK

CALIBRATION

PRESSURE

CALIBRATION

FLOW

CALIBRATION

TEST

CHANNEL

TEST

OUTPUT

ENTR

PREV NEXT

CAL

EDIT

EXIT

Start step Test

Starts Test

VIEW

CAL

0) EXT ZERO CAL

1) EXT SPAN CAL

2) SYNC OK

ENTR

3) MAINT MODE

4) LANG2 SELECT

NONE

CO2 MEASURE

CO2 REFERENCE

AOUTS CALIBRATED

CAL

<SET

SET>

5) SAMPLE LED

6) CAL LED

7) FAULT LED

8) AUDIBLE BEEPER

9) ELEC TEST

SAMPLE PRESSURE

SAMPLE FLOW

SAMPLE TEMP

BENCH TEMP

SAMPLE LOW = XXX.X MV

SAMPLE LOW = X.X IN-HG-A

SAMPLE HIGH = XXX.X MV

SAMPLE HIGH = X.X IN-HG-A

CONC OUT 1

CONC OUT 2

TEST OUTPUT

10) DARK CAL

WHEEL TEMP²

CHASSIS TEMP

PHT DRIVE

11) ST SYSTEM OK

12) ST CONC VALID

13) ST HIGH RANGE

14) ST ZERO CAL

15) ST SPAN CAL

16) ST DIAG MODE

17) ST SYSTEM OK2

18) ST CONC ALARM 1

19) ST CONC ALARM 2

20) RELAY WATCHDOG

21) WHEEL HEATER

22) BENCH HEATER

23) CAL VALVE

EDIT

OFF

24) SPAN VALVE

25) SHUTOFF VALVE

RANGE

REC OFFSET

AUTO CAL

CALIBRATED

CAL

↓

INTERNAL ANALOG

VOLTAGE SIGNALS

(see Appendix A)

0.1V 1V

5V 10V CURR

46) CONC OUT 1

47) CONC OUT 2

48) TEST OUTPUT

OFF

Only relevant to on M200EH

Only relevant to analyzers with IZS options installed

Figure A-8: Secondary Setup Menu (DIAG)

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Model GFC7000E Instruction Manual

APPENDIX A-2: Setup Variables For Serial I/O, Revision

E.0APPENDIX A-3: Warnings and Test Functions, Revision E.0

APPENDIX A-2: Setup Variables For Serial I/O, Revision E.0

Table A-1:

MGFC7000E Setup Variables, Revision E.0

SETUP VARIABLE

NUMERIC

UNITS

DEFAULT VALUE

VALUE RANGE

DESCRIPTION

STANDARD SETUP VARIABLES

DAS_HOLD_OFF

Minutes

—

0.5–20

Duration of DAS hold off

period.

CONC_PRECISION

AUTO, 0, 1, 2, 3,

Number of digits to display to

the right of the decimal point

for concentrations on the

display.

DYN_ZERO

DYN_SPAN

CLOCK_ADJ

—

OFF

ON, OFF

-60–60

ON enables remote dynamic

zero calibration; OFF disables

it.

ON enables remote dynamic

span calibration; OFF disables

it.

Sec./Day

Time-of-day clock speed

adjustment.

MEDIUM ACCESS LEVEL SETUP VARIABLES

LANGUAGE_SELECT

MAINT_TIMEOUT

—

ENGL

ENGL,

SECD,

EXTN

Selects the language to use

for the user interface.

Hours

0.1–100

Time until automatically

switching out of software-

controlled maintenance

mode.

CONV_TIME

—

33 MS

33 MS, 66 MS,

133 MS,

266 MS,

Conversion time for

measure/reference detector

channel.

533 MS, 1 SEC, 2

SEC

CO_DWELL

CO_SAMPLE

Seconds

Samples

0.2

0.1–30

Dwell time before taking

measure or reference sample.

1–30

Number of samples to take in

measure or reference mode.

3, 8

FILT_SIZE

Samples

750, 200

1–1000

Moving average filter size.

3, 8

FILT_ASIZE

48, 20

4, 15

Moving average filter size in

adaptive mode.

3, 8

FILT_DELTA

FILT_PCT

PPM

1–1000

1–100

Absolute change to trigger

adaptive filter.

Percent change to trigger

adaptive filter.

FILT_DELAY

FILT_ADAPT

Seconds

—

0–180

Delay before leaving adaptive

filter mode.

ON, OFF

1–300

ON enables adaptive filter;

OFF disables it.

CO2_FILT_ADAPT

—

ON enables CO₂adaptive

filter; OFF disables it.

CO2_FILT_SIZE

Samples

CO₂moving average filter

size.

CO2_FILT_ASIZE

1–300

CO₂moving average filter

size in adaptive mode.

CO2_FILT_DELTA

0.5

0.01–10

0.1–100

0–300

Absolute CO₂conc. change to

trigger adaptive filter.

CO2_FILT_PCT

Percent CO₂conc. change to

trigger adaptive filter.

CO2_FILT_DELAY

Seconds

Delay before leaving CO₂

adaptive filter mode.

045840110 Rev B.3

231

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Model GFC7000E Instruction Manual

APPENDIX A-2: Setup Variables For Serial I/O, Revision

E.0APPENDIX A-3: Warnings and Test Functions, Revision E.0

SETUP VARIABLE

NUMERIC

UNITS

DEFAULT VALUE

VALUE RANGE

DESCRIPTION

3, 8

USER_UNITS

DIL_FACTOR

—

PPM

PPB, PPM,

Concentration units for user

interface.

3, 8

UGM, MGM

—

0.1–1000

Dilution factor. Used only if is

dilution enabled with

FACTORY_OPT variable.

DARK_CAL_DURATION

Seconds

180,

10–600

Duration of dark cal. First

two-thirds is stabilization

period; final third is measure

period.

DARK_MEAS_MV

DARK_REF_MV

-1000–1000

1–10000

Dark offset for measure

reading.

Dark offset for reference

reading.

LIN_TARGET_CONC1

Conc

300

Target concentration during

linearity adjustment for range

LIN_NORM_CONC1

LIN_RATIO1

PPM

—

300

0.01–10000

0.01–100

Target concentration during

linearity adjustment

normalized for T/P for range

Measure/reference ratio

measured during linearity

adjustment for range 1.

LIN_CORRECT1

—

0.001–999.999

1–10000

Linearity correction factor for

range 1.

LIN_TARGET_CONC2

Conc

300

Target concentration during

linearity adjustment for range

LIN_NORM_CONC2

LIN_RATIO2

PPM

—

300

0.01–10000

0.01–100

Target concentration during

linearity adjustment

normalized for T/P for range

Measure/reference ratio

measured during linearity

adjustment for range 2.

LIN_CORRECT2

LIN_TARGET_CONC

LIN_NORM_CONC

—

0.001–999.999

1–10000

Linearity correction factor for

range 2.

Conc

PPM

300

Target concentration during

linearity adjustment.

0.01–10000

Target concentration during

linearity adjustment

normalized for T/P.

LIN_RATIO

—

0.01–100

Measure/reference ratio

measured during linearity

adjustment.

LIN_CORRECT

—

0.001–999.999

ON, OFF

Linearity correction factor.

CO2_COMP_ENABLE

OFF

ON enables CO₂

compensation; OFF disables

it.

CO2_COMP_CONC

0–20

CO₂concentration to

compensate for.

3, 8

CO_CONST1

CO_CONST2

—

700, 500 ⁴, 40000

100–50000

0–10

CO calculation constant.

0.13, 0.198 ⁸1.448

⁴,1.458 ¹², 0.187

ET_MEAS_GAIN

ET_REF_GAIN

—

0.0001–9.9999

0–5000

Electrical test gain factor for

measure reading.

Electrical test gain factor for

reference reading.

ET_TARGET_DET

4375

Target detector reading

during electrical test.

045840110 Rev B.3

232

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Model GFC7000E Instruction Manual

APPENDIX A-2: Setup Variables For Serial I/O, Revision

E.0APPENDIX A-3: Warnings and Test Functions, Revision E.0

SETUP VARIABLE

NUMERIC

UNITS

DEFAULT VALUE

VALUE RANGE

DESCRIPTION

3, 8

ET_TARGET_CONC

ET_CONC_RANGE

STD_TEMP

PPM

Conc.

ºK

40, 400

1–10000

0.1–50000

1–500

Target concentration during

electrical test.

3, 8

50, 5000

D/A concentration range

during electrical test.

321

Standard temperature for

temperature compensation.

STD_PRESS

"Hg

ºC

28.5, 28.7 ⁸, 28.8

1–50

Standard pressure for

pressure compensation.

28.1

BENCH_SET

0–100

Optical bench temperature

set point and warning limits.

Warnings: 43–53

WHEEL_SET

ºC

0–100

Wheel temperature set point

and warning limits.

Warnings: 63–73

3, 5, 8

ZERO_ENABLE

—

ON, OFF

OFF, ON

ON enables auto-zero

calibration using scrubber;

OFF disables it.

3, 5, 8

ZERO_FREQ

Minutes

5, 20

0.1–1440

Auto-zero calibration

frequency.

3, 5, 8

ZERO_DWELL

Seconds,

Minutes

7, 5

1–60, 1–30

Dwell time after closing or

opening zero scrubber valve.

3, 5, 8

ZERO_SAMPLES

Samples

Ratio

1–1000

1–100

0–5

Number of zero samples to

average.

3, 5, 8

ZERO_FILT_SIZE

Auto-zero offset moving

average filter size.

3, 5, 8

3, 8

ZERO_LIMIT

1.2, 1.15

Minimum auto-zero ratio

allowed; must be greater

than this value to be valid.

3, 5, 8

ZERO_CAL

Ratio

1.18

0.5–5

Calibrated auto-zero ratio.

3, 8

CO_SPAN1

Conc.

40, 400

1–10000,

1–20000

Target CO concentration

during span calibration of

range 1.

3, 8

CO_SLOPE1

CO_OFFSET1

CO_SPAN2

—

0.001–999.999

-10–10

CO slope for range 1.

CO offset for range 1.

3, 8

Conc.

40, 400

1–10000,

Target CO concentration

during span calibration of

range 2.

3, 8

1–20000

CO_SLOPE2

CO_OFFSET2

RANGE_MODE

—

0.001–999.999

-10–10

CO slope for range 2.

CO offset for range 2.

Range control mode.

SNGL

SNGL, DUAL,

AUTO

3, 8

CONC_RANGE1

Conc.

50, 200 ⁶, 500

0.1–50000

1–15

D/A concentration range 1.

D/A concentration range 2.

3, 8

CONC_RANGE2

CONC_RANGE3

D/A concentration range 3

(CO₂).

045840110 Rev B.3

233

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Model GFC7000E Instruction Manual

APPENDIX A-2: Setup Variables For Serial I/O, Revision

E.0APPENDIX A-3: Warnings and Test Functions, Revision E.0

SETUP VARIABLE

RS232_MODE

NUMERIC

UNITS

DEFAULT VALUE

VALUE RANGE

DESCRIPTION

BitFlag

0–65535

RS-232 COM1 mode flags.

Add values to combine flags.

1 = quiet mode

2 = computer mode

4 = enable security

8 = enable hardware

handshaking

16 = enable Hessen protocol

32 = enable multi-drop

64 = enable modem

128 = ignore RS-232 line

errors

256 = disable XON / XOFF

support

512 = disable hardware

FIFOs

1024 = enable RS-485 mode

2048 = even parity, 7 data

bits, 1 stop bit

4096 = enable command

prompt

BAUD_RATE

—

19200

300, 1200, 2400,

4800,

RS-232 COM1 baud rate.

9600, 19200,

38400, 57600,

115200

MODEM_INIT

“AT Y0 &D0 &H0 &I0

S0=2 &B0 &N6 &M0

Any character in

the allowed

character set. Up

to 100 characters

long.

RS-232 COM1 modem

initialization string. Sent

verbatim plus carriage return

to modem on power up or

manually.

E0 Q1 &W0”

RS232_MODE2

BAUD_RATE2

BitFlag

—

0–65535

RS-232 COM2 mode flags.

(Same settings as

RS232_MODE.)

19200

300, 1200, 2400,

4800, 9600,

RS-232 COM2 baud rate.

19200, 38400,

57600, 115200

MODEM_INIT2

—

“AT Y0 &D0 &H0 &I0

S0=2 &B0 &N6 &M0

Any character in

the allowed

character set. Up

to 100 characters

long.

RS-232 COM2 modem

initialization string. Sent

verbatim plus carriage return

to modem on power up or

manually.

E0 Q1 &W0”

RS232_PASS

MACHINE_ID

Password

940331

0–999999

0–9999

RS-232 log on password.

300, 320

Unique ID number for

instrument.

COMMAND_PROMPT

—

“Cmd> ”

Any character in

the allowed

character set. Up

to 100 characters

long.

RS-232 interface command

prompt. Displayed only if

enabled with RS232_MODE

variable.

045840110 Rev B.3

234

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Model GFC7000E Instruction Manual

APPENDIX A-2: Setup Variables For Serial I/O, Revision

E.0APPENDIX A-3: Warnings and Test Functions, Revision E.0

SETUP VARIABLE

TEST_CHAN_ID

NUMERIC

UNITS

DEFAULT VALUE

VALUE RANGE

DESCRIPTION

—

NONE

NONE,

Diagnostic analog output ID.

CO MEASURE,

CO REFERENCE,

VACUUM

PRESSURE,

SAMPLE

PRESSURE,

SAMPLE FLOW,

SAMPLE TEMP,

BENCH TEMP,

WHEEL TEMP,

CHASSIS TEMP,

PHT DRIVE

REMOTE_CAL_MODE

—

LOW

LOW,

HIGH

Range to calibrate during

contact closure or Hessen

calibration.

PASS_ENABLE

STABIL_GAS

—

OFF

ON, OFF

ON enables passwords; OFF

disables them.

—

CO,

CO2

Selects gas for stability

measurement.

STABIL_FREQ

STABIL_SAMPLES

Seconds

Samples

1–300

Stability measurement

sampling frequency.

2–40

Number of samples in

concentration stability

reading.

PHOTO_TEMP_SET

2000

0–5000

Photometer temperature

warning limits. Set point is

not used.

Warnings: 500–3000

SAMP_PRESS_SET

PURGE_PRESS_SET

SAMP_FLOW_SET

In-Hg

PSIG

cc/m

29.92

Warnings: 15–35

0–100

0–5000

Sample pressure warning

limits. Set point is not used.

7.5

Purge pressure warning

limits. Set point is not used.

Warnings: 2.5–12.5

750, 800 ^{3, 8}, 3000 ⁴,

Sample flow warning limits.

Set point is not used.

2000

Warnings:

500–1000, 500–

1200^3,8

1000–5000⁴,

8,9

400–1000

1500–2500

SAMP_FLOW_SLOPE

VAC_SAMP_RATIO

—

0.001–100

0.1–2

Slope term to correct sample

flow rate.

0.53,

0.61

Maximum vacuum pressure /

sample pressure ratio for

valid sample flow calculation.

SAMP_TEMP_SET

BOX_SET

ºC

0–100

Sample temperature warning

limits. Set point is not used.

Warnings: 10.1–100

Internal box temperature

warning limits. Set point is

not used.

Warnings: 5–48

BENCH_CYCLE

BENCH_PROP

Seconds

1/ºC

0.5–30

0–100

Optical bench temperature

control cycle period.

Optical bench temperature

PID proportional coefficient.

Proportional band is the

reciprocal of this setting.

BENCH_INTEG

—

0.5

0–100

Optical bench temperature

PID integral coefficient.

045840110 Rev B.3

235

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Model GFC7000E Instruction Manual

APPENDIX A-2: Setup Variables For Serial I/O, Revision

E.0APPENDIX A-3: Warnings and Test Functions, Revision E.0

SETUP VARIABLE

NUMERIC

UNITS

DEFAULT VALUE

VALUE RANGE

DESCRIPTION

BENCH_DERIV

WHEEL_CYCLE

WHEEL_PROP

—

0–100

0.5–30

0–100

Optical bench temperature

PID derivative coefficient.

Seconds

1/ºC

4, 2

Wheel temperature control

cycle period.

Wheel temperature PID

proportional coefficient.

Proportional band is the

reciprocal of this setting.

WHEEL_INTEG

WHEEL_DERIV

TPC_ENABLE

—

0.135, 0.035

0–100

Wheel temperature PID

integral coefficient.

0–100

Wheel temperature PID

derivative coefficient.

OFF, ON

ON enables temperature/

pressure compensation; OFF

disables it.

CONC_LIN_ENABLE

SERIAL_NUMBER

—

OFF, ON

ON enables concentration

linearization; OFF disables it.

“00000000 ”

Any character in

the allowed

Unique serial number for

instrument.

character set. Up

to 100 characters

long.

DISP_INTENSITY

—

HIGH

HIGH,

MED,

LOW,

DIM

Front panel display intensity.

I2C_RESET_ENABLE

FACTORY_OPT

—

OFF, ON

ON enables automatic reset

of the I²C bus in the event of

communication failures; OFF

disables automatic reset.

BitFlag

0, 4

0–65535

Factory option flags. Add

values to combine flags.

1 = enable dilution factor

2 = zero/span valves

installed

4 = conc. alarms routed to

relays

8 = enable linearity

adjustment factor

16 = display units in

concentration field

32 = enable software-

controlled maintenance mode

3, 5

= span valve installed

128 = enable switch-

controlled maintenance mode

2048 = enable Internet

option

4096 = use “old” style

numeric data entry menus

when editing conc. table

045840110 Rev B.3

236

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Model GFC7000E Instruction Manual

APPENDIX A-2: Setup Variables For Serial I/O, Revision

E.0APPENDIX A-3: Warnings and Test Functions, Revision E.0

SETUP VARIABLE

CLOCK_FORMAT

NUMERIC

UNITS

DEFAULT VALUE

VALUE RANGE

DESCRIPTION

—

“TIME=%H:%M:%S”

Any character in

the allowed

character set. Up

to 100 characters

long.

Time-of-day clock format

flags. Enclose value in double

quotes (") when setting from

the RS-232 interface.

“%a” = Abbreviated weekday

name.

“%b” = Abbreviated month

name.

“%d” = Day of month as

decimal number (01 – 31).

“%H” = Hour in 24-hour

format (00 – 23).

“%I” = Hour in 12-hour

format (01 – 12).

“%j” = Day of year as

decimal number (001 – 366).

“%m” = Month as decimal

number (01 – 12).

“%M” = Minute as decimal

number (00 – 59).

“%p” = A.M./P.M. indicator

for 12-hour clock.

“%S” = Second as decimal

number (00 – 59).

“%w” = Weekday as decimal

number (0 – 6; Sunday is 0).

“%y” = Year without century,

as decimal number (00 – 99).

“%Y” = Year with century, as

decimal number.

“%%” = Percent sign.

ALARM_TRIGGER^3,4

REF_SDEV_LIMIT

Cycles

1–100

Concentration alarm trigger

sensitivity adjustment.

0.1–500

Reference detector standard

deviation must be below this

limit to switch out of startup

mode.

Enclose value in double quotes (") when setting from the RS-232 interface.

Multi-range modes.

Hessen protocol.

M300EH.

GFC7000E.

M300ES.

Fixed range special.

iCHIP option.

M300EM.

FC7000E.

M306E.

Must power-cycle instrument for these options to take effect.

GFC7000EU.

045840110 Rev B.3

237

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Model GFC7000E Instruction Manual

APPENDIX A-3: Warnings and Test Functions, Revision

E.0APPENDIX A-3: Warnings and Test Functions, Revision E.0

APPENDIX A-3: Warnings and Test Functions, Revision E.0

Table A-2:

GFC7000E Warning Messages, Revision E.0

NAME

WSYSRES

MESSAGE TEXT

DESCRIPTION

Instrument was power-cycled or the CPU was reset.

Data storage was erased.

SYSTEM RESET

DATA INITIALIZED

CONFIG INITIALIZED

WDATAINIT

WCONFIGINIT

Configuration storage was reset to factory configuration

or erased.

WSOURCE

SOURCE WARNING

AZERO WARN 1.001

Reference reading below 1250 mV (50 mV in N₂O, CO₂,

and high level instruments) or above 4950 mV in normal

sample mode.

4, 5

WAUTOZERO

WBENCHTEMP

WWHEELTEMP

Auto-reference ratio below limit specified by ZERO_LIMIT

variable.

BENCH TEMP

WARNING

Bench temperature outside of warning limits specified by

BENCH_SET variable.

WHEEL TEMP

WARNING

Wheel temperature outside of warning limits specified by

WHEEL_SET variable.

WSAMPFLOW

WSAMPPRESS

WSAMPTEMP

WPURGEPRESS

WBOXTEMP

SAMPLE FLOW WARN

SAMPLE PRESS WARN

SAMPLE TEMP WARN

PURGE PRESS WARN

BOX TEMP WARNING

SYNC WARNING

Sample flow outside of warning limits specified by

SAMP_FLOW_SET variable.

Sample pressure outside of warning limits specified by

SAMP_PRESS_SET variable.

Sample temperature outside of warning limits specified

by SAMP_TEMP_SET variable.

Purge pressure outside of warning limits specified by

PURGE_PRESS_SET variable.

Chassis temperature outside of warning limits specified

by BOX_SET variable.

WSYNC

SYNC_OK digital input is off.

WPHOTOTEMP

PHOTO TEMP

WARNING

Photometer temperature outside of warning limits

specified by PHOTO_TEMP_SET variable.

WDYNZERO

WDYNSPAN

CANNOT DYN ZERO

Contact closure zero calibration failed while DYN_ZERO

was set to ON.

CANNOT DYN SPAN

Contact closure span calibration failed while DYN_SPAN

was set to ON.

WREARBOARD

WRELAYBOARD

WFRONTPANEL

WANALOGCAL

REAR BOARD NOT DET

RELAY BOARD WARN

FRONT PANEL WARN

Rear board was not detected during power up.

Firmware is unable to communicate with the relay board.

Firmware is unable to communicate with the front panel.

ANALOG CAL WARNING The A/D or at least one D/A channel has not been

calibrated.

045840110 Rev B.3

238

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Model GFC7000E Instruction Manual

Table A-3:

GFC7000E Test Functions, Revision

E.0APPENDIX A-3: Warnings and Test Functions, Revision E.0

Table A-3:

GFC7000E Test Functions, Revision E.0

TEST FUNCTION

NAME¹

MESSAGE TEXT

DESCRIPTION

RANGE

RANGE=50.0 PPM ³

CO RANGE=50.0 PPM ^{3, 7}

D/A range in single or auto-range modes.

RANGE1

RANGE2

RANGE1=50.0 PPM ³

D/A #1 range in dual range mode.

D/A #2 range in dual range mode.

D/A #3 range.

CO RANGE1=50.0 PPM ^{3, 7}

RANGE2=50.0 PPM ³

CO RANGE2=50.0 PPM ^{3, 7}

CO2 RANGE=50.0 PPM ^{3, 7}

RANGE3

STABILITY

STABIL=0.0 PPM ³

CO/CO2 STB=0.0 PPM ^3,7

Concentration stability (standard deviation based on setting of

STABIL_FREQ and STABIL_SAMPLES).

RESPONSE ²

RSP=0.20(0.00) SEC

Instrument response. Length of each signal processing loop.

Time in parenthesis is standard deviation.

COMEAS

COREF

CO MEAS=4125.0 MV

CO REF=3750.0 MV

MR RATIO=1.100

Detector measure reading.

Detector reference reading.

Measure/reference ratio.

Measure/reference ratio during auto-reference.

Sample pressure.

MRRATIO

4, 5

AUTOZERO

AZERO RATIO=1.234

PRES=29.9 IN-HG-A

PURGE=7.5 PSIG

SAMPPRESS

PURGEPRESS

Purge pressure

VACUUM

VAC=6.8 IN-HG-A

SAMP FL=751 CC/M

SAMPLE TEMP=26.8 C

BENCH TEMP=48.1 C

WHEEL TEMP=68.1 C

BOX TEMP=26.8 C

PHT DRIVE=2500.0 MV

SLOPE=1.000

Vacuum pressure.

SAMPFLOW

Sample flow rate.

SAMPTEMP

BENCHTEMP

WHEELTEMP

BOXTEMP

Sample temperature.

Bench temperature.

Wheel temperature.

Internal chassis temperature.

Photometer temperature.

PHOTOTEMP

COSLOPE

CO slope for current range, computed during zero/span

calibration.

CO SLOPE=1.000

COOFFSET

OFFSET=0.000

CO offset for current range, computed during zero/span

calibration.

CO OFFSET=0.000

CO2SLOPE

CO2 SLOPE=1.000

CO₂slope for current range, computed during zero/span

calibration.

CO2OFFSET

CO2 OFFSET=0.000

CO₂offset for current range, computed during zero/span

calibration.

CO2

CO=17.7 PPM ³

CO2=15.0 % ⁷

CO concentration for current range.

CO₂concentration for current range.

TESTCHAN

TEST=1751.4 MV

Value output to TEST_OUTPUT analog output, selected with

TEST_CHAN_ID variable.

CLOCKTIME

TIME=09:52:20

Current instrument time of day clock.

The name is used to request a message via the RS-232 interface, as in “T BOXTEMP”.

Engineering software.

Current instrument units.

M300ES.

M300EH.

Except GFC7000EU (APR version).

M306E.

Sample pressure or differential pressure flow measurement option.

GFC7000E.

045840110 Rev B.3

239

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Model 360E Instruction Manual

APPENDIX A-4: MGFC7000E Signal I/O Definitions, Revision E.0

Table A-4:

GFC7000E Signal I/O Definitions, Revision E.0

SIGNAL NAME

BIT OR CHANNEL

NUMBER

DESCRIPTION

1 = sync. OK

SYNC_OK

0 = sync. error

1–7

Spare

Internal outputs, U8, J108, pins 1–8 = bits 0–7, default I/O

ELEC_TEST

DARK_CAL

1 = electrical test on

0 = off

1 = dark calibration on

0 = off

2–5

Spare

I2C_RESET

1 = reset I2C peripherals

0 = normal

I2C_DRV_RST

0 = hardware reset 8584 chip

1 = normal

Control inputs, U11, J1004, pins 1–6 = bits 0–5, default I/O address 321 hex

EXT_ZERO_CAL

0 = go into zero calibration

1 = exit zero calibration

EXT_SPAN_CAL

0 = go into span calibration

1 = exit span calibration

REMOTE_RANGE_HI

0 = remote select high range

1 = default range

3–5

6–7

Spare

Always 1

Control inputs, U14, J1006, pins 1–6 = bits 0–5, default I/O

0–5

6–7

Spare

Always 1

Control outputs, U17, J1008, pins 1–8 = bits 0–7, default I/

0–7 Spare

Control outputs, U21, J1008, pins 9–12 = bits 0–3, default I/

0–3 Spare

Alarm outputs, U21, J1009, pins 1–12 = bits 4–7, default I/O

ST_SYSTEM_OK2

1 = system OK

0 = any alarm condition or in diagnostics mo

ST_CONC_ALARM_1

1 = conc. limit 1 exceeded

0 = conc. OK

2 + 8

ST_CONC_ALARM_2

1 = conc. limit 2 exceeded

0 = conc. OK

2 + 8

Spare

A status outputs, U24, J1017, pins 1–8 = bits 0–7, default I/

ST_SYSTEM_OK

ST_CONC_VALID

ST_HIGH_RANGE

ST_ZERO_CAL

0 = system OK

1 = any alarm condition

0 = conc. valid

1 = hold off or other conditions

0 = high auto-range in use

1 = low auto-range

0 = in zero calibration

1 = not in zero

045840110 Rev B.3

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Model 360E Instruction Manual

APPENDIX A-4: MGFC7000E Signal I/O Definitions, Revision E.0

SIGNAL NAME

BIT OR CHANNEL

NUMBER

DESCRIPTION

ST_SPAN_CAL

0 = in span calibration

1 = not in span

ST_DIAG_MODE

0 = in diagnostic mode

1 = not in diagnostic mode

ST_CONC_ALARM_1

0 = conc. limit 1 exceeded

1 = conc. OK

ST_CONC_ALARM_2

0 = conc. limit 2 exceeded

1 = conc. OK

B status outputs, U27, J1018, pins 1–8 = bits 0–7, default I/

2, 3

ST_AUTO_REF

0 = in auto-reference mode

1 = not in auto-reference mode

1–7

Spare

Front panel I²C keyboard, default I²C address 4

MAINT_MODE

LANG2_SELECT

SAMPLE_LED

CAL_LED

5 (input)

6 (input)

0 = maintenance mode

1 = normal mode

0 = select second language

1 = select first language (English)

8 (output)

9 (output)

0 = sample LED on

1 = off

0 = cal. LED on

1 = off

FAULT_LED

10 (output)

14 (output)

0 = fault LED on

1 = off

AUDIBLE_BEEPER

0 = beeper on (for diagnostic testing only)

1 = off

Relay board digital output (PCF8574), default I²C add

RELAY_WATCHDOG

WHEEL_HTR

Alternate between 0 and 1 at least every 5 se

relay board active

0 = wheel heater on

1 = off

BENCH_HTR

0 = optical bench heater on

1 = off

O2_CELL_HEATER

0 = O₂sensor cell heater on

1 = off

CAL_VALVE

SPAN_VALVE

0 = let cal. gas in

1 = let sample gas in

0 = let span gas in

1 = let zero gas in

ZERO_SCRUB_VALV

0 = open zero scrubber valve

1 = close

SHUTOFF_VALVE

IR_SOURCE_ON

0 = energize shutoff valve

1 = de-energize

0 = IR source on

1 = off

Rear board primary MUX analog inputs

SAMPLE_PRESSURE

Sample pressure

Vacuum pressure

Purge pressure

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Model 360E Instruction Manual

APPENDIX A-4: MGFC7000E Signal I/O Definitions, Revision E.0

SIGNAL NAME

BIT OR CHANNEL

NUMBER

DESCRIPTION

CO_MEASURE

Detector measure reading

Detector reference reading

Temperature MUX

CO_REFERENCE

SAMPLE_FLOW

PHOTO_TEMP

TEST_INPUT_7

TEST_INPUT_8

REF_4096_MV

Sample flow

Photometer detector temperature

Diagnostic test input

4.096V reference from MAX6241

O₂concentration sensor

Spare

O2_SENSOR

CO2_SENSOR

CO₂concentration sensor

Spare

DAC loopback MUX

REF_GND

Ground reference

Rear board temperature MUX analog input

Internal box temperature

Sample temperature

BOX_TEMP

SAMPLE_TEMP

BENCH_TEMP

WHEEL_TEMP

TEMP_INPUT_4

TEMP_INPUT_5

O2_CELL_TEMP

Optical bench temperature

Wheel temperature

Diagnostic temperature input

O₂sensor cell temperature

Spare

Rear board DAC MUX analog inputs

DAC channel 0 loopback

DAC channel 1 loopback

DAC channel 2 loopback

DAC channel 3 loopback

Rear board analog outputs

Concentration output #1

Concentration output #2

Test measurement output

Concentration output #3 (CO₂)

DAC_CHAN_0

DAC_CHAN_1

DAC_CHAN_2

DAC_CHAN_3

CONC_OUT_1

CONC_OUT_2

TEST_OUTPUT

CONC_OUT_3

Hessen protocol.

M300EH.

M300ES.

M320E.

O₂option.

Sample pressure or differential pressure flow measurement option.

M306E.

Factory option enables concentration alarms on relay outputs.

GFC7000E.

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Model 360E Instruction Manual

APPENDIX A-5: GFC7000E iDAS Functions, Revision E.0

Table A-5:

MGFC7000E DAS Trigger Events, Revision E.0

NAME

ATIMER

EXITZR

EXITSP

EXITMP

EXITC2 ⁵

SLPCHG

DESCRIPTION

Automatic timer expired

Exit zero calibration mode

Exit span calibration mode

Exit multi-point calibration mode

Exit CO2 calibration mode

Slope and offset recalculated

CO2 slope and offset recalculated

Exit diagnostic mode

CO2SLP

EXITDG

SOURCW

Source warning

1, 2

AZEROW

Auto-zero warning

CONCW1 ^{1, 3, 4}

Concentration limit 1 exceeded

Concentration limit 2 exceeded

Sync warning

1, 3, 4

CONCW2

SYNCW

BNTMPW

WTEMPW

STEMPW

Bench temperature warning

Wheel temperature warning

Sample temperature warning

Sample flow warning

SFLOWW

SPRESW

Sample pressure warning

Purge pressure warning

PPRESW

BTEMPW

PTEMPW

Box temperature warning

Photometer detector temperature warning

M300EH.

M300ES.

M320E.

GFC7000E.

M306E.

Except GFC7000EU (APR version).

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Model 360E Instruction Manual

APPENDIX A-5: GFC7000E iDAS Functions, Revision E.0

Table A-6:

NAME

MGFC7000E iDAS Functions, Revision E.0

DESCRIPTION

UNITS

DETMES

DETREF

RATIO

Detector measure reading

Detector reference reading

M/R ratio.

None

SLOPE1

SLOPE2

Slope for range #1

Slope for range #2

CO₂slope

CO2SLP

OFSET1

OFSET2

CO2OFS

Offset for range #1

Offset for range #2

CO₂offset

1,2

AZERO

Auto-zero reading

M/R

ZSCNC1

Concentration for range #1 during zero/span calibration, just before

computing new slope and offset

PPM

ZSCNC2

Concentration for range #2 during zero/span calibration, just before

computing new slope and offset

PPM

CO2ZSC

CO₂concentration during zero/span calibration, just before

computing new slope and offset

CONC1

CONC2

Concentration for range #1

Concentration for range #2

CO₂concentration

PPM

CO2CNC

STABIL

Concentration stability

PPM

°C

BNTEMP

WTEMP

SMPTMP

Bench temperature

Wheel temperature

°C

Sample temperature

°C

SMPFLW

SMPPRS

Sample flow

cc/m

"Hg

PSIG

°C

Sample pressure

1, 3, 6

VACUUM

PRGPRS

Vacuum pressure

Purge pressure

BOXTMP

PHTDRV

TEST7

Internal box temperature

Photometer detector temperature drive

Diagnostic test input (TEST_INPUT_7)

Diagnostic test input (TEST_INPUT_8)

Diagnostic temperature input (TEMP_INPUT_4)

Diagnostic temperature input (TEMP_INPUT_5)

Ground reference (REF_GND)

4096 mV reference (REF_4096_MV)

Bench temperature control duty cycle

°C

TEST8

TEMP4

TEMP5

°C

REFGND

RF4096

BNCDTY

Fraction

0 = off,

1 = on

WHLDTY

Wheel temperature control duty cycle

Fraction

M300EH.

M300ES.

M320E.

GFC7000E.

M306E.

Except GFC7000EU (APR version).

The units, including the concentration units, are always fixed, regardless of the current instrument

units.

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Model 360E Instruction Manual

APPENDIX A-6: Terminal Command Designators, Revision E.0

Table A-7: Terminal Command Designators, Revision E.0

COMMAND

? [ID]

ADDITIONAL COMMAND SYNTAX

DESCRIPTION

Display help screen and commands list

Establish connection to instrument

Terminate connection to instrument

Display test(s)

LOGON [ID]

LOGOFF [ID]

password

SET ALL|name|hexmask

LIST [ALL|name|hexmask] [NAMES|HEX]

name

Print test(s) to screen

Print single test

T [ID]

CLEAR ALL|name|hexmask

SET ALL|name|hexmask

LIST [ALL|name|hexmask] [NAMES|HEX]

name

Disable test(s)

Display warning(s)

Print warning(s)

W [ID]

Clear single warning

CLEAR ALL|name|hexmask

ZERO|LOWSPAN|SPAN [1|2]

ASEQ number

Clear warning(s)

Enter calibration mode

Execute automatic sequence

Compute new slope/offset

Exit calibration mode

C [ID]

COMPUTE ZERO|SPAN

EXIT

ABORT

Abort calibration sequence

Print all I/O signals

LIST

name[=value]

Examine or set I/O signal

Print names of all diagnostic tests

Execute diagnostic test

Exit diagnostic test

LIST NAMES

ENTER name

EXIT

RESET [DATA] [CONFIG] [exitcode]

PRINT ["name"] [SCRIPT]

RECORDS ["name"]

Reset instrument

D [ID]

Print iDAS configuration

Print number of iDAS records

REPORT ["name"] [RECORDS=number]

[FROM=<start date>][TO=<end

date>][VERBOSE|COMPACT|HEX] (Print DAS

records)(date format: MM/DD/YYYY(or YY)

[HH:MM:SS]

Print iDAS records

CANCEL

Halt printing iDAS records

Print setup variables

LIST

name[=value [warn_low [warn_high]]]

name="value"

Modify variable

Modify enumerated variable

Print instrument configuration

Enter/exit maintenance mode

Print current instrument mode

Upload iDAS configuration

Upload single iDAS channel

Delete iDAS channels

V [ID]

CONFIG

MAINT ON|OFF

MODE

DASBEGIN [<data channel definitions>] DASEND

CHANNELBEGIN propertylist CHANNELEND

CHANNELDELETE ["name"]

The command syntax follows the command type, separated by a space character. Strings in [brackets] are

optional designators. The following key assignments also apply.

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Model 360E Instruction Manual

APPENDIX A-6: Terminal Command Designators, Revision E.0

Table A-8:

Terminal Key Assignments, Revision E.0

TERMINAL KEY ASSIGNMENTS

ESC

Abort line

CR (ENTER)

Execute command

Ctrl-C

Switch to computer mode

COMPUTER MODE KEY ASSIGNMENTS

LF (line feed)

Ctrl-T

Execute command

Switch to terminal mode

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Model 360E Instruction Manual

APPENDIX A-6: Terminal Command Designators, Revision E.0

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Model GFC7000E Instruction Manual

APPENDIX B - GFC7000E Spare Parts List

NOTE

The spare parts list for the Model GFC7000E is currently being compiled.

For information is spare parts please contact Teledyne Analytical Instruments customer

service department at

16830 Chestnut St., City of Industry, Ca. 91748

Phone: +1 626 961-9221 or 1-626-934-1500.

Fax: +1 626-961-2538

Email: [email protected].

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Model GFC7000E Instruction Manual

Appendix C - Repair Questionnaire - GFC7000E

Company: _________________________ Contact Name: _____________________________

Phone Number: ___________ Fax Number: _____________ Email: ____________________

Site Address: __________________________________________________________________

Can we connect to the instrument? If so, provide IP address or modem #:___________________

Model GFC7000E Serial Number:_________________ Firmware revision: _________________

The serial number can be found on the back of the instrument, the firmware revision is displayed in the upper left corner of the

display when pressing SETUP on the front panel (Example: C.3).

1. List all front panel error/warning messages:_________________________________________

______________________________________________________________________________

2. Please complete the following table: (Depending on options installed, not all test parameters

shown below may be available in your instrument)

RECORDED

VALUE

ACCEPTABLE

VALUE

RECORDED

VALUE

ACCEPTABLE

VALUE

PARAMETER

RANGE

STABIL

ppb/ppm 50 ppb - 20 ppm

SLOPE

1.0 ± 0.3

< 250

ppb ≤ 1 ppb with zero

OFFSET

air

SAMP FL

cm³/min

500 ± 50

HVPS

5500-900

PMT SIGNAL

WITH ZERO

AIR

-20 to 150

ETEST

2000 ± 1000

PMT SIGNAL

SPAN GAS

CONC

ppb/ppm

0-5000

0-20 000 ppb

OTEST

°C

2000 ± 1000

50 ± 1

NORM PMT

ppb/ppm

0-5000

0-20 000 ppb

RCELL TEMP

SPAN GAS

CONC

UV LAMP

STR. LGT

mV 2 000 to 4 000

BOX TEMP

PMT TEMP

°C Ambient + ~5

ppm ≤ 100 ppb/ zero

°C

7 ± 2

air

DARK PMT

-50 to 200

IZS TEMP

°C

50 ± 3

DARK LAMP

3. Has the analyzer been checked for leaks? Yes

For proper flows? Yes

4. What are the failure symptoms? _________________________________________________

______________________________________________________________________________

______________________________________________________ Continue on back if necessary

5. Which tests have you done trying to solve the problem? _______________________________

________________________________________________________ Continue on back if necessary

6. If possible, fax a portion of a strip chart or email a data file to customer service.

CUSTOMER SERVICE CONTACT INFORMATION: 16830 Chestnut St., City of Industry, Ca. 91748

PHONE: +1 626-961-9221 or 1-626-934-1500. FAX: +1 626-961-2538.

EMAIL: [email protected].

You can access and submit an online version of this form at http://www.teledyne-api.com/forms/csformGFC7000E.asp

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Notes and further information: _____________________________________________________

______________________________________________________________________________

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Model GFC7000E Instruction Manual

APPENDIX D - ELECTRONIC SCHEMATICS

Table D-1:

List of Included Electronic Schematics

DOCUMENT # DOCUMENT TITLE

04217

04216

04136

03297

04070

03632

03976

04259

04003

04089

04468

Interconnect List - M300E SNs >=100

Interconnect Drawing - M300E SNs >=100

PCA, 04135 Rev A, M300E Relay

PCA, 03296, IR Photodetector Preamp and Sync Demodulator

PCA, 04069, Motherboard, E-series

PCA, 03631, 0-20mA driver

PCA, 03975, Keyboard & Display Driver

PCA, 04258, Keyboard & Display Driver

PCA, 04003, Pressure/Flow Transducer Interface

PCA, 04088, Opto Pickup Interface

PCA, 04467, Analog Output Series Res

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Model GFC7000E Instruction Manual

User Notes

04584 Rev A1

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