Emerson Oxymitter 4000 Instruction manual

Instruction Manual
IM-106-340, Rev 4.0
February 2006
Oxymitter 4000
Oxygen Transmitter
http://www.raihome.com
Instruction Manual
IM-106-340, Rev 4.0
February 2006
Oxymitter 4000
Table of Contents
Essential Instructions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . i
SECTION i
Introduction
Preface. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . iv
Definitions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . iv
Symbols . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . iv
What You Need To Know. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . v
Can You Use the Quick Start Guide? . . . . . . . . . . . . . . . . . . . . . . . . . .vii
Quick Start Guide for Oxymitter 4000 Systems . . . . . . . . . . . . . . . . . . viii
Quick Reference Guide Manual Calibration Instructions . . . . . . . . . . . . ix
HART Communicator Fast Key Sequences . . . . . . . . . . . . . . . . . . . . . . x
SECTION 1
Description and
Specifications
Component Checklist . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-1
System Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-1
Scope . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-1
System Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .1-3
System Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-4
System Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-4
Handling the
Oxymitter 4000 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .1-8
System Considerations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .1-9
IMPS 4000 (Optional). . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-12
SPS 4001B (Optional) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-12
Mounting . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-12
Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-12
Model 751 Remote Powered Loop LCD Display . . . . . . . . . . . . . . . . 1-13
Probe Options . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .1-13
Diffusion Elements . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-13
Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-16
SECTION 2
Installation
Mechanical Installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .2-2
Selecting Location. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-2
Probe Installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-2
Remote Electronics Installation. . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-9
Electrical Installation (with Integral Electronics) . . . . . . . . . . . . . . . . .2-10
Electrical Installation (with Remote Electronics) . . . . . . . . . . . . . . . . 2-13
Install Interconnecting Cable. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-16
Pneumatic Installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-16
IMPS 4000 Connections . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-18
SPS 4001B Connections . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-18
SECTION 3
Configuration of
Oxymitter 4000
with Membrane
Keypad
Verify Installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-1
Mechanical Installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-1
Terminal Block Wiring . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-1
Oxymitter 4000 Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-2
Logic I/O . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-5
Recommended Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-6
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Instruction Manual
Oxymitter 4000
IM-106-340, Rev 4.0
February 2006
SECTION 4
Configuration of
Oxymitter 4000 with LOI
Verify installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-1
Mechanical Installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-1
Terminal Block Wiring. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-1
Oxymitter 4000 Configuration. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-2
Logic I/O . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-4
Recommended Configuration. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-6
SECTION 5
Startup and Operation of
Oxymitter 4000 with
Membrane Keypad
Power Up . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-1
Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-2
Overview. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-2
SECTION 6
Startup and Operation of
Oxymitter 4000 with LOI
Power Up . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-1
Start Up Oxymitter 4000 Calibration . . . . . . . . . . . . . . . . . . . . . . . . . . 6-3
Navigating the Local Operator Interface . . . . . . . . . . . . . . . . . . . . . . . 6-3
Overview. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-3
Lockout . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-3
LOI Key Designations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-4
LOI Menu Tree. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-4
Oxymitter 4000 Setup at the LOI . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-6
LOI Installation. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-9
Oxymitter 4000 Test Points . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-10
Remote Powered Loop LCD Display (Optional) . . . . . . . . . . . . . . . . 6-10
SECTION 7
HART/AMS
Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7-1
HART Communicator Signal Line Connections. . . . . . . . . . . . . . . . . . 7-2
HART Communicator PC Connections . . . . . . . . . . . . . . . . . . . . . . . . 7-2
Off-Line and On-Line Operations. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7-4
Logic I/O Configurations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7-4
HART/AMS Menu Tree . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7-4
HART Communicator O2 Cal Method . . . . . . . . . . . . . . . . . . . . . . . . . 7-8
Defining a Timed Calibration via HART . . . . . . . . . . . . . . . . . . . . . . . . 7-9
D/A Trim Procedure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7-9
SECTION 8
Troubleshooting
Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8-1
General . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8-3
Alarm Indications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8-3
Alarm Contacts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8-4
Identifying And Correcting Alarm Indications. . . . . . . . . . . . . . . . . . . . 8-5
Calibration Passes, but Still Reads Incorrectly . . . . . . . . . . . . . . . . . 8-22
SECTION 9
Maintenance and Service
Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9-1
Calibration with Keypad . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9-1
Automatic Calibration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9-2
Semi-Automatic Calibration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9-3
Manual Calibration with Membrane Keypad. . . . . . . . . . . . . . . . . . 9-3
Calibration with LOI . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9-5
Oxymitter 4000 Repair. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9-7
Removal and Replacement of Probe . . . . . . . . . . . . . . . . . . . . . . . 9-7
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Instruction Manual
IM-106-340, Rev 4.0
February 2006
Oxymitter 4000
SECTION 10
Replacement Parts
Probe Replacement Parts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10-1
Electronics Replacement Parts . . . . . . . . . . . . . . . . . . . . . . . . . . . . .10-6
SECTION 11
Optional
Accessories
HART Handheld 375 Communicator . . . . . . . . . . . . . . . . . . . . . . . . . 11-1
Asset Management Solutions (AMS) . . . . . . . . . . . . . . . . . . . . . . . . . 11-2
By-Pass Packages . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11-2
IMPS 4000 Intelligent Multiprobe Test gas Sequencer . . . . . . . . . . . 11-3
SPS 4001B Single Probe Autocalibration Sequencer . . . . . . . . . . . . 11-4
O2 Calibration Gas . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11-5
Catalyst Regeneration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11-6
Oxy Balance Display and Averaging System . . . . . . . . . . . . . . . . . . . 11-6
APPENDIX A
Safety Data
Safety Instructions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . A-2
Safety Data Sheet for Ceramic Fiber Products . . . . . . . . . . . . . . . . A-15
APPENDIX B
Return of Material
Returning Material . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . B-1
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Oxymitter 4000
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IM-106-340, Rev 4.0
February 2006
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Oxymitter Oxygen Transmitters
READ THIS PAGE BEFORE PROCEEDING!
ESSENTIAL
INSTRUCTIONS
Emerson Process Management designs, manufactures and tests its products
to meet many national and international standards. Because these
instruments are sophisticated technical products, you MUST properly
install, use, and maintain them to ensure they continue to operate within
their normal specifications. The following instructions MUST be adhered to
and integrated into your safety program when installing, using, and
maintaining Rosemount Analytical products. Failure to follow the proper
instructions may cause any one of the following situations to occur: Loss of
life; personal injury; property damage; damage to this instrument; and
warranty invalidation.
• Read all instructions prior to installing, operating, and servicing the
product.
• If you do not understand any of the instructions, contact your
Rosemount Analytical representative for clarification.
• Follow all warnings, cautions, and instructions marked on and
supplied with the product.
• Inform and educate your personnel in the proper installation,
operation, and maintenance of the product.
• Install your equipment as specified in the Installation Instructions
of the appropriate Instruction Manual and per applicable local and
national codes. Connect all products to the proper electrical and
pressure sources.
• To ensure proper performance, use qualified personnel to install,
operate, update, program, and maintain the product.
• When replacement parts are required, ensure that qualified people use
replacement parts specified by Rosemount Analytical. Unauthorized
parts and procedures can affect the product's performance, place the
safe operation of your process at risk, and VOID YOUR WARRANTY.
Look-alike substitutions may result in fire, electrical hazards, or
improper operation.
• Ensure that all equipment doors are closed and protective covers
are in place, except when maintenance is being performed by
qualified persons, to prevent electrical shock and personal injury.
The information contained in this document is subject to change without
notice.
If a Model 275/375 Universal HART® Communicator is used with this unit, the software
within the Model 275/375 may require modification. If a software modification is required,
please contact your local Rosemount Analytical Service Group or National Response
Center at 1-800-433-6076 or 1-888-433-6829.
http://www.processanalytic.com
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Section i
Oxymitter 4000
Introduction
Preface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page iv
Definitions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page iv
Symbols . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page iv
What You Need To Know . . . . . . . . . . . . . . . . . . . . . . . . . . page v
Can You Use the Quick Start Guide? . . . . . . . . . . . . . . . . page vii
Quick Start Guide for Oxymitter 4000 Systems . . . . . . . . page viii
Quick Reference Guide Manual Calibration Instructions page ix
HART Communicator Fast Key Sequences . . . . . . . . . . . page x
http://www.processanalytic.com
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
PREFACE
The purpose of this manual is to provide information concerning the
components, functions, installation and maintenance of the Oxymitter 4000
Oxygen Transmitter.
Some sections may describe equipment not used in your configuration. The
user should become thoroughly familiar with the operation of this module
before operating it. Read this instruction manual completely.
DEFINITIONS
The following definitions apply to WARNINGS, CAUTIONS, and NOTES
found throughout this publication.
Highlights an operation or maintenance procedure, practice, condition, statement, etc. If not
strictly observed, could result in injury, death, or long-term health hazards of personnel.
Highlights an operation or maintenance procedure, practice, condition, statement, etc. If not
strictly observed, could result in damage to or destruction of equipment, or loss of
effectiveness.
NOTE
Highlights an essential operating procedure, condition, or statement.
SYMBOLS
: EARTH (GROUND) TERMINAL
: PROTECTIVE CONDUCT OR TERMINAL
: RISK OF ELECTRICAL SHOCK
: WARNING: REFER TO INSTRUCTION MANUAL
NOTE TO USERS
The number in the lower right corner of each illustration in this publication is a
manual illustration number. It is not a part number, and is not related to the
illustration in any technical manner.
iv
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
WHAT YOU NEED TO
KNOW
Highlights an operation or maintenance procedure, practice, condition, statement, etc. If not
strictly observed, could result in injury, death, or long-term health hazards of personnel.
BEFORE INSTALLING AND WIRING A ROSEMOUNT ANALYTICAL
OXYMITTER 4000 OXYGEN TRANSMITTER
1. What type of installation does your system require?
Use the following drawings, Figure 1 and Figure 2, to identify which type
of installation is required for your Oxymitter 4000 system.
Figure 1. Installation Options Oxymitter 4000 with Integral
Electronics
OXYMITTER 4000
Line Voltage
4-20 mA
Cal. Gas
Instr. Air (Ref. Air)
OXYMITTER 4000 WITH
SPS 4001B
Line Voltage
4-20 mA
SPS
4001B
Line Voltage
Cal. Gas 1
Cal. Gas 2
Instr. Air (Ref. Air)
LOGIC I/O
Cal. Gas
Ref. Air
OXYMITTER 4000 WITH REMOTE
IMPS 4000 OPTION
Line Voltage
4-20 mA
LOGIC I/O
Cal. Gas
Ref. Air
Line Voltage
Cal. Gas 1
Cal. Gas 2
Instr. Air (Ref. Air)
37260001
IMPS
4000
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Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 2. Installation Options Oxymitter 4000 with Remote
Electronics
OXYMITTER 4000
Line Voltage
4-20 mA
Cal. Gas
Instr. Air (Ref. Air)
OXYMITTER 4000 WITH
REMOTE ELECTRONICS
AND SPS 4001B
Line Voltage
4-20 mA
Logic I/O
Calibration Gas
Reference Air
Cal. Gas 2
Cal. Gas 1
Instr. Air
SPS
4001B
OXYMITTER 4000 WITH
REMOTE ELECTRONICS
AND IMPS
Line Voltage
4-20 mA
Logic I/O
Reference Air
Cal. Gas 2
Cal. Gas 1
Instr. Air
vi
IMPS
4000
37260049
Calibration Gas
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
CAN YOU USE THE
QUICK START GUIDE?
Oxymitter 4000
Use this Quick Start Guide if...
1. Your system requires an Oxymitter 4000 with or without the SPS 4001B
OPTION. Installation options for the Oxymitter 4000 are shown in
Figure 1.
2. Your system does NOT require an IMPS 4000 OPTION installation.
3. Your system does NOT use a Remote Electronics as shown in Figure 2.
4. You are familiar with the installation requirements for the Oxymitter 4000
Oxygen Transmitter. You are familiar with the installation requirements
for the Oxymitter 4000 Oxygen Transmitter with a SPS 4001B.
If you cannot use the Quick Start Guide, turn to Section 2: Installation, in
this Instruction Manual.
vii
Instruction Manual
Oxymitter 4000
QUICK START GUIDE
FOR OXYMITTER 4000
SYSTEMS
IM-106-340, Rev. 4.0
February 2006
Before using the Quick Start Guide, please read "WHAT YOU NEED TO
KNOW BEFORE INSTALLING AND WIRING A ROSEMOUNT
ANALYTICAL OXYMITTER 4000 OXYGEN TRANSMITTER" on the
preceding page.
1. Install the Oxymitter 4000 in an appropriate location on the stack or
duct. Refer to "Selecting Location" in Section 2: Installation, for
information on selecting a location for the Oxymitter 4000.
2. If using an SPS 4001B, connect the calibration gasses to the
appropriate fittings on the SPS 4001B manifold.
3. Connect reference air to the Oxymitter 4000 or SPS 4001B, as
applicable.
4. If using an SPS 4001B, make the wiring connections as shown in the
SPS 4001B Single Probe Autocalibration Sequencer Instruction
Manual.
5. If NOT using an SPS 4001B, make the following wire connections as
shown in Figure 3: line voltage, 4-20 mA, and logic I/O.
6. Verify the Oxymitter 4000 switch configuration is as desired. Refer to
"Oxymitter 4000 Configuration", "SW1 Setting", and "SW2 Setting" all in
Section 3: Configuration of Oxymitter 4000 with Membrane Keypad, or
"Oxymitter 4000 Configuration", "SW1 Setting", and "SW2 Setting" all in
Section 4: Configuration of Oxymitter 4000 with LOI.
7. Apply power to the Oxymitter 4000; the cell heater will turn on. Allow
approximately one half hour for the cell to heat to operating
temperature. Once the ramp cycle has completed and the
Oxymitter 4000 is at normal operation, proceed with step 8 or 9.
8. If using an SPS 4001B, initiate a semi-automatic calibration.
9. If NOT using an SPS 4001B, perform a manual calibration. Refer to
"Calibration with Keypad" or "Calibration with LOI" both in Section 9:
Maintenance and Service, in this instruction manual.
NOTE
If your system has a membrane keypad you can refer to the Quick Start Guide
on the following pages.
viii
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 3. Oxymitter 4000 without
SPS 4001B Wiring Diagram
Terminal
Block
AC Line
Voltage Port
AC Terminal
Cover
Line Voltage
(85 to 264 VAC)
AC
L1
AC
N
Ground
Lugs
+
Logic I/O
+
4-20 mA
Signal
4-20
Left Side of
Oxymitter 4000
QUICK REFERENCE
GUIDE MANUAL
CALIBRATION
INSTRUCTIONS
Signal
Port
29770003
-
Performing a Manual Calibration with a Membrane Keypad
1. Place the control loop in manual.
2. Press the CAL key. The CAL LED will light solid.
3. Apply the first calibration gas.
4. Press the CAL key. When the unit has taken the readings using the first
calibration gas, the CAL LED will flash continuously.
5. Remove the first calibration gas and apply the second calibration gas.
6. Push the CAL key. The CAL LED will light solid. When the unit has
taken the readings using the second calibration gas, the CAL LED will
flash a two-pattern flash or a three-pattern flash. A two-pattern flash
equals a valid calibration, three-pattern flash equals an invalid
calibration.
7. Remove the second calibration gas and cap off the calibration gas port.
8. Press the CAL key. The CAL LED will be lit solid as the unit purges.
When the purge is complete, the CAL LED will turn off.
9. If the calibration was valid, the DIAGNOSTIC ALARMS LEDs indicate
normal operation. If the new calibration values are not within the
parameters, the DIAGNOSTIC ALARMS LEDs will indicate an alarm.
10. Place the control loop in automatic.
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Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Perform Calibration
2
3
1
O2 Upper Range Value
1
3
Trim Analog Output
2
3
4
1
1
Analog Output Lower Range Value
3
Toggle Analog Output Tracking
2
2
2
View O2 Value
2
1
1
View Analog Output
1
2
2
1
1
38330001
HART COMMUNICATOR
FAST KEY SEQUENCES
Technical Support Hotline:
For assistance with technical problems, please call the Customer Support
Center (CSC). The CSC is staffed 24 hours a day, 7 days a week.
Phone: 1-800-433-6076
1-440-914-1261
In addition to the CSC, you may also contact Field Watch. Field Watch
coordinates Emerson Process Management’s field service throughout the
U.S. and abroad.
Phone: 1-800-654-RSMT (1-800-654-7768)
Rosemount Analytical may also be reached via the Internet through e-mail
and the World Wide Web:
e-mail: GAS.CSC@.emersonprocess.com
World Wide Web: www.raihome.com
x
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Section 1
Oxymitter 4000
Description and Specifications
Component Checklist . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 1-1
System Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 1-1
IMPS 4000 (Optional) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 1-12
SPS 4001B (Optional) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 1-12
Model 751 Remote Powered Loop LCD Display . . . . . . . page 1-13
Probe Options . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 1-13
Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 1-16
COMPONENT
CHECKLIST
A typical Rosemount Analytical Oxymitter 4000 Oxygen Transmitter should
contain the items shown in Figure 1-1. Record the part number, serial number,
and order number for each component of your system in the table located on
the first page of this manual.
Also, use the product matrix in Table 1-1 at the end of this section to compare
your order number against your unit. The first part of the matrix defines the
model. The last part defines the various options and features of the Oxymitter
4000. Ensure the features and options specified by your order number are on
or included with the unit.
SYSTEM OVERVIEW
Scope
http://www.processanalytic.com
This Instruction Manual is designed to supply details needed to install, start
up, operate, and maintain the Oxymitter 4000. Signal conditioning electronics
outputs a 4-20 mA signal representing an O2 value and provides a membrane
keypad or fully functional Local Operator Interface (optional) for setup,
calibration, and diagnostics. This same information, plus additional details,
can be accessed with the HART Model 275/375 handheld communicator or
Asset Management Solutions (AMS) software.
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 1-1. Typical System
Package
1
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Rev.
2005 4.2
OX
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MAN 4275A00
English
Communicator
HART
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1.
2.
3.
4.
5.
6.
7.
8.
1-2
Instruction Manual
IMPS 4000 Intelligent Multiprobe Test Gas Sequencer (Optional)
Oxymitter 4000 with Integral Electronics
SPS 4001B Single Probe Autocalibration Sequencer (Optional) (Shown with reference air option)
HART® 275/375 Communicator Package (Optional)
Adapter Plate with Mounting Hardware and Gasket
Remote Electronics (Optional)
Reference Air Set (used if SPS 4001B without reference air option or IMPS 4000 supplied)
37260002
An
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Instruction Manual
IM-106-340, Rev. 4.0
February 2006
System Description
Oxymitter 4000
The Oxymitter 4000 is designed to measure the net concentration of oxygen
in an industrial combustion processes process; i.e., the oxygen remaining
after all fuels have been oxidized. The probe is permanently positioned within
an exhaust duct or stack and performs its task without the use of a sampling
system.
The equipment measures oxygen percentage by reading the voltage
developed across a heated electrochemical cell, which consists of a small
yttria stabilized, zirconia disc. Both sides of the disc are coated with porous
metal electrodes. When operated at the proper temperature, the millivolt
output voltage of the cell is given by the following Nernst equation:
EMF = KT log10(P1/P2) + C
Where:
1. P2 is the partial pressure of the oxygen in the measured gas on one
side of the cell.
2. P1 is the partial pressure of the oxygen in the reference air on the
opposite side of the cell.
3. T is the absolute temperature.
4. C is the cell constant.
5. K is an arithmetic constant.
NOTE
For best results, use clean, dry, instrument air (20.95% oxygen) as the
reference air.
When the cell is at operating temperature and there are unequal oxygen
concentrations across the cell, oxygen ions will travel from the high oxygen
partial pressure side to the low oxygen partial pressure side of the cell. The
resulting logarithmic output voltage is approximately 50 mV per decade. The
output is proportional to the inverse logarithm of the oxygen concentration.
Therefore, the output signal increases as the oxygen concentration of the
sample gas decreases. This characteristic enables the Oxymitter 4000 to
provide exceptional sensitivity at low oxygen concentrations.
The Oxymitter 4000 measures net oxygen concentration in the presence of all
the products of combustion, including water vapor. Therefore, it may be
considered an analysis on a "wet" basis. In comparison with older methods,
such as the portable apparatus, which provides an analysis on a "dry" gas
basis, the "wet" analysis will, in general, indicate a lower percentage of
oxygen. The difference will be proportional to the water content of the
sampled gas stream.
1-3
Instruction Manual
Oxymitter 4000
System Configuration
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000 units are available in seven length options, giving the user the
flexibility to use an in situ penetration appropriate to the size of the stack or
duct. The options on length are 18 in. (457 mm), 3 ft (0,91 m), 6 ft (1,83 m),
9 ft (2,7 m), 12 ft (3,66 m), 15 ft (4,57 m), and 18 ft (5,49 m).
The electronics control probe temperature and provide an isolated output,
4-20 mA, that is proportional to the measured oxygen concentration. The
power supply can accept voltages of 90-250 VAC and 48/62 Hz; therefore, no
setup procedures for power are required. The oxygen sensing cell is maintained at a constant temperature by modulating the duty cycle of the probe
heater portion of the electronics. The electronics accepts millivolt signals generated by the sensing cell and produces the outputs to be used by remotely
connected user devices. The output is an isolated 4-20 mA linearized current.
The Oxymitter 4000 transmitter is available with an integral or remote electronics package. Two calibration gas sequencers are available: the IMPS
4000 and the SPS 4001B (Figure 1-2).
Systems with multiprobe applications may employ an optional IMPS 4000
Intelligent Multiprobe Test Gas Sequencer. The IMPS 4000 provides automatic calibration gas sequencing for up to four Oxymitter 4000 units and
accommodates autocalibrations based on the CALIBRATION RECOMMENDED signal from the Oxymitter 4000, a timed interval set up in HART or
the IMPS 4000, or whenever a calibration request is initiated.
For systems with one or two Oxymitter 4000 units per combustion process, an
optional SPS 4001B Single Probe Autocalibration Sequencer can be used
with each Oxymitter 4000 to provide automatic calibration gas sequencing.
The SPS 4001B is fully enclosed in a NEMA cabinet suited for wall-mounting.
The sequencer performs autocalibrations based on the CALIBRATION RECOMMENDED signal from the Oxymitter 4000, a timed interval set up in HART,
or whenever a calibration request is initiated.
System Features
1. The CALIBRATION RECOMMENDED feature detects when the sensing
cell is likely out of limits. This may eliminate the need to calibrate on a
"time since last cal" basis.
2. The cell output voltage and sensitivity increase as the oxygen
concentration decreases.
1-4
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 1-2. Oxymitter 4000
AutoCalibration System Options
OXYMITTER 4000
IMPS 4000
(1 to 4 Probes)
An
aly
tic
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SPS 4001B
(1 Probe)
37260039
An
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3. Membrane keypad, Figure 1-3, and HART communication are standard.
To use the HART capability, you must have either:
a. HART Model 275/375 Communicator.
b. Asset Management Solutions (AMS) software for the PC.
1-5
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 1-3. Membrane Keypad
DIAGNOSTIC
ALARMS
HEATER T/C
HEATER
02 CELL
CALIBRATION
CALIBRATION RECOMMENDED
INC
INC
HIGH
GAS
LOW
GAS
DEC
DEC
02 CELL mV +
02 CELL mv HEATER T/C +
HEATER T/C -
CAL
TEST GAS +
PROCESS % 02
MEMBRANE
KEYPAD
37260003
TEST
POINTS
4. An optional Local Operator Interface, Figure 1-4, allows continuous O2
display and full interface capability.
37260004
Figure 1-4. Local Operator
Interface (LOI)
5. Field replaceable cell, heater, thermocouple, and diffusion element.
6. The Oxymitter 4000 is constructed of rugged 316 L stainless steel for all
wetted parts.
7. The electronics are adaptable for line voltages from 90-250 VAC;
therefore, no configuration is necessary.
1-6
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
8. The Oxymitter 4000 membrane keypad is available in five languages:
English
French
German
Italian
Spanish
9. An operator can calibrate and diagnostically troubleshoot the Oxymitter
4000 in one of four ways:
a. Membrane Keypad. The membrane keypad, housed within the right
side of the electronics housing, provides fault indication by way of
flashing LEDs. Calibration can be performed from the membrane
keypad.
b. LOI. The optional LOI takes the place of the membrane keypad and
allows local communication with the electronics. Refer to Section 6
for more information.
c. Optional HART Interface. The Oxymitter 4000's 4-20 mA output line
transmits an analog signal proportional to the oxygen level. The
HART output is superimposed on the 4-20 mA output line. This
information can be accessed through the following:
i.
Rosemount Analytical Model 275/375 Handheld
Communicator - The handheld communicator requires
Device Description (DD) software specific to the
Oxymitter 4000. The DD software will be supplied with
many Model 275/375 units but can also be programmed
into existing units at most Rosemount Analytical service
offices. See Section 7, HART/ AMS, for additional
information.
ii. Personal Computer (PC) - The use of a personal
computer requires AMS software available from
Rosemount Analytical.
iii. Selected Distributed Control Systems - The use of
distributed control systems requires input/output (I/O)
hardware and AMS software which permit HART
communications.
d. Optional IMPS 4000. The Programmable Logic Controller (PLC) in
the IMPS 4000 provides fault indications using flashing LEDs and
LCD display messages. Refer to the IMPS 4000 Intelligent
Multiprobe Test Gas Sequencer Instruction Manual for more
information.
1-7
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 1-5. Model 751 LCD
Display Panel
+
+
%
+
22220059
+
10. The optional Rosemount Analytical 751 remote-mounted LCD display
panel shown in Figure 1-5 is loop-driven by the 4-20 mA output signal
representing the O2 percentage.
11. Optional OxyBalance Display and Averaging System. Reviews up to
eight 4-20 mA signals from individual probes. Trends individual outputs,
calculates four programmable averages as additional 4-20 mA outputs.
Figure 1-6. OxyBalance Display
Displaying Outputs
An
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38370013
al
Handling the
Oxymitter 4000
It is important that printed circuit boards and integrated circuits are handled only when
adequate antistatic precautions have been taken to prevent possible equipment damage.
The Oxymitter 4000 is designed for industrial applications. Treat each component of the
system with care to avoid physical damage. Some probe components are made from
ceramics, which are susceptible to shock when mishandled.
1-8
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 1-7. Oxymitter 4000
HART Communications and
AMS Application
Hazardous Area
Oxymitter 4000
with Integral Electronics
2 Calibration Gas Lines
by Customer
[300 ft (90 m) max]
Termination in
Control Room
Line Voltage
System Considerations
Asset Management Solutions
37260005
4-20 mA Output
(Twisted Pairs)
HART
Model 275/375
Handheld
Interface
Prior to installing your Oxymitter 4000, make sure you have all the
components necessary to make the system installation. Ensure all the
components are properly integrated to make the system functional.
After verifying that you have all the components, select mounting locations
and determine how each component will be placed in terms of available line
voltage, ambient temperatures, environmental considerations, convenience,
and serviceability.
Figure 1-7 shows a typical system wiring.
A typical system installation for an Oxymitter 4000 with integral electronics is
shown in Figure 1-8. A typical system installation for an Oxymitter 4000 with
remote electronics is shown in Figure 1-9.
A source of instrument air is optional at the Oxymitter 4000 for reference
air use. Since the unit is equipped with an in place calibration feature,
provisions can be made to permanently connect calibration gas bottles to the
Oxymitter 4000.
If the calibration gas bottles will be permanently connected, a check valve is
required next to the calibration fittings on the integral electronics.
This check valve is to prevent breathing of the calibration gas line and
subsequent flue gas condensation and corrosion. The check valve is in
addition to the stop valve in the calibration gas kit or the solenoid valves in the
IMPS 4000 or SPS 4001B.
NOTE:
The electronics is rated NEMA 4X (IP66) and is capable of operation at
temperatures up to 185°F (85°C).
The optional LOI is also rated for operation at temperatures up to 185°F
(85°C). The infrared keypad functionality will degrade at temperatures above
158°F (70°C).
Retain the packaging in which the Oxymitter 4000 arrived from the factory in
case any components are to be shipped to another site. This packaging has
been designed to protect the product.
1-9
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 1-8. Typical System
Installation - Oxymitter 4000 with
Integral Electronics
Gases
STANDARD
Duct
Stack
Oxymitter
4000
Adapter
Plate
Line
Voltage
Instrument
Air Supply
(Reference Air)
Logic I/O
Flowmeter
4 to 20 mA
Signal
Pressure
Regulator
IMPS 4000* MULTIPROBE
AUTOCALIBRATION
OPTION
Calibration
Gas
Gases
Duct
Stack
Adapter
Plate
SPS 4001B* SINGLE PROBE
AUTOCALIBRATION OPTION
(WITH REFERENCE AIR OPTION)
Calibration
Gas
Oxymitter
4000
C Inst
Caalibra . Air
lib tio S
rat n up
ion G ply
Gaas 2
s
1
Line
Voltage
Gases
4 to 20 mA
Signal
Duct
Logic I/O
Stack
Adapter Plate
Reference
Air
IMPS 4000
Calibration Gas
Oxymitter
4000
Line Voltage
Logic I/O
C Ins
Caalibr t. Air
lib atio S
rat n up
ion G ply
Gaas 2
s
1
37260047
4 to 20 mA
Signal
Reference
Air
SPS 4001B
1-10
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 1-9. Typical System
Installation - Oxymitter 4000 with
Remote Electronics
Gases
STANDARD
Duct
Stack
Oxymitter 4000
Adapter Plate
Flowmeter
Remote
Electronics
Instrument
Air Supply
(Reference Air)
Pressure
Regulator
Logic I/O
Calibration
Gas
4 to 20 mA
Signal
Line
Voltage
Gases
IMPS 4000* MULTIPROBE
AUTOCALIBRATION
OPTION
Duct
Stack
Adapter Plate
Calibration Gas
Oxymitter 4000
SPS 4001B* SINGLE PROBE
AUTOCALIBRATION OPTION
(WITH REFERENCE AIR OPTION)
Reference Air
I
Ca nst.
Ca libra Air
libr tio Su
ati n G pp
on
a ly
Ga s 2
s
1
Remote
Electronics
Gases
Duct
Line Voltage
Stack
4 to 20 mA
Signal
Adapter Plate
Oxymitter
4000
Logic I/O
Line Voltage
IMPS 4000
Calibration Gas
Reference Air
Remote
Electronics
C Ins
Caalibr t. Air
libr atio S
ati n up
on Ga ply
Ga s 2
s
1
*Note: The IMPS 4000 or SPS 4001B must
be installed in a non-hazardous,
explosive-free environment.
4 to 20 mA
Signal
37260006
Line Voltage
Logic I/O
Line Voltage
SPS 4001B
1-11
Instruction Manual
Oxymitter 4000
IM-106-340, Rev. 4.0
February 2006
IMPS 4000 (OPTIONAL)
Information on the IMPS 4000 is available in the IMPS 4000 Intelligent
Multiprobe Test Gas Sequencer Instruction Manual.
SPS 4001B (OPTIONAL)
The SPS 4001B Single Probe Autocalibration Sequencer provides the
capability of performing automatic, timed or on demand, calibrations of a
single Oxymitter 4000 without sending a technician to the installation site.
Mounting
The SPS 4001B is fully enclosed in a NEMA cabinet suited for wall-mounting.
This cabinet provides added protection against dust and minor impacts. The
SPS 4001B consists of a manifold and a calibration gas flowmeter. The manifold provides electrical feedthroughs and calibration gas ports to route power
and signal connections and calibration gases to and from the sequencer. In
addition, the manifold houses two calibration gas solenoids that sequence the
gases to the Oxymitter 4000, a pressure switch that detects low calibration
gas pressure, and two PC boards. A terminal strip housed within the terminal
cover provides convenient access for all user connections.
Components optional to the SPS 4001B include a reference air flowmeter and
pressure regulator. The reference air flowmeter indicates the flow rate of
reference air continuously flowing to the Oxymitter 4000. The reference air
pressure regulator ensures the instrument air (reference air) flowing to the
Oxymitter 4000 is at a constant pressure [20 psi (138 kPa)]. The regulator
also has a filter to remove particulates in the reference air and a drain valve to
bleed the moisture that collects in the filter bowl.
Brass fittings and Teflon tubing are standard. Stainless steel fittings and
tubing are optional. Also, disposable calibration gas bottles are available as
an option or can be purchased through a local supplier.
Operation
1-12
The SPS 4001B works in conjunction with the Oxymitter 4000's CALIBRATION RECOMMENDED feature to perform an autocalibration. This feature
automatically performs a gasless calibration check every hour on the Oxymitter 4000. If a calibration is recommended and its contact output signal is set
for "handshaking" with the sequencer, the Oxymitter 4000 sends a signal to
the sequencer. The sequencer automatically performs a calibration upon
receiving the signal. Thus, no human interface is required for the automatic
calibration to take place. For further SPS 4001B information, refer to the SPS
4001B Single Probe Autocalibration Sequencer Instruction Manual.
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
MODEL 751 REMOTE
POWERED LOOP LCD
DISPLAY
Oxymitter 4000
The display (Figure 1-10) provides a simple, economical means to obtain
accurate, reliable, and remote indication of important process variables. This
display operates on the 4-20 mA line from the Oxymitter 4000. Refer to Model
751 remote powered loop LCD manual for calibration and wiring.
Figure 1-10. Model 751 Remote
Powered Loop LCD Display
+
+
%
+
22220059A
+
PROBE OPTIONS
Diffusion Elements
Ceramic Diffusion Assembly
The ceramic diffusion assembly, Figure 1-11, is the traditional design for the
probe. Used for over 25 years, the ceramic diffusion assembly provides a
greater filter surface area. This element is also available with a flame arrestor,
and with a dust seal for use with an abrasive shield.
19280010
Figure 1-11. Ceramic Diffusion
Assembly
1-13
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Snubber Diffusion Assembly
The snubber diffusion assembly, Figure 1-12, is satisfactory for most
applications. This element is also available with a flame arrestor, and with a
dust seal for use with an abrasive shield.
36210012
Figure 1-12. Snubber Diffusion
Assembly
Cup-Type Diffusion Assembly
The cup-type diffusion assembly, Figure 1-13, is typically used in high
temperature applications where frequent diffusion element plugging is a
problem. It is available with either a 5 or 40 micron, sintered, Hastelloy
element.
This element is also available with a dust seal for use with an abrasive shield.
36150001
Figure 1-13. Hastelloy Cup-Type
Diffusion Assembly
Abrasive Shield Assembly
The abrasive shield assembly, Figure 1-14, is a stainless steel tube that
surrounds the probe assembly. The shield protects against particle abrasion,
provides a guide for ease of insertion, and acts as a position support,
especially for longer probes. The abrasive shield assembly uses a modified
diffuser and vee deflector assembly, fitted with dual dust seal packing.
1-14
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 1-14. Abrasive Shield
Assembly
2
.187 1
.187
B
A
15o
3.584
3.554
90o
90
o
On inside break
for smooth
rounded edge on
both ends
of chamfer
A
.45 min
.187
B
125
6.00
o
Skin Cut Face for 90
VIEW B
VIEW A
22.5o
0.75 thru 4 pls,
eq sp on 4.75 B.C.
2 Before welding, butt item 2 with
Item 1 as shown.
16860033
1 Weld on both sides with expanding
chill block.
.745 Dia on a 7.50 Dia B.C. (ref)
.755
NOTE
In highly abrasive applications, rotate the shield 90 degrees at normal
service intervals to present a new wear surface to the abrasive flow stream.
1-15
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
SPECIFICATIONS
Oxymitter Specifications
O2 Range
Standard
Accuracy
System Response to Calibration
Gas
Temperature Limits
Process
Emerson Process
Managrement has
satisfied all obligations
coming from European
legislation to harmonize
the product requirements
in Europe
Electronics Housing
Electronics Package
Local Operator Interface
Probe Lengths
Mounting and Mounting Position
0 to 10% O2, 0 to 25% O2, 0 to 40% O2 (via HART)
±0.75% of reading or 0.05% O2, whichever is greater
Initial – less than 3 seconds, T90 – less than 8
seconds
0° to 704°C (32° to 1300°F) up to 1300°C (2400°F)
with optional accessories
-40° to 70°C (-40° to 158°F) ambient
-40° to 85°C (-40° to 185°F) [Operating temperature
of electronics inside of instrument housing, as
measured by a HART communicator, Rosemount
Analytical Asset Management Solutions software.]
-40° to 70°C (-40° to 158°F), [above 70°C (158°F) the
infrared keypad will cease to function, but the
Oxymitter 4000 will continue to operate properly.]
18 in. (457 mm)
12 ft (3,66 m)
3 ft (0,91 m)
15 ft (4,57 m)
6 ft (1,83 m)
18 ft (5,49 m)
9 ft (2,74 m)
Vertical or horizontal;
a spool piece, (P/N 3D39761G02), is available to
offset transmitter housing from hot ductwork.
Materials
Probe
Electronics Enclosure
Calibration
Calibration Gas Mixtures
Recommended
Calibration Gas Flow
Reference Air
Electronics
Electric Noise
Line Voltage
Wetted or welded parts - 316L stainless steel (SS)
Non-wetted parts - 304 SS, low-copper aluminum
Low-copper aluminum
Manual, semi-automatic, or automatic
0.4% O2, Balance N2
8% O2, Balance N2
2.5 l/m (5 scfh)
2 scfh (1 l/m), clean, dry, instrument-quality air
(20.95% O2), regulated to 34 kPa (5 psi)
NEMA 4X, IP66 with fitting and pipe on reference
exhaust port to clear dry atmosphere
Meets EN 55022 Generic Emissions Std.,
Includes EN 61000-4-2 for Electrostatic Discharge
Includes EN 6100-4-3 for RFI
Includes EN 6100-4-4 for Fast Transients
Includes EN 6100-4-6 for RFI
90-250 VAC, 48/62 Hz. No configuration necessary.
3/4in. -14 NPT conduit port
Table continued on next page
1-16
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Oxymitter Specifications
Signals
Analog Output/HART
Logic I/O
Power Requirements:
Probe Heater
Electronics
Maximum
SPS 4001B
Materials of Construction:
Box
Manifold/Electronics Enclosure
Door Hinge Pins
Mounting Brackets
Pneumatic Fittings
Pneumatic Tubing
Assembly Hardware
Humidity Range
Temperature Range in Electronics
Housing
Electrical Classification
Explosion-Proof Option (both pending)
Electrical Feedthroughs
Input Power
Power Consumption
External Electrical Noise
Handshake Signal to/from
Oxymitter 4000 (self-powered)
Cal Initiate Contact input from Control
Room
Relay Outputs to Control Room
Cabling Distance between
SPS 4001B and Oxymitter 4000
Piping Distance between
SPS 4001B and Oxymitter 4000
Approximate Shipping Weight
4-20 mA isolated from power supply, 950 ohms
maximum load
Two-terminal logic contact configurable as either an
alarm output or as a bi-directional calibration
handshake signal to IMPS 4000 or SPS 4001B,
self-powered (+5 V) in series with 340 ohms
Conduit ports — 3/4 in.-14 NPT (for analog output and
logic I/O signal lines)
175 W nominal
10 W nominal
500 W
Molded fiberglass reinforced polyester
Aluminum
316 stainless steel (SS)
316 stainless steel (SS)
1/8 in. brass NPT (SS optional)
1/4 in. Teflon (SS optional)
Galvanized and stainless steel
100% relative humidity
-40 to 185 F (-40 to 85 C)
NEMA 4X (IP56)
ATEX EExd 11B + H2 (Class 1, Division 1, Group
B,C,D)
1/2 in. NPT
90 to 250 VAC, 50/60 Hz
5 VA maximum
EN 50 082-2, includes 4 kV electrostatic discharge
5 V (5 mA maximum)
5 VDC (self-powered)
5 to 30 VDC, Form A (SPST)
(one "In-Cal", one "Cal Failed")
Maximum 1000 ft (303 m)
Maximum 300 ft (91 m)
10 lbs (4,5 kg)
1-17
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Table 1-1. Product Matrix
OXT4A
Oxymitter 4000 In Situ Oxygen Transmitter
Oxygen Transmitter - Instruction Book
Code
1
2
3
4
5
6
7
8
9
Sensing Probe Type
ANSI (N. American Std.) Probe with Ceramic Diffuser
ANSI Probe with Flame Arrestor and Ceramic Diffuser
ANSI Probe with Snubber Diffuser
DIN (European Std.) Probe with Ceramic Diffuser
DIN Probe with Flame Arrestor and Snubber Diffuser
DIN Probe with Snubber Diffuser
JIS (Japanese Std.) Probe with Ceramic Diffuser
JIS Probe with Flame Arrestor and Ceramic Diffuser
JIS Probe with Snubber Diffuser
Code
0
1
2
3
4
5
6
7
8
9
A
B
Probe Assembly
18 in. (457 mm) Probe
18 in. (457 mm) Probe with Abrasive Shield (1)
3 ft (0,91 m) Probe
3 ft (0,91 m) Probe with Abrasive Shield (1)
6 ft (1,83 m) Probe
6 ft (1,83 m) Probe with Abrasive Shield (1)
9 ft (2,74 m) Probe
9 ft (2,74 m) Probe with Abrasive Shield (1)
12 ft (3,66 m) Probe
12 ft (3,66 m) Probe with Abrasive Shield (1)
15 ft (4,57 m) Probe with Abrasive Shield (1)
18 ft (5,49 m) Probe with Abrasive Shield (1)
Code
0
1
2
3
4
5
Mounting Hardware- Stack Side
No Mounting Hardware ("0" must be chosen under "Mounting Hardware - Probe Side" below)
New Installation - Square weld plate with studs
Mounting to Model 218 Mounting Plate (with Model 218 Shield Removed)
Mounting to Existing Model 218 Support Shield
Mounting to Other Mounting(2)
Mounting to Model 132 Adapter Plate
Code
0
1
2
4
5
7
8
Mounting Hardware- Probe Side
No Mounting Hardware
Probe Only (ANSI) (N. American Std.)
New Bypass or New Abrasive Shield (ANSI)
Probe Only (DIN)
New Bypass or New Abrasive Shield (DIN)
Probe Only (JIS) (Japanese Std.)
New Bypass or Abrasive Shield (JIS)
Code
11
12
13
14
OXT4C
1-18
3
3
1
1
11
Electronic Housing & Filtered Customer Termination - NEMA 4X, IP66
HART Integral Electronics, Standard Filtered Termination, ATEX Certification
HART Integral Electronics, Transient Protected Filtered Termination, ATEX
Certification
Remote Electronics with Standard Filtered Termination (requires cable)
Remote Electronics with Transient Protected Filtered Termination
(requires cable)
Example
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Cont’d
Code
1
2
3
Operator Interface(3)
HART with Membrane Keypad - blind cover
HART with Membrane Keypad - glass cover
HART with Local Operation Interface, glass cover, English only
Code
1
2
3
4
5
Language
English
German
French
Spanish
Italian
Code
00
Termination Filtering
Specified as part of Electronic Housing
Code
00
01
02
03
04
05
06
07
08
09
10
Calibration Accessories
No Hardware
Calibration Gas Flowmeter and Reference Air Set
Intelligent Multiprobe Sequencer (Refer to Table 1-3)
Single Probe Sequencer, Horizontal Orientation, Brass/Teflon, no Reference Air Set
Single Probe Sequencer, Horizontal Orientation, Brass/Teflon, with Reference Air Set
Single Probe Sequencer, Horizontal Orientation, Stainless Steel, no Reference Air Set
Single Probe Sequencer, Horizontal Orientation, Stainless Steel, with Reference Air Set
Single Probe Sequencer, Vertical Orientation, Brass/Teflon, no Reference Air Set
Single Probe Sequencer, Vertical Orientation, Brass/Teflon, with Reference Air Set
Single Probe Sequencer, Vertical Orientation, Stainless Steel, no Reference Air Set
Single Probe Sequencer, Vertical Orientation, Stainless Steel, with Reference Air Set
Code
00
10
11
12
13
14
15
16
Cont’d
1
3
00
03
00
Electronics to Probe Cable
No Cable
20 ft (6 m) Cable
40 ft (12 m) Cable
60 ft (18 m) Cable
80 ft (24 m) Cable
100 ft (30 m) Cable
150 ft (45 m) Cable
200 ft (61 m) Cable
Example
NOTES:
(1)
Recommended uses: High velocity particulates in flue stream, installation within 11.5 ft (3,5 m) of soot blowers or heavy salt cake buildup. Applications:
Pulverized coal, recovery boilers, lime kiln.
(2)
Where possible, specify ANSI or DIN designation; otherwise, provide details of the existing mounting plate as follows:
Plate with studs
Plate without studs
Bolt circle diameter, number, and arrangement of studs; stud thread; and stud height above mounting plate.
Bolt circle diameter, number, and arrangement of holes; thread; and depth of stud mounting plate with accessories.
1-19
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Table 1-2. Calibration
Components
Part Number
1A99119G01
1A99119G02
1A99119G03
Description
Two disposable calibration gas bottles - 0.4% and 8% O2, balance
nitrogen - 550 liters each*
Two flow regulators for calibration gas bottles
Bottle rack
Notes:
*Calibration gas bottles cannot be shipped via airfreight.
When the bottles are used with CALIBRATION RECOMMENDED features, the bottles should provide
2 to 3 years of calibrations in normal service.
Table 1-3. Intelligent Multiprobe
Test Gas Sequencer Versions
Part Number
3D39695G01
3D39695G02
3D39695G03
3D39695G04
3D39695G05
3D39695G06
3D39695G07
3D39695G08
3D39695G09
3D39695G10
3D39695G11
3D39695G12
1-20
Description
IMPS
IMPS
IMPS
IMPS
IMPS w/115 V Heater
IMPS w/115 V Heater
IMPS w/115 V Heater
IMPS w/115 V Heater
IMPS w/220V Heater
IMPS w/220V Heater
IMPS w/220V Heater
IMPS w/220V Heater
Number of Oxymitters
1
2
3
4
1
2
3
4
1
2
3
4
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Section 2
Oxymitter 4000
Installation
Mechanical Installation . . . . . . . . . . . . . . . . . . . . . . . . . . . page 2-2
Electrical Installation (with Integral Electronics) . . . . . . . page 2-10
Electrical Installation (with Remote Electronics) . . . . . . . page 2-13
Pneumatic Installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 2-16
IMPS 4000 Connections . . . . . . . . . . . . . . . . . . . . . . . . . . . page 2-18
SPS 4001B Connections . . . . . . . . . . . . . . . . . . . . . . . . . . page 2-18
Before installing this equipment, read the "Safety instructions for the wiring and installation
of this apparatus" at the front of this Instruction Manual. Failure to follow safety instructions
could result in serious injury or death.
Install all protective equipment covers and safety ground leads after installation. Failure to
install covers and ground leads could result in serious injury or death.
http://www.processanalytic.com
Instruction Manual
Oxymitter 4000
IM-106-340, Rev. 4.0
February 2006
MECHANICAL
INSTALLATION
Selecting Location
1. The location of the Oxymitter 4000 in the stack or flue is most important
for maximum accuracy in the oxygen analyzing process. The Oxymitter
4000 must be positioned so the gas it measures is representative of the
process. Best results are normally obtained if the Oxymitter 4000 is
positioned near the center of the duct (40-60% insertion). Longer ducts
may require several Oxymitter 4000 units since the O2 can vary due to
stratification. A point too near the wall of the duct, or the inside radius of
a bend, may not provide a representative sample because of the very
low flow conditions. The sensing point should be selected so the
process gas temperature falls within a range of 32° to 1300°F
(0° to 704°C). Figure 2-1 through Figure 2-8 provide mechanical
installation references. The ambient temperature of the integral
electronics housing must not exceed 185°F (85°C). For higher ambient
temperatures, we recommend the remote mounted electronics option.
2. Check the flue or stack for holes and air leakage. The presence of this
condition will substantially affect the accuracy of the oxygen reading.
Therefore, either make the necessary repairs or install the Oxymitter
4000 upstream of any leakage.
3. Ensure the area is clear of internal and external obstructions that will
interfere with installation and maintenance access to the membrane
keypad or LOI. Allow adequate clearance for removal of the Oxymitter
4000.
Do not allow the temperature of the Oxymitter 4000 electronics to exceed 185°F (85°C) or
damage to the unit may result.
Probe Installation
1. Ensure all components are available to install the Oxymitter 4000. If
equipped with the optional ceramic diffusion element, ensure it is not
damaged.
2. The Oxymitter 4000 may be installed intact as it is received.
NOTE
An abrasive shield is recommended for high velocity particulates in the flue
stream (such as those in coal-fired boilers, kilns, and recovery boilers).
Vertical and horizontal brace clamps are provided for 9 ft and 12 ft (2,75 m
and 3,66 m) probes to provide mechanical support for the Oxymitter 4000.
Refer to Figure 2-6.
3. Weld or bolt adapter plate (Figure 2-5) onto the duct.
4. If using the optional ceramic diffusion element, the vee deflector must
be correctly oriented. Before inserting the Oxymitter 4000, check the
direction of gas flow in the duct. Orient the vee deflector so the apex
points upstream toward the flow (Figure 2-7). This may be done by
loosening the setscrews and rotating the vee deflector to the desired
position. Retighten the setscrews.
2-2
4.75
(121)
5.71
(145)
5.12
(130)
Bottom View
WHE N
CI R
CU
IT
12
(305)
Rosemount Analytical Inc.
Orrville, OH 44667-0901
800-433-6076
R
500 VA
5 Amps
6.52
(166)
Ref Air
ANSI 1/4 (6.35) Tube
DIN 6 mm Tube
JIS 6 mm Tube
Cal Gas
SMART FAMILY
HART TM
Cover Removal and Access
2.89
(73)
1.55
(39)
12
(305)
R
TM
OXYMITTER 4000
SERIAL NO.
TAG NO.
VOLTS: 85-264 VAC WATTS:
48-62 Hz
OUTPUT: 4-20 mALINE FUSE:
IG
HT
WH E N
CI R
CU
VE ATM
OS I
O
PL WA RN I NG - SPH
EX -
18 in.
PROBE
18 ft
15 ft
12 ft
9 ft
6 ft
3 ft
REF.
GAS
229.8
(5837)
193.8
(4923)
178
(4521)
214
(5436)
31.8
(808)
49.8
(1265)
85.8
(2179)
121.8
(3094)
157.8
(4008)
DIM "B"
16
(406)
34
(864)
70
(1778)
106
(2692)
142
(3607)
DIM "A"
Table 2. Installation/Removal
Elec Conn
3/4 NPT
IT
IM-106-340, Rev. 4.0
February 2006
36920001
Flange
Dia
Hole
Dia
(4) Holes
Eq Sp
on BC
Table 1. Mounting Flange
DIN
ANSI
JIS
4512C17H01 4512C19H01 4512C18H01
6.10
6.00
7.28
(155)
(185)
(153)
0.75
0.71
0.59
(18)
(15)
(20)
12.50 (318)
Dim "B”
Removal Envelope
6.02 (153)
P
T
With
Standard
Snubber
Diffuser
4.77 (121)
T
KEE
P
Add to Dim “A”
for probe with
Ceramic Diffuser
and Flame
Arrestor
Dim "A"
CAL.
GAS
IG
H
VE ATM
OS I
O
PL WA RN I NG - SPH
EX -
KEE
Add to Dim “A”
for probe
with Ceramic
Diffuser
5.14(131)
3.80(96)
2.27 (58)
Dia Max
Insulate if exposed to
Ambient weather conditions
-
IN
-
I VE
0.062 THK Gasket
ANSI 3535B18H02
JIS
3535B46H01
3535B45H01
DIN
-
IN
-
I VE
Note: Dimensions are in
inches with millimeters
in parentheses.
E
ER
AL
E
ER
AL
Process flow must be in
this direction with respect
to deflector 3534B48G01
Instruction Manual
Oxymitter 4000
Figure 2-1. Oxymitter 4000
Probe Installation
T
2-3
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 2-2. Oxymitter 4000
Remote Electronics Installation
REMOTE ELECTRONICS
WITH MEMBRANE KEYPAD AND BLIND COVER
REMOTE ELECTRONICS
WITH LOI AND WINDOW COVER
2.44
(62,0)
DIA.
2.21
(56,0)
6.48
(164,6)
7.47
(189,8)
8.72 (221,5)
3.33
(84,6)
5.52
(140,2)
37260046
WALL MOUNT
CONFIGURATION
2.68 (68,1)
PIPE MOUNT
CONFIGURATION
2.62
(66,5)
Note: Dimensions are in inches with millimeters in parentheses.
2-4
36920002
18 ft
15 ft
12 ft
9 ft
Dim "A"
13
(330)
31
(787)
67
(1702)
103
(2616)
139
(3531)
175
(4445)
211
(5359)
Dim "B"
32.5
(826)
50.5
(1283)
86.5
(2197)
122.5
(3112)
158.5
(4026)
194.5
(4940)
230.5
(5855)
Hole
Dia
(8) Holes
Eq Sp
on BC
7.50
(190)
0.75
(19)
7.48
(190)
0.75
(19)
7.48
(190)
0.94
(24)
TABLE 4. Abrasive Shield
-3D39003
ANSI
DIN
Flange
JIS
9.25
9.00
9.25
Flange
(235)
(229)
(235)
Dia
Cal Gas*
U
IT
3/4 NPT Electrical
Connection
*Add check valve in Cal Gas line
ANSI 1/4 in. Tube
JIS
6 mm Tube
6 mm Tube
DIN
Ref Air
C
CI R
IM-106-340, Rev. 4.0
February 2006
6 ft
3 ft
18 in.
Probe
WHE N
VE ATM
OS I
O
PL WARN I NG - SPH
EX -
IG
HT
T
TABLE 3.
Installation/Removal Table
4.77
(121) 6.02
(153)
CAL.
GAS
12.50
(318)
P
Diffuser/Dust
Seal Assy
3.6 (91) Dia Nominal
7.00
(178)
Dim "B"
Removal Envelope
KE E
Deflector Assy
Snubber/Dust
Seal Assembly
0.2
(5)
3.9
(99)
Dim "A"
-
IN
I VE
2. Dimensions are in inches with millimeters in parentheses.
E
ER
AL
Notes:
1. These flat-faced flanges are manufactured to ANSI, DIN, and JIS bolt patterns
and are not pressure rated.
Instruction Manual
Oxymitter 4000
Figure 2-3. Oxymitter 4000 with
Abrasive Shield
2-5
2-6
0.625-11
4.75
(121)
"B"
Thread
"C"
Dia
35830004
B
C
45o
7.50
(191)
"D"
Dia
A
B
Crosshatched area in 4
corners may be used to
provide additional holes for
field bolting of plate to
outside wall surface.
A
C
22.5o
*Part numbers for adapter plates include
attaching hardware.
(M-16 x 2)
0.625-11
"C"
Thread
7.48
(190)
3.94
(100)
9.25
(235)
7.894
(200)
(M-20 x 2.5)
4.92
(125)
9.25
(235)
JIS
(P/N 3535B58G04)
Abrasive Shield
Flange O.D.
8 threaded holes
equally spaced on
D Dia B.C.
DIN
(P/N 3535B58G06)
4.75
(121)
9.00
(229)
ANSI
(P/N 3535B58G02)
"B"
Dia
"A"
Dimensions
in.
(mm)
Adapter plate for 3, 6, 9,
and 12 ft. Abrasive Shield
Installations. See figure 2-3.
4 studs,
lockwashers and
nuts equally
spaced on
C Dia B.C.
A
5.118
(130)
(M-12 x 1.75)
6.50
(165)
JIS
(P/N 4512C35G01)
TABLE 6. ADAPTER PLATE* DIMENSIONS FOR OXYMITTER 4000
WITH ABRASIVE SHIELD
Oxymitter 4000
Adapter plate
for Oxymitter 4000
Installation. See
Figure 2-1.
2.500 Dia
(63,5)
Note: Dimensions are
in inches with
millimeters in
parentheses.
A
5.708
(145)
(M-16 x 2)
7.5
(191)
DIN
(P/N 4512C36G01)
*Part numbers for adapter plates include
attaching hardware.
6.00
(153)
ANSI
(P/N 4512C34G01)
"A"
Dimensions
in.
(mm)
TABLE 5. ADAPTER PLATE* DIMENSIONS FOR OXYMITTER 4000
ADAPTOR PLATE OUTLINE
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Figure 2-4. Oxymitter 4000
Adapter Plate Dimensions
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 2-5. Oxymitter 4000
Adapter Plate Installation
INSTALLATION FOR METAL WALL
STACK OR DUCT CONSTRUCTION
INSTALLATION FOR MASONRY
WALL STACK CONSTRUCTION
0.50 (13)
0.50 (13)
Bolt mounting plate to
outside wall surface
3.75 (95)
Field weld pipe
to adapter plate
Minimum Dia
hole in wall
Mounting Holeso
shown rotated 45
out of true position
Mounting holes
shown rotated 45o
out of true position
Stack or duct
metal wall
Joint must
be air tight
Weld or bolt mounting plate to metal wall
of stack or duct; Joint must be air tight.
4.50 (114)
O.D. Ref
Pipe 4.00 in. Sched 40 Pipe
Sleeve (Not by
Rosemount Analytical)
length by Customer
Masonry
stack wall
Outside wall
surface
Bolt adapter plate to
outside wall surface
Field weld pipe
to adapter plate
3.5 (89)
O.D. Ref
2.50 (63,5)
Minimum Dia
hole in wall
Joint must
be air tight
Weld or bolt adapter plate to
metal wall of stack or duct.
Joint must be air tight.
Notes: 1.
2.
Dimensions are in inches with
millimeters in parentheses.
All masonry stack work and joints except adaptor
plate are not furnished by Rosemont Analytical.
Outside wall
surface
Pipe 3.00 in. Sched 40 Pipe
Sleeve (Not by
Rosemount Analytical)
length by Customer
Masonry
stack wall
35830005
Stack or duct
metal wall
2-7
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 2-6. Oxymitter 4000 Abrasive Shield Bracing Installation
Brace Bars
(Not by Rosemount Analytical)
Note: Dimensions are in inches with
millimeters in parentheses.
2.00
(51)
60o Max
1.00
(25)
30o Min
}
Vertical brace clamp assy.
By Rosemount Analytical
Horizontal brace clamp assy.
(Both brace clamp assemblies are the same.
Installation and location of clamp assemblies
and brace bars to be done in field.)
2 Holes - 0.625
(16) Dia for
0.50 (12) Dia
Bolt
5.62
(143)
Abrasive Shield
4.12
(105)
4.12
(105)
0.375
(10)
1.00
(25) Max
5.62
(143)
Note: Bracing is for vertical and horizontal Oxymitter 4000
Installation. External bracing required for 9 ft. through 18 ft.
(2,75 m through 5,49 m) probes as shown above.
36920003
36.00 (914)
5. In vertical installations, ensure the system cable drops vertically from
the Oxymitter 4000 and the conduit is routed below the level of the
electronics housing. This drip loop minimizes the possibility that
moisture will damage the electronics (Figure 2-8).
6. If the system has an abrasive shield, check the dust seal gaskets. The
joints in the two gaskets must be staggered 180°. Also, make sure the
gaskets are in the hub grooves as the Oxymitter 4000 slides into the 15°
forcing cone in the abrasive shield.
7. Insert probe through the opening in the mounting flange and bolt the unit
to the flange. When probe lengths selected are 9 to 18 ft (2.74 to
5.49 m), special brackets are supplied to provide additional support for
the probe inside the flue or stack (Figure 2-6).
NOTE
If process temperatures will exceed 392°F (200°C), use anti-seize compound
on stud threads to ease future removal of Oxymitter 4000. For ambient
temperatures that will exceed 185°F (85°C), we recommend the remote
mounted electronics option.
2-8
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Figure 2-7. Orienting the
Optional Vee Deflector
Oxymitter 4000
Gas Flow
Direction
Vee
Deflector
Apex
Diffusion
Element
Filter
Setscrew
22220020
Vee
Deflector
Uninsulated stacks or ducts may cause ambient temperatures around the electronics to
exceed 185°F (85°C), which may cause overheating damage to the electronics.
8. If insulation is being removed to access the duct work for Oxymitter
4000 mounting, make sure the insulation is replaced afterward
(Figure 2-8).
Remote Electronics
Installation
For an Oxymitter 4000 equipped with remote electronics, install the probe
according to the instructions in "Probe Installation". Install the remote
electronics unit on a stand pipe or similar structure, Figure 2-2.
2-9
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 2-8. Installation with Drip
Loop and Insulation Removal
-
IVE
-
KEE
IG
HT
WHE N
CI R
CU
VE ATM
O
OS I
PL WARN I NG - SPH
EX -
AL
E
ER
IN
P
T
Drip
Loop
CAL.
GAS
Replace Insulation
after Installing
Oxymitter 4000
Logic I/O,
4-20 mA Signal
IT
Line
Voltage
Adapter
Plate
ELECTRICAL
INSTALLATION (WITH
INTEGRAL
ELECTRONICS)
Stack or Duct
Metal Wall
29340005
Insulation
For Oxymitter 4000 with Integral Electronics
All wiring must conform to local and national codes.
Disconnect and lock out power before connecting the power supply.
Install all protective covers and safety ground leads after installation. Failure to install covers
and ground leads could result in serious injury or death.
To meet the Safety Requirements of IEC 1010 (EC requirement), and ensure safe operation
of this equipment, connection to the main electrical power supply must be made through a
circuit breaker (min 10 A) which will disconnect all current-carrying conductors during a fault
situation. This circuit breaker should also include a mechanically operated isolating switch.
If not, then another external means of disconnecting the supply from the equipment should
be located close by. Circuit breakers or switches must comply with a recognized standard
such as IEC 947.
2-10
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
NOTE
To maintain CE compliance, ensure a good connection exists between the
mounting flange bolts and earth.
1. Remove screw (32, Figure 9-3), gasket (33), and cover lock (34).
Remove cover (27).
2. Connect Line Voltage
a. Connect the line, or L1 wire to the L1 terminal and the neutral, or
L2 wire, to the N terminal (Figure 2-9). The Oxymitter 4000
automatically will configure itself for 90-250 VAC line voltage and
50/60 Hz. The power supply requires no setup.
3. Connect 4-20 mA Signal and Calibration Handshake/Logic I/O Leads
a. 4-20 mA Signal. The 4-20 mA signal represents the O2 value and
can also operate the Model 751 Remote Powered Loop LCD Display
or any other loop powered display. Superimposed on the 4-20 mA
signal is HART information that is accessible through a Model
275/375 Handheld Communicator or AMS software.
b. Calibration Handshake/Logic I/O. The output can either be an alarm
or provide the handshaking to interface with an IMPS 4000 or
SPS 4001B. For more information, refer to "Logic I/O" in Section 4:
Configuration of Oxymitter 4000 with LOI, and either the IMPS 4000
Intelligent Multiprobe Test Gas Sequencer Instruction Manual or the
SPS 4001B Single Probe Autocalibration Sequencer Instruction
Manual.
c. If autocalibration is not utilized, a common bi-directional logic contact
is provided for any of the diagnostic alarms listed in Table 8-1. The
assignment of alarms which can actuate this contact can be modified
to one of seven additional groupings listed in Table 3-1 and
Table 4-1.
The logic contact is self-powered, +5 VDC, 340 ohm series
resistance. An interposing relay will be required if this contact is to be
utilized to annunciate a higher voltage device, such as a light or
horn, and may also be required for certain DCS input cards. A Potter
& Brumfield R10S-E1Y1-J1.0K 3.2 mA DC or an equal interposing
relay will be mounted where the contact wires terminate in the
control/relay room.
d. Install cover (27, Figure 9-3). Secure with cover lock (34), gasket
(33), and screw (32).
2-11
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 2-9. Electrical
Installation - Oxymitter 4000 with
Integral Electronics
INTEGRAL ELECTRONICS
WITHOUT SPS 4001B
Calibration
Handshake/
Logic I/O
4-20 mA Signal
Line Voltage
-
+
-
+
AC
AC
N
L1
Logic I/O +
Logic I/O –
4-20 mA +
4-20 mA –
Ground
90-250 VAC, 50-60 Hz
Line Voltage Input
Terminal
Block
Line 1
Neutral
Ground
Ground
Lugs
INTEGRAL ELECTRONICS
WITH REMOTE SPS 4001B
Line 1
Neutral
Ground
90-250 VAC, 50-60 Hz
Line Voltage Input
4-20 mA +
Signal Ground
Calibration
Handshake
90-250 VAC, 50-60 Hz
Line Voltage Input
Refer to SPS 4001B
Instruction Manual
Line 1
Neutral
Ground
INTEGRAL ELECTRONICS
WITH REMOTE IMPS 4000
Calibration Handshake
Refer to IMPS 4000
Instruction Manual
2-12
90-250 VAC, 50-60 Hz
Line Voltage Input
+ 4-20 mA
– 4-20 mA
Ground
37260051
Line 1
Neutral
Ground
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
ELECTRICAL
INSTALLATION (WITH
REMOTE
ELECTRONICS)
Oxymitter 4000
For Oxymitter 4000 with Remote Electronics
All wiring must conform to local and national codes.
Disconnect and lock out power before connecting the power supply.
Install all protective covers and safety ground leads after installation. Failure to install covers
and ground leads could result in serious injury or death.
To meet the Safety Requirements of IEC 1010 (EC requirement), and ensure safe operation
of this equipment, connection to the main electrical power supply must be made through a
circuit breaker (min 10 A) which will disconnect all current-carrying conductors during a fault
situation. This circuit breaker should also include a mechanically operated isolating switch.
If not, then another external means of disconnecting the supply from the equipment should
be located close by. Circuit breakers or switches must comply with a recognized standard
such as IEC 947.
NOTE
To maintain CE compliance, ensure a good connection exists between the
mounting flange bolts and earth.
1. Remove screw (32, Figure 9-4), gasket (33), cover lock (34), and cover
(27) from remote electronics.
2. Connect Line Voltage
a. Connect the line, or L1 wire to the L1 terminal and the neutral, or
L2 wire, to the N terminal (Figure 2-10). The Oxymitter 4000
automatically will configure itself for 90-250 VAC line voltage and
50/60 Hz. The power supply requires no setup.
3. Connect 4-20 mA Signal and Calibration Handshake/Logic I/O Leads
(Figure 2-10).
a. 4-20 mA Signal. The 4-20 mA signal represents the O2 value and
can also operate the Model 751 Remote Powered Loop LCD Display
or any other loop powered display. Superimposed on the 4-20 mA
signal is HART information that is accessible through a Model
275/375 Handheld Communicator or AMS software.
2-13
Instruction Manual
Oxymitter 4000
IM-106-340, Rev. 4.0
February 2006
b. Calibration Handshake/Logic I/O. The output can either be an alarm
or provide the handshaking to interface with an IMPS 4000 or
SPS 4001B. For more information, refer to "Logic I/O" in Section 4:
Configuration of Oxymitter 4000 with LOI, and either the IMPS 4000
Intelligent Multiprobe Test Gas Sequencer Instruction Manual or the
SPS 4001B Single Probe Autocalibration Sequencer Instruction
Manual.
c. If autocalibration is not utilized, a common bi-directional logic contact
is provided for any of the diagnostic alarms listed in Table 8-1. The
assignment of alarms which can actuate this contact can be modified
to one of seven additional groupings listed in Table 4-1.
The logic contact is self-powered, +5 VDC, 340 ohm series
resistance. An interposing relay will be required if this contact is to be
utilized to annunciate a higher voltage device, such as a light or
horn, and may also be required for certain DCS input cards. A Potter
& Brumfield R10S-E1Y1-J1.0K 3.2 mA DC or an equal interposing
relay will be mounted where the contact wires terminate in the
control/relay room.
4. Install cover (27, Figure 9-4). Secure with cover lock (34), gasket (33),
and screw (32).
5. Install Interconnecting Cable
a. Remove the cover (3) from the junction box (5). Connect the
electronics end of the interconnecting cable to the "FROM PROBE"
side of the terminal block (Figure 2-10).
b. Remove screw (32, Figure 9-4), gasket (33), and cover lock (34) at
the probe head. Remove housing cover (27).
c. Connect the heater power leads, the thermocouple leads and the
oxygen signal leads at the terminal block. The leads are tagged for
polarity.
2-14
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 2-10. Electrical
Installation - Oxymitter 4000 with
Remote Electronics
WHT
YEL +
RED -
BLU -
ORN+
BLK
Type K
Thermocouple
Signal
Heater Power
(Below Cover)
Oxygen
Signal
PROBE
Terminal
Block
Ground
Lugs
REMOTE
ELECTRONICS
Calibration
Handshake/
Logic I/O
4-20 mA
Signal
Line Voltage
-
+
-
+
4-20
AC
AC
N
L1
Terminal
Block
(BY FACTORY)
TO ELECTRONICS
GRN
YEL
ORN
RED
BLK
BLK
Interconnecting
Cable
1
2 3
4
5
6
Ground Lugs
2
T/C
O
CELL
HTR
WHT
BLK
RED
YEL
ORN
BLU
FROM PROBE
GRN
GRN
To IMPS 4000 or SPS 4001B
if used. Refer to IMPS 4000
or SPS 4001B
Instruction Manual
GRN
Logic I/O +
Logic I/O -
90-250 VAC, 50-60 Hz
Line Voltage Input
Line 1
Neutral
Ground
37260052
4-20 mA +
4-20 mA Ground
2-15
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Install Interconnecting
Cable
NOTE
If interconnect cable was not purchased with the Hazardous Area Oxymitter
4000, consult the factory for the proper wire type and gauge.
1. Remove cover (27, Figure 9-4) from the junction box (5). Connect the
electronics end of the interconnecting cable (9) to the "FROM PROBE"
side of the terminal block (Figure 2-10).
2. Loosen screw (32, Figure 9-3), cover lock (34) and gasket (33) at the
probe head. Remove cover (27).
3. See (Figure 2-10). Connect the heater power leads, the thermocouple
leads, and the oxygen signal leads of the interconnecting cable to the
terminal block. The cable leads are tagged for polarity. To avoid a shock
hazard, the heater power terminal cover must be installed.
4. Install covers (27, Figure 9-3 and Figure 9-4) and secure with gasket
(33), cover locks (34), and screws (32).
PNEUMATIC
INSTALLATION
OXYMITTER 4000
Reference Air Package
After the Oxymitter 4000 is installed, connect the reference air set to the
Oxymitter 4000. Refer to Figure 2-11.
Instrument Air (Reference Air): 10 psig (68.95 kPag) minimum, 225 psig
(1551.38 kPag) maximum at 2 scfh (56.6 L/hr) maximum; less than 40
parts per million total hydrocarbons. Regulator outlet pressure should be
set at 5 psi (35 kPa). Reference air can be supplied by the reference air
set of the IMPS 4000 or SPS 4001B.
If using an IMPS 4000, refer to the IMPS 4000 Intelligent Multiprobe Test
Gas Sequencer Instruction Manual for the proper reference air connections.
If using an SPS 4001B, refer to the SPS 4001B Single Probe Autocalibration Sequencer Instruction Manual for the proper reference air connections.
Do not use 100% nitrogen as a low gas (zero gas). It is suggested that gas for the low (zero)
be between 0.4% and 2.0% O2. Do not use gases with hydrocarbon concentrations of more
than 40 parts per million. Failure to use proper gases will result in erroneous readings.
Calibration Gas
Two calibration gas concentrations are used with the Oxymitter 4000, Low
Gas - 0.4% O2 and High Gas - 8% O2. See Figure 2-12 for the Oxymitter
4000 connections.
2-16
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 2-11. Air Set, Plant Air
Connection
0.125-27 NPT Female
Outlet Connection
1
2
Outlet
3.12 (79,25) Max
2.250 (57,15)
3
4.81 (122,17)
0.25-18 NPT Female
Inlet Connection
Flow Set
Point Knob
1.19
(30,22)
2.0
(50,80)
1.50
(38,10)
Drain Valve
10.0
(254)
REF
SMART FAMILY
HARTTM
8.50
(215,90)
Max
2 Mounting Holes
3.19 (81,03) Lg
through Body for
0.312 (7,92) Dia Bolts
Replacement Parts
1
2
3
To Electronics
Rosemount Analytical Inc.
Orrville, OH 44667-0901
800-433-6076
Note: Dimensions are in inches with
millimeters in parentheses.
Flowmeter
2" Pressure Gage
Combination Filter-Reg.
0.2-2.0 scfh
0-15 psig
0-30 psig
771B635H02
275431-006
4505C21G01
R
TM
OXYMITTER 4000
SERIAL NO.
TAG NO.
VOLTS: 85-264 VAC 48-62 Hz
OUTPUT: 4-20 mA LINE FUSE:
WATTS:
500 VA
5 Amps
Instrument Air Supply
10-225 psig Max Pressure
Ref Air Set
263C152G01
Schematic Hookup for Reference Air Supply on Oxymitter 4000 Probe Head.
26170035
0.250 or 6 mm O.D. Tubing
(Supplied by Customer)
Figure 2-12. Oxymitter 4000
Gas Connections Calibration
Gas Connections
R
Rosemount Analytical Inc.
Orrville, OH 44667-0901
800-433-6076
SMART FAMILY
HARTTM
R
TM
500 VA
5 Amps
Reference Air
Calibration Gas
26170025
OXYMITTER 4000
SERIAL NO.
TAG NO.
VOLTS:
WATTS:
85-264
VAC 48-62 Hz
OUTPUT: 4-20 mALINE
FUSE:
2-17
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
IMPS 4000
CONNECTIONS
See the IMPS 4000 Intelligent Multiprobe Sequencer Instruction Manual for
wiring and pneumatic connection.
SPS 4001B
CONNECTIONS
See the SPS 4001B Single Probe Autocalibration Sequencer Instruction
Manual for wiring and pneumatic connection.
NOTE:
Upon completing installation, make sure that the Oxymitter 4000 is turned on
and operating prior to firing up the combustion process. Damage can result
from having a cold Oxymitter 4000 exposed to the process gases.
During outages, and if possible, leave all Oxymitter 4000 units running to
prevent condensation and premature aging from thermal cycling.
If the ducts will be washed down during outage, MAKE SURE to power down the Oxymitter
4000 units and remove them from the wash areas.
2-18
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Section 3
Oxymitter 4000
Configuration of Oxymitter 4000
with Membrane Keypad
Verify Installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 3-1
Logic I/O . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 3-5
VERIFY INSTALLATION
Install all protective equipment covers and safety ground leads before equipment startup.
Failure to install covers and ground leads could result in serious injury or death.
Mechanical Installation
Terminal Block Wiring
Ensure the Oxymitter 4000 is installed correctly. See Section 2: Installation.
1. Remove screw (32, Figure 9-3 or Figure 9-4), gasket (33), and cover
lock (34) that secure the housing cover (27). Remove the cover to
expose the terminal block (25).
2. Check the terminal block wiring (Figure 3-1). Be sure the power,
4-20 mA signal, and the logic outputs are properly connected and
secure. To avoid a shock hazard, the power terminal cover must be
installed. For units with remote electronics, check the terminal block
wiring at the probe and at the remote electronics unit.
3. Install the housing cover (27, Figure 9-3 or Figure 9-4) on the terminal
block (25) and secure with cover lock (34), gasket (33), and screw (32).
http://www.processanalytic.com
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 3-1. Electronics Housing
Terminals and Membrane
Keypad
Oxymitter 4000
Electronics
Housing
Rosemount Analytical Inc.
Orrville, OH 44667-0901
800-433-6076
SMART FAMILY
HARTTM
R
TM
OXYMITTER 4000
SERIAL NO.
TAG NO.
VOLTS: 85-264 VAC 48-62 Hz WATTS:
OUTPUT: 4-20 mA LINE FUSE:
500 VA
5 Amps
L1
N
INC
Terminal
Block
INC
HIGH
GAS
LOW
GAS
DEC
DEC
02 CELL mV +
02 CELL mv HEATER T/C +
HEATER T/C -
TP1
J1
TP2
TP3
TP4
CAL
TEST GAS +
PROCESS % 02
TP5
TP6
37260009
Logic I/O
Ground Lugs
Oxymitter 4000
Configuration
SW2
ON
AC
AC
TEST
POINTS
4-20 mA
Signal
HEATER T/C
HEATER
02 CELL
CALIBRATION
RED
YEL
GRN
ORG
-
+
-
+
4-20
DIAGNOSTIC
ALARMS
CALIBRATION RECOMMENDED
Located on the microprocessor board, the top board, are two switches that
configure outputs for the Oxymitter 4000 (Figure 3-2). SW1 determines if the
4-20 mA signal is internally or externally powered. SW2 determines:
1. Oxymitter 4000 status, HART or LOCAL.
2. Oxygen range, 0 to 10% O2 or 0 to 25% O2. (0 to 40% O2 is also
configurable only through HART/AMS.)
3. The 4-20 mA signal, at fault or power up, 3.5 mA or 21.6 mA.
Remove power from the Oxymitter 4000 before changing defaults. If defaults are changed
under power, damage to the electronics package may occur.
SW1 Setting
The two settings are internally or externally powering the 4-20 mA signal. The
factory setting is for the 4-20 mA signal to be internally powered.
3-2
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
SW2 Setting
The factory sets this switch as follows:
1. Position 1 is HART/LOCAL. This switch setting controls the configuration of the Oxymitter 4000. The defaults cannot be changed via
HART/AMS unless the switch is in the HART position. Placing SW2,
position 1 in the LOCAL position forces the O2 range to the setting of
position 2. The position 1 switch must be placed in the LOCAL position
or changes in SW2, position 2 will have no effect.
2. Position 2 determines the O2 range. This can be set to either 0 to 10%
O2 or 0 to 25% O2. The factory setting is 0 to 10% O2. If necessary, the
O2 range can be configured from 0 to 40% O2. To select values within
this range, set SW2, position 1 to HART and then enter the range via
HART/AMS. Do not change SW2, position 1 to LOCAL unless you want
to operate in the range specified by SW2, position 2.
Typically, the probe's sensing cell, in direct contact with the process gases, is heated to
approximately 736°C (1357°F). The external temperature of the probe body may exceed
450°C (842°F). If operating conditions also contain high oxygen levels and combustible
gases, the Oxymitter 4000 may self-ignite.
3. Position 3 determines the output at startup or at an alarm. The settings
are 3.5 mA or 21.6 mA. The factory setting is 3.5 mA. At startup, the
current at the analog output is 3.5 mA or 21.6 mA.
4. Position 4 can be used to set the heater for 115 or 220 VAC operation.
This switch is functional only when the software is set for manual
voltage selection (Auto Tune = No). Otherwise, the internal electronics
auto detect the input line voltage and sets the heater voltage
accordingly (Auto Tune = Yes).
3-3
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 3-2. Defaults - Oxymitter
4000 with Membrane Keypad
HART: O2 Range set by HART/AMS
(From 0 to 40% O2)
Local: O2 Range set by Pos 2
0 to 10% O2 /
0 to 25% O2: O2 Range
3.5 mA/21.6 mA: When alarm exists, or on powerup, output current goes to this
value
ON
OFF
4-20 mA
is internally
powered (Default)
Local
HART
0 to 25% O2
0 to 10% O2
21.6 mA
3.5 mA
115 V
220 V
Default
position
(Ex-factory)
4-20 mA requires
external power
SW
1
HEATER T/C
HEATER
O2 CELL
CALIBRATION
SW2
ON
DIAGNOSTIC
ALARMS
Note:
1
2
3
4
CALIBRATION RECOMMENDED
INC
HIGH
GAS
LOW
GAS
DEC
DEC
J1
TP2
TP3
TP4
CAL
TEST GAS +
PROCESS % O2
TP5
TP6
37260010
INC
TP1
RED
YEL
GRN
ORG
TEST
POINTS
O2 CELL mV +
O2 CELL mV HEATER T/C +
HEATER T/C -
The 115 V option at switch
SW2 position 4 is active only
when the heater voltage
option is set to manual in the
software
(auto tune = no).
Read O2 Concentration
Once the cell is up to operating temperature, the O2 percentage can be read:
1. Access TP5 and TP6 next to the membrane keypad. Attach a
multimeter across TP5 and TP6. The calibration and process gases can
now be monitored. Pressing the INC or DEC once will cause the output
to switch from the process gas to the calibration gas. Pressing INC or
DEC a second time will increase or decrease the calibration gas
parameter. If the keys have been inactive for one minute, the output
reverts to the process gas. If the keys have been inactive for one
minute, the output reverts to the process gas.
3-4
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
When a calibration has been initiated, the value at TP5 and TP6 is the
% O2 seen by the cell.
Oxygen levels, as seen on the multimeter, are:
8.0% O2 = 8.0 VDC
0.4% O2 = 0.4 VDC
2. HART/AMS.
3. Model 751. The loop-driven LCD display.
LOGIC I/O
Table 3-1. Logic I/O
Configuration (as set at
HART/AMS or LOI)
This two-terminal logic contact can be configured either as a solid-state
relay-activated alarm or as a bi-directional calibration handshake signal to an
IMPS 4000 or SPS 4001B. The configuration of this signal depends on the
setting of the LOGIC I/O PIN MODE via HART/AMS or LOI. The ten different
modes available are explained in Table 3-1.
Mode
Configuration
0
1
2
3
4
The unit is not configured for any alarm condition.
The unit is configured for a Unit Alarm.
The unit is configured for Low O2.
The unit is configured for both a Unit Alarm and Low O2.
The unit is configured for a High AC Impedance/CALIBRATION
RECOMMENDED.
The unit is configured for both a Unit Alarm and a High AC
Impedance/CALIBRATION RECOMMENDED.
The unit is configured for both a Low O2 and High AC Impedance/CALIBRATION
RECOMMENDED.
The unit is configured for a Unit Alarm, a Low O2, and a High AC
Impedance/CALIBRATION RECOMMENDED.
The unit is configured for a calibration handshake with IMPS 4000 or SPS 4001B.
CALIBRATION RECOMMENDED will initiate the calibration cycle.
The unit is configured for a calibration handshake. CALIBRATION
RECOMMENDED will not initiate the calibration cycle with the IMPS 4000 or
SPS 4001B.
5*
6
7
8**
9
*The default condition for an Oxymitter 4000 without an IMPS 4000 or SPS 4001B.
**The default condition for an Oxymitter 4000 with an IMPS 4000 or SPS 4001B.
Alarm
When configured as an alarm, this signal alerts you to an out-of-spec
condition. The output is 5 V in series with a 340 ohm resistor. For optimum
performance, Emerson Process Management recommends connecting the
output to a Potter & Brumfield 3.2 mA DC relay (P/N R10S-E1Y1-J1.0K).
Of the ten modes in Table 3-1, mode 1 through mode 7 are the alarm modes.
The factory default is mode 5 for Oxymitter 4000 units without an IMPS 4000
or SPS 4001B. In this mode, the output will signal when a unit alarm or a
CALIBRATION RECOMMENDED indication occurs.
3-5
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Calibration Handshake Signal
If using an optional IMPS 4000 or SPS 4001B, the logic I/O must be
configured for calibration handshaking. Of the ten modes in Table 3-1, only
modes 8 and 9 are configured for calibration handshaking. For an Oxymitter
4000 with an IMPS 4000 or an SPS 4001B, the factory sets the default to
mode 8. In this mode, the logic I/O will be used to communicate between the
Oxymitter 4000 and sequencer and to signal the sequencer when a
CALIBRATION RECOMMENDATION indication occurs.
Recommended
Configuration
4-20 mA Signal Upon Critical Alarm
Rosemount Analytical recommends that the factory default be utilized. The
4-20 mA signal will go to the 3.5 mA level upon any critical alarm which will
cause the O2 reading to be unusable. Customer can also select 21.6 mA as
the failure setting if normal operations cause O2 readings to go below the zero
% O2 (3.5 mA) level.
If the O2 measurement is being utilized as part of an automatic control loop,
the loop should be placed into manual upon this failure event or other
appropriate action should be taken.
Calibration
Rosemount Analytical recommends utilizing an autocalibration system,
actuated by the "calibration recommended" diagnostic. New O2 cells may
operate for more than a year, but older cells may require recalibration every
few weeks as they near the end of their life. This strategy ensures that the O2
reading is always accurate, and eliminates many unnecessary calibrations
based on calendar days or weeks since previous calibration. When utilizing
the SPS 4001B or IMPS 4000, consider wiring some or all associated alarm
contacts.
1. CALIBRATION INITIATE. Contact from the control room to an
SPS 4001B or IMPS 4000 (one per probe) provides the ability to
manually initiate a calibration at any time from the control room. Note
that calibrations can also be initiated from a HART handheld
communicator, from Asset Management Solutions software, or from the
keypad on the Oxymitter 4000.
2. IN CALIBRATION. One contact per probe provides notification to the
control room that the "calibration recommended" diagnostic has initiated
an automatic calibration through the SPS 4001B or IMPS 4000. If the O2
signal is being utilized in an automatic control loop, this contact should
be utilized to place the control loop into manual during calibration.
3. CALIBRATION FAILED. One contact per probe from an SPS 4001B or
IMPS 4000 to the control room for notification that the calibration
procedure failed. Grouped with this alarm is an output from a pressure
switch which indicates when the calibration gas bottles are empty.
4. 4-20 mA SIGNAL DURING CALIBRATION. The 4-20 mA signal can be
configured to respond normally during any calibration, or it can be
configured to hold the last O2 value upon the initiation of calibration. The
factory default is for the 4-20 mA signal to operate normally throughout
calibration. Holding the last O2 value may be useful if several probes are
being averaged for the purpose of automatic control. Unless several
probes are being averaged, always place control loops that are using
the O2 signal into the manual mode prior to starting the calibration.
3-6
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Section 4
Oxymitter 4000
Configuration of Oxymitter 4000
with LOI
Verify installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 4-1
Logic I/O . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 4-4
VERIFY INSTALLATION
Install all protective equipment covers and safety ground leads before equipment startup.
Failure to install covers and ground leads could result in serious injury or death.
Mechanical Installation
Terminal Block Wiring
Ensure the Oxymitter 4000 is installed correctly. See Section 2: Installation.
1. Remove screw (32, Figure 9-3 or Figure 9-4), gasket (33), and cover
lock (34) that secure the housing cover (27). Remove the cover to
expose the terminal block (25).
2. Check the terminal block wiring, Figure 4-1. Be sure the power, 4-20 mA
signal, and logic outputs are properly connected and secure.
3. Install the housing cover (27, Figure 9-3 or Figure 9-4) on the terminal
block and secure with cover lock (34), gasket (33), and screw (32).
http://www.processanalytic.com
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 4-1. Electronics Housing
Terminals with LOI
Oxymitter 4000
Electronics
Housing
Rosemount Analytical Inc.
Orrville, OH 44667-0901
800-433-6076
SMART FAMILY
HARTTM
R
TM
OXYMITTER 4000
SERIAL NO.
TAG NO.
VOLTS: 85-264 VAC 48-62 Hz WATTS:
OUTPUT: 4-20 mA LINE FUSE:
500 VA
5 Amps
-
+
-
+
4-20
AC
AC
N
L1
4-20 mA
Signal
Terminal
Block
LOI
Ground Lugs
Oxymitter 4000
Configuration
37260011
Logic I/O
Located on the microprocessor board are two switches that configure outputs
(Figure 4-2). To access these switches, the LOI module must be removed.
SW1 determines if the 4-20 mA signal is internally or externally powered.
SW2 determines:
1. Range control, HART or LOCAL.
2. Oxygen range, 0 to 10% O2 or 0 to 25% O2. (0 to 40% O2 is also
configurable only through HART/AMS.)
3. The 4-20 mA signal, at fault or power up, 3.5 mA or 21.6 mA.
Remove power before changing defaults. If defaults are changed under power, damage to
the electronics package may occur.
SW1 Setting
The two settings are internally or externally powering the 4-20 mA signal. The
factory setting is for the 4-20 mA signal to be internally powered.
4-2
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
SW2 Setting
The factory sets this switch as follows:
1. Position 1 is HART/LOCAL. This switch setting controls the configuration of the Oxymitter 4000. The defaults cannot be changed via
HART/AMS or the LOI unless the switch is in the HART position. Placing
SW2, position 1 in the LOCAL position forces the O2 range to the setting
of position 2. The position 1 switch must be in the LOCAL position or
changes in SW2, position 2 will have no effect.
2. Position 2 determines the O2 range. This can be set to either 0 to 10%
O2 or 0 to 25% O2. The factory setting is 0 to 10% O2. If necessary, the
O2 range can be configured from 0 to 40% O2. To select values within
this range, set SW2, position 1 to HART and then enter the range via
HART/AMS or the LOI. Do not change SW2, position 1 to LOCAL
unless you want to operate in the range specified by SW2, position 2.
Typically, the probe's sensing cell, in direct contact with the process gases, is heated to
approximately 1357°F (736°C). The external temperature of the probe body may exceed
842°F (450°C). If operating conditions also contain high oxygen levels and combustible
gases, the Oxymitter 4000 may self-ignite.
3. Position 3 determines the output at startup or at an alarm. The settings
are 3.5 mA or 21.6 mA. The factory setting is 3.5 mA. At startup, the
current at the analog output is 3.5 mA or 21.6 mA.
4. Position 4 can be used to set the heater for 115 or 220 VAC operation.
This switch is functional only when the software is set for manual
voltage selection (Auto Tune = No). Otherwise, the internal electronics
auto detect the input line voltage and sets the heater voltage
accordingly (Auto Tune = Yes).
Read O2 Concentration
Once the cell is up to operating temperature, the O2 percentage can be read:
1. To access TP5 and TP6 under the LOI module (Figure 4-2), power
down the Oxymitter 4000 and remove the LOI module. Attach alligator
leads from a multimeter across TP5 and TP6. Install the LOI module
and power up the Oxymitter 4000. Allow time for the cell to reach
operating temperature. The calibration and process gases can now be
monitored. When a calibration has been initiated, the value at TP5 and
TP6 is the % O2 seen by the cell. Oxygen levels, as seen on the
multimeter, are:
8.0% O2 = 8.0 VDC
0.4% O2 = 0.4 VDC
2. HART/AMS.
3. Model 751. The loop-driven LCD display.
4-3
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 4-2. Defaults - Oxymitter
4000 with LOI
HART: O2 Range set by HART/AMS
(From 0 to 40% O2)
Local: O2 Range set by Pos 2
0 to 10% O2/
0 to 25% O2: O2 Range
3.5 mA/21.6 mA When alarm exists, or
on power up, current
output goes to this value
ON
OFF
4-20 mA
is internally
powered
(Default)
Local
HART
0 to 25% O2
0 to 10% O2
21.6 mA
3.5 mA
220 V
115 V
Default
position
(Ex-factory)
4-20 mA requires
external power
SW
1
SW2
Note:
1
2
3
4
TP1
J1
TP2
The 115 V option
at switch SW2
position 4 is active
only when the
heater voltage
option is set to
manual in the
software.
TP4
RED
YEL
GRN
ORG
TP3
TP5
37260012
TP6
LOGIC I/O
This two-terminal logic contact can be configured either as a solid-state
relay-activated alarm or as a bi-directional calibration handshake signal to an
IMPS 4000 or SPS 4001B. The configuration of this signal depends on the
setting of the LOGIC I/O PIN MODE via HART/AMS or LOI. The ten different
modes available are explained in Table 4-1.
Alarm
When configured as an alarm, this signal alerts you to an out-of-spec
condition. The output is +5 Vdc in series with a 340 ohm resistor.
For optimum performance, Rosemount Analytical recommends connecting
the output to a Potter & Brumfield 3.2 mA DC relay (P/N R10S-E1Y1-J1.0K).
4-4
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Of the ten modes in Table 4-1, mode 1 through mode 7 are the alarm modes.
The factory default is mode 5 for Oxymitter 4000 units without an IMPS 4000
or SPS 4001B. In this mode, the output will signal when a unit alarm or a
CALIBRATION RECOMMENDED indication occurs.
Calibration Handshake Signal
If using an optional IMPS 4000 or SPS 4001B, the logic I/O must be
configured for calibration handshaking. Of the ten modes in Table 4-1, only
modes 8 and 9 are configured for calibration handshaking. For an Oxymitter
4000 with an IMPS 4000 or an SPS 4001B, the factory sets the default to
mode 8. In this mode, the logic I/O will be used to communicate between the
Oxymitter 4000 and the sequencer and to signal the sequencer when a
CALIBRATION RECOMMENDED indication occurs.
Table 4-1. Logic I/O
Configuration (as set at
HART/AMS or LOI)
Mode
Configuration
0
1
2
3
4
The unit is not configured for any alarm condition.
The unit is configured for a Unit Alarm.
The unit is configured for Low O2.
The unit is configured for both a Unit Alarm and Low O2.
The unit is configured for a High AC Impedance/CALIBRATION
RECOMMENDED.
The unit is configured for both a Unit Alarm and a High AC
Impedance/CALIBRATION RECOMMENDED.
The unit is configured for both a Low O2 and High AC Impedance/CALIBRATION
RECOMMENDED.
The unit is configured for a Unit Alarm, a Low O2, and a High AC
Impedance/CALIBRATION RECOMMENDED.
The unit is configured for a calibration handshake with IMPS 4000 or SPS 4001B.
CALIBRATION RECOMMENDED will initiate the calibration cycle.
The unit is configured for a calibration handshake. CALIBRATION
RECOMMENDED will not initiate the calibration cycle with the IMPS 4000 or SPS
4001B.
5*
6
7
8**
9
*The default condition for an Oxymitter 4000 without an IMPS 4000 or SPS 4001B.
**The default condition for an Oxymitter 4000 with an IMPS 4000 or SPS 4001B.
4-5
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Recommended
Configuration
Recommended Configuration
4-20 mA Signal
The 4-20 mA signal is linear, and can be ranged by the user for O2 range from
0-40% O2. It should be noted that the 4-20 mA signal will go to one of several
default values under certain conditions:
Condition
Default
Option
In calibration
4-20 mA signal responds
normally to cal gas
4-20 mA signal holds last value during
cal. (recommended only if several O2
probes are being averaged together)
none
O2 over preset
range
4-20 mA signal defaults to
20.5 mA
Critical alarm
4-20 mA signal defaults to
3.5 mA
4-20 mA signal dfaults to 21.1 mA
Dead Instrument
4-20 mA signal goes to
zero mA
none
It is very important that the control system be configured to recognize these
various signal levels, and operators be briefed as to their meaning.
Calibration
Rosemount Analytical recommends utilizing an autocalibration system,
actuated by the "calibration recommended" diagnostic. New O2 cells may
operate for more than a year, but older cells may require recalibration every
few weeks as they near the end of their life. This strategy ensures that the O2
reading is always accurate, and eliminates many unnecessary calibrations
based on calendar days or weeks since previous calibration. When utilizing
the SPS 4001B or IMPS 4000, consider wiring some or all associated alarm
contacts.
1. CALIBRATION INITIATE. Contact from the control room to an SPS
4001B or IMPS 4000 (one per probe) provides the ability to manually
initiate a calibration at any time from the control room. Note that
calibrations can also be initiated from a HART handheld communicator,
from Asset Management Solutions software, or from the keypad on the
Oxymitter 4000.
2. IN CALIBRATION. One contact per probe provides notification to the
control room that the "calibration recommended" diagnostic has initiated
an automatic calibration through the SPS 4001B or IMPS 4000. If the O2
signal is being utilized in an automatic control loop, this contact should
be utilized to place the control loop into manual during calibration.
3. CALIBRATION FAILED. One contact per probe from an SPS 4001B or
IMPS 4000 to the control room for notification that the calibration
procedure failed. Grouped with this alarm is an output from a pressure
switch which indicates when the calibration gas bottles are empty.
4. 4-20 mA SIGNAL DURING CALIBRATION. The 4-20 mA signal can be
configured to respond normally during any calibration, or it can be
configured to hold the last O2 value upon the initiation of calibration. The
factory default is for the 4-20 mA signal to track (operate normally)
throughout calibration. Holding the last O2 value may be useful if
several probes are being averaged for the purpose of automatic control.
Unless several probes are being averaged, always place control loops
that are using the O2 signal into the manual mode prior to starting the
calibration.
4-6
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Section 5
Startup and Operation of
Oxymitter 4000 with Membrane
Keypad
Power Up . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 5-1
Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 5-2
POWER UP
Startup Display
When power is applied to the probe, the cell heater turns on. It takes
approximately one half hour for the cell to heat to operating temperature. This
condition is indicated by the top four LEDs (DIAGNOSTIC ALARMS) on the
membrane keypad (Figure 5-1). Starting with the CALIBRATION LED, the
LEDs light in ascending order until all four LEDs are on. At this point, all four
turn off and the cycle starts again. This ramp cycle continues until the cell is
up to operating temperature.
Operating Display
The ramp cycle turns into a cycle where the diagnostic LEDs light in sequence
from the top to the bottom, one at a time. After the bottom LED turns on, the
sequence starts again at the top with the HEATER T/C LED (Figure 5-1).
Figure 5-1. Startup and Normal Operation
HEATER T/C
HEATER
HEATER T/C
HEATER
O2 CELL
CALIBRATION
O2 CELL
SW2
CALIBRATION
ON
DIAGNOSTIC
ALARMS
CALIBRATION RECOMMENDED
INC
HIGH
GAS
LOW
GAS
DEC
DEC
TP1
1
J1
TP3
TP4
2
3
4
1
2
3
4
Lighting sequence during warm-up
(Startup display)
TP2
HEATER T/C
CAL
HEATER
TEST GAS +
PROCESS % O2
TP5
O2 CELL
TP6
CALIBRATION
1
2
3
4
1
2
3
4
Lighting sequence during normal operation
(Operating display)
http://www.processanalytic.com
22220056
INC
O2 CELL mV +
O2 CELL mv HEATER T/C +
HEATER T/C -
RED
YEL
GRN
ORG
TEST
POINTS
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Error
If there is an error condition at startup, one of the diagnostics LEDs will be
blinking. Refer to Section 8: Troubleshooting, to determine the cause of the
error. Clear the error, cycle power, and the operating display should return.
Keypad
The five membrane keys on the membrane keypad are only used during
calibration to adjust the high and low gas and to initiate the calibration
sequence (Figure 5-2).
Reference Air
Ensure reference air, if used, is set to 0.25 l/min (0.5 scfh)
OPERATION
Overview
Ensure the Oxymitter 4000 is at normal operation. The diagnostic LEDs will
display the operating cycle. All other LEDs should be off (See Figure 5-1).
DIAGNOSTIC ALARM LEDs
If there is an error in the system, one of these LEDs will flash various blink
codes (See Section 8: Troubleshooting). In the case of multiple errors, only
one will be displayed based on a priority system. Correct the problem and
cycle power. The operating display will return or the next error will be
displayed. The alarms are:
HEATER T/C
HEATER
O2 CELL
CALIBRATION
CALIBRATION RECOMMENDED LED
Turns on when the system determines that a calibration is recommended.
Further information is available in Section 9: Maintenance and Service.
TEST POINTS
Test points 1 through 6 will allow you to monitor with a multimeter: the heater
thermocouple, O2 cell millivolt, and the process O2.
1. TP1 and TP2 monitor the oxygen cell millivolt output which equates to
the percentage of oxygen present.
2. TP3 and TP4 monitor the heater thermocouple.
3. TP5 and TP6 monitor the process gas or the calibration gas parameter.
CAL LED
The CAL LED is on steady or flashing during calibration. Further information
is available in Section 9: Maintenance and Service.
5-2
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 5-2. Calibration Keys
Diagnostic
LEDs
Membrane
Keys
DIAGNOSTIC
ALARMS
HEATER T/C
HEATER
02 CELL
CALIBRATION
CALIBRATION RECOMMENDED
INC
INC
HIGH
GAS
LOW
GAS
DEC
DEC
02 CELL mV +
02 CELL mv HEATER T/C +
HEATER T/C -
CAL
TEST GAS +
PROCESS % 02
Membrane
Key
Membrane
Keys
22220023
TEST
POINTS
Keys
INC and DEC. The INC and DEC keys are used to set the values of the
calibration gases. Attach a multimeter across TP5 and TP6. The calibration
and process gases can now be monitored. Pressing the INC or DEC once will
cause the output to switch from the process gas to the calibration gas.
Pressing INC or DEC a second time will increase or decrease the calibration
gas parameter. If the keys have been inactive for one minute, the output
reverts to the process gas. When a calibration has been initiated, the value at
TP5 and TP6 is the % O2 seen by the cell.
Oxygen levels, as seen on the multimeter, are:
8.0% O2 = 8.0 volts DC
0.4% O2 = 0.4 volts DC
CAL
The CAL key can:
• Initiate a calibration.
• Sequence through calibration.
• Abort the calibration.
NOTE
Refer Section 9: Maintenance and Service, for calibration instructions.
Model 751 Remote Powered Loop LCD Display (Optional)
Refer to Remote Powered Loop LCD manual for calibration and operation.
5-3
Instruction Manual
Oxymitter 4000
5-4
IM-106-340, Rev. 4.0
February 2006
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Section 6
Oxymitter 4000
Startup and Operation of
Oxymitter 4000 with LOI
Power Up . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 6-1
Start Up Oxymitter 4000 Calibration . . . . . . . . . . . . . . . . . page 6-3
Navigating the Local Operator Interface . . . . . . . . . . . . . page 6-3
LOI Key Designations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 6-4
LOI Menu Tree . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 6-4
Oxymitter 4000 Setup at the LOI . . . . . . . . . . . . . . . . . . . . page 6-6
LOI Installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 6-9
Oxymitter 4000 Test Points . . . . . . . . . . . . . . . . . . . . . . . . page 6-10
Remote Powered Loop LCD Display (Optional) . . . . . . . . page 6-10
POWER UP
Startup Display
When power is applied to the probe, the cell heater turns on. It takes
approximately one half hour for the cell to heat to operating temperature. This
condition is indicated by a "warm up" display on the LOI (Figure 6-1). This
message will continue to display until the cell is up to operating temperature.
Operating Display
The normal operating display is the % O2 concentration. The "normal" display
is shown in Figure 6-2.
Error
If there is an error condition at startup, an alarm message will be displayed.
Refer to Section 8: Troubleshooting, to determine the cause of the error. Clear
the error, cycle power, and the % O2 display should return.
LOI
The Local Operator Interface can be used to change the software and alarm
settings, to adjust the high and low gas settings, and to initiate the calibration
sequence. Refer to the LOI menu (Figure 6-4).
http://www.processanalytic.com
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 6-1. Startup Display
37260035
O2:
Ø.ØØ%
LK
warm up
367dgC
Figure 6-2. O2 Concentration
Display
LK
37260036
O2:
2.59%
normal
6-2
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 6-3. LOI Features
Selection
Arrow
Touch
Confirmation
LED
Selection
Arrow
Selection
Arrows
START UP OXYMITTER
4000 CALIBRATION
37260054
LCD
Display
Window
Refer to Section 9: Maintenance and Service, for calibration instructions.
NAVIGATING THE
LOCAL OPERATOR
INTERFACE
Overview
The Local Operator Interface (LOI), shown in Figure 6-3, utilizes a bright blue
gas-fluorescent display. Intensity is adjustable. There is an Infrared LED
source and a detector for each key. The detectors can detect a finger placed
above the button through the glass window. There is no need to open the
instrument in bad weather in order to access the electronics.
It should be noted that the Oxymitter 4000 also utilizes HART communications, permitting access to all instrument functionality anywhere the 4-20 mA
signal terminates via a HART model 275/375 handheld communicator.
Lockout
The Local Operator Interface (LOI) has a lockout feature that prevents nuisance actuation by someone brushing against the glass window, raindrops,
dirt, insects, etc. This lockout mode is automatically established when no buttons are pushed for 30 seconds (default). This countdown to lockout is configurable.
6-3
Instruction Manual
Oxymitter 4000
IM-106-340, Rev. 4.0
February 2006
In order to unlock the display, input a "Z" pattern. First, push the top left (gray)
arrow, then the top right, followed by the bottom left and finally the bottom
right. The "LK" notation in the upper right corner of the display will now disappear. Push the gray arrow at the top left hand corner once more to enter
into the menu structure. Once one moves deeper into the menu structure,
additional time is provided to the user so that the lockout initiation does not
become a nuisance. This additional "revert" time is defaulted at one hour and
is also user configurable.
LOI KEY DESIGNATIONS
The gray key (top left) will move one level higher in the menu structure. When
entering numbers, this key will move the cursor to the left. This key also doubles as an "Enter" key, once numbers are entered, and when the cursor is
moved to it's left-most position. The new data entry value will appear in the
top line of the LOI display once it is accepted.
The blue key (bottom left) acts as a selector when choosing from among a
number of menu items. This key also will move the cursor to the right when
entering numbers.
Up/Down keys (to the left side of the keypad) are used to increment up and
down when selecting from a series of menu picks. They are also used for
incrementing values up and down for data input.
LOI MENU TREE
This LOI menu for the Oxymitter 4000 is shown in Figure 6-4. This menu tree
is specific to the Oxymitter 4000. The menu tree will assist in navigating the
LOI.
Menu items in normal text display information, only. Menu Items in italics permit data entry. Menu items in bold text are procedures.
6-4
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 6-4. Menu Tree for Local
Operator Interface on the
Oxymitter 4000 (Sheet 1 of 2)
O2 Temp
O2 Temp-MAX
Board Temp
Board Temp-MAX
Temperatures
SENSOR
DATA
_____dgC
_____dgC
_____dgC
_____dgC
Voltages
O2 Sensor
O2 Sensor T/C
Board Temp IC
_____mV
_____mV
_____mV
Output Values
O2 Analog %
O2 Analog mA
_____%
____mA
O2 Slope
O2 Constant
O2 Cell Imped
____ mV/D
____ mV
____ ohm
Pre O2 Slope
Pre O2 Constant
_____mV/D
_______mV
O2% 2.59% LK
normal
Start Calib
NOTE
Use Z pattern
touch command
to unlock menu.
Current Calib
Previous
CALIBRATION
Cal Constants
Failed Calib
Cal Status
(CONTINUED ON
SHEET 2)
Bad O2 Slope
Bad O2 Constant
Calib Step
Calib Time
Next O2 Cal
_____mV/D
_______mV
_______
___Sec.
___H
NOTE
For this menu column, the
selections in Italics are
user configurable. All other
parameters are display only.
Idle
Recommend Cal
Apply Gas 1
Flow Gas 1
Read Gas 1
Done Gas 1
Apply Gas 2
Flow Gas 2
Read Gas 2
Done Gas 2
Cal Abort
Stop Gas
Purge
37260017
Abort Calib
6-5
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 6-4. Menu Tree for Local
Operator Interface (LOI) on the
Oxymitter 4000 (Sheet 2 of 2)
O2 Gas 1
O2 Gas 2
O2-Reset Vals
O2 Out Tracks
O2 Cal Intervl
O2-Next Cal
Gas Time
Purge Time
Auto Calib?
Calib Setup
Analog
Input/Output
Digital
SYSTEM
_____%
_____%
Yes/No
Yes/No
____H
____H
___Sec.
___Sec.
Yes/No
O2 Type
O2 Range
O2 Alarm Level
Do O2 Trim
_______
______%
_____mA
Logic IO Mode See Table 4-1
Low O2 Alarm See “Abort
Calibration” in Section 9.
Input State
Force Output
Parameters
O2 Slope
O2 Constant
O2 T90 Time
Auto Tune?
Lockout Time
Revert Time
Luminance
____ mV/D
____ mV
0:00
Yes/No
0:00
0:00
______
Software
Version
Checksum
Build Number
Build Date
Test Code
SW Err File
SW Err Line
xxx
xxx
xxx
xxxxxx
xx
xx
xx
Status
Alarms
__________
PID Parameters
115/220
Reset Device?
Yes/No
(Cal. required after reset)
NOTE
In column four of this menu, the selections in Italics are user configurable. Bold text selections are
procedures; related instructions are displayed on the LOI. All other parameters are display only.
OXYMITTER 4000 SETUP
AT THE LOI
37260018
(CONTINUED FROM
SHEET 1)
In setting up the Oxymitter 4000 from the LOI, it is best to start at the
SYSTEM/Calibration Setup menu, Figure 6-4.
SYSTEM/Calibration Setup
O2 Gas #1 - Enter the high or low cal gas value (the order is not important).
O2 Gas #2 - Enter the second cal gas value.
NOTE
Refer to Section 9: Maintenance and Service, for calibration instructions.
6-6
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
NOTE
Rosemount Analytical recommends 0.4% O2 and 8% O2 for calibration gases.
O2 Reset Values - Resets factory default values.
O2 Output Tracks - 4 to 20 mA signal can be held at the last value during
calibration, or the signal can be left to track the cal gases.
O2 Cal Interval - If automatic calibration is selected, this selects the interval
between calibrations.
O2 Next Cal - If automatic calibration is selected, this selects the time until
the first initial calibration takes place.
Gas Time - How long should each cal gas flow. Factory default is 300
seconds, but the user may want to vary this depending upon the length of
calibration gas tubing runs.
Purge Time - Used if the O2 output is selected to hold the last value during
calibration. After the second cal gas is removed, how long until the sensor
comes back to the normal process reading, and the 4-20 mA signal can be
released.
Auto Calib? - Select "Yes" if an SPS or IMPS autocalibration system is part of
the system.
SYSTEM/Input/Output
Analog
Pertaining to the analog 4-20 mA signal representing O2.
O2 Type - 4-20 mA signal may be configured to increase with increasing
O2 or the reverse.
O2 Range - Upper O2 range is user selectable.
O2 Alarm Level - User can configure the digital output to alarm at a given
O2 level.
Do O2 Trim - Procedure for calibrating the 4-20 mA signal to a precision
mA source. Procedure is intuitive.
Digital
A bi-directional logic signal may be configured as an alarm, or as a calibration
handshake signal.
Logic I/O Mode - One of 9 different sets of conditions can be set for the
digital signal. See Table 8-2.
Low O2 Alarm - If any of the conditions noted above include a low O2
process alarm, set the value here.
Input State - Notes the current condition of the bi-directional digital signal.
Force Output - Forces the output state of the signal to either open or
closed. This is used primarily when diagnosing potential problems with this
signal.
6-7
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
SYSTEM/Parameters
O2 Slope - O2 slope is data regarding the strength of the sensing cell output.
This information is automatically calculated after a calibration, and the user
does not normally input this data.
O2 Constant - O2 constant is the amount of voltage a cell generates with
ambient air as the calibration gas. Again, this is normally calculated as a
result of calibration, and is not normally input by the user.
O2 T90 Time - Some users may feel that the O2 reading is too active for
certain processes. This feature permits the user to dampen the O2 signal. The
default value is zero seconds dampening.
Auto Tune - The electronics detects the line voltage powering the instrument
automatically, and picks proper algorithms for heater control. User can force a
high voltage algorithm, or a low, but Auto Tune is the default, and is
recommended.
Lockout Time - Keypad lockout time default is 30 sec., but it is user
configurable. A "Z" keypad pattern will unlock the keypad.
Revert Time - Once a user goes one level deep into the menu structure, an
additional "revert time" is provided to prevent nuisance lockouts. One hour is
the default, and it is user configurable.
Luminance - Gas fluorescence brightness is user adjustable.
SYSTEM/Status
Alarms - Diagnostic alarms. Section 8: Troubleshooting.
PID Parameter - Displays the line voltage, powering the Oxymitter, and infers
the temperature control algorithm being used to control heater temperature.
Reset Device - Device can be reset here as opposed to re-powering.
Calibration parameters will be lost.
SYSTEM/Software
This is data regarding the Oxymitter 4000 software version, and errors that
may have occurred.
SENSOR DATA
Displays information about the O2 cell and thermocouple.
6-8
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Temperatures
O2 Temp - Indicates the thermocouple temperature at the sensing cell;
this should always be 736°C.
O2 Temp Max - Maximum temperature the cell has seen. (Some process
temperatures can exceed the 736°C setpoint temperature, and this will
indicate this condition.)
Board Temp - The temperature inside the Oxymitter electronics housing
(85°C is the max.).
Board Temp Max - This is the maximum temperature that the electronics
has experienced over time.
Voltages
The raw mV signals feeding the temperature indications listed in the
previous paragraph.
Output Values
Indication of the current readings for O2 and mA.
LOI INSTALLATION
The LOI module connects to the top of the electronic assembly in the
electronics housing. There are four matching connectors (Figure 6-5) on the
back of the LOI module that allow the user to orient (rotate) the LOI as
desired.
Figure 6-5. LOI Module
Connectors
LOI Module
Rear View
37260055
Connector
Receptacles
6-9
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
OXYMITTER 4000 TEST
POINTS
Refer to Figure 6-6. System test points are located on the board below the
LOI module. Test points 1 through 6 allow you to monitor with a multimeter:
the heater thermocouple, the O2 cell millivolt, and the process O2.
• TP1 and TP2 monitor the oxygen cell millivolt output which equates to
the percentage of oxygen present.
• TP3 and TP4 monitor the heater thermocouple.
• TP5 and TP6 monitor the process gas or the calibration gas parameter.
REMOTE POWERED
LOOP LCD DISPLAY
(OPTIONAL)
Refer to Remote Powered Loop LCD manual for calibration and operation.
Figure 6-6. Oxymitter 4000 Test Points
TP1
J1
TP2
TP4
RED
YEL
GRN
ORG
TP3
TP5
37260037
TP6
6-10
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Section 7
Oxymitter 4000
HART/AMS
Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 7-1
HART Communicator Signal Line Connections . . . . . . . page 7-2
HART Communicator PC Connections . . . . . . . . . . . . . . . page 7-2
Off-Line and On-Line Operations . . . . . . . . . . . . . . . . . . . page 7-4
Logic I/O Configurations . . . . . . . . . . . . . . . . . . . . . . . . . . page 7-4
HART/AMS Menu Tree . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 7-4
HART Communicator O2 Cal Method . . . . . . . . . . . . . . . . page 7-8
Defining a Timed Calibration via HART . . . . . . . . . . . . . . page 7-9
D/A Trim Procedure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 7-9
OVERVIEW
The HART Communicator is a handheld communications interface device. It
provides a common communications link to all microprocessor-based instruments that are HART compatible. The handheld communicator contains an 8
x 21 character liquid crystal display (LCD) and 25 keys. A pocket-sized manual, included with the HART Communicator, details the specific functions of all
the keys.
To interface with the Oxymitter 4000, the HART Communicator requires a termination point along the 4-20 mA current loop and a minimum load resistance
of 250 ohms between the communicator and the power supply.
The HART Communicator accomplishes its task using a frequency shift keying (FSK) technique. With the use of FSK, high-frequency digital communication signals are superimposed on the Oxymitter 4000's 4-20 mA current loop.
The HART communicator does not disturb the 4-20 mA signal, since no net
energy is added to the loop.
The HART Communicator may be interfaced with a personal computer (PC),
providing that special software has been installed. To connect the HART Communicator to a PC, an interface adapter is required. Refer to the proper HART
Communicator documentation in regard to the PC interface option.
http://www.processanalytic.com
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
HART COMMUNICATOR
SIGNAL LINE
CONNECTIONS
The HART Communicator can connect to the Oxymitter 4000's analog output
signal line at any wiring termination in the 4-20 mA current loop. There are
two methods of connecting the HART Communicator to the signal line. For
applications in which the signal line has a load resistance of 250 ohms or
more, refer to method 1. For applications in which the signal line load resistance is less than 250 ohms, refer to method 2.
Method 1, For Load Resistance
≥ 250 Ohms
Refer to Figure 7-1 and the following steps to connect the HART Communicator to a signal line < 250 ohms or more of load resistance.
Explosions can result in death or serious injury. Do not make connections to the HART
Communicator's serial port, 4-20 mV signal line, or NiCad recharger jack in an explosive
atmosphere.
Using the supplied lead set, connect the HART Communicator in parallel with
to the Oxymitter 4000. Use any wiring termination points in the analog output
4-20 mA signal line.
Method 2, For Load Resistance < 250 ohms
Refer to Figure 7-2 and the following steps to connect the HART Communicator to a signal line with < 250 ohms load resistance.
Explosions can result in death or serious injury. Do not make connections to the HART
Communicator's serial port, 4-20 mV signal line, or NiCad recharger jack in an explosive
atmosphere.
1. At a convenient point, break the analog output 4-20 mA signal line and
install the optional 250 ohm load resistor.
2. Plug the load resistor into the loop connectors (located on the rear panel
of the HART Communicator).
HART COMMUNICATOR
PC CONNECTIONS
There is an option to interface the HART Communicator with a personal computer. Load the designated AMS software into the PC. Then link the HART
Communicator to the PC using the interface PC adapter that connects to the
serial port (on the communicator rear panel).
Refer to the proper HART Communicator documentation in regard to the PC
interface option.
7-2
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 7-1. Signal Line Connections, ≥ 250 Ohms Load Resistance
AC
L1
AC
N
RL ≥ 250Ω
+
-
4-20 mA Signal Line
+
4-20
-
Terminal Block
Analog Output Device
Loop Connectors
SERIAL PORT & BATTERY
LOOP CONNECTORS
CHARGER MUST
USE INTERFACE
00275 0013 ONLY
SERIAL PORT
NOT BE USED IN
HAZARDOUS AREAS
23230001
HART
Communicator
Lead Set
HART Communicator
Rear Panel
Figure 7-2. Signal Line Connections, < 250 Ohms Load Resistance
AC
L1
AC
N
RL < 250Ω
+
-
4-20 mA Signal Line
+
4-20
-
Terminal Block
Analog Output Device
Loop Connectors
SERIAL PORT & BATTERY
CHARGER MUST
LOOP CONNECTORS
250 Ohm Load
Resistor
(Note)
USE INTERFACE
00275 0013 ONLY
SERIAL PORT
NOT BE USED IN
HART
Communicator
HART Communicator
Rear Panel
Note: The signal loop must be broken
to insert the optional 250 Ohm
load resistor.
23230002
HAZARDOUS AREAS
7-3
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
OFF-LINE AND ON-LINE
OPERATIONS
The HART Communicator can be operated both off-line and on-line.
Off-line operations are those in which the communicator is not connected to
the Oxymitter 4000. Off-line operations can include interfacing the HART
Communicator with a PC (refer to applicable HART documentation regarding
HART/PC applications.
In the on-line mode, the communicator is connected to the 4-20 mA analog
output signal line. The communicator is connected in parallel to the Oxymitter
4000 or in parallel to the 250 ohm load resistor.
NOTE
If the HART Communicator is turned on while connected to the 4-20 mA
analog output signal line, an undefined status indication appears while the
communicator warms up. Wait until the warm-up period ends to continue.
The opening menu displayed on the LCD is different for on-line and off-line
operations. When powering up a disconnected (off-line) communicator, the
LCD will display the Main Menu. When powering up a connected (on-line)
communicator, the LCD will display the On-line Menu. Refer to the HART
Communicator manual for detailed menu information.
LOGIC I/O
CONFIGURATIONS
The Oxymitter 4000 logic I/O output can be configured for ten different modes
through HART/AMS. The factory default condition is Mode 5. A list of possible
configurations appear in Table 7-1.
The Unit Alarm configuration available for Modes 1, 3, 5, and 7 refers to the
diagnostic alarm faults in Table 8-1.
HART/AMS MENU TREE
Table 7-1. Logic I/O
Configuration (as set at
HART/AMS or LOI)
This section consists of a menu tree for the HART Communicator. This menu
is specific to Oxymitter 4000 applications.
Mode
Configuration
0
1
2
3
4
The unit is not configured for any alarm condition.
The unit is configured for a Unit Alarm.
The unit is configured for Low O2.
The unit is configured for both a Unit Alarm and Low O2.
The unit is configured for a High AC Impedance/CALIBRATION
RECOMMENDED.
The unit is configured for both a Unit Alarm and a High AC
Impedance/CALIBRATION RECOMMENDED.
The unit is configured for both a Low O2 and High AC Impedance/CALIBRATION
RECOMMENDED.
The unit is configured for a Unit Alarm, a Low O2, and a High AC
Impedance/CALIBRATION RECOMMENDED.
The unit is configured for a calibration handshake with IMPS 4000 or SPS 4001B.
CALIBRATION RECOMMENDED will initiate the calibration cycle.
The unit is configured for a calibration handshake. CALIBRATION
RECOMMENDED will not initiate the calibration cycle with the IMPS 4000 or SPS
4001B.
5*
6
7
8**
9
*The default condition for an Oxymitter 4000 without an IMPS 4000 or SPS 4001B.
**The default condition for an Oxymitter 4000 with an IMPS 4000 or SPS 4001B.
7-4
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 7-3. HART/AMS Menu
Tree (Sheet 1 of 3)
VIEW FLD
DEV VARS
PROCESS
VARIABLES
O2 value
O2 cell temp
CJ temp
VIEW PV-Aout
PV is
PV O2 value
PV % rnge
PV AO
VIEW SV
SV is Cold Junct
SV __ mV
VIEW TV
TV is Cell
TV __ mV
VIEW 4V
4V is Cell TC
4V __ mV
VIEW OUTPUT
VARS
VIEW FLD
DEV mV
Cell mV
Cell TC mV
CJ mV
Status Group 1
DEVICE SETUP
PV
PV AO
PV LRV
PV URV
STATUS
Status Group 2
Cell Temp Low
Cell Temp High
Cell Open
High Cell Imp.
CK.ER - EEPROM
Cal.Error Slope
Cal. Recommended
Status Group 3
Cal. Error Const.
Last Cal. Failed
Operate Model
AO Saturated
DIAG/SERVICE
Open T/C
Shorted T/C
Reversed T/C
Heater Open
Cell Temp Very HI
High Case Temp
AO1 Out Rnge lim
AO Fixed
Max Case Temp
LOOP TEST
Loop test
method...
O2 CALIBRATE
PERFORM O2
CAL
O2 Cal
Optrak TG?
CalState
O2 CAL
STATUS
CalState
TimeRemain
Present O2
LAST
CALCONSTANTS
Cal slope
Cal const
Cell Imp
RESET
CALCONSTANTS
Reset
CalConstants
method...
O2 Cal method...
Refer to “HART
Communicator O2 Cal
Method” for the
complete O2 calibration
method using the
HART Communicator.
D/A TRIM
D/A trim method
26170028
(CONTINUED ON
SHEET 2)
7-5
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 7-3. HART/AMS Menu
Tree (Sheet 2 of 3)
(CONTINUED FROM
SHEET 1)
BASIC SETUP
Tag
ASSIGN
PV & SV
SELECT O2
RANGE
DEVICE
INFORMATION
S/W VERSION
INFO
SENSORS
SIGNAL
CONDITION
PV is
SV is
TV is
4V is
URV
LRV
Oxygen
Cold Junct
Cell
Cell TC
____%
____%
Dev id
Descriptor
Message
Date
Final asmbly num
Snsr s/n
Ver
Chk sum
Bld num
Bld date
O2
O2 CELLTEMP
COLDJUNCTEMP
O2 CELL MV
O2 CELLTCMV
COLD JUNC MV
LIMITS DISPLAYED
PV URV
PV LRV
PV % rnge
PV AO ____ mA
PV AO Alrm typ
DEVICE SETUP
PV
PV AO
PV LRV
PV URV
OUTPUT
CONDITION
DETAILED
SETUP
ANALOG
OUTPUT
HART OUTPUT
ALARM
OUTPUT
O2
LOOP TEST
Loop test
method...
D/A TRIM
D/A trim method...
Poll addr
Num req preams
Logic I/O Pin State
Logic I/O Pin Mode
SLOPE
No Alarm
Unit Alarm
Low O2 Alarm
Low O2/Unit Alarm
Cal Rec
Cal Rec/Unit Alarm
Low O2/Cal Rec
Low O2/Unit/Cal Rec
Cal Rec/Handshake
Handshake
CONSTANT
O2
CALIBRATION
O2 ALARMS
7-6
HighTG
LowTG
OPtrak TG?
TGtime
PurgeTime
Cal Mode
Cal Intrvl h
Next CalTime h
LoAlarmSP
OP locks
OP tracks
Manual
Auto
35830006
(CONTINUED ON
SHEET 3)
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 7-3. HART/AMS Menu
Tree (Sheet 3 of 3)
DEVICE
INFORMATION
CAL INFO
Optrak TG?
Tgtime
PurgeTime
LowTG
HighTG
Cal slope
Cal const
CellImp
Imp Delta
DEVICE CONFIG
Slope
Constant
OUTPUTS
CONFIG
URV
LRV
LoAlarmSP
I/O Pin Mode
Poll addr
Num req preams
REVIEW
DEVICE SETUP
PV
PV AO
PV LRV
PV URV
26170030
(CONTINUED FROM
SHEET 2)
Manufacturer
Model
Dev id
Tag
Descriptor
Message
Date
Final asmbly num
Snsr s/n
Fld dev rev
Hardware rev
Software rev
Universal rev
7-7
Instruction Manual
Oxymitter 4000
HART COMMUNICATOR
O2 CAL METHOD
IM-106-340, Rev. 4.0
February 2006
Use the following procedure to perform a calibration using the HART Communicator. If necessary, use the menu tree in Figure 7-3 (sheet 1 of 3) for reference.
NOTE
To select a menu item, either use the up and down arrow keys to scroll to the
menu item and press the right arrow key or use the number keypad to select
the menu item number. To return to a preceding menu, press the left arrow
key.
1. From the PERFORM O2 CAL screen, select menu item 1, O2 CAL, to
access the O2 calibration procedure.
Failure to remove the Oxymitter 4000 from automatic control loops prior to performing this
procedure may result in a dangerous operating condition.
2. In the first O2 CAL screen, a "Loop should be removed from automatic
control" warning appears. Remove the Oxymitter 4000 from any automatic control loops to avoid a potentially dangerous operating condition
and press OK.
3. The next several screens indicate the calibration status. At each of the
following status prompts, select menu item 2, NEXT CAL STEP:
COMPLETE
CAL RECOMMENDED
APPLY GAS 1
GAS 1 FLOW
4. At this point, select menu item 4, EXIT, to leave the O2 CAL procedure.
5. From the PERFORM O2 CAL screen, view menu item 3, CALSTATE, to
monitor the calibration status as it updates. Or, access the O2 CALIBRATE screen and select menu item 2, O2 CAL STATUS, to view menu
item 1, CALSTATE; menu item 2, TIMEREMAIN; and menu item 3,
PRESENT O2, as the calibration status updates.
6. When CALSTATE displays APPLY GAS 2, return to the O2 CAL
procedure.
7. When the "Loop should be removed from automatic control" warning
appears, return the Oxymitter 4000 to the automatic control loops previously removed and press OK.
8. At the STOP GAS status prompt, select menu item 2, NEXT CAL STEP.
When the status displays PURGING, select menu item 4, EXIT, to leave
the O2 CAL procedure.
9. From the PERFORM O2 CAL screen, view menu item 3, CALSTATE, to
monitor the calibration status as it updates. Or, access the O2 CALIBRATE screen and select menu item 2, O2 CAL STATUS, to view menu
item 1, CALSTATE; menu item 2, TIMEREMAIN; and menu item 3,
PRESENT O2, as the calibration status updates.
10. When CALSTATE displays STOP GAS, return to the O2 CAL procedure.
7-8
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
11. When the "Loop should be returned to automatic control" message
appears, return the Hazardous Area Oxymitter 4000 to the automatic
control loops previously removed and press OK.
12. At the STOP GAS status prompt, select menu item 2, NEXT CAL STEP
When the status displays PURGING, select menu item 4, EXIT, to leave
the O2 CAL procedure.
13. From the PERFORM O2 CAL screen, view menu item 3, CALSTATE, to
monitor the calibration status as it updates. Or, access the O2 CALIBRATE screen and select menu item 2, O2 CAL STATUS, to view menu
item 1, CAL-STATE; menu item 2, TIMEREMAIN; and menu item 3,
PRESENT O2, as the calibration status updates.
14. When CALSTATE displays COMPLETE, the calibration is finished.
DEFINING A TIMED
CALIBRATION VIA HART
Use the following procedure to specify a time interval (in hours) at which the
Oxymitter 4000 will be automatically calibrated. If necessary, use the menu
tree in Figure 7-3 (Sheet 2 of 3) for reference.
NOTE
To select a menu item, either use the up and down arrow keys to scroll to the
menu item and press the right arrow key or use the number keypad to select
the menu item number. To return to a preceding menu, press the left arrow
key.
1. From the DEVICE SETUP screen, select DETAILED SETUP.
2. From the DETAILED SETUP screen, select O2 CALIBRATION.
3. From the O2 CALIBRATION screen, select menu item 6, CAL MODE.
Set the CAL MODE to AUTO.
4. Return to the O2 CALIBRATION screen and select menu item 7, CAL
INTRVL.
5. At the prompt, input a time interval (in hours) at which an automatic
calibration will occur; then press ENTER.
D/A TRIM PROCEDURE
The D/A trim procedure is used to calibrate the 4-20 mA output signal to a
precision mA measurement device (calibrated digital ammeter, etc.). The
procedure is interactive and stored in the Oxymitter software.
Use one of the following communication methods to access the D/A trim
procedure:
LOI Menu
1. Use the "Z" pattern key entry to access the LOI menu.
2. Press the down key two times to access the SYSTEM menu.
3. Press the down key once to access the Input/Output menu.
4. From the Analog selection, press the right-pointing key to display the
Analog submenu listing.
5. Press the down key as needed to access Trim O2 Out.
6. Press the Enter key to start the trim procedure. Follow the LOI display
prompts to perform the trim procedure.
7-9
Instruction Manual
Oxymitter 4000
7-10
IM-106-340, Rev. 4.0
February 2006
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Section 8
Oxymitter 4000
Troubleshooting
Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 8-1
General . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 8-3
Alarm Indications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 8-3
Alarm Contacts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 8-4
Identifying And Correcting Alarm Indications . . . . . . . . . page 8-5
Calibration Passes, but Still Reads Incorrectly . . . . . . . . page 8-22
OVERVIEW
While the Oxymitter 4000 electronics provides a significant number of
diagnostic alarms to assist in troubleshooting potential problems, it is good to
place these alarms in perspective with respect to the instrument's operating
principles:
When the Zirconium Oxide sensing cell is heated to its setpoint [1357°F
(736°C)], the cell will generate a voltage that represents the difference
between the process O2% and the reference O2% inside the probe (20.95%
O2 ambient air).
Test points, Figure 8-1, are provided to read the raw millivolt value generated
by the thermocouple that controls the cell temperature and also the raw cell
signal.
The cell temperature at test points 3 and 4 should always be stable at
approximately 29 to 30 millivolts, which represents the [1357°F (736°C)]
setpoint temperature.
When flowing calibration gasses, the raw cell millivolt value at test points 1
and 2 should represent the levels on the chart in Figure 8-1. Note that the raw
cell millivolt value increases logarithmically as the O2 concentration
decreases.
http://www.processanalytic.com
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 8-1. O2 Sensor mV
Reading vs. % O2 at 1357°F
(736°C) (Reference Air, 20.9%
O 2)
200
O
O
O2 Sensor Performance at 1357 F (736 C)
EMF (mV)
150
100
0
0
0.01
0.1
1
10
100
Concentration O2 (%)
O2 %
100
20
15
10
9
8
7
6
5
4
EMF(mV)
-34
1.0
7.25
16.1
18.4
21.1
23.8
27.2
31.2
36.0
3
2
1
0.8
0.6
0.5
0.4
0.2
0.1
0.01
42.3
51.1
66.1
71.0
77.5
81.5
86.3
101.4
116.6
166.8
O2 %
EMF(mV)
8-2
37260043
50
Instruction Manual
IM-106-340, Rev. 4.0
February 2005
Oxymitter 4000
Install all protective equipment covers and safety ground leads after troubleshooting. Failure
to install covers and ground leads could result in serious injury or death.
GENERAL
The troubleshooting section describes how to identify and isolate faults that
may develop in the Oxymitter 4000. When troubleshooting, reference the
following.
Grounding
It is essential that adequate grounding precautions are taken when installing
the system. Thoroughly check both the probe and electronics to ensure the
grounding quality has not degraded during fault finding. The system provides
facilities for 100% effective grounding and the total elimination of ground
loops.
Electrical Noise
The Oxymitter 4000 has been designed to operate in the type of environment
normally found in a boiler room or control room. Noise suppression circuits
are employed on all field terminations and main inputs. When fault finding,
evaluate the electrical noise being generated in the immediate circuitry of a
faulty system. Ensure all cable shields are connected to earth.
Loose Integrated Circuits
The Oxymitter 4000 uses a microprocessor and supporting integrated circuits
(IC). If the electronics are handled roughly during installation or located where
subjected to severe vibration, the ICs could work loose. Before troubleshooting the system, ensure all ICs are fully seated.
Electrostatic Discharge
Electrostatic discharge can damage the ICs used in the electronics. Before
removing or handling the processor board or the ICs, ensure you are at
ground potential.
ALARM INDICATIONS
The majority of the fault conditions for the Oxymitter 4000 will be indicated by
one of the four LEDs referred to as diagnostic, or unit alarms on the operator's
keypad (Figure 8-2). An LED will flash a code that will correspond to an error
message. Only one LED will blink at a time. An alarm code guide is provided
inside the screw-on cover for the electronics.
Alarm indications will be also available via the optional LOI or the HART
Model 275/375 hand-held communicator and Rosemount Analytical's Asset
Management software. When the error is corrected and/or power is cycled,
the diagnostic alarms will clear or the next error on the priority list will appear.
8-3
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 8-2. Diagnostic LEDs
Diagnostic
LEDs
DIAGNOSTIC
ALARMS
HEATER T/C
HEATER
02 CELL
CALIBRATION
CALIBRATION RECOMMENDED
TEST
POINTS
INC
LOW
GAS
DEC
DEC
CAL
TEST GAS +
PROCESS % 02
37260044
INC
HIGH
GAS
02 CELL mV +
02 CELL mv HEATER T/C +
HEATER T/C -
ALARM CONTACTS
If autocalibration is not utilized, a common bidirectional logic contact is provided for any of the diagnostic alarms listed in Table 8-1. The assignment of
alarms which can actuate this contact can be modified to one of seven additional groupings (mode 0 through mode 7) listed in Table 7-1.
The logic contact is self-powered, +5 VDC, with a 340 ohm series resistance.
An interposing relay will be required if this contact is to be utilized to annunciate a higher voltage device, such as a light or horn. An interposing relay may
also be required for certain DCS input cards.
A Potter & Brumfield R10S-E1Y1-J1.0K 3.2 mA DC or an equal interposing
relay will be mounted where the contact wires terminate in the control/relay
room.
If autocalibration systems are utilized, the bidirectional logic contact is utilized
as a "hand-shake" signal between the autocalibration system (SPS 4001B or
IMPS 4000) and is unavailable for alarming purposes. The following additional contacts are provided through the autocalibration systems:
8-4
Instruction Manual
IM-106-340, Rev. 4.0
February 2005
Oxymitter 4000
SPS 4001B and IMPS 4000, 1-4 probes
• One contact closure per probe from the control room to the SPS 4001B
or IMPS 4000 for "calibration initiate".
• One contact output per probe from the SPS 4001B or IMPS 4000 to the
control room for "in calibration" notification.
• One contact output per probe from the SPS 4001B or IMPS 4000 to the
control room for "calibration failed" notification. (Includes output from
pressure switch indicating "cal gas bottles empty").
Additional IMPS 4000 Alarm Contacts
• One contact per IMPS 4000 for "low calibration gas flowing".
• One contact per IMPS 4000 for "high calibration gas flowing".
NOTE
The 4-20 mA signal can be configured to respond normally during any
calibration, or can be configured to hold the last O2 value upon the initiation of
calibration. Factory default is for the 4-20 mA signal to operate normally
throughout calibration.
NOTE
Holding the last O2 value may be useful if several probes are being averaged
for the purpose of automatic control. Unless several probes are being
averaged, always place any control loops using the O2 signal into manual
prior to calibrating.
IDENTIFYING AND
CORRECTING ALARM
INDICATIONS
For an Oxymitter 4000 with a membrane keypad, faults are indicated by four
diagnostic, or unit, alarm LEDs. A pattern of repeating blinks define the
problem. A condensed table of the errors and the corresponding blink codes
can be found on the inside right cover of the electronics housing. Table 8-1
also identifies the blink code and fault status of each LED as well as the
output of the 4-20 mA signal line and a fault number that corresponds to the
troubleshooting instructions provided in this section.
For an Oxymitter 4000 with the optional LOI, alarm messages are displayed
on the LOI display window when the alarm status display is accessed via the
LOI menu. A listing of the alarm/fault messages and the related fault status
descriptions and fault numbers are shown in Table 8-2.
8-5
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Table 8-1. Diagnostic/Unit
Alarm Fault Definitions Membrane Keypad Only
LED
HEATER T/C
HEATER
O2 CELL
CALIBRATION
Flashes
1
2
3
4
1
2
3
4
5
1
3
4
1
2
3
**
Status
Open
Shorted
Reversed
A/D Comm Error
Open
High High Temp
High Case Temp
Low Temp
High Temp
High mV
Bad
EEprom Corrupt
Invalid Slope
Invalid Constant
Last Calibration Failed
Calibration Recommended
4-20 mA Line
Fault
Recoverable
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
No
No
No
No
No
No
Yes
Yes
Yes
Yes
Yes
No
Yes
Yes
Yes
Yes
Dependent on position 3 of SW2*
Dependent on position 3 of SW2*
Dependent on position 3 of SW2*
Dependent on position 3 of SW2*
Dependent on position 3 of SW2*
Dependent on position 3 of SW2*
Dependent on position 3 of SW2*
Dependent on position 3 of SW2*
Dependent on position 3 of SW2*
Dependent on position 3 of SW2*
Track O2
Dependent on position 3 of SW2*
Track O2
Track O2
Track O2
Track O2
*Critical alarm conditions will render the O2 measurement as unusable, and any of these events will cause the 4-20 mA signal to go to a
user-selectable limit of 3.5 mA or 21.6 mA (position 3 of SW2). Factory default value is 3.5 mA. Alarms which are not self-clearing
(Self-Clearing = NO) will require a reset. Perform the Reset Procedure in Section 3: Configuration of Oxymitter 4000 with Membrane
Keypad to continue operation.
**The CALIBRATION RECOMMENDED alarm flashes the Calibration Recommended LED on the operator's keypad.
Table 8-2. Diagnostic/Unit
Alarm Fault Definitions - LOI
Message
Status
O2 T/C OPEN
O2 T/C SHORTED
O2 T/C REVERSED
ADC ERROR
O2 HEATER OPEN
VERY HI O2 TEMP
BOARD TEMP HI
O2 TEMP LOW
O2 TEMP HI
O2 CELL OPEN
O2 CELL BAD
EEPROM CORRUPT
CALIB FAILED
LINE FREQ ERROR
Heater T/C Open
Heater T/CShorted
Heater T/C Polarity Reversed
A/D Comm Error
O2 Heater Open
Very High Process Temperature
Electronics Overheated
Low Process Temperature
High Process Temperature
O2 Cell Open
O2 Cell Failed
EEprom Failed
Last Calibration Failed
Incorrect Input Line Frequency Detected on Power Up
8-6
Fault Number
Self Clearing
1
2
3
4
5
6
7
8
9
10
11, 13, 14
12
15
No
No
No
No
No
No
Yes
Yes
Yes
Yes
Yes
No
Yes
No
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 8-3. Fault 1, Open Thermocouple
Fault 1, Open Thermocouple
HEATER T/C
HEATER
O2 CELL
CALIBRATION
SW2
ON
DIAGNOSTIC
ALARMS
Figure 8-3 shows the electronic assembly for an
Oxymitter 4000 with a membrane keypad (upper
view) and a Oxymitter 4000 with an LOI (lower
view). The upper view also shows J1 and test
points TP1 through TP6, located on the
microprocessor board, below the membrane
keypad or the LOI module.
Membrane Keypad
CALIBRATION RECOMMENDED
INC
INC
HIGH
GAS
LOW
GAS
DEC
DEC
O2 CELL mV +
O2 CELL mv HEATER T/C +
HEATER T/C -
TP1
When Fault 1 is detected, the HEATER T/C LED
flashes once, pauses for three seconds, and
repeats.
TP2
TP3
TP4
RED
YEL
GRN
ORG
TEST
POINTS
J1
1. Check connector J1. Ensure the connector
is properly seated.
CAL
TEST GAS +
PROCESS % O2
2. Using a multimeter, measure the voltage
from TP3+ to TP4-. If the reading is 1.2
VDC ±0.1 VDC, the thermocouple is open.
TP5
TP6
3. Remove power. Disconnect J1. Measure
the resistance across the red and yellow
thermocouple leads. The resistance should
be approximately 1 ohm.
KEYPAD
4. If the thermocouple is open, see "Heater
Strut Replacement" in Section 9:
Maintenance and Service.
LOI
When Fault 1 is detected, the LOI displays the
"O2 T/C Open" message.
1. Remove power. Unscrew and remove the
LOI module from the electronic assembly.
2. Reconnect power to the Oxymitter 4000.
3. Perform the diagnostic steps 1 through 4
shown for the membrane keypad.
LOI
37260019
Alarms
O2 T/C Open
8-7
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 8-4. Fault 2, Shorted Thermocouple
Fault 2, Shorted Thermocouple
HEATER T/C
HEATER
O2 CELL
CALIBRATION
SW2
ON
DIAGNOSTIC
ALARMS
Figure 8-4 shows the electronic assembly for an
Oxymitter 4000 with a membrane keypad (upper
view) and an Oxymitter 4000 with an LOI (lower
view). The upper view also shows J1 and test
points TP1 through TP6, located on the
microprocessor board, below the membrane
keypad or the LOI module.
Membrane Keypad
CALIBRATION RECOMMENDED
INC
INC
HIGH
GAS
LOW
GAS
DEC
DEC
O2 CELL mV +
O2 CELL mv HEATER T/C +
HEATER T/C -
TP1
TP2
TP3
TP4
RED
YEL
GRN
ORG
TEST
POINTS
J1
CAL
TEST GAS +
PROCESS % O2
TP5
When Fault 2 is detected, the HEATER T/C LED
flashes twice, pauses for three seconds, and
repeats.
1. Using a multimeter, measure the voltage
from TP3+ to TP4-. If the reading is 0 ±0.5
mV, then a shorted thermocouple is likely.
2. Remove power and disconnect J1.
TP6
3. Measure the resistance from TP3+ to TP4-.
The reading should be approximately 20K
ohms.
4. If so, the short is not on the PC board. The
thermocouple wiring or the thermocouple is
shorted. See "Heater Strut Replacement" in
Section 9: Maintenance and Service.
KEYPAD
LOI
When Fault 2 is detected, the LOI displays the
"O2 T/C Shorted" message.
1. Remove power. Unscrew and remove the
LOI module from the electronic assembly.
2. Reconnect power to the Oxymitter 4000.
3. Perform the diagnostic steps 1 through 4
shown for the membrane keypad.
LOI
8-8
37260020
Alarms
O2 T/C Shorted
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 8-5. Fault 3, Reversed Thermocouple
Fault 3, Reversed Thermocouple Wiring or
Faulty PC Board
HEATER T/C
HEATER
O2 CELL
CALIBRATION
SW2
ON
DIAGNOSTIC
ALARMS
Figure 8-5 shows the electronic assembly for an
Oxymitter 4000 with a membrane keypad (upper
view) and an Oxymitter 4000 with an LOI (lower
view). The upper view also shows J1 and test
points TP1 through TP6, located on the
microprocessor board, below the membrane
keypad or the LOI module.
CALIBRATION RECOMMENDED
INC
INC
HIGH
GAS
LOW
GAS
DEC
DEC
O2 CELL mV +
O2 CELL mv HEATER T/C +
HEATER T/C -
TP1
J1
Membrane Keypad
TP2
TP3
TP4
RED
YEL
GRN
ORG
TEST
POINTS
CAL
TEST GAS +
PROCESS % O2
When Fault 3 is detected, the HEATER T/C LED
flashes three times, pauses for three seconds,
and repeats.
1. Using a multimeter, measure the voltage
from TP3+ to TP4-. If the reading is
negative, the thermocouple wiring is
reversed.
TP5
TP6
2. Check red and yellow wires in the J1
connector for the proper placement.
3. If the wiring is correct, the fault is in the PC
board. See "Electronic Assembly
Replacement" in Section 9: Maintenance
and Service.
KEYPAD
LOI
When Fault 3 is detected, the LOI displays the
"O2 T/C Reversed" message.
1. Remove power. Unscrew and remove the
LOI module from the electronic assembly.
2. Reconnect power to the Oxymitter 4000.
3. Perform the diagnostic steps 1 through 3
shown for the membrane keypad.
LOI
37260021
Alarms
O2 T/C Reversed
8-9
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 8-6. Fault 4, A/D Comm Error
Fault 4, A/D Comm Error
Membrane Keypad
HEATER T/C
HEATER
O2 CELL
CALIBRATION
SW2
1. Call the factory for assistance.
ON
DIAGNOSTIC
ALARMS
When Fault 4 is detected, the HEATER T/C LED
flashes four times, pauses for three seconds,
and repeats (Figure 8-6).
CALIBRATION RECOMMENDED
INC
INC
HIGH
GAS
LOW
GAS
DEC
DEC
O2 CELL mV +
O2 CELL mV HEATER T/C +
HEATER T/C -
TP1
J1
TP2
TP3
TP4
RED
YEL
GRN
ORG
TEST
POINTS
CAL
TEST GAS +
PROCESS % O2
TP5
TP6
KEYPAD
LOI
When Fault 4 is detected, the LOI displays the
"ADC Error" message.
1. Call the factory for assistance.
37260022
Alarms
ADC Error
LOI
8-10
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 8-7. Fault 5, Open Heater
Fault 5, Open Heater
Figure 8-7 shows the electronic assembly for an
Oxymitter 4000 with a membrane keypad (upper
view) and a Oxymitter 4000 with an LOI (lower
view).
HEATER T/C
HEATER
O2 CELL
CALIBRATION
Membrane Keypad
SW2
ON
DIAGNOSTIC
ALARMS
When Fault 5 is detected, the HEATER LED
flashes once, pauses for three seconds, and
repeats.
CALIBRATION RECOMMENDED
TEST
POINTS
INC
INC
HIGH
GAS
LOW
GAS
DEC
DEC
TP1
J1
1. Remove power.
TP2
TP3
TP4
RED
YEL
GRN
ORG
O2 CELL mV +
O2 CELL mv HEATER T/C +
HEATER T/C -
CAL
TEST GAS +
PROCESS % O2
2. Remove the electronic assembly per
"Electronic Assembly Replacement" in
Section 9: Maintenance and Service.
3. Using a multimeter, measure the resistance
across the terminals of heater connector,
J8.
TP5
TP6
4. The measurement should be approximately 72 ohms. If the heater is open, see
"Heater Strut Replacement" in Section 9:
Maintenance and Service.
KEYPAD
LOI
When Fault 5 is detected, the LOI displays the
"O2 Heater Open" message.
1. Remove power. Unscrew and remove the
LOI module from the electronic assembly.
2. Perform the diagnostic steps 2 through 4
shown for the membrane keypad.
LOI
37260023
Alarms
O2 Heater Open
8-11
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 8-8. Fault 6, High High Heater Temp
Fault 6, High High Heater Temp
Figure 8-8 shows the electronic assembly for an
Oxymitter 4000 with a membrane keypad (upper
view) and an Oxymitter 4000 with an LOI (lower
view).
HEATER T/C
HEATER
O2 CELL
CALIBRATION
Membrane Keypad
SW2
ON
DIAGNOSTIC
ALARMS
When Fault 6 is detected, the HEATER LED
flashes twice, pauses for three seconds, and
repeats.
CALIBRATION RECOMMENDED
INC
INC
HIGH
GAS
LOW
GAS
DEC
DEC
O2 CELL mV +
O2 CELL mv HEATER T/C +
HEATER T/C -
TP1
J1
TP2
1. The High High Heater Temp alarm will
activate when the thermocouple produces
a voltage of 37.1 mV [1652°F (900°C)].
TP3
TP4
RED
YEL
GRN
ORG
TEST
POINTS
2. The triac and the temperature control may
be at fault.
CAL
TEST GAS +
PROCESS % O2
3. Remove power. Allow Oxymitter 4000 to
cool for five minutes. Restore power.
TP5
TP6
4. If the condition repeats, replace the
electronic assembly per "Electronic
Assembly Replacement" in Section 9:
Maintenance and Service.
KEYPAD
LOI
When Fault 6 is detected, the LOI displays the
"Very Hi O2 Temp" message.
1. The very high O2 temperature alarm will
activate when the thermocouple produces
a voltage of 37.1 mV [1652°F (900°C)].
2. The triac and the temperature control may
be at fault.
3. Remove power. Allow the Oxymitter 4000
to cool for five minutes. Restore power.
Alarms
Very Hi O2 Temp
8-12
37260024
LOI
4. If the condition repeats, replace the
electronic assembly per "Electronic
Assembly Replacement" in Section 9:
Maintenance and Service.
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 8-9. Fault 7, High Case Temp
Fault 7, High Case Temp
HEATER T/C
HEATER
O2 CELL
CALIBRATION
SW2
Membrane Keypad
ON
DIAGNOSTIC
ALARMS
Figure 8-9 shows the electronic assembly for an
Oxymitter 4000 with a membrane keypad (upper
view) and an Oxymitter 4000 with an LOI (lower
view).
When Fault 7 is detected, The HEATER LED
flashes three times, pauses for three seconds,
and repeats.
CALIBRATION RECOMMENDED
INC
INC
HIGH
GAS
LOW
GAS
DEC
O2 CELL mV +
O2 CELL mv HEATER T/C +
HEATER T/C -
TP1
J1
TP2
TP3
TP4
RED
YEL
GRN
ORG
TEST
POINTS
CAL
TEST GAS +
PROCESS % O2
DEC
1. If the case temperature exceeds [185°F
(85°C)], the temperature control will shut
off and the 4-20 mA signal output will go to
the default value.
2. This signifies that the environment where
the Oxymitter 4000 is installed exceeds the
ambient temperature requirements or that
heat due to convection is causing case
temperature to rise above the limit.
TP5
TP6
3. Placing a spool piece between the stack
flange and the Oxymitter 4000 flange may
eliminate this problem.
KEYPAD
4. If a spool piece does not solve the problem,
relocation is the only solution.
LOI
When Fault 7 is detected, the LOI displays the
"Board Temp Hi" message. Refer to the
comments in paragraphs 1 through 4 above.
LOI
37260025
Alarms
Board Temp Hi
8-13
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 8-10. Fault 8, Low Heater Temp
Fault 8, Low Heater Temp
Figure 8-10 shows the electronic assembly for
an Oxymitter 4000 with a membrane keypad
(upper view) and an Oxymitter 4000 with an LOI
(lower view).
HEATER T/C
HEATER
O2 CELL
CALIBRATION
Membrane Keypad
SW2
ON
DIAGNOSTIC
ALARMS
When Fault 8 is detected, the HEATER LED
flashes four times, pauses for three seconds,
and repeats.
CALIBRATION RECOMMENDED
INC
INC
HIGH
GAS
LOW
GAS
DEC
DEC
O2 CELL mV +
O2 CELL mv HEATER T/C +
HEATER T/C -
TP1
J1
TP2
TP3
TP4
RED
YEL
GRN
ORG
TEST
POINTS
2. If the thermocouple reading continues to
ramp downward for one minute and does
not return to the temperature set point of
approximately 29.3 mV, then an Open
Heater fault will be displayed.
CAL
TEST GAS +
PROCESS % O2
1. The low heater temperature alarm is active
when the thermocouple reading has
dropped below 28.6 mV.
TP5
TP6
3. Power down the electronics. Remove the
electronic assembly per "Electronic
Assembly Replacement" in Section 9:
Maintenance and Service. Using a
multimeter, measure the resistance across
the terminals of heater connector, J8.
KEYPAD
4. If the heater is good, the reading will be
approximately 70 ohms. If the heater is
open, see "Heater Strut Replacement" in
Section 9: Maintenance and Service.
LOI
When Fault 8 is detected, the LOI displays the
"O2 Temp Low" message. Refer to the
comments and procedures in paragraphs 1
through 4 above.
LOI
8-14
37260026
Alarms
O2 Temp Low
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 8-11. Fault 9, High Heater Temp
Fault 9, High Heater Temp
Figure 8-11 shows the electronic assembly for an
Oxymitter 4000 with a membrane keypad (upper
view) and an Oxymitter 4000 with an LOI (lower
view).
HEATER T/C
HEATER
O2 CELL
CALIBRATION
Membrane Keypad
SW2
ON
DIAGNOSTIC
ALARMS
When Fault 9 is detected, the HEATER LED
flashes five times, pauses for three seconds, and
repeats.
CALIBRATION RECOMMENDED
INC
INC
HIGH
GAS
LOW
GAS
DEC
DEC
TP1
J1
TP2
TP3
TP4
RED
YEL
GRN
ORG
TEST
POINTS
O2 CELL mV +
O2 CELL mv HEATER T/C +
HEATER T/C -
2. The 4-20 mA signal returns to the default
value (4 or 20 mA).
CAL
TEST GAS +
PROCESS % O2
1. If the thermocouple produces a voltage in
excess of approximately 30.7 mV, the high
heater temp alarm activates.
3. This alarm is self-clearing. When
temperature control is restored and the
thermocouple voltage returns to the normal
range, the alarm clears.
TP5
TP6
4. If the temperature continues to rise, the
next alarm will be the High High Heater
Temp alarm.
KEYPAD
LOI
When Fault 9 is detected, the LOI displays the
"O2 Temp Hi" message. Refer to the comments
and procedures in paragraphs 1 through 4
above.
LOI
37260027
Alarms
O2 Temp Hi
8-15
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 8-12. Fault 10, High Cell mV
Fault 10, High Cell mV
SW2
ON
HEATER T/C
HEATER
O2 CELL
CALIBRATION
DIAGNOSTIC
ALARMS
Figure 8-12 shows the electronic assembly for
an Oxymitter 4000 with a membrane keypad
(upper view) and an Oxymitter 4000 with an LOI
(lower view). The upper view also shows J1 and
test points TP1 through TP6, located on the
microprocessor board, below the membrane
keypad or the LOI module.
CALIBRATION RECOMMENDED
TEST
POINTS
INC
INC
HIGH
GAS
LOW
GAS
DEC
DEC
Membrane Keypad
TP1
J1
When Fault 10 is detected, the O2 CELL flashes
once, pauses for three seconds, and repeats.
TP2
TP3
TP4
RED
YEL
GRN
ORG
O2 CELL mV +
O2 CELL mv HEATER T/C +
HEATER T/C -
CAL
TEST GAS +
PROCESS % O2
TP5
TP6
1. Using a multimeter, measure across TP1+
to TP2-. If you measure 204 mV to 1 volt
DC, the cell reading is due to high
combustibles. This is a self-clearing alarm,
once the combustible conditions go away.
If you measure 1.2 VDC, the cell wires,
either orange or green, have become
detached from the input.
2. One possible cause is connector J1. The
orange or green wire has come loose from
the crimped connection.
KEYPAD
3. The platinum pad could also be at fault.
The pad could have broken free from the
back of the cell.
4. Replace heater strut per "Heater Strut
Replacement" in Section 9: Maintenance
and Service. If necessary, replace the cell
and flange assembly per "Cell Replacement" in Section 9: Maintenance and Service.
LOI
Alarms
O2 Cell Open
When Fault 10 is detected, the LOI displays the
"O2 Cell Open" message.
1. Remove power. Unscrew and remove the
LOI module from the electronic assembly.
2. Reconnect power to the Oxymitter 4000.
LOI
8-16
37260028
3. Perform the diagnostic steps 1 through 4
shown for the membrane keypad.
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 8-13. Fault 11, Bad Cell
Fault 11, Bad Cell
Figure 8-13 shows the electronic assembly for
an Oxymitter 4000 with a membrane keypad
(upper view) and an Oxymitter 4000 with an LOI
(lower view).
HEATER T/C
HEATER
O2 CELL
CALIBRATION
Membrane Keypad
SW2
ON
DIAGNOSTIC
ALARMS
When Fault 11 is detected, the O2 CELL flashes
three times, pauses for three seconds, and
repeats.
CALIBRATION RECOMMENDED
INC
INC
HIGH
GAS
LOW
GAS
DEC
DEC
O2 CELL mV +
O2 CELL mv HEATER T/C +
HEATER T/C -
TP1
J1
TP2
TP3
TP4
RED
YEL
GRN
ORG
TEST
POINTS
CAL
TEST GAS +
PROCESS % O2
TP5
1. The bad cell alarm activates when the cell
exceeds the maximum resistance value.
2. The cell should be replaced. See "Cell
Replacement" in Section 9: Maintenance
and Service, for cell replacement
instructions.
TP6
KEYPAD
LOI
When Fault 11 is detected, the LOI displays the
"O2 Cell Bad" message. Refer to the comments
and procedures in paragraphs 1 and 2 above.
LOI
37260029
Alarms
O2 Cell Bad
8-17
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 8-14. Fault 12, EEprom Corrupt
Fault 12, EEprom Corrupt
Figure 8-14 shows the electronic assembly for
an Oxymitter 4000 with a membrane keypad
(upper view) and an Oxymitter 4000 with an LOI
(lower view).
HEATER T/C
HEATER
O2 CELL
CALIBRATION
Membrane Keypad
SW2
ON
DIAGNOSTIC
ALARMS
When Fault 12 is detected, the O2 CELL LED
flashes four times, pauses for three seconds,
and repeats.
CALIBRATION RECOMMENDED
INC
INC
HIGH
GAS
LOW
GAS
DEC
DEC
O2 CELL mV +
O2 CELL mv HEATER T/C +
HEATER T/C -
TP1
J1
TP2
1. This alarm can occur if the EEprom is
changed for a later version. At power up,
the EEprom is not updated.
TP3
TP4
RED
YEL
GRN
ORG
TEST
POINTS
2. To correct this problem, power down and
then restore power. The alarm should clear.
CAL
TEST GAS +
PROCESS % O2
3. If the alarm occurs while the unit is running,
there is a hardware problem on the
microprocessor board.
TP5
TP6
4. If cycling the power does not clear the
alarm, see "Electronic Assembly
Replacement" in Section 9: Maintenance
and Service.
KEYPAD
LOI
When Fault 12 is detected, the LOI displays the
"EEprom Corrupt" message. Refer to the
comments and procedures in paragraphs 1
through 4 above.
LOI
8-18
37260030
Alarms
EEprom Corrupt
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 8-15. Fault 13, Invalid Slope
Fault 13, Invalid Slope
Figure 8-15 shows the electronic assembly for
an Oxymitter 4000 with a membrane keypad
(upper view) and an Oxymitter 4000 with an LOI
(lower view).
Membrane Keypad
SW2
ON
HEATER T/C
HEATER
O2 CELL
CALIBRATION
DIAGNOSTIC
ALARMS
When Fault 13 is detected, the CALIBRATION
LED flashes once, pauses for three seconds,
and repeats.
CALIBRATION RECOMMENDED
INC
INC
HIGH
GAS
LOW
GAS
DEC
DEC
TP1
J1
TP2
TP3
TP4
RED
YEL
GRN
ORG
O2 CELL mV +
O2 CELL mv HEATER T/C +
HEATER T/C -
TEST
POINTS
CAL
TEST GAS +
PROCESS % O2
1. During a calibration, the electronics
calculates a slope value. If the value of the
slope is less than 35 mV/dec or more than
52 mV/dec, the slope alarm will be active
until the end of the purge cycle.
2. See "Calibration with Keypad" in Section 9:
Maintenance and Service. Verify the
calibration by carefully repeating it. Ensure
the calibration gases match the calibration
gas parameters. If you attach a multimeter
to TP1+ and TP2-, sample gas
measurements are:
TP5
TP6
KEYPAD
8% O2 23 mV
0.4% O2 85 mV
3. Power down the Oxymitter 4000 and
remove it from the stack.
4. Replace the cell per "Cell Replacement" in
Section 9: Maintenance and Service.
LOI
When Fault 13 is detected, the LOI displays the
"O2 Cell Bad" message. Refer to the comments
and procedures in paragraphs 1 through 4
above.
LOI
37260031
Alarms
O2 Cell Bad
8-19
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 8-16. Fault 14, Invalid Constant
Fault 14, Invalid Constant
Figure 8-16 shows the electronic assembly for
an Oxymitter 4000 with a membrane keypad
(upper view) and an Oxymitter 4000 with an LOI
(lower view).
Membrane Keypad
SW2
ON
HEATER T/C
HEATER
O2 CELL
CALIBRATION
DIAGNOSTIC
ALARMS
When Fault 14 is detected, the CALIBRATION
LED flashes twice, pauses for three seconds,
and repeats.
CALIBRATION RECOMMENDED
TEST
POINTS
INC
INC
HIGH
GAS
LOW
GAS
DEC
DEC
TP1
J1
TP2
1. After a calibration has been performed, the
electronics calculates a cell constant value.
TP3
TP4
RED
YEL
GRN
ORG
O2 CELL mV +
O2 CELL mv HEATER T/C +
HEATER T/C -
2. If the cell constant value is outside of the
range, -4 mV to 10 mV, the alarm will
activate. See "Calibration with Keypad" in
Section 9: Maintenance and Service, and
verify the last calibration was performed
correctly.
CAL
TEST GAS +
PROCESS % O2
TP5
TP6
3. Power down the Oxymitter 4000 and
remove it from the stack.
4. Replace the cell per "Cell Replacement" in
Section 9: Maintenance and Service.
KEYPAD
LOI
When Fault 14 is detected, the LOI displays the
"O2 Cell Bad" message. Refer to the comments
and procedures in paragraphs 1 through 4
above.
LOI
8-20
37260032
Alarms
O2 Cell Bad
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 8-17. Fault 15, Last Calibration Failed
Fault 15, Last Calibration Failed
SW2
Membrane Keypad
ON
HEATER T/C
HEATER
O2 CELL
CALIBRATION
DIAGNOSTIC
ALARMS
Figure 8-17 shows the electronic assembly for
an Oxymitter 4000 with a membrane keypad
(upper view) and an Oxymitter 4000 with an LOI
(lower view).
When Fault 15 is detected, the CALIBRATION
LED flashes three times, pauses for three
seconds, and repeats.
CALIBRATION RECOMMENDED
INC
INC
HIGH
GAS
LOW
GAS
DEC
DEC
TP1
J1
TP2
1. The last calibration failed alarm activates
when the slope and constant values
calculated are out of range and the unit
reverts to using the previous calibration
values.
TP3
TP4
RED
YEL
GRN
ORG
O2 CELL mV +
O2 CELL mv HEATER T/C +
HEATER T/C -
TEST
POINTS
CAL
TEST GAS +
PROCESS % O2
TP5
2. The cell should be replaced. See "Cell
Replacement" in Section 9: Maintenance
and Service, for cell replacement
instructions.
TP6
KEYPAD
LOI
When Fault 15 is detected, the LOI displays the
"Calib Failed" message. Refer to the comments
in paragraphs 1 and 2 above.
LOI
37260033
Alarms
Calib Failed
8-21
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
CALIBRATION PASSES,
BUT STILL READS
INCORRECTLY
There are a few fault conditions where no alarm indication is present and the
probe passes calibration, but the O2 reading may still be incorrect:
Probe passes calibration, but still appears to read high
There may be a leak that is permitting ambient air to mix with the process
gases. Since many combustion processes are slightly negative in pressure,
ambient air can be sucked into the cell area, biasing the O2 reading upward.
1. Make sure that the calibration gas line is capped tightly between
calibrations. If autocal is used, make sure the check valve is seating
properly.
2. If an abrasive shield is installed to protect the entire probe from
particulate erosion, a leak in the probe flange gasket can allow ambient
air to migrate down the annular space between the probe and shield,
and then into the cell. Always install a new probe flange gasket when
reinstalling a probe.
There may be a leak inside the probe itself, permitting the reference air
(20.95% O2) to mix with the process gases at the cell. To confirm this leak
condition, instrument air will need to be connected for reference. Pressurize
the inside (reference side) of the probe by plugging the reference air exhaust
port with your finger for 1 minute. The O2 reading should decrease slightly. If
the O2 reading increases during this test, there is a leak inside the probe.
1. Acid condensation inside the probe can degrade the red silicon tube
(item 38, Figure 9-3) that carries the cal gas to the cell. Remove the
housing (11) to inspect this hose. (See Section 9: Maintenance and
Service). Black vitan material is optionally available with greater
chemical resistance.
Figure 8-18. Probe Leakage
Paths
Corrugated
Seal
Probe
Flange
Gasket
Reference Air
Exhaust Port
PROBE HEAD
BOTTOM VIEW
2. The sensing cell is bolted to the end of the probe, and uses a corrugated
metallic seal (item 25, Figure 9-3) to separate the process gases from
the ambient reference air. This seal can be used only one time, so
always replace this seal when a cell is removed or replaced. Always
apply anti-seize compound on both sides of the corrugations.
8-22
Instruction Manual
IM-106-340, Rev. 4.0
February 2005
Oxymitter 4000
Probe passes calibration, but still appears to read low
The diffusion element at the end of the probe is a passive filter. It plugs very
slowly, since there is no active flow being drawn across it. In applications that
have a heavy particulate loading (coal or wood fired boilers, cement and lime
kilns, catalyst regeneration, recovery boilers, etc.), this diffusion element will
eventually plug.
It is important not to pressurize the sensing cell during calibrations by flowing
excessive cal gas against a plugged diffuser. Calibration flow rates should be
set only when a new diffuser is installed. As the diffuser plugs, do not adjust
the flow rates upward.
How do I detect a plugged diffuser?
The O2 signal's speed of response will degrade. The O2 trend in the control
room will become smoother.
When calibrating, the calibration gas flow rate will be noted to be lower. Never
readjust this flow upwards. Adjust this flow only when a new diffuser is
installed.
Always note the time it takes for the cell to recover to the normal process
value after the cal gas is removed. As the diffuser plugs, this recovery time will
get longer and longer. Use the Calibration Record form provided in this
manual.
Can I calibrate a badly plugged diffuser?
It may not be possible to immediately replace a plugged diffuser while the
process is on line.
One can calibrate the probe without pressurizing the cell by adjusting the
calibration gas flow rate downward before calibration. For instance, say the
process is at 3%, and the first calibration gas is 8%. Adjust the flow of cal gas
downward until the reading begins to migrate from 8% to lower values,
indicating that process gases are now mixing in with the calibration gases.
Adjust the flow rate back up until this mixing is just eliminated. Calibrate at this
flow rate. Replace the diffuser at the first opportunity.
Install all protective equipment covers and safety ground leads after troubleshooting. Failure
to install covers and ground leads could result in serious injury or death.
8-23
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Calibration Record
For
Rosemount Analytical In Situ O2 Probe
Probe Serial Number: ______________________________________________________________________
Probe Tag Number: _______________________________________________________________________
Probe Location: __________________________________________________________________________
Date Placed Into Service: __________________________________________________________________
Date
Slope
Constant
Impedance
Responseinitial
Responsefinal
Notes: Responseinitial When the second calibration gas is turned off, note the number of seconds required for the O2 value to begin migrating
back to the process value.
Responsefinal
9-0
When the second calibration gas is turned off, note the number of seconds required for the O2 value to settle out at the
process value.
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Section 9
Oxymitter 4000
Maintenance and Service
Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 9-1
Calibration with Keypad . . . . . . . . . . . . . . . . . . . . . . . . . . . page 9-1
Calibration with LOI . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 9-5
Oxymitter 4000 Repair . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 9-7
OVERVIEW
This section identifies the calibration methods available and provides the
procedures to maintain and service the Oxymitter 4000.
Install all protective equipment covers and safety ground leads after equipment repair or
service. Failure to install covers and ground leads could result in serious injury or death.
CALIBRATION WITH
KEYPAD
During a calibration, two calibration gases with known O2 concentrations are
applied to the Oxymitter 4000. Slope and constant values calculated from the
two calibration gases determine if the Oxymitter 4000 is correctly measuring
the net concentration of O2 in the industrial process. A calibration record
sheet has been provided at the back of this section to track performance.
Before calibrating, verify that the calibration gas parameters are correct by
setting the gas concentrations used when calibrating the unit (see "Overview"
in Section 5: Startup and Operation of Oxymitter 4000 with Membrane
Keypad, or Section 6: Startup and Operation of Oxymitter 4000 with LOI) and
by setting the calibration gas flowmeter. The calibration gas flowmeter
regulates the calibration gas flow and must be set to 5 scfh. Only adjust the
flowmeter to 5 scfh after placing a new diffusion element on the end of the
Oxymitter 4000. Adjusting the flowmeter at any other time can pressurize the
cell and bias the calibration.
In applications with a heavy dust loading, the O2 probe diffusion element may
become plugged over time, causing a slower speed of response. The best
way to detect a plugged diffusion element is to note the time it takes the
Oxymitter 4000 to return to the normal process reading after the last
calibration gas is removed and the calibration gas line is blocked off. A
plugged diffusion element also can be indicated by a slightly lower reading on
the flowmeter.
Change the diffusion element when the calibration gas flowmeter reads
slightly lower during calibration or when response to the process flue gases
becomes very slow. Each time the diffusion element is changed, reset the
http://www.processanalytic.com
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 9-1. Membrane Keypad
DIAGNOSTIC
ALARMS
HEATER T/C
HEATER
O2 CELL
CALIBRATION
CALIBRATION RECOMMENDED
TEST
POINTS
INC
LOW
GAS
DEC
DEC
CAL
TEST GAS +
PROCESS % O2
22220067
INC
HIGH
GAS
O2 CELL mV +
O2 CELL mv HEATER T/C +
HEATER T/C -
calibration gas flowmeter to 5 scfh and calibrate the Oxymitter 4000. To
change the diffusion element, refer to "Ceramic Diffusion Element
Replacement".
Three types of calibration methods are available: automatic, semi-automatic,
and manual.
NOTE
A calibration can be aborted any time during the process. Press the CAL key
(Figure 9-1) on the Oxymitter 4000 keypad three times within three seconds,
or abort via the LOI, HART/AMS, or an IMPS 4000. An aborted calibration will
retain the values of the previous good calibration.
Automatic Calibration
Automatic calibrations require no operator action. However, the calibration
gases must be permanently piped to the Oxymitter 4000, an SPS 4001B or
IMPS 4000 must be installed to sequence the gases, and the logic I/O must
be set to mode 8 via HART/AMS so the sequencer and Oxymitter 4000 can
communicate.
Depending on your system setup, an automatic calibration can be initiated by
the following methods:
1. The Oxymitter 4000's CALIBRATION RECOMMENDED alarm signals
that a calibration is required.
2. Enter a "time since last cal" parameter (CAL INTRVL) via HART/AMS or
the LOI that will initiate an automatic calibration at a scheduled time
interval (in hours). To configure the CAL INTRVL parameter, refer to
"Defining a Timed Calibration via HART" in Section 7: HART/AMS, or
"Navigating the Local Operator Interface" in Section 6: Startup and
Operation of Oxymitter 4000 with LOI.
9-2
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
3. If using an IMPS 4000, enter a time interval via the IMPS 4000 keypad
that will initiate an automatic calibration at a scheduled time interval (in
hours). To set the CalIntvX parameter of the CHANGE PRESETS
display mode, refer to the IMPS 4000 Intelligent Multiprobe Test Gas
Sequencer Instruction Manual for more information.
Once an automatic calibration is initiated, by any of the methods previously
described, the Oxymitter 4000's CALIBRATION RECOMMENDED alarm
signals an IMPS 4000 or SPS 4001B to initiate a calibration. The sequencer
sends an "in cal" signal to the control room so that any automatic control loops
can be placed in manual. Then, the sequencer begins to sequence the
calibration gases.
Semi-Automatic
Calibration
Semi-automatic calibrations only require operator initiation. However, the
calibration gases must be permanently piped to the Oxymitter 4000, an SPS
4001B or IMPS 4000 must be installed to sequence the gases, and the logic
I/O must be set to mode 8 or 9 via HART/AMS to allow the sequencer and the
Oxymitter 4000 to communicate.
Depending on your system setup, a semi-automatic calibration can be
initiated by the following methods:
1. Oxymitter 4000 with membrane keypad. Press the CAL key on the
Oxymitter 4000 keypad.
2. Oxymitter 4000 with LOI. Select "Start Calib" from the CALIBRATION
menu.
3. IMPS 4000. Use the IMPS 4000 keypad to change the InitCalX
parameter of the CHANGE PRESETS display mode from 0000 to 0001.
Refer to the IMPS 4000 Intelligent Multiprobe Test Gas Sequencer
Instruction Manual for more information.
4. HART. Use the HART Communicator to access the O2 CALIBRATE
menu and perform the O2 CAL method. Refer to "HART Communicator
O2 Cal Method" in Section 7: HART/AMS for the complete calibration
procedure.
5. AMS. Refer to AMS documentation for more information.
6. Remote Contact. Initiate a calibration from a remote location via the
remote contact input connection provided by an IMPS 4000 or SPS
4001B. Refer to the documentation available for the control system in
use for more information.
Once a semi-automatic calibration is initiated by any of the methods
previously described, the Oxymitter 4000's CALIBRATION RECOMMENDED
alarm signals an IMPS 4000 or SPS 4001B to initiate a calibration. The
sequencer sends an "in cal" signal to the control room so that any automatic
control loops can be placed in manual. Then, the sequencer begins to
sequence the calibration gases.
Manual Calibration with
Membrane Keypad
Manual calibrations must be performed at the Oxymitter 4000 site and will
require operator intervention throughout the process. Manual calibration
instructions, in condensed form, can also be found on the inside of the right
electronics housing cover. See Figure 9-2.
Use the following procedure to perform a manual calibration:
1. Place control loop in manual.
9-3
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 9-2. Inside Right Cover
MANUAL
CALIBRATION
ALARMS
LED
FLASHES
1
HEATER T/C
SHORTED
3
REVERSED
A/D COMM
ERROR
OPEN
HIGH HIGH
TEMP
HIGH CASE
TEMP
LOW TEMP
1
2
3
4
5
O2 CELL
1
3
4
1
CALIBRATION
OPEN
2
4
HEATER
STATUS
2
3
HIGH TEMP
OPEN
BAD
EPROM
CORRUPT
INVALID SLOPE
INVALID
CONSTANT
LAST CAL
FAILED
CONTROL LOOP
* PLACE
IN MANUAL
LED ON
* IFGOCAL
TO STEP 2
1 PUSH CAL
CAL LED ON
2 PUSH CAL
CAL LED FLASH
3 APPLY TG1
PUSH CAL
CAL LED ON SOLID
WAIT FOR FLASH
5 REMOVE TG1 & APPLY TG2
4
PUSH CAL
CAL LED ON SOLID
WAIT FOR FLASH
2 FLASH-VALID CAL
3 FLASH-INVALID CAL
7 REMOVE TG2
PUSH CAL
CAL LED ON FOR
8
PURGE TIME
CAL LED OFF
6
SW2 DIP SWITCH
LOCAL
0-25%
20mA
NOT USED
29770005
HART
0-10%
4mA
NOT USED
2. Verify the calibration gas parameters are correct per "Calibration with
Keypad".
3. If performing a manual calibration with the CALIBRATION
RECOMMENDED LED off and the CAL LED off, start at step a.
4. If performing a manual calibration with the CALIBRATION
RECOMMENDED LED on and the CAL LED on, start at step b.
a. Push the CAL key. The CALIBRATION RECOMMENDED LED will
come on and the CAL LED will be on solid. If a multimeter is
attached across TP5 and TP6, the reading will display the
percentage of oxygen seen by the cell.
b. Push the CAL key. The CALIBRATION RECOMMENDED LED will
turn off and the CAL LED will flash continuously. The Oxymitter 4000
can be configured so that the 4-20 mA signal will hold the last value.
The default condition is for the output to track. A flashing LED
indicates that the Oxymitter 4000 is ready to accept the first
calibration gas.
c. Apply the first calibration gas. (Electronics will abort the calibration if
step 4 is not done within 30 minutes).
d. Push the CAL key; the CAL LED will be on solid. A timer is activated
to allow the calibration gas adequate time to flow (default time of five
minutes). When the timer times out, the Oxymitter 4000 has taken
the readings using the first calibration gas and the CAL LED will flash
continuously. The flashing indicates the Oxymitter 4000 is ready to
take readings using the second calibration gas.
9-4
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
e. Remove the first calibration gas and apply the second calibration
gas. (Electronics will abort the calibration if step f is not done within
30 minutes).
f. Push the CAL key; the CAL LED will be on solid. The timer is
activated for the second calibration gas flow. When the timer times
out, the CAL LED will flash a 2 pattern flash or a 3 pattern flash (2
pattern flash equals a valid calibration, 3 pattern flash equals an
invalid calibration). If the slope or the constant is out of specification,
a diagnostic alarm LED will be flashing. The diagnostic alarm will
remain active until the purge cycle is over. If the three pattern flash
occurs without a diagnostic alarm, the calibration gases could be the
same or the calibration gas was not turned on.
A flashing CAL LED indicates the calibration is done. (See Section 8:
Troubleshooting, for an explanation of the 2 pattern and 3 pattern
flashes).
g. Remove the second calibration gas and cap off the calibration gas
port.
h. Push the CAL key; the CAL LED will be on solid as the unit purges.
(Default purge time is three minutes). When the purge is complete,
the CAL LED will turn off and the Oxymitter 4000 output unlocks from
its held value and begins to read the process O2.
If the calibration was valid, the DIAGNOSTIC ALARMS LEDs will
indicate normal operation. If either new calibration value (slope or
constant) is not within parameters, the DIAGNOSTIC ALARMS LED will
indicate an alarm. (See Section 8: Troubleshooting, for alarm codes). If
the calibration was invalid, the Oxymitter 4000 will return to normal
operation, as it was before a calibration was initiated, and the
parameters will not be updated.
5. Place control loop in automatic.
CALIBRATION WITH LOI
Refer to Figure 6-4 for a view of the LOI menu tree. To calibrate the Oxymitter
4000 from the LOI, access the CALIBRATION/ Start Calibration menu.
CALIBRATION/Start Calibration
This is the starting point for calibrations. The LOI will instruct the user through
this entire procedure. You can select "Abort Calib" at any time to abort the
calibration.
1. The LOI displays the following:
Apply Gas 1
Hit E when ready
The Oxymitter 4000 is ready to accept the first calibration gas. Apply the
first calibration gas. (Electronics will abort the calibration if this step is
not done within 30 minutes).
2. Touch the Enter key to start the Gas 1 flow. A timer is activated to allow
the calibration gas adequate time to flow (default time of five minutes).
The LOI displays:
Flow Gas 1 xxxxs
Read Gas 1 xxxxs
Done Gas 1
9-5
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
The display counts down the seconds remaining to flow Gas 1, then the
time remaining for sensing the O2 concentration of Gas 1. Done Gas 1
indicates completion.
3. Remove the first calibration gas and apply the second calibration gas.
(Electronics will abort the calibration if this step is not done within 30
minutes). The LOI displays the following:
Apply Gas 2
Hit E when ready
4. Touch the Enter arrow to start the Gas 2 flow. The timer is activated and
the LOI displays:
Flow Gas 2 xxxxs
Read Gas 2 xxxxs
Done Gas 2
Stop Gas
Hit E when ready
5. Remove the second calibration gas and cap off the calibration gas port.
Then, touch the Enter arrow to indicate completion. The timer is
activated and the LOI displays:
Purge xxxxs
The default purge time is three minutes. When the gas purge timer
times out, the Oxymitter 4000 begins to read the process O2.
Abort Calibration
Exits the calibration. After calibration gases are removed, and the purge times
out, the instrument goes back to normal operational mode.
Cal Constants - Results of the Calibration
Current calibration
If the calibration passed these values will be updated. Log these values
onto the calibration log sheet supplied. If the process has high levels of
particulate, the response back to the process after cal gas is also
removed.
Previous Calibration
Values from the prior good calibration.
Failed Calibration
Bad calibration values are not loaded into the electronics.
Calibration Status
Calibration Step
The current step in an active calibration procedure.
Calibration Time
Time until the next scheduled calibration.
Next O2 Cal
Time until the next O2 calibration, if different than the next scheduled
calibration.
9-6
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
OXYMITTER 4000
REPAIR
Oxymitter 4000
Each of the following procedures details how to remove and replace a specific
component of the Oxymitter 4000.
It is recommended that the Oxymitter 4000 be removed from the stack for all service
activities. The unit should be allowed to cool and be taken to a clean work area. Failure to
comply may cause severe burns.
Disconnect and lock out power before working on any electrical components. There is
voltage up to 115 VAC.
Removal and
Replacement of Probe
1. Remove.
a. Turn off power to the system.
b. Shut off the calibration gases at the cylinders and the instrument air.
c. Disconnect the calibration gas and instrument air lines from the
Oxymitter 4000.
d. While facing the Oxymitter 4000 and looking at the Rosemount label,
remove screw (32, Figure 9-3 or Figure 9-4), gasket (33), and cover
lock (34) securing left housing cover (27). Remove the cover to
expose the terminal block.
e. Remove all signal and power wiring to the probe.
f. Remove insulation to access the mounting bolts.
g. Unbolt the Oxymitter 4000 from the stack and take it to a clean work
area.
h. Allow the unit to cool to a comfortable working temperature.
2. Replace.
a. Bolt the Oxymitter 4000 to the stack and install the insulation.
b. Connect all signal and power leads at the probe. Refer to Section 2:
Installation, for detailed wiring instructions.
c. Install left housing cover (27, Figure 9-3 or Figure 9-4) and ensure it
is tight. Secure the cover using cover lock (34), gasket (33), and
screw (32).
d. Connect the calibration gas and instrument air lines to probe.
e. Turn on instrument air.
f. Restore power to the system; refer to "Power Up" in Section 5:
Startup and Operation of Oxymitter 4000 with Membrane Keypad or
"Power Up" in Section 6: Startup and Operation of Oxymitter 4000
with LOI. When the probe is at operating temperature, calibrate the
probe per "Calibration with Keypad".
NOTE
Recalibration is required whenever electronic cards or sensing cell is
replaced.
9-7
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 9-3. Oxymitter 4000 with Integral Electronics - Exploded View
26
22
25
23
24
Note: The Electronic Assembly, item 12,
consists of items 13 through 20.
21
27
32
33
12
27A
20
17
18
19
34
14
13
27A
DIA
GN
O
AL STIC
AR
MS
CAL
IBR
AT
34
HEA
TE
R T/
HEA
C
CAL 02 TE
IBR CELR
AT L
IO
OM
N
MEN
DED
02
C
02 ELL
HEACEL mV
+
L
HEATER mv
TE T/C INC
R T/ +
C-
IO
NR
EC
TE
PO ST
INTS
INC
HIGH
GA
S
DEC
LO
W
GA
S
DEC
33
32
15
CAL
TE
ST
PR GAS
OC
ES +
%
02 S -
16
7
11
14A
11A
6
10
1.
2.
3.
4.
5.
6.
7.
8.
9.
10.
11.
11A.
12.
13.
14.
14A.
15.
16.
17.
18.
19.
20.
21.
22.
23.
24.
25.
26.
Heater Strut Assembly
Diffusion Assembly (Snubber)
Retainer Screw
Cell and Flange Assembly
Corrugated Seal
Probe Tube Assembly
Screw
Tube Connector
Gas Port
O-Ring
Blind Cover
Window Cover (Optional)
Electronic Assembly
Screw
Membrane Keypad
LOI Module (Optional)
Snap Connector
Captive Screw
Microprocessor Board
Fuse Cap
Fuse
Power Supply Board
Housing
Screw
Lock Washer
Cable Clamp
Terminal Block
Captive Screw
5
28
9
4
3
8
2
29
30
31
Note: Not all parts shown.
9-8
27.
27A.
28.
29.
30.
31.
32.
33.
34.
Left Housing Cover
O-Ring
Silicon Tube
Tube Clamp
Screw
Washer
Screw
Gasket
Cover Lock
37260015
1
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 9-4. Oxymitter 4000 with Remote Electronics - Exploded View
22
REMOTE
ELECTRONICS
26
23 25
24
21
27
14A
27A
20
11A
1
32
2
34
17
18 19
33
14
13
27A
34
32
DIAG
NO
AL STIC
HE
AR
AT
MS
ER
CA
LIB
HE T/C
AT
RA
TION CALIB02 ER
CE
RA LL
RE
TI
CO
MM ON
TE
EN
PO ST
DE
INTS
02
D
CE
02 LL
HE CELL mV
+
AT
INC
HE ER mv
AT T/ ER C +
INC
HIG
T/C
GA H
S
LO
W
GA
DE
S
CA
C
L
DE
C
TE
ST
PR GA
OC S
ES +
%
02 S -
10
33
7
6
15
3
4
5
16
12
27A
Note: The electronic assembly, item 12,
consists of items 13 through 20.
11
35
27A
26
22
36
23
27
24
21
32
INTERCONNECTING
CABLE
PROBE HEAD
9
34
27A
33
11
Mounting Kit
Screw
Housing Cover
Wiring Diagram Label
Junction Box
Jumper Assembly, Power
Jumper Assembly, Signal
Connecting Cable, Signal
Connecting Cable, Heater
O-Ring
Blind Cover
Window Cover (Optional)
Electronic Assembly
Screw
Membrane Keypad
LOI Module (Optional)
Snap Connector
Captive Screw
Microprocessor Board
Fuse Cap
Fuse
2
33
34
8
20.
21.
22.
23.
24.
25.
26.
27A.
27.
32.
33.
34.
35.
36.
32
Power Supply Board
Housing
Screw
Lock Washer
Cable Clamp
Terminal Block, Remote Electronics
Captive Screw
O-Ring
Left Housing Cover
Screw
Gasket
Cover Lock
Interconnecting Cable
Terminal Block, Remote Probe Head
10
PROBE
Refer to Figure 9-3 for
component parts of probe.
37260034
1.
2.
3.
4.
5.
6.
7.
8.
9.
10.
11.
11A.
12.
13.
14.
14A.
15.
16.
17.
18.
19.
9-9
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Replace Entire Integral Electronics (with Housing)
NOTE
Only perform this procedure on units with integral electronics.
NOTE
Recalibration is required whenever electronic cards or sensing cell is
replaced.
1. Follow the instructions in "Removal and Replacement of Probe", to
remove the Oxymitter 4000 from the stack or duct.
2. Remove the right housing cover uncovering the electronic assembly
(Figure 9-5).
3. Depress and remove the J1 (cell and T/C) connector from the J1 socket.
Loosen the three captive mounting screws (16, Figure 9-3 or Figure 9-4)
on the microprocessor board (top board).
4. The J8 connector (heater leads) can be accessed by moving the J1
connector leads out of the slot on the microprocessor board (17) and
sliding the electronic assembly (12) partially out of the housing
(Figure 9-6).
5. Squeeze the J8 connector on the sides and carefully remove. The
electronic assembly can now be completely removed from the housing.
6. Remove the four screws (7, Figure 9-3) from the probe finned housing.
The probe and the electronic housing can now be separated.
7. When reinstalling or replacing the electronic housing, make sure that
O-ring (10) is in good condition. Place the J1 and J8 connectors in the
hole on the flat side of the electronic housing.
8. Hold the J1 and J8 connectors out and to the probe side of the
electronic housing. Make sure that the conduit port of the electronic
housing is on the same side as the CAL and REF gas ports. Replace
the four screws and tighten.
9. Reconnect the J8 connector to the power supply board. Make sure the
connector is secure.
10. Holding the J1 connector leads, slide the electronic assembly the rest of
the way into the housing. Align the electronic assembly so that it fits
flush on the pins. To ensure that it is flush, gently try to rotate the
electronics. If the electronics rotates, repeat the alignment.
11. Reconnect the J1 connector to the microprocessor board. Ensure the
connector is secure and tighten the three captive screws on the
microprocessor board (top board).
12. Replace the housing cover and ensure it is tight.
13. Follow the instructions in "Removal and Replacement of Probe" to
install the Oxymitter 4000 into the stack or duct.
9-10
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 9-5. Electronic Assembly
Mounting
Screw
SMART FAMILY
HARTTM
TM
OXYMITTER 4000
SERIAL NO.
TAG NO.
VOLTS: 85-264 VAC WATTS:
48-62 Hz
OUTPUT: 4-20 mALINE FUSE:
500 VA
5 Amps
J1
CALIBRATION RECOMMENDED
R
TEST
POINTS
INC
INC
HIGH
GAS
LOW
GAS
DEC
DEC
O2 CELL mV +
O2 CELL mv HEATER T/C +
HEATER T/C -
TP1
J1
TP2
TP3
TP4
CAL
TEST GAS +
PROCESS % O2
TP5
TP6
Mounting
Screw
26170018
Rosemount Analytical Inc.
Orrville, OH 44667-0901
800-433-6076
SW2
RED
YEL
GRN
ORG
R
HEATER T/C
HEATER
O2 CELL
CALIBRATION
ON
Mounting
Screw
DIAGNOSTIC
ALARMS
Figure 9-6. J8 Connector
Power
Supply
Board
22220061
J8
9-11
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Electronic Assembly Replacement
(Figure 9-5)
1. Remove the right housing cover uncovering the electronic assembly.
2. Depress and remove the J1 (cell and T/C) connector from the J1 socket.
Loosen the three captive mounting screws (16, Figure 9-3 or Figure 9-4)
on the microprocessor board (top board).
3. The J8 connector (heater leads) can be accessed by moving the J1 connector leads out of the slot on the microprocessor board (17) and sliding
the electronic assembly (12) partially out of the housing (Figure 9-6).
4. Squeeze the J8 connector on the sides and carefully remove. The electronic assembly can now be completely removed from the housing.
5. Reconnect the J8 connector to the power supply board. Make sure the
connector is secure.
6. Holding the J1 connector leads, slide the electronic assembly the rest of
the way into the housing. Align the electronic assembly so that it fits
flush on the pins. To ensure that it is flush, gently try to rotate the electronics. If the electronics rotates, repeat the alignment.
7. Reconnect the J1 connector to the microprocessor board. Ensure the
connector is secure and tighten the three captive mounting screws on
the microprocessor board (top board).
8. Replace the housing cover and ensure it is tight.
Terminal Block Replacement
1. Unscrew left housing cover (27, Figure 9-3).
2. Loosen the mounting screws (26) on the terminal block (25) and carefully lift the block out of the housing.
3. Carefully align the new terminal block on the pins so that it sits flat in the
housing. The round end of the terminal block should be on the opposite
side of the housing conduit ports and should not be able to rotate.
4. Tighten the three mounting screws and ensure the terminal block is
secure in the housing.
Fuse Replacement
(Figure 9-7)
1. Remove the right housing cover uncovering the electronic assembly.
2. Depress and remove the J1 (cell and T/C) connector from the J1 socket.
Loosen the three captive mounting screws (16, Figure 9-3 or Figure 9-4)
on the microprocessor board (top board).
3. The J8 connector (heater leads) can be accessed by moving the J1 connector leads out of the slot on the microprocessor board (17) and sliding
the electronic assembly (12) partially out of the housing (Figure 9-6).
4. Squeeze the J8 connector on the sides and carefully remove. The electronic assembly can now be completely removed from the housing.
5. Completely remove the three mounting screws (16) on the microprocessor board (17).
9-12
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 9-7. Fuse Location
Power
Supply
Board
22220058
Fuse
6. Turn the electronic assembly over so that you are looking at the bottom
of the power supply printed circuit board. Gently depress the two white
posts one at a time. Carefully separate the power supply board (20)
from the microprocessor board (17).
7. Remove the fuse (19) and replace it with a new one (Figure 9-7).
8. Align the white posts with the post holes on the power supply board and
the pin connector on the power supply board with the connector port on
the back of the microprocessor board. Gently push the boards together
until the white posts snap in place. Ensure the assembly is secure by
gently trying to separate the boards.
9. Reconnect connector J8 to the power supply board. Make sure the connector is secure.
10. Holding the J1 connector leads, slide the electronic assembly the rest of
the way into the housing. Align the electronic assembly so that it fits
flush on the pins. To ensure that it is flush, gently try to rotate the electronics. If the electronics rotates, repeat the alignment.
11. Reconnect the J1 connector to the microprocessor board. Ensure the
connector is secure and tighten the three captive screws on the microprocessor board (top board).
12. Replace the housing cover and ensure that it is tight.
Entire Probe Replacement (Excluding Probe Head)
1. Do not attempt to replace the probe until all other possibilities for poor
performance have been considered. If probe replacement is needed,
see Table 11-1 for part numbers.
2. Follow the instructions in "Removal and Replacement of Probe" to
remove the Oxymitter 4000 from the stack or duct.
3. Separate the probe and the probe head per "Replace Entire Integral
Electronics (with Housing)", steps 2 through 6.
4. Reinstall the probe head on the new probe per "Replace Entire Integral
Electronics (with Housing)", steps 7 through 13.
9-13
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Heater Strut Replacement
This paragraph covers heater strut replacement. Do not attempt to replace the
heater strut until all other possibilities for poor performance have been
considered. If heater strut replacement is needed, order a replacement heater
strut. (Table 10-1). Refer to Figure 9-3 or Figure 9-4 to view the component
parts of the Oxymitter 4000.
Use heat resistant gloves and clothing when removing probe. Do not attempt to work on the
probe until it has cooled to room temperature. The probe can be as hot as 800°F (427°C).
This can cause severe burns.
1. Follow the instructions in "Removal and Replacement of Probe" to
remove the Oxymitter 4000 from the stack or duct.
2. For a unit with integral electronics, disconnect electronics per "Replace
Entire Integral Electronics (with Housing)", steps 2 through 5.
3. For a unit with remote electronics, remove cover (11, Figure 9-4) from
housing (21), and disconnect signal and heater connecting cables
(8 and 9) from heater strut assembly (1, Figure 9-4).
4. Remove the four screws (7, Figure 9-4). Remove the probe from the
housing (21).
5. Remove tube clamps (29) and silicon tubes (28) from the CAL and REF
gas ports and the CAL and REF gas lines.
6. Loosen, but do not remove, the three screws (30, Figure 9-3). The
spring tension will release and the heater strut assembly should move
up.
7. When the spring tension is released, remove the three screws (30).
Grasp the wire loop and carefully slide the heater strut assembly
(Figure 9-8) out of the probe tube.
8. When replacing the strut, orient the probe so the small calibration gas
tube is at the 6 o'clock position of the probe tube. Align the slot on the
heater plate with the calibration gas line in the probe tube. Slide the strut
into the probe tube. It will turn to align the hole on the back plate of the
strut with the calibration gas line. When the hole and the calibration gas
line are aligned correctly, the strut will slide in the rest of the way.
9. As the strut installation nears completion, install the guide rod into the
calibration gas tube to assist in guiding the calibration gas tube through
the hole in the end of the strut.
10. Push down on the back plate of the strut to make sure you have spring
tension and then tighten the three screws on the back plate.
11. Replace the CAL and REF gas silicon tubes.
12. For units with integral electronics, install the entire electronics per
"Replace Entire Integral Electronics (with Housing)", steps 7 through 13.
9-14
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 9-8. Heater Strut
Assembly
Wire
Loop
V-Deflector
Ceramic Support Rod
Cell Flange
22220050
Ceramic
Diffuser
Assembly
Heater
Figure 9-9. Probe to Probe Head
Assembly - Remote Electronics
Only
O-Ring (10)
Probe (6)
Housing (21)
Signal
Cable
(9)
Probe Signal
Wire Connector
Heater
Cable
(8)
2 Wire
Probe Heater
Wire Connector
37260058
4 Wire
9-15
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
13. For units with remote electronics, install the probe head as follows:
a. See Figure 9-9. Make sure that the O-ring (10) is in good condition.
Seat the O-ring in the mating groove of the probe (6).
b. Insert the probe signal cables (8 and 9, into the housing 21).
c. Turn the conduit ports of the housing (21) to the CAL and REF gas
ports side of the probe (6) and position the housing on the probe
d. Install and tighten four screws (12, Figure 9-4).
e. Reconnect the probe signal cables (8 and 9) to the probe signal and
heater wire connectors, Figure 9-9. Make sure the connectors are
secure.
f. Install and tighten cover.
14. Follow the instructions in "Removal and Replacement of Probe" to
install the Oxymitter 4000 into the stack or duct.
Cell Replacement
This paragraph covers oxygen sensing cell replacement. Do not attempt to
replace the cell until all other possibilities for poor performance have been
considered. If cell replacement is needed, order the cell replacement kit
(Table 10-1). Refer to Figure 9-3 or Figure 9-4 to view the component parts of
the Oxymitter 4000.
The cell replacement kit (Figure 9-10) contains a cell and flange assembly,
corrugated seal, setscrews, socket head cap screws, and anti-seize
compound. The items are carefully packaged to preserve precise surface
finishes. Do not remove items from the packaging until they are ready to be
used. Spanner wrenches and hex wrenches needed for this procedure are
part of an available special tools kit (Table 10-1 and Figure 10-2).
Figure 9-10. Cell
Replacement Kit
Probe Tube
(Not Included in Kit)
Corrugated
Seal
Cell and Flange
Assembly
Socket H
Cap Scre
22220028
Calibration Gas
Passage
9-16
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Use heat-resistant gloves and clothing when removing the probe. Do not attempt to work on
these components until they have cooled to room temperature. Probe components can be
as hot as 572°F (300°C). This can cause severe burns.
Disconnect and lock out power before working on any electrical components. There is
voltage of up to 115 VAC.
Do not remove the cell unless certain it needs to be replaced. Removal may damage the
cell and platinum pad. Go through the complete troubleshooting procedure to make sure the
cell needs to be replaced before removing it.
1. Follow the instructions in "Removal and Replacement of Probe" to
remove the Oxymitter 4000 from the stack or duct.
2. If the probe uses the standard diffusion element, use a spanner wrench
to remove the diffuser assembly.
NOTE
To determine if the diffuser needs to be replaced, refer to "Calibration with
Keypad".
3. If equipped with the optional ceramic diffusion assembly, remove and
discard the setscrews and remove the vee deflector (Figure 9-11). Use
spanner wrenches from the probe disassembly kit (Table 10-1), to turn
the hub free from the retainer. Inspect the diffusion element. If damaged,
replace the element.
4. Loosen the four socket head cap screws from the cell and flange
assembly and remove the assembly and the corrugated seal. The cell
flange has a notch that may be used to gently pry the flange away from
the probe. Note that the contact pad inside of the probe will sometimes
fuse to the oxygen sensing cell. If the cell is fused to the contact pad,
push the cell assembly back into the probe (against spring pressure)
and quickly twist the cell assembly. The cell and contact pad should
separate. If the contact pad stays fused to the cell, a new contact/
thermocouple assembly must be installed. Disconnect the cell and the
thermocouple wires at the crimp connections and withdraw the cell with
the wires still attached.
5. For units with integral electronics, disconnect the entire electronics per
"Replace Entire Integral Electronics (with Housing)", steps 2 through 5.
6. Remove the four screws (7, Figure 9-3) from the probe finned housing.
The probe and the probe head can now be separated.
7. If the contact assembly is damaged, replace the strut or the contact pad.
Instructions for replacing the contact pad are in the cell replacement kit.
8. Remove and discard the corrugated seal. Clean the mating faces of the
probe tube and retainer. Remove burrs and raised surfaces with a block
of wood and crocus cloth. Clean the threads on the retainer and hub.
9-17
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
9. Rub a small amount of anti-seize compound on both sides of the new
corrugated seal.
10. Assemble the cell and flange assembly, corrugated seal, and probe
tube. Make sure the calibration tube lines up with the calibration gas
passage in each component. Apply a small amount of anti-seize
compound to the screw threads and use the screws to secure assembly.
Torque to 35 in-lbs (4 N·m).
11. Install the entire electronics per "Replace Entire Integral Electronics
(with Housing)", steps 7 through 13.
12. Apply anti-seize compound to the threads of the cell assembly, hub, and
setscrews. Reinstall the hub on the cell assembly. Using pin spanner
wrenches, torque to 10 ft-lbs (14 N·m). If applicable, reinstall the vee
deflector, orienting apex toward gas flow. Secure with the setscrews and
anti-seize compound. Torque to 25 in-lbs (2.8 N·m).
13. On systems equipped with an abrasive shield, install the dust seal
gaskets, with joints 180° apart.
14. Reinstall the probe and gasket on the stack flange.
15. Follow the instructions in "Removal and Replacement of Probe" to
install the Oxymitter 4000 into the stack or duct. If there is an abrasive
shield in the stack, make sure the dust seal gaskets are in place as they
enter the 15° reducing cone.
16. Turn on power and monitor thermocouple output. It should stabilize at
29.3+0.2 mV. Set reference air flow at 2 scfh (56.6 l/hr). After the
Oxymitter 4000 stabilizes, calibrate the unit. If new components have
been installed, repeat calibration after 24 hours of operation.
Ceramic Diffusion Element Replacement
NOTE
This refers to the ceramic diffusion element only.
General
The diffusion element protects the cell from particles in process gases.
Normally, it does not need to be replaced because the vee deflector
protects it from particulate erosion.
In severe environments, the filter may be broken or subject to excessive
erosion. Examine the ceramic diffusion element whenever removing the
probe for any purpose. Replace if damaged.
Damage to the ceramic diffusion element may become apparent during
calibration. Compare probe response with previous response. A broken
diffusion element will cause a slower response to calibration gas. Hex
wrenches needed to remove setscrews and socket head screws in the
following procedure are available as part of a Probe Disassembly Kit,
Table 10-1.
Replacement Procedure
a. Follow the instructions in "Removal and Replacement of Probe" to
remove the Oxymitter 4000 from the stack or duct.
9-18
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
b. Loosen setscrews, Figure 9-11, using hex wrench from Probe
Disassembly Kit, Table 10-1, and remove vee deflector. Inspect
setscrews. If damaged, replace with stainless setscrews coated with
anti-seize compound.
Figure 9-11. Ceramic Diffuser
Element Replacement
Retainer
Spanner
Wrench
Optional Ceramic
Diffusion Element
Set Screw
Hub
Cement
Fillet
Vee
Deflector
Heater (black)
Heater (black)
Oxygen Cell (green)
Thermocouple (yellow)
Thermocouple +
(red)
Oxygen Cell +
(orange)
36940005
Figure 9-12. Contact and
Thermocouple Assembly
Replacement
22220029
Cement
Port
Termination Housing Wiring (Remote Electronics Probe Head Only)
Under normal circumstances, the right termination housing cover should not
need to be removed. This side of the housing contains only two wire
harnesses that connect the internal electrical barrier to pins in the housing
wall. If these jumper wires should become disconnected or need to be
replaced, use the diagram in Figure 9-12 to connect the wires.
9-19
Instruction Manual
Oxymitter 4000
9-20
IM-106-340, Rev. 4.0
February 2006
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Section 10
Replacement Parts
Probe Replacement Parts . . . . . . . . . . . . . . . . . . . . . . . . . page 10-1
Electronics Replacement Parts . . . . . . . . . . . . . . . . . . . . . page 10-6
PROBE REPLACEMENT
PARTS
Table 10-1. Replacement Parts
for Probe
Part Number
Figure and
Index Number
Dust Seal
No Dust Seal
Description
9-3, 1 thru 6, 8,9,28 thru 31
9-3, 1 thru 6, 8,9,28 thru 31
9-3, 1 thru 6, 8,9,28 thru 31
9-3, 1 thru 6, 8,9,28 thru 31
9-3, 1 thru 6, 8,9,28 thru 31
9-3, 1 thru 6, 8,9,28 thru 31
9-3, 1 thru 6, 8,9,28 thru 31
9-3, 1 thru 6, 8,9,28 thru 31
9-3, 1 thru 6, 8,9,28 thru 31
9-3, 1 thru 6, 8,9,28 thru 31
9-3, 1 thru 6, 8,9,28 thru 31
9-3, 1 thru 6, 8,9,28 thru 31
9-3, 1 thru 6, 8,9,28 thru 31
9-3, 1 thru 6, 8,9,28 thru 31
9-3, 1 thru 6, 8,9,28 thru 31
9-3, 1 thru 6, 8,9,28 thru 31
9-3, 1 thru 6, 8,9,28 thru 31
3D39648G01
3D39648G02
3D39648G03
3D39648G04
3D39648G05
--3D39648G06
3D39648G07
3D39648G08
3D39648G09
3D39648G10
3D39648G11
3D39648G12
3D39648G13
3D39648G14
3D39648G15
3D39649G01
3D39649G02
3D39649G03
3D39649G04
3D39649G05
3D39649G53
3D39649G54
3D39649G06
3D39649G07
3D39649G08
3D39649G09
3D39649G10
3D39649G11
3D39649G12
3D39649G13
3D39649G14
3D39649G15
18" ANSI Probe with Ceramic Diffuser
3' ANSI Probe with Ceramic Diffuser
6' ANSI Probe with Ceramic Diffuser
9' ANSI Probe with Ceramic Diffuser
12' ANSI Probe with Ceramic Diffuser
15' ANSI Probe with Ceramic Diffuser
18' ANSI Probe with Ceramic Diffuser
18" JIS Probe with Ceramic Diffuser
3' JIS Probe with Ceramic Diffuser
6' JIS Probe with Ceramic Diffuser
9' JIS Probe with Ceramic Diffuser
12' JIS Probe with Ceramic Diffuser
18" DIN Probe with Ceramic Diffuser
3' DIN Probe with Ceramic Diffuser
6' DIN Probe with Ceramic Diffuser
9' DIN Probe with Ceramic Diffuser
12' DIN Probe with Ceramic Diffuser
9-3, 1 thru 6, 8,9,28 thru 31
9-3, 1 thru 6, 8,9,28 thru 31
9-3, 1 thru 6, 8,9,28 thru 31
9-3, 1 thru 6, 8,9,28 thru 31
9-3, 1 thru 6, 8,9,28 thru 31
9-3, 1 thru 6, 8,9,28 thru 31
9-3, 1 thru 6, 8,9,28 thru 31
9-3, 1 thru 6, 8,9,28 thru 31
9-3, 1 thru 6, 8,9,28 thru 31
9-3, 1 thru 6, 8,9,28 thru 31
9-3, 1 thru 6, 8,9,28 thru 31
3D39648G17
3D39648G18
3D39648G19
3D39648G20
3D39648G21
--3D39648G22
3D39648G23
3D39648G24
3D39648G25
3D39648G17
3D39648G18
3D39648G19
3D39648G20
3D39648G21
3D39649G55
3D39649G56
3D39649G22
3D39648G23
3D39648G24
3D39648G25
18" ANSI Probe with Flame Arrestor and Ceramic Diffuser
3' ANSI Probe with Flame Arrestor and Ceramic Diffuser
6' ANSI Probe with Flame Arrestor and Ceramic Diffuser
9' ANSI Probe with Flame Arrestor and Ceramic Diffuser
12' ANSI Probe with Flame Arrestor and Ceramic Diffuser
15' ANSI Probe with Flame Arrestor and Ceramic Diffuser
18' ANSI Probe with Flame Arrestor and Ceramic Diffuser
18" JIS Probe with Flame Arrestor and Ceramic Diffuser
3' JIS Probe with Flame Arrestor and Ceramic Diffuser
6' JIS Probe with Flame Arrestor and Ceramic Diffuser
9' JIS Probe with Flame Arrestor and Ceramic Diffuser
http://www.processanalytic.com
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Table 10-1. Replacement Parts
for Probe (Continued)
Figure and
Index Number
Part Number
9-3, 1 thru 6, 8,9,28 thru 31
9-3, 1 thru 6, 8,9,28 thru 31
9-3, 1 thru 6, 8,9,28 thru 31
9-3, 1 thru 6, 8,9,28 thru 31
9-3, 1 thru 6, 8,9,28 thru 31
9-3, 1 thru 6, 8,9,28 thru 31
9-3, 1 thru 6, 8,9,28 thru 31
9-3, 1 thru 6, 8,9,28 thru 31
9-3, 1 thru 6, 8,9,28 thru 31
9-3, 1 thru 6, 8,9,28 thru 31
9-3, 1 thru 6, 8,9,28 thru 31
9-3, 1 thru 6, 8,9,28 thru 31
9-3, 1 thru 6, 8,9,28 thru 31
9-3, 1 thru 6, 8,9,28 thru 31
9-3, 1 thru 6, 8,9,28 thru 31
9-3, 1 thru 6, 8,9,28 thru 31
9-3, 1 thru 6, 8,9,28 thru 31
9-3, 1 thru 6, 8,9,28 thru 31
9-3, 1 thru 6, 8,9,28 thru 31
9-3, 1 thru 6, 8,9,28 thru 31
9-3, 1 thru 6, 8,9,28 thru 31
9-3, 1 thru 6, 8,9,28 thru 31
9-3, 1 thru 6, 8,9,28 thru 31
9-3, 6
9-3, 6
9-3, 6
9-3, 6
9-3, 6
9-3, 6
9-3, 6
9-3, 6
9-3, 6
9-3, 6
9-3, 6
9-3, 6
9-3, 6
9-3, 6
9-3, 6
9-3, 6
9-3, 6
9-3, 6
9-3, 1
9-3, 1
9-3, 1
9-3, 1
9-3, 1
9-3, 1
3D39648G26
3D39649G26
3D39648G27
3D39649G27
3D39648G28
3D39649G28
3D39648G29
3D39649G29
3D39648G30
3D39649G30
3D39648G31
3D39649G31
3D39648G33
3D39649G33
3D39648G34
3D39649G34
3D39648G35
3D39649G35
3D39648G36
3D39649G36
3D39648G37
3D39649G37
-3D39649G49
-3D39649G50
3D39648G38
3D39649G38
3D39648G39
3D39649G39
3D39648G40
3D39649G40
3D39648G41
3D39649G41
3D39648G42
3D39649G42
3D39648G43
3D39649G43
3D39648G44
3D39649G44
3D39648G45
3D39649G45
3D39648G46
3D39649G46
3D39648G47
3D39649G47
3D39644G01
3D39644G02
3D39644G03
3D39644G04
3D39644G05
3D39644G17
3D39644G18
3D39644G06
3D39644G07
3D39644G08
3D39644G09
3D39644G10
3D39644G11
3D39644G12
3D39644G13
3D39644G14
3D39644G15
3D39645G01
3D39645G02
3D39645G03
3D39645G04
3D39645G05
3D39645G07
3D39645G08
10-2
Description
12' JIS Probe with Flame Arrestor and Ceramic Diffuser
18" DIN Probe with Flame Arrestor and Snubber Diffuser
3' DIN Probe with Flame Arrestor and Snubber Diffuser
6' DIN Probe with Flame Arrestor and Snubber Diffuser
9' DIN Probe with Flame Arrestor and Snubber Diffuser
12' DIN Probe with Flame Arrestor and Snubber Diffuser
18" ANSI Probe with Snubber Diffuser
3' ANSI Probe with Snubber Diffuser
6' ANSI Probe with Snubber Diffuser
9' ANSI Probe with Snubber Diffuser
12' ANSI Probe with Snubber Diffuser
15' ANSI Probe with Snubber Diffuser
18' ANSI Probe with Snubber Diffuser
18" JIS Probe with Snubber Diffuser
3' JIS Probe with Snubber Diffuser
6' JIS Probe with Snubber Diffuser
9' JIS Probe with Snubber Diffuser
12' JIS Probe with Snubber Diffuser
18" DIN Probe with Snubber Diffuser
3' DIN Probe with Snubber Diffuser
6' DIN Probe with Snubber Diffuser
9' DIN Probe with Snubber Diffuser
12' DIN Probe with Snubber Diffuser
18" ANSI Probe Tube Assy.
3' ANSI Probe Tube Assy.
6' ANSI Probe Tube Assy.
9' ANSI Probe Tube Assy.
12' ANSI Probe Tube Assy
15' ANSI Probe Tube Assy.
18' ANSI Probe Tube Assy.
18" JIS Probe Tube Assy.
3' JIS Probe Tube Assy.
6' JIS Probe Tube Assy
9' JIS Probe Tube Assy.
12' JIS Probe Tube Assy.
18" DIN Probe Tube Assy.
3' DIN Probe Tube Assy.
6' DIN Probe Tube Assy.
9' DIN Probe Tube Assy.
12' DIN Probe Tube Assy.
18" Heater Strut Assy.
3' Heater Strut Assy.
6' Heater Strut Assy.
9' Heater Strut Assy.
12' Heater Strut Assy.
15' Heater Strut Assy.
18' Heater Strut Assy.
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Figure 10-1. Cell
Replacement Kit
ANSI
Gasket
Wire and
Pad Assembly
Anti-Seize
Compound
Probe Tube
(Not Included in Kit)
Corrugated
Seal
22 Ga.
Wire
Closed end
Connector
Cell and
Flange
Assembly
Socket Head
Cap Screws
Set Screws
Teflon
Tubing
35830009
Calibration Gas
Passage
Table 10-1. Replacement Parts
for Probe (Continued)
Figure and
Index Number
Part Number
10-1
10-1
10-1
10-1
10-1
10-1
10-1
10-1
10-1
10-1
10-1
10-1
10-1
4847B61G02
4847B61G03
4847B61G04
4847B61G05
4847B61G06
4847B61G27
4847B61G28
4847B61G08
4847B61G09
4847B61G10
4847B61G11
4847B61G12
4847B61G14
ANSI 18" Cell Replacement Kit*
ANSI 3' Cell Replacement Kit*
ANSI 6' Cell Replacement Kit*
ANSI 9' Cell Replacement Kit*
ANSI 12' Cell Replacement Kit*
ANSI 15' Cell Replacement Kit*
ANSI 18' Cell Replacement Kit*
JIS 18" Cell Replacement Kit*
JIS 3' Cell Replacement Kit*
JIS 6' Cell Replacement Kit*
JIS 9' Cell Replacement Kit*
JIS 12' Cell Replacement Kit*
DIN 18" Cell Replacement Kit*
10-1
10-1
10-1
10-1
4847B61G15
4847B61G16
4847B61G17
4847B61G18
DIN 3' Cell Replacement Kit*
DIN 6' Cell Replacement Kit*
DIN 9' Cell Replacement Kit*
DIN 12' Cell Replacement Kit*
Description
* Includes pad and wire
10-3
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Table 10-1. Replacement Parts
for Probe (Continued)
Figure and
Index Number
Part Number
10-1
4849B94G01
4849B94G02
10-1
10-1
10-1
10-1
4849B94G03
4849B94G04
4849B94G05
4849B94G06
10-1
4849B94G19
10-1
4849B94G20
10-1
10-1
10-1
10-1
10-1
4849B94G07
4849B94G08
4849B94G09
4849B94G10
4849B94G11
4849B94G12
4849B94G13
4849B94G14
4849B94G15
4849B94G16
4849B94G17
4849B94G18
ANSI 18' Cell Replacement Kit, High
Sulfur/HCl Resistant*
JIS High Sulfur/HCl Resistant Cell Only
JIS 18" Cell Replacement Kit, High Sulfur/HCl Resistant*
JIS 3' Cell Replacement Kit, High Sulfur/HCl Resistant*
JIS 6' Cell Replacement Kit, High Sulfur/HCl Resistant*
JIS 9' Cell Replacement Kit, High Sulfur/HCl Resistant*
JIS 12' Cell Replacement Kit, High Sulfur/HCl Resistant*
DIN High Sulfur/HCl Resistant Cell Only
DIN 18" Cell Replacement Kit, High Sulfur/HCl Resistant*
DIN 3' Cell Replacement Kit, High Sulfur/HCl Resistant*
DIN 6' Cell Replacement Kit, High Sulfur/HCl Resistant*
DIN 9' Cell Replacement Kit, High Sulfur/HCl Resistant*
DIN 12' Cell Replacement Kit, High Sulfur/HCl Resistant*
2-4
3D39003G09
JIS 9' Abrasive Shield Assy.
2-4
2-4
2-4
2-4
2-4
2-4
2-4
2-4
3D39003G10
3D39003G11
3D39003G12
3D39003G13
3D39003G14
3D39003G15
3D39003G25
3D39003G28
JIS 12' Abrasive Shield Assy.
DIN 9' Abrasive Shield Assy.
DIN 12' Abrasive Shield Assy.
ANSI 18" Abrasive Shield Assy
JIS 18" Abrasive Shield Assy.
DIN 18" Abrasive Shield Assy.
ANSI 15' Abrasive Shield Assy.
ANSI 18' Abrasive Shield Assy.
9-12
9-12
9-12
9-12
9-12
9-12
9-12
4513C61G03
4513C61G04
4513C61G05
4513C61G06
4513C61G07
4513C61G08
4513C61G09
18" Contact and Thermocouple Replacement Assembly
3' Contact and Thermocouple Replacement Assembly
6' Contact and Thermocouple Replacement Assembly
9' Contact and Thermocouple Replacement Assembly
12' Contact and Thermocouple Replacement Assembly
15' Contact and Thermocouple Replacement Assembly
18' Contact and Thermocouple Replacement Assembly
10-1
10-1
10-1
10-1
10-1
*Includes pad and wire
10-4
Description
ANSI High Sulfur/Hl Resistant Cell Only
ANSI 18" Cell Replacement Kit, High
Sulfur/HCl Resistant*
ANSI 3' Cell Replacement Kit, High Sulfur/HCl Resistant*
ANSI 6' Cell Replacement Kit, High Sulfur/HCl Resistant*
ANSI 9' Cell Replacement Kit, High Sulfur/HCl Resistant*
ANSI 12' Cell Replacement Kit, High
Sulfur/HCl Resistant*
ANSI 15' Cell Replacement Kit, High
Sulfur/HCl Resistant*
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Table 10-1. Replacement Parts
for Probe (Continued)
Figure and
Index Number
Part Number
1-11
1-11
1-11
1-11
1-12
1-12
1-12
1-12
9-11
9-11
1-13
1-13
1-13
1-13
10-2
3534B18G01
3535B60G01
3535B62G01
3535B63G01
4843B37G01
4843B38G02
4846B70G01
4846B71G01
3534B18G01
3534B48G01
4851B89G04
4851B89G05
4851B90G04
4851B90G05
3535B42G02
Description
Ceramic Diffuser
Ceramic Diffuser with Dust Seal
Flame Arrestor Ceramic Diffuser
Flame Arrestor Ceramic Diffuser with Dust Seal
Snubber Diffuser
Snubber Diffuser with Dust Seal
Flame Arrestor Snubber Diffuser
Flame Arrestor Snubber Diffuser with Dust Seal
Ceramic Diffuser Hub Assy.
Vee Deflector Assy.
Cup Type Diffusion Assembly, 5 microns
Cup Type Diffusion Assembly, 40 microns
Cup Type Diffusion Assembly/Dust Seal, 5 microns
Cup Type Diffusion Assembly/Dust Seal, 40 microns
Probe Disassembly Kit
Figure 10-2. Probe
Disassembly Kit
Hex Keys
Philips
Screwdriver
Spanner
Wrench
Wrench
Tube Insertion
Tube
37250001
Anti-Seize
Compound
10-5
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
ELECTRONICS
REPLACEMENT PARTS
Table 10-2. Replacement Parts
for Electronics
Figure and
Index Number
10-6
Part Number
Description
9-3, 10
9-3, 11
9-3, 11A
9-3, 12
9-3, 14
9-3, 14
9-3, 14
9-3, 14
9-3, 14
9-3, 14A
9-3, 21
9-3, 25
9-3, 25
9-3, 27A
120039076
5R10145G01
5R10199G01
3D39861G01
4849B72H01
4849B72H02
4849B72H03
4849B72H04
4849B72H05
6A00115G01
4849B95G01
08732-0002-0001
08732-0002-0002
120039078
O-Ring
Cover
Cover, with Window
Electronic Assembly
Membrane Keypad English
Membrane Keypad German
Membrane Keypad French
Membrane Keypad Spanish
Membrane Keypad Italian
LOI Module (Local Operator Interface)
Housing
Termination Block Standard
Termination Block Transient Protected
O-Ring
9-4, 5
9-4, 8
9-4, 9
9-4, 10
9-4, 11
9-4, 11A
9-4, 12
9-4, 14A
9-4, 21
9-4, 25
9-4, 25
9-4, 27A
9-4, 35
9-4, 35
9-4, 35
9-4, 35
9-4, 35
9-4, 35
9-4, 35
9-4, 36
9-4, 36
6A00091G01
4849B92G20
4849B92G21
120039076
5R10145G01
5R10199G01
3D39861G01
6A00115G01
4849B95G01
08732-0002-0001
08732-0002-0002
120039078
6A00121G01
6A00121G02
6A00121G03
6A00121G04
6A00121G05
6A00121G06
6A00121G07
3D39866G01
3D39866G02
Junction Box
Connecting Cable, Signal
Connecting Cable, Heater
O-Ring
Cover
Cover, with Window
Electronic Assembly
LOI Module (Local Operator Interface)
Housing
Termination Block, Standard
Termination Block, Transient Protected
O-Ring
Cable Assembly, 20 ft. (6 m)
Cable Assembly, 40 ft. (12 m)
Cable Assembly, 60 ft. (18 m)
Cable Assembly, 80 ft. (24 m)
Cable Assembly, 100 ft. (30 m)
Cable Assembly, 150 ft. (46 m)
Cable Assembly, 200 ft. (61 m)
Termination Block, Standard, Remote Probe Head
Termination Block, Transient Protected, Remote Probe Head
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Table 10-3. Replacement Parts
for SPS 4001B
Figure and
Index Number
9-13, 4
9-15, 19
9-13, 15
9-15, 17
9-15, 16
9-15, 8
9-13, 17
9-13, 19
9-13, 18
9-13, 12
9-13, 13 and 20
9-13, 8
9-13, 28
9-13, 25
Part Number
1A99093H01
6292A97H03
1A99089H01
771B635H01
771B635H02
1A99094H01
1A97913H03
4850B56G02
4850B54G01
7305A67H01
3D39435G01
120039-0077
4850B75H01
1A99147H01
Description
Bushing Gasket
Check Valve
Cover O-Ring
Flowmeter Assembly, Calibration Gas
Flowmeter Assembly, Reference Air (Optional)
Pressure Regulator, Reference Air (Optional)
Fuse, 5A, 250V, 5 20 mm, Slow Blow
Interface Board
Power Supply Board
Pressure Switch
Solenoid
O-Ring
Terminal Cover Gasket
Terminal Strip
Table 10-4. Replacement Parts
for Calibration Components
Figure and
Index Number
Part Number
11-5
1A99119G01
11-5
11-5
1A99119G02
1A99119G03
Description
Calibration Gas Bottles - 0.4% and 8% O2, balance
nitrogen - 550 liters each*
Two Flow Regulators (for calibration gas bottles)
Bottle rack
*Calibration gas bottles cannot be shipped via airfreight.
10-7
Instruction Manual
Oxymitter 4000
10-8
IM-106-340, Rev. 4.0
February 2006
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Section 11
Oxymitter 4000
Optional Accessories
HART Handheld 375 Communicator . . . . . . . . . . . . . . . . . page 11-1
Asset Management Solutions (AMS) . . . . . . . . . . . . . . . . page 11-2
By-Pass Packages . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 11-2
IMPS 4000 Intelligent Multiprobe Test gas Sequencer . . page 11-3
SPS 4001B Single Probe Autocalibration Sequencer . . . page 11-4
O2 Calibration Gas . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 11-5
Catalyst Regeneration . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 11-6
HART HANDHELD 375
COMMUNICATOR
Figure 11-1. HART Model 375
Handheld Communicator
MAN 4275A00
English
HART Communicator
37260059
o
The HART Handheld 275/375 Communicator is an interface device that
provides a common communication link to HART-compatible instruments,
such as the Oxymitter 4000. HART Communications Protocol permits all the
information available from the Oxymitter 4000's electronics to be transmitted
over standard 4-20 mA signal wires. By attaching the HART handheld
communicator at a termination point along the 4-20 mA signal line, a
technician can diagnose problems and configure and calibrate the Oxymitter
4000 as if he or she were standing in front of the instrument.
For more information, call Emerson Process Management at 1-800-433-6076.
http://www.processanalytic.com
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
ASSET MANAGEMENT
SOLUTIONS (AMS)
Asset Management Solutions (AMS) software works in conjunction with the
HART Communication Protocol and offers the capability to communicate with
all HART plant devices from a single computer terminal.
For more information, call Emerson Process Management at 1-800-433-6076.
BY-PASS PACKAGES
I VE
IG
H
T
WHE N
CI R
CU
VE ATM
OS I
O
PL WA RN I NG - SPH
EX -
AL
-
E
ER
IT
Figure 11-2. By-Pass Mounting
P
T
IN
26170024
CAL.
GAS
EE
The specially designed Rosemount Analytical By-Pass Package for oxygen
analyzers has proven to withstand the high temperatures in process heaters
while providing the same advantages offered by the in situ sensor. Inconel or
Kanthal steel tubes provide effective resistance to corrosion, and the package
uses no moving parts, air pumps, or other components common to other
sampling systems.
For more information, call Emerson Process Management at 1-800-433-6076.
11-2
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
IMPS 4000 INTELLIGENT
MULTIPROBE TEST GAS
SEQUENCER
26170006
Figure 11-3. IMPS 4000
The IMPS 4000 Intelligent Multiprobe Test Gas Sequencer is housed within
an IP56 (NEMA 4X) enclosure and has the intelligence to provide calibration
gas sequencing of up to four Oxymitter 4000 units to accommodate automatic
and semi-automatic calibration routines.
This sequencer works in conjunction with the Oxymitter 4000 CALIBRATION
RECOMMENDED feature, eliminating out-of-calibration occurrences and the
need to send a technician to the installation site. In addition, the SPS 4001B
provides a remote contact input to initiate a calibration from a remote location
and relay outputs to alert when a calibration is in progress, an Oxymitter 4000
is out of calibration, calibration gases are on, and calibration gas pressure is
low.
For more information, call Emerson Process Management at 1-800-433-6076.
11-3
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
SPS 4001B SINGLE
PROBE
AUTOCALIBRATION
SEQUENCER
Figure 11-4. SPS 4001B
OXYMITTER 4000
26170007
SPS 4001B
Rosemount Analytical specifically designed the SPS 4001B Single Probe
Autocalibration Sequencer to provide the capability to perform automatic or
on-demand Oxymitter 4000 calibrations. The SPS 4001B is fully enclosed in a
NEMA cabinet suited for wall-mounting. This cabinet provides added
protection against dust and minor impacts.
The SPS 4001B works in conjunction with the Oxymitter 4000's
CALIBRATION RECOMMENDED feature, eliminating out-of-calibration
occurrences and the need to send a technician to the installation site. In
addition, the SPS 4001B provides a remote contact input to initiate a
calibration from a remote location and relay outputs to indicate when a
calibration is in progress or the Oxymitter 4000 is out of calibration.
For more information, call Emerson Process Management at 1-800-433-6076.
11-4
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
O2 CALIBRATION GAS
26170021
Figure 11-5. Calibration Gas
Bottles
Rosemount Analytical's O2 Calibration Gas and Service Kits have been
carefully designed to provide a more convenient and fully portable means of
testing, calibrating, and servicing.
Rosemount Analytical's oxygen analyzers. These lightweight, disposable gas
cylinders eliminate the need to rent gas bottles.
For more information, call Emerson Process Management at 1-800-433-6076.
11-5
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
CATALYST
REGENERATION
Figure 11-6. Catalyst
Regeneration
Oxymitter 4000
Probe in Retracted
Position
Isolation Valving
System
37260042
Integral Pressure
Balancing
Assembly
Measure O2 in regenerators at pressures up to 50 psi. In-situ design resists
plugging due to catalyst fines Class I, Div. I, Group B, C, and D.
Optional pressure balancing arrangement. Optional isolation valving system
permits installation and withdrawal while the process is running. Specified by
UOP.
See Application Data Sheet ADS 106-300F.A01, Isolation Valving System.
OXYBALANCE DISPLAY
AND AVERAGING
SYSTEM
Figure 11-7. OxyBalance
An
aly
tic
38370012
al
11-6
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Appendix A
Oxymitter 4000
Safety Data
Safety Instructions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page A-2
Safety Data Sheet for Ceramic Fiber Products . . . . . . . . page A-15
http://www.processanalytic.com
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
SAFETY INSTRUCTIONS
IMPORTANT
SAFETY INSTRUCTIONS FOR THE WIRING
AND INSTALLATION OF THIS APPARATUS
The following safety instructions apply specifically to all EU member
states. They should be strictly adhered to in order to assure compliance
with the Low Voltage Directive. Non-EU states should also comply with
the following unless superseded by local or National Standards.
1. Adequate earth connections should be made to all earthing points,
internal and external, where provided.
2. After installation or troubleshooting, all safety covers and safety grounds
must be replaced. The integrity of all earth terminals must be maintained
at all times.
3. Mains supply cords should comply with the requirements of IEC227 or
IEC245.
4. All wiring shall be suitable for use in an ambient temperature of greater
than 75°C.
5. All cable glands used should be of such internal dimensions as to
provide adequate cable anchorage.
6. To ensure safe operation of this equipment, connection to the mains
supply should only be made through a circuit breaker which will
disconnect all circuits carrying conductors during a fault situation. The
circuit breaker may also include a mechanically operated isolating
switch. If not, then another means of disconnecting the equipment from
the supply must be provided and clearly marked as such. Circuit
breakers or switches must comply with a recognized standard such as
IEC947. All wiring must conform with any local standards.
7. Where equipment or covers are marked with the symbol
to the right, hazardous voltages are likely to be present
beneath. These covers should only be removed when
power is removed from the equipment - and then only
by trained service personnel.
8. Where equipment or covers are marked with the symbol
to the right, there is a danger from hot surfaces beneath.
These covers should only be removed by trained
service personnel when power is removed from the
equipment. Certain surfaces may remain hot to the
touch.
9. Where equipment or covers are marked with the symbol
to the right, refer to the Operator Manual for instructions.
10. All graphical symbols used in this product are from one
or more of the following standards: EN61010-1, IEC417,
and ISO3864.
A-2
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
BELANGRIJK
Veiligheidsvoorschriften voor de aansluiting en installatie van dit
toestel.
De hierna volgende veiligheidsvoorschriften zijn vooral bedoeld voor de
EU lidstaten. Hier moet aan gehouden worden om de onderworpenheid
aan de Laag Spannings Richtlijn (Low Voltage Directive) te verzekeren.
Niet EU staten zouden deze richtlijnen moeten volgen tenzij zij reeds
achterhaald zouden zijn door plaatselijke of nationale voorschriften.
1. Degelijke aardingsaansluitingen moeten gemaakt worden naar alle
voorziene aardpunten, intern en extern.
2. Na installatie of controle moeten alle veiligheidsdeksels en -aardingen
terug geplaatst worden. Ten alle tijde moet de betrouwbaarheid van de
aarding behouden blijven.
3. Voedingskabels moeten onderworpen zijn aan de IEC227 of de IEC245
voorschriften.
4. Alle bekabeling moet geschikt zijn voor het gebruik in
omgevingstemperaturen, hoger dan 75°C.
5. Alle wartels moeten zo gedimensioneerd zijn dat een degelijke kabel
bevestiging verzekerd is.
6. Om de veilige werking van dit toestel te verzekeren, moet de voeding
door een stroomonderbreker gevoerd worden (min 10A) welke alle
draden van de voeding moet onderbreken. De stroomonderbreker mag
een mechanische schakelaar bevatten. Zoniet moet een andere
mogelijkheid bestaan om de voedingsspanning van het toestel te halen
en ook duidelijk zo zijn aangegeven. Stroomonderbrekers of
schakelaars moeten onderworpen zijn aan een erkende standaard
zoals IEC947.
7. Waar toestellen of deksels aangegeven staan met het
symbool is er meestal hoogspanning aanwezig. Deze
deksels mogen enkel verwijderd worden nadat de
voedingsspanning werd afgelegd en enkel door getraind
onderhoudspersoneel.
8. Waar toestellen of deksels aangegeven staan met het
symbool is er gevaar voor hete oppervlakken. Deze
deksels mogen enkel verwijderd worden door getraind
onderhoudspersoneel nadat de voedingsspanning
verwijderd werd. Sommige oppper-vlakken kunnen 45
minuten later nog steeds heet aanvoelen.
9. Waar toestellen of deksels aangegeven staan met het
symbool gelieve het handboek te raadplegen.
10. Alle grafische symbolen gebruikt in dit produkt, zijn
afkomstig uit een of meer van devolgende standaards:
EN61010-1, IEC417 en ISO3864.
A-3
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
VIGTIGT
Sikkerhedsinstruktion for tilslutning og installering af dette udstyr.
Følgende sikkerhedsinstruktioner gælder specifikt i alle
EU-medlemslande. Instruktionerne skal nøje følges for overholdelse af
Lavsspændingsdirektivet og bør også følges i ikke EU-lande medmindre
andet er specificeret af lokale eller nationale standarder.
1. Passende jordforbindelser skal tilsluttes alle jordklemmer, interne og
eksterne, hvor disse forefindes.
2. Efter installation eller fejlfinding skal alle sikkerhedsdæksler og
jordforbindelser reetableres.
3. Forsyningskabler skal opfylde krav specificeret i IEC227 eller IEC245.
4. Alle ledningstilslutninger skal være konstrueret til omgivelsestemperatur
højere end 75°C.
5. Alle benyttede kabelforskruninger skal have en intern dimension, så
passende kabelaflastning kan etableres.
6. For opnåelse af sikker drift og betjening skal der skabes beskyttelse
mod indirekte berøring gennem afbryder (min. 10A), som vil afbryde alle
kredsløb med elektriske ledere i fejlsitua-tion. Afbryderen skal indholde
en mekanisk betjent kontakt. Hvis ikke skal anden form for afbryder
mellem forsyning og udstyr benyttes og mærkes som sådan. Afbrydere
eller kontakter skal overholde en kendt standard som IEC947.
7. Hvor udstyr eller dæksler er mærket med dette symbol,
er farlige spændinger normalt forekom-mende bagved.
Disse dæksler bør kun afmonteres, når
forsyningsspændingen er frakoblet - og da kun af
instrueret servicepersonale.
8. Hvor udstyr eller dæksler er mærket med dette symbol,
forefindes meget varme overflader bagved. Disse
dæksler bør kun afmonteres af instrueret
servicepersonale, når forsyningsspænding er frakoblet.
Visse overflader vil stadig være for varme at berøre i op
til 45 minutter efter frakobling.
9. Hvor udstyr eller dæksler er mærket med dette symbol,
se da i betjeningsmanual for instruktion.
10. Alle benyttede grafiske symboler i dette udstyr findes i
én eller flere af følgende standarder:- EN61010-1,
IEC417 & ISO3864.
A-4
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
BELANGRIJK
Veiligheidsinstructies voor de bedrading en installatie van dit apparaat.
Voor alle EU lidstaten zijn de volgende veiligheidsinstructies van
toepassing. Om aan de geldende richtlijnen voor laagspanning te
voldoen dient men zich hieraan strikt te houden. Ook niet EU lidstaten
dienen zich aan het volgende te houden, tenzij de lokale wetgeving
anders voorschrijft.
1. Alle voorziene interne- en externe aardaansluitingen dienen op
adequate wijze aangesloten te worden.
2. Na installatie, onderhouds- of reparatie werkzaamheden dienen alle
beschermdeksels /kappen en aardingen om reden van veiligheid weer
aangebracht te worden.
3. Voedingskabels dienen te voldoen aan de vereisten van de normen IEC
227 of IEC 245.
4. Alle bedrading dient geschikt te zijn voor gebruik bij een omgevings
temperatuur boven 75°C.
5. Alle gebruikte kabelwartels dienen dusdanige inwendige afmetingen te
hebben dat een adequate verankering van de kabel wordt verkregen.
6. Om een veilige werking van de apparatuur te waarborgen dient de
voeding uitsluitend plaats te vinden via een meerpolige automatische
zekering (min.10A) die alle spanningvoerende geleiders verbreekt
indien een foutconditie optreedt. Deze automatische zekering mag ook
voorzien zijn van een mechanisch bediende schakelaar. Bij het
ontbreken van deze voorziening dient een andere als zodanig duidelijk
aangegeven mogelijkheid aanwezig te zijn om de spanning van de
apparatuur af te schakelen. Zekeringen en schakelaars dienen te
voldoen aan een erkende standaard zoals IEC 947.
7. Waar de apparatuur of de beschermdeksels/kappen
gemarkeerd zijn met het volgende symbool, kunnen
zich hieronder spanning voerende delen bevinden die
gevaar op kunnen leveren. Deze beschermdeksels/
kappen mogen uitsluitend verwijderd worden door
getraind personeel als de spanning is afgeschakeld.
8. Waar de apparatuur of de beschermdeksels/kappen
gemarkeerd zijn met het volgende symbool, kunnen
zich hieronder hete oppervlakken of onderdelen
bevinden. Bepaalde delen kunnen mogelijk na 45 min.
nog te heet zijn om aan te raken.
9. Waar de apparatuur of de beschermdeksels/kappen
gemarkeerd zijn met het volgende symbool, dient men
de bedieningshandleiding te raadplegen.
10. Alle grafische symbolen gebruikt bij dit produkt zijn
volgens een of meer van de volgende standaarden: EN
61010-1, IEC 417 & ISO 3864.
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TÄRKEÄÄ
Turvallisuusohje, jota on noudatettava tämän laitteen asentamisessa ja
kaapeloinnissa.
Seuraavat ohjeet pätevät erityisesti EU:n jäsenvaltioissa. Niitä täytyy
ehdottomasti noudattaa jotta täytettäisiin EU:n matalajännitedirektiivin
(Low Voltage Directive) yhteensopivuus. Myös EU:hun kuulumattomien
valtioiden tulee nou-dattaa tätä ohjetta, elleivät kansalliset standardit
estä sitä.
1. Riittävät maadoituskytkennät on tehtävä kaikkiin maadoituspisteisiin,
sisäisiin ja ulkoisiin.
2. Asennuksen ja vianetsinnän jälkeen on kaikki suojat ja suojamaat
asennettava takaisin pai-koilleen. Maadoitusliittimen kunnollinen
toiminta täytyy aina ylläpitää.
3. Jännitesyöttöjohtimien täytyy täyttää IEC227 ja IEC245 vaatimukset.
4. Kaikkien johdotuksien tulee toimia >75°C lämpötiloissa.
5. Kaikkien läpivientiholkkien sisähalkaisijan täytyy olla sellainen että
kaapeli lukkiutuu kun-nolla kiinni.
6. Turvallisen toiminnan varmistamiseksi täytyy jännitesyöttö varustaa
turvakytkimellä (min 10A), joka kytkee irti kaikki jännitesyöttöjohtimet
vikatilanteessa. Suojaan täytyy myös sisältyä mekaaninen erotuskytkin.
Jos ei, niin jännitesyöttö on pystyttävä katkaisemaan muilla keinoilla ja
merkittävä siten että se tunnistetaan sellaiseksi. Turvakytkimien tai
kat-kaisimien täytyy täyttää IEC947 standardin vaatimukset
näkyvyydestä.
7. Mikäli laite tai kosketussuoja on merkitty tällä merkillä
on merkinnän takana tai alla hengenvaarallisen
suuruinen jännite. Suojaa ei saa poistaa jänniteen
ollessa kytkettynä laitteeseen ja poistamisen saa
suorittaa vain alan asian-tuntija.
8. Mikäli laite tai kosketussuoja on merkitty tällä merkillä
on merkinnän takana tai alla kuuma pinta. Suojan saa
poistaa vain alan asiantuntija kun jännite-syöttö on
katkaistu. Tällainen pinta voi säilyä kosketuskuumana
jopa 45 mi-nuuttia.
9. Mikäli laite tai kosketussuoja on merkitty tällä merkillä
katso lisäohjeita käyt-töohjekirjasta.
10. Kaikki tässä tuotteessa käytetyt graafiset symbolit ovat
yhdestä tai useammasta seuraavis-ta standardeista:
EN61010-1, IEC417 & ISO3864.
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IMPORTANT
Consignes de sécurité concernant le raccordement et l'installation de
cet appareil.
Les consignes de sécurité ci-dessous s'adressent particulièrement à
tous les états membres de la communauté européenne. Elles doivent
être strictement appliquées afin de satisfaire aux directives concernant
la basse tension. Les états non membres de la communauté
européenne doivent également appliquer ces consignes sauf si elles
sont en contradiction avec les standards locaux ou nationaux.
1. Un raccordement adéquat à la terre doit être effectuée à chaque borne
de mise à la terre, interne et externe.
2. Après installation ou dépannage, tous les capots de protection et toutes
les prises de terre doivent être remis en place, toutes les prises de terre
doivent être respectées en permanence.
3. Les câbles d'alimentation électrique doivent être conformes aux normes
IEC227 ou IEC245.
4. Tous les raccordements doivent pouvoir supporter une température
ambiante supérieure à 75°C.
5. Tous les presse-étoupes utilisés doivent avoir un diamètre interne en
rapport avec les câbles afin d'assurer un serrage correct sur ces
derniers.
6. Afin de garantir la sécurité du fonctionnement de cet appareil, le
raccordement à l'alimentation électrique doit être réalisé exclusivement
au travers d'un disjoncteur (minimum 10A.) isolant tous les conducteurs
en cas d'anomalie. Ce disjoncteur doit également pouvoir être actionné
manuellement, de façon mécanique. Dans le cas contraire, un autre
système doit être mis en place afin de pouvoir isoler l'appareil et doit
être signalisé comme tel. Disjoncteurs et interrupteurs doivent être
conformes à une norme reconnue telle IEC947.
7. Lorsque les équipements ou les capots affichent le
symbole suivant, cela signifie que des tensions
dangereuses sont présentes. Ces capots ne doivent
être démontés que lorsque l'alimentation est coupée, et
uniquement par un personnel compétent.
8. Lorsque les équipements ou les capots affichent le
symbole suivant, cela signifie que des surfaces
dangereusement chaudes sont présentes. Ces capots
ne doivent être démontés que lorsque l'alimentation est
coupée, et uniquement par un personnel compétent.
Certaines surfaces peuvent rester chaudes jusqu'à 45
mn.
9. Lorsque les équipements ou les capots affichent le
symbole suivant, se reporter au manuel d'instructions.
10. Tous les symboles graphiques utilisés dans ce produit
sont conformes à un ou plusieurs des standards
suivants: EN61010-1, IEC417 & ISO3864.
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WICHTIG
Sicherheitshinweise für den Anschluß und die Installation dieser Geräte.
Die folgenden Sicherheitshinweise sind in allen Mitgliederstaaten der
europäischen Gemeinschaft gültig. Sie müssen strickt eingehalten
werden, um der Niederspannungsrichtlinie zu genügen.
Nichtmitgliedsstaaten der europäischen Gemeinschaft sollten die
national gültigen Normen und Richtlinien einhalten.
1. Alle intern und extern vorgesehenen Erdungen der Geräte müssen
ausgeführt werden.
2. Nach Installation, Reparatur oder sonstigen Eingriffen in das Gerät
müssen alle Sicherheitsabdeckungen und Erdungen wieder installiert
werden. Die Funktion aller Erdverbindungen darf zu keinem Zeitpunkt
gestört sein.
3. Die Netzspannungsversorgung muß den Anforderungen der IEC227
oder IEC245 genügen.
4. Alle Verdrahtungen sollten mindestens bis 75°C ihre Funktion dauerhaft
erfüllen.
5. Alle Kabeldurchführungen und Kabelverschraubungen sollten in Ihrer
Dimensionierung so gewählt werden, daß diese eine sichere
Verkabelung des Gerätes ermöglichen.
6. Um eine sichere Funktion des Gerätes zu gewährleisten, muß die
Spannungsversorgung über mindestens 10 A abgesichert sein. Im
Fehlerfall muß dadurch gewährleistet sein, daß die
Spannungsversorgung zum Gerät bzw. zu den Geräten unterbrochen
wird. Ein mechanischer Schutzschalter kann in dieses System integriert
werden. Falls eine derartige Vorrichtung nicht vorhanden ist, muß eine
andere Möglichkeit zur Unterbrechung der Spannungszufuhr
gewährleistet werden mit Hinweisen deutlich gekennzeichnet werden.
Ein solcher Mechanismus zur Spannungsunterbrechung muß mit den
Normen und Richtlinien für die allgemeine Installation von
Elektrogeräten, wie zum Beispiel der IEC947, übereinstimmen.
7. Mit dem Symbol sind Geräte oder Abdeckungen gekennzeichnet, die
eine gefährliche (Netzspannung) Spannung führen. Die Abdeckungen
dürfen nur entfernt werden, wenn die Versorgungsspannung
unterbrochen wurde. Nur geschultes Personal darf an diesen Geräten
Arbeiten ausführen.
8. Mit dem Symbol sind Geräte oder Abdeckungen gekennzeichnet, in
bzw. unter denen heiße Teile vorhanden sind. Die Abdeckungen dürfen
nur entfernt werden, wenn die Versorgungsspannung unterbrochen
wurde. Nur geschultes Personal darf an diesen Geräten Arbeiten
ausführen. Bis 45 Minuten nach dem Unterbrechen der Netzzufuhr
können derartig Teile noch über eine erhöhte Temperatur verfügen.
9. Mit dem Symbol sind Geräte oder Abdeckungen gekennzeichnet, bei
denen vor dem Eingriff die entsprechenden Kapitel im Handbuch
sorgfältig durchgelesen werden müssen.
10. Alle in diesem Gerät verwendeten graphischen Symbole entspringen
einem oder mehreren der nachfolgend aufgeführten Standards:
EN61010-1, IEC417 & ISO3864.
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February 2006
Oxymitter 4000
IMPORTANTE
Norme di sicurezza per il cablaggio e l'installazione dello strumento.
Le seguenti norme di sicurezza si applicano specificatamente agli stati
membri dell'Unione Europea, la cui stretta osservanza è richiesta per
garantire conformità alla Direttiva del Basso Voltaggio. Esse si
applicano anche agli stati non appartenenti all'Unione Europea, salvo
quanto disposto dalle vigenti normative locali o nazionali.
1. Collegamenti di terra idonei devono essere eseguiti per tutti i punti di
messa a terra interni ed esterni, dove previsti.
2. Dopo l'installazione o la localizzazione dei guasti, assicurarsi che tutti i
coperchi di protezione siano stati collocati e le messa a terra siano
collegate. L'integrità di ciscun morsetto di terra deve essere
costantemente garantita.
3. I cavi di alimentazione della rete devono essere secondo disposizioni
IEC227 o IEC245.
4. L'intero impianto elettrico deve essere adatto per uso in ambiente con
temperature superiore a 75°C.
5. Le dimensioni di tutti i connettori dei cavi utilizzati devono essere tali da
consentire un adeguato ancoraggio al cavo.
6. Per garantire un sicuro funzionamento dello strumento il collegamento
alla rete di alimentazione principale dovrà essere eseguita tramite
interruttore automatico (min.10A), in grado di disattivare tutti i conduttori
di circuito in caso di guasto. Tale interruttore dovrà inoltre prevedere un
sezionatore manuale o altro dispositivo di interruzione
dell'alimentazione, chiaramente identificabile. Gli interruttori dovranno
essere conformi agli standard riconosciuti, quali IEC947.
7. Il simbolo riportato sullo strumento o sui coperchi di
protezione indica probabile presenza di elevati voltaggi.
Tali coperchi di protezione devono essere rimossi
esclusivamente da personale qualificato, dopo aver
tolto alimentazione allo strumento.
8. Il simbolo riportato sullo strumento o sui coperchi di
protezione indica rischio di contatto con superfici ad alta
temperatura. Tali coperchi di protezione devono essere
rimossi esclusivamente da personale qualificato, dopo
aver tolto alimentazione allo strumento. Alcune superfici
possono mantenere temperature elevate per oltre 45
minuti.
9. Se lo strumento o il coperchio di protezione riportano il
simbolo, fare riferimento alle istruzioni del manuale
Operatore.
10. Tutti i simboli grafici utilizzati in questo prodotto sono
previsti da uno o più dei seguenti standard: EN61010-1,
IEC417 e ISO3864.
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Oxymitter 4000
VIKTIG
Sikkerhetsinstruks for tilkobling og installasjon av dette utstyret.
Følgende sikkerhetsinstruksjoner gjelder spesifikt alle EU medlemsland
og land med i EØS-avtalen. Instruksjonene skal følges nøye slik at
installasjonen blir i henhold til lavspenningsdirektivet. Den bør også
følges i andre land, med mindre annet er spesifisert av lokale- eller
nasjonale standarder.
1. Passende jordforbindelser må tilkobles alle jordingspunkter, interne og
eksterne hvor disse forefinnes.
2. Etter installasjon eller feilsøking skal alle sikkerhetsdeksler og
jordforbindelser reetableres. Jordingsforbindelsene må alltid holdes i
god stand.
3. Kabler fra spenningsforsyning skal oppfylle kravene spesifisert i
IEC227 eller IEC245.
4. Alle ledningsforbindelser skal være konstruert for en
omgivelsestemperatur høyere en 750°C.
5. Alle kabelforskruvninger som benyttes skal ha en indre dimensjon slik
at tilstrekkelig avlastning oppnåes.
6. For å oppnå sikker drift og betjening skal forbindelsen til
spenningsforsyningen bare skje gjennom en strømbryter (minimum
10A) som vil bryte spenningsforsyningen til alle elektriske kretser ved en
feilsituasjon. Strømbryteren kan også inneholde en mekanisk operert
bryter for å isolere instrumentet fra spenningsforsyningen. Dersom det
ikke er en mekanisk operert bryter installert, må det være en annen
måte å isolere utstyret fra spenningsforsyningen, og denne måten må
være tydelig merket. Kretsbrytere eller kontakter skal oppfylle kravene i
en annerkjent standard av typen IEC947 eller tilsvarende.
7. Der hvor utstyr eller deksler er merket med symbol for
farlig spenning, er det sannsynlig at disse er tilstede bak
dekslet. Disse dekslene må bare fjærnes når
spenningsforsyning er frakoblet utstyret, og da bare av
trenet servicepersonell.
8. Der hvor utstyr eller deksler er merket med symbol for
meget varm overflate, er det sannsynlig at disse er
tilstede bak dekslet. Disse dekslene må bare fjærnes
når spenningsforsyning er frakoblet utstyret, og da bare
av trenet servicepersonell. Noen overflater kan være for
varme til å berøres i opp til 45 minutter etter
spenningsforsyning frakoblet.
9. Der hvor utstyret eller deksler er merket med symbol,
vennligst referer til instruksjonsmanualen for instrukser.
10. Alle grafiske symboler brukt i dette produktet er fra en
eller flere av følgende standarder: EN61010-1, IEC417
& ISO3864.
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Oxymitter 4000
IMPORTANTE
Instruções de segurança para ligação e instalação deste aparelho.
As seguintes instruções de segurança aplicam-se especificamente a
todos os estados membros da UE. Devem ser observadas rigidamente
por forma a garantir o cumprimento da Directiva sobre Baixa Tensão.
Relativamente aos estados que não pertençam à UE, deverão cumprir
igualmente a referida directiva, exceptuando os casos em que a
legislação local a tiver substituído.
1. Devem ser feitas ligações de terra apropriadas a todos os pontos de
terra, internos ou externos.
2. Após a instalação ou eventual reparação, devem ser recolocadas todas
as tampas de segurança e terras de protecção. Deve manter-se
sempre a integridade de todos os terminais de terra.
3. Os cabos de alimentação eléctrica devem obedecer às exigências das
normas IEC227 ou IEC245.
4. Os cabos e fios utilizados nas ligações eléctricas devem ser adequados
para utilização a uma temperatura ambiente até 75ºC.
5. As dimensões internas dos bucins dos cabos devem ser adequadas a
uma boa fixação dos cabos.
6. Para assegurar um funcionamento seguro deste equipamento, a
ligação ao cabo de alimentação eléctrica deve ser feita através de um
disjuntor (min. 10A) que desligará todos os condutores de circuitos
durante uma avaria. O disjuntor poderá também conter um interruptor
de isolamento accionado manualmente. Caso contrário, deverá ser
instalado qualquer outro meio para desligar o equipamento da energia
eléctrica, devendo ser assinalado convenientemente. Os disjuntores ou
interruptores devem obedecer a uma norma reconhecida, tipo IEC947.
7. Sempre que o equipamento ou as tampas contiverem o
símbolo, é provável a existência de tensões perigosas.
Estas tampas só devem ser retiradas quando a energia
eléctrica tiver sido desligada e por Pessoal da
Assistência devidamente treinado.
8. Sempre que o equipamento ou as tampas contiverem o
símbolo, há perigo de existência de superfícies
quentes. Estas tampas só devem ser retiradas por
Pessoal da Assistência devidamente treinado e depois
de a energia eléctrica ter sido desligada. Algumas
superfícies permanecem quentes até 45 minutos
depois.
9. Sempre que o equipamento ou as tampas contiverem o
símbolo, o Manual de Funcionamento deve ser
consultado para obtenção das necessárias instruções.
10. Todos os símbolos gráficos utilizados neste produto
baseiam-se em uma ou mais das seguintes normas:
EN61010-1, IEC417 e ISO3864.
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IMPORTANTE
Instrucciones de seguridad para el montaje y cableado de este aparato.
Las siguientes instrucciones de seguridad, son de aplicacion especifica
a todos los miembros de la UE y se adjuntaran para cumplir la normativa
europea de baja tension.
1. Se deben preveer conexiones a tierra del equipo, tanto externa como
internamente, en aquellos terminales previstos al efecto.
2. Una vez finalizada las operaciones de mantenimiento del equipo, se
deben volver a colocar las cubiertas de seguridad aasi como los
terminales de tierra. Se debe comprobar la integridad de cada terminal.
3. Los cables de alimentacion electrica cumpliran con las normas IEC 227
o IEC 245.
4. Todo el cableado sera adecuado para una temperatura ambiental de
75ºC.
5. Todos los prensaestopas seran adecuados para una fijacion adecuada
de los cables.
6. Para un manejo seguro del equipo, la alimentacion electrica se realizara
a traves de un interruptor magnetotermico ( min 10 A ), el cual
desconectara la alimentacion electrica al equipo en todas sus fases
durante un fallo. Los interruptores estaran de acuerdo a la norma IEC
947 u otra de reconocido prestigio.
7. Cuando las tapas o el equipo lleve impreso el simbolo
de tension electrica peligrosa, dicho alojamiento
solamente se abrira una vez que se haya interrumpido
la alimentacion electrica al equipo asimismo la
intervencion sera llevada a cabo por personal
entrenado para estas labores.
8. Cuando las tapas o el equipo lleve impreso el simbolo,
hay superficies con alta temperatura, por tanto se abrira
una vez que se haya interrumpido la alimentacion
electrica al equipo por personal entrenado para estas
labores, y al menos se esperara unos 45 minutos para
enfriar las superficies calientes.
9. Cuando el equipo o la tapa lleve impreso el simbolo, se
consultara el manual de instrucciones.
10. Todos los simbolos graficos usados en esta hoja, estan
de acuerdo a las siguientes normas EN61010-1,
IEC417 & ISO 3864.
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VIKTIGT
Säkerhetsföreskrifter för kablage och installation av denna apparat.
Följande säkerhetsföreskrifter är tillämpliga för samtliga
EU-medlemsländer. De skall följas i varje avseende för att
överensstämma med Lågspännings direktivet. Icke EU medlemsländer
skall också följa nedanstående punkter, såvida de inte övergrips av
lokala eller nationella föreskrifter.
1. Tillämplig jordkontakt skall utföras till alla jordade punkter, såväl internt
som externt där så erfordras.
2. Efter installation eller felsökning skall samtliga säkerhetshöljen och
säkerhetsjord återplaceras. Samtliga jordterminaler måste hållas
obrutna hela tiden.
3. Matningsspänningens kabel måste överensstämma med föreskrifterna i
IEC227 eller IEC245.
4. Allt kablage skall vara lämpligt för användning i en
omgivningstemperatur högre än 75ºC.
5. Alla kabelförskruvningar som används skall ha inre dimensioner som
motsvarar adekvat kabelförankring.
6. För att säkerställa säker drift av denna utrustning skall anslutning till
huvudströmmen endast göras genom en säkring (min 10A) som skall
frånkoppla alla strömförande kretsar när något fel uppstår. Säkringen
kan även ha en mekanisk frånskiljare. Om så inte är fallet, måste ett
annat förfarande för att frånskilja utrustningen från strömförsörjning
tillhandahållas och klart framgå genom markering. Säkring eller
omkopplare måste överensstämma med en gällande standard såsom t
ex IEC947.
7. Där utrustning eller hölje är markerad med vidstående
symbol föreliggerisk för livsfarlig spänning i närheten.
Dessa höljen får endast avlägsnas när strömmen ej är
ansluten till utrustningen - och då endast av utbildad
servicepersonal.
8. När utrustning eller hölje är markerad med vidstående
symbol föreligger risk för brännskada vid kontakt med
uppvärmd yta. Dessa höljen får endast avlägsnas av
utbildad servicepersonal, när strömmen kopplats från
utrustningen. Vissa ytor kan vara mycket varma att
vidröra även upp till 45 minuter efter avstängning av
strömmen.
9. När utrustning eller hölje markerats med vidstående
symbol bör instruktionsmanualen studeras för
information.
10. Samtliga grafiska symboler som förekommer i denna
produkt finns angivna i en eller flera av följande
föreskrifter:- EN61010-1, IEC417 & ISO3864.
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February 2006
SAFETY DATA SHEET
FOR CERAMIC FIBER
PRODUCTS
Oxymitter 4000
JULY 1, 1996
SECTION I. IDENTIFICATION
PRODUCT NAME
Ceramic Fiber Heaters, Molded Insulation Modules and Ceramic Fiber
Radiant Heater Panels.
CHEMICAL FAMILY
Vitreous Aluminosilicate Fibers with Silicon Dioxide.
CHEMICAL NAME
N.A.
CHEMICAL FORMULA
N.A.
MANUFACTURER'S NAME AND ADDRESS
Watlow Columbia
2101 Pennsylvania Drive
Columbia, MO 65202
573-814-1300, ext. 5170
573-474-9402
HEALTH HAZARD SUMMARY WARNING
•
Possible cancer hazard based on tests with laboratory animals.
•
May be irritating to skin, eyes and respiratory tract.
•
May be harmful if inhaled.
•
Cristobalite (crystalline silica) formed at high temperatures (above
1800ºF) can cause severe respiratory disease.
SECTION II. PHYSICAL DATA
APPEARANCE AND ODOR
Cream to white colored fiber shapes. With or without optional white to
gray granular surface coating and/or optional black surface coating.
SPECIFIC WEIGHT: 12-25 LB./CUBIC FOOT
BOILING POINT: N.A.
VOLATILES (% BY WT.): N.A.
WATER SOLUBILITY: N.A.
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Oxymitter 4000
SECTION III. HAZARDOUS INGREDIENTS
MATERIAL, QUANTITY, AND THRESHOLD/EXPOSURE LIMIT VALUES
Aluminosilicate (vitreous) 99+ % 1 fiber/cc TWA
CAS. No. 142844-00-0610 fibers/cc CL
Zirconium Silicate0-10% 5 mg/cubic meter (TLV)
Black Surface Coating**0 - 1% 5 mg/cubic meter (TLV)
Armorphous Silica/Silicon Dioxide0-10% 20 mppcf (6 mg/cubic meter)
PEL (OSHA 1978) 3 gm cubic meter
(Respirable dust): 10 mg/cubic meter,
Intended TLV (ACGIH 1984-85)
**Composition is a trade secret.
SECTION IV. FIRE AND EXPLOSION DATA
FLASH POINT: None
FLAMMABILITY LIMITS: N.A.
EXTINGUISHING MEDIA
Use extinguishing agent suitable for type of surrounding fire.
UNUSUAL FIRE AND EXPLOSION HAZARDS / SPECIAL FIRE
FIGHTING PROCEDURES
N.A.
SECTION V. HEALTH HAZARD DATA
THRESHOLD LIMIT VALUE
(See Section III)
EFFECTS OF OVER EXPOSURE
A-16
•
EYE - Avoid contact with eyes. Slightly to moderately irritating.
Abrasive action may cause damage to outer surface of eye.
•
INHALATION - May cause respiratory tract irritation. Repeated or
prolonged breathing of particles of respirable size may cause
inflammation of the lung leading to chest pain, difficult breathing,
coughing and possible fibrotic change in the lung (Pneumoconiosis).
Pre-existing medical conditions may be aggravated by exposure:
specifically, bronchial hyper-reactivity and chronic bronchial or lung
disease.
•
INGESTION - May cause gastrointestinal disturbances. Symptoms
may include irritation and nausea, vomiting and diarrhea.
•
SKIN - Slightly to moderate irritating. May cause irritation and
inflammation due to mechanical reaction to sharp, broken ends of
fibers.
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
EXPOSURE TO USED CERAMIC FIBER PRODUCT
Product which has been in service at elevated temperatures (greater
than 1800ºF/982ºC) may undergo partial conversion to cristobalite, a
form of crystalline silica which can cause severe respiratory disease
(Pneumoconiosis). The amount of cristobalite present will depend on
the temperature and length of time in service. (See Section IX for
permissible exposure levels).
SPECIAL TOXIC EFFECTS
The existing toxicology and epidemiology data bases for RCF's are still
preliminary. Information will be updated as studies are completed and
reviewed. The following is a review of the results to date:
EPIDEMIOLOGY
At this time there are no known published reports demonstrating
negative health outcomes of workers exposed to refractory ceramic
fiber (RCF). Epidemiologic investigations of RCF production workers
are ongoing.
1. There is no evidence of any fibrotic lung disease (interstitial fibrosis)
whatsoever on x-ray.
2. There is no evidence of any lung disease among those employees
exposed to RCF that had never smoked.
3. A statistical "trend" was observed in the exposed population between
the duration of exposure to RCF and a decrease in some measures
of pulmonary function. These observations are clinically insignificant.
In other words, if these observations were made on an individual
employee, the results would be interpreted as being within the
normal range.
4. Pleural plaques (thickening along the chest wall) have been
observed in a small number of employees who had a long duration of
employment. There are several occupational and non-occupational
causes for pleural plaque. It should be noted that plaques are not
"pre-cancer" nor are they associated with any measurable effect on
lung function.
TOXICOLOGY
A number of studies on the health effects of inhalation exposure of rats
and hamsters are available. Rats were exposed to RCF in a series of
life-time nose-only inhalation studies. The animals were exposed to 30,
16, 9, and 3 mg/m3, which corresponds with approximately 200, 150,
75, and 25 fibers/cc.
Animals exposed to 30 and 16 mg/m3 were observed to have
developed a pleural and parenchymal fibroses; animals exposed to 9
mg/m3 had developed a mild parenchymal fibrosis; animals exposed to
the lowest dose were found to have the response typically observed any
time a material is inhaled into the deep lung. While a statistically
significant increase in lung tumors was observed following exposure to
the highest dose, there was no excess lung cancers at the other doses.
Two rats exposed to 30 mg/m3 and one rat exposed to 9 mg/m3
developed masotheliomas.
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Oxymitter 4000
The International Agency for Research on Cancer (IARC) reviewed the
carcinogenicity data on man-made vitreous fibers (including ceramic
fiber, glasswool, rockwool, and slagwool) in 1987. IARC classified
ceramic fiber, fibrous glasswool and mineral wool (rockwool and
slagwool) as possible human carcinogens (Group 2B).
EMERGENCY FIRST AID PROCEDURES
•
EYE CONTACT - Flush eyes immediately with large amounts of
water for approximately 15 minutes. Eye lids should be held away
from the eyeball to insure thorough rinsing. Do not rub eyes. Get
medical attention if irritation persists.
•
INHALATION - Remove person from source of exposure and move
to fresh air. Some people may be sensitive to fiber induced irritation
of the respiratory tract. If symptoms such as shortness of breath,
coughing, wheezing or chest pain develop, seek medical attention. If
person experiences continued breathing difficulties, administer
oxygen until medical assistance can be rendered.
•
INGESTION - Do not induce vomiting. Get medical attention if
irritation persists.
•
SKIN CONTACT - Do not rub or scratch exposed skin. Wash area of
contact thoroughly with soap and water. Using a skin cream or lotion
after washing may be helpful. Get medical attention if irritation
persists.
SECTION VI. REACTIVITY DATA
STABILITY/CONDITIONS TO AVOID
Stable under normal conditions of use.
HAZARDOUS POLYMERIZATION/CONDITIONS TO AVOID
N.A.
INCOMPATIBILITY/MATERIALS TO AVOID
Incompatible with hydrofluoric acid and concentrated alkali.
HAZARDOUS DECOMPOSITION PRODUCTS
N.A.
SECTION VII. SPILL OR LEAK PROCEDURES
STEPS TO BE TAKEN IF MATERIAL IS RELEASED OR SPILLED
Where possible, use vacuum suction with HEPA filters to clean up
spilled material. Use dust suppressant where sweeping if necessary.
Avoid clean up procedure which may result in water pollution. (Observe
Special Protection Information Section VIII.)
WASTE DISPOSAL METHODS
The transportation, treatment, and disposal of this waste material must
be conducted in compliance with all applicable Federal, State, and Local
regulations.
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Oxymitter 4000
SECTION VIII. SPECIAL PROTECTION INFORMATION
RESPIRATORY PROTECTION
Use NIOSH or MSHA approved equipment when airborne exposure
limits may be exceeded. NIOSH/MSHA approved breathing equipment
may be required for non-routine and emergency use. (See Section IX
for suitable equipment).
Pending the results of long term health effects studies, engineering
control of airborne fibers to the lowest levels attainable is advised.
VENTILATION
Ventilation should be used whenever possible to control or reduce
airborne concentrations of fiber and dust. Carbon monoxide, carbon
dioxide, oxides of nitrogen, reactive hydrocarbons and a small amount
of formaldehyde may accompany binder burn off during first heat. Use
adequate ventilation or other precautions to eliminate vapors resulting
from binder burn off. Exposure to burn off fumes may cause respiratory
tract irritation, bronchial hyper-reactivity and asthmatic response.
SKIN PROTECTION
Wear gloves, hats and full body clothing to prevent skin contact. Use
separate lockers for work clothes to prevent fiber transfer to street
clothes. Wash work clothes separately from other clothing and rinse
washing machine thoroughly after use.
EYE PROTECTION
Wear safety glasses or chemical worker's goggles to prevent eye
contact. Do not wear contact lenses when working with this substance.
Have eye baths readily available where eye contact can occur.
SECTION IX. SPECIAL PRECAUTIONS
PRECAUTIONS TO BE TAKEN IN HANDLING AND STORING
General cleanliness should be followed.
The Toxicology data indicate that ceramic fiber should be handled with
caution. The handling practices described in this MSDS must be strictly
followed. In particular, when handling refractory ceramic fiber in any
application, special caution should be taken to avoid unnecessary
cutting and tearing of the material to minimize generation of airborne
dust.
It is recommended that full body clothing be worn to reduce the potential
for skin irritation. Washable or disposable clothing may be used. Do not
take unwashed work clothing home. Work clothes should be washed
separately from other clothing. Rinse washing machine thoroughly after
use. If clothing is to be laundered by someone else, inform launderer of
proper procedure. Work clothes and street clothes should be kept
separate to prevent contamination.
Product which has been in service at elevated temperatures (greater
than 1800°F/982°C) may undergo partial conversion to cristobalite, a
form of crystalline silica. This reaction occurs at the furnace lining hot
face. As a consequence, this material becomes more friable; special
caution must be taken to minimize generation of air-borne dust. The
amount of cristobalite present will depend on the temperature and
length in service.
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February 2006
Oxymitter 4000
IARC has recently reviewed the animal, human, and other relevant
experimental data on silica in order to critically evaluate and classify the
cancer causing potential. Based on its review, IARC classified
crystalline silica as a group 2A carcinogen (probable human
carcinogen).
The OSHA permissible exposure limit (PEL for cristobalite is 0.05
mg/m3 (respirable dust). The ACGIH threshold limit value (TLV) for
cristobalite is 0.05 mg/m3 (respirable dust) (ACGIH 1991-92). Use
NIOSH or MSHA approved equipment when airborne exposure limits
may be exceeded. The minimum respiratory protection recommended
for given airborne fiber or cristobalite concentrations are:
CONCENTRATION
Concentration
Personal Protective Equipment
0-1 fiber/cc or 0-0.05 mg/m3
cristobalite (the OSHA PEL)
Up to 5 fibers/cc or up to 10 times
the OSHA PEL for cristobalite
Optional disposable dust respirator (e.g. 3M
9970 or equivalent).
Half face, air purifying respirator equipped
with high efficiency particulate air
(HEPA)filter cartridges (e.g. 3M 6000 series
with 2040 filter or equivalent).
Full face, air purifying respirator with high
efficiency particulate air (HEPA) filter
cartridges (e.g. 3M 7800S with 7255 filters
or equivalent) or powered air purifying
respirator (PARR) equipped with HEPA filter
cartridges (e.g. 3M W3265S with W3267
filters or equivalent).
Full face, positive pressure supplied air
respirator (e.g. 3M 7800S with W9435 hose
& W3196 low pressure regulator kit
connected to clean air supply or equivalent).
Up to 25 fibers/cc or 50 times the
OSHA PEL for cristobalite (2.5
mg/m3)
Greater than 25 fibers/cc or 50
times the OSHA PEL for
cristobalite (2.5 mg/m3)
If airborne fiber or cristobalite concentrations are not known, as
minimum protection, use NIOSH/MSHA approved half face, air purifying
respirator with HEPA filter cartridges.
Insulation surface should be lightly sprayed with water before removal to
suppress airborne dust. As water evaporates during removal, additional
water should be sprayed on surfaces as needed. Only enough water
should be sprayed to suppress dust so that water does not run onto the
floor of the work area. To aid the wetting process, a surfactant can be
used.
After RCF removal is completed, dust suppressing cleaning methods,
such as wet sweeping or vacuuming, should be used to clean the work
area. If dry vacuuming is used, the vacuum must be equipped with
HEPA filter. Air blowing or dry sweeping should not be used. Dust
suppressing components can be used to clean up light dust.
Product packaging may contain product residue. Do not reuse except to
reship or return Ceramic Fiber products to the factory.
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Instruction Manual
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February 2006
Oxymitter 4000
GENERAL PRECAUTIONS FOR HANDLING AND STORING HIGH
PRESSURE GAS CYLINDERS
Edited from selected paragraphs of the Compressed
Gas Association's "Handbook of Compressed Gases"
published in 1981
Compressed Gas Association
1235 Jefferson Davis Highway
Arlington, Virginia 22202
Used by Permission
1. Never drop cylinders or permit them to strike each other violently.
2. Cylinders may be stored in the open, but in such cases, should be
protected against extremes of weather and, to prevent rusting, from
the dampness of the ground. Cylinders should be stored in the
shade when located in areas where extreme temperatures are
prevalent.
3. The valve protection cap should be left on each cylinder until it has
been secured against a wall or bench, or placed in a cylinder stand,
and is ready to be used.
4. Avoid dragging, rolling, or sliding cylinders, even for short distance;
they should be moved by using a suitable handtruck.
5. Never tamper with safety devices in valves or cylinders.
6. Do not store full and empty cylinders together. Serious suckback can
occur when an empty cylinder is attached to a pressurized system.
7. No part of cylinder should be subjected to a temperature higher than
52°C (125°F). A flame should never be permitted to come in contact
with any part of a compressed gas cylinder.
8. Do not place cylinders where they may become part of an electric
circuit. When electric arc welding, precautions must be taken to
prevent striking an arc against the cylinder.
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February 2006
Instruction Manual
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February 2006
Oxymitter 4000
Appendix B
Return of Material
RETURNING MATERIAL
If factory repair of defective equipment is required, proceed as follows:
1. Secure a return authorization number from a Rosemount Analytical
Sales Office or representative before returning the equipment.
Equipment must be returned with complete identification in accordance
with Rosemount Analytical instructions or it will not be accepted.
In no event will Rosemount Analytical be responsible for equipment returned
without proper authorization and identification.
2. Carefully pack defective unit in a sturdy box with sufficient shock
absorbing material to ensure that no additional damage will occur during
shipping.
3. In a cover letter, describe completely:
a. The symptoms from which it was determined that the equipment is
faulty.
b. The environment in which the equipment has been operating
(housing, weather, vibration, dust, etc.).
c. Site from which equipment was removed.
d. Whether warranty or nonwarranty service is requested.
e. Complete shipping instructions for return of equipment.
f. Reference the return authorization number.
4. Enclose a cover letter and purchase order and ship the defective
equipment according to instructions provided in Rosemount Analytical
Return Authorization, prepaid, to:
Rosemount Analytical Inc.
RMR Department
6565P Davis Industrial Parkway
Solon, Ohio 44139
If warranty service is requested, the defective unit will be carefully inspected
and tested at the factory. If failure was due to conditions listed in the standard
Rosemount Analytical warranty, the defective unit will be repaired or replaced
at Rosemount Analytical's option, and an operating unit will be returned to the
customer in accordance with shipping instructions furnished in the cover
letter.
For equipment no longer under warranty, the equipment will be repaired at the
factory and returned as directed by the purchase order and shipping
instructions.
http://www.processanalytic.com
Instruction Manual
Oxymitter 4000
B-2
IM-106-340, Rev. 4.0
February 2006
Instruction Manual
IM-106-340, Rev 4.0
February 2006
Oxymitter 4000
Index
A
L
Alarm Contacts . . . . . . . . . . . 8-4
Alarm Indications . . . . . . . . . . 8-3
Alarms, Corrective Actions . . . 8-5
Local Operator Interface
Logic I/O Mode . . . . . .
LOI Menu Tree . . . . . .
LOI, Lockout . . . . . . . .
....
.....
.....
.....
6-1
4-5
6-4
6-3
B
By-Pass Packages . . . . . . . . 11-2
C
Calibration . . . . . . . . 3-6, 4-6, 6-3
Calibration Gas Bottles 1-20, 11-5,
11-6
Calibration Handshake
Cell Replacement Kit .
Configuration . . . . . . .
HART . . . . . . . . .
Recommended . .
. . . . . . 4-5
. . . . . 10-3
. . . . . . 3-2
. . 3-2, 4-2
. . 3-6, 4-6
D
Display, Error . . . . . . . . 5-2, 6-1
Display, Operating . . . . . 5-1, 6-1
Display, Startup . . . . . . . 5-1, 6-1
E
Electrical Noise . . . . . . . . . . . 8-3
Electrostatic Discharge . . . . . . 8-3
Essential Instructions . . . . . . . . i-i
H
HART Communications . . . . . 7-1
HART Handheld Communicator 11-1
I
IMPS 4000 . . . . . . . . . . . . . 11-3
Installation
Mechanical . . . . . . . . . . . 2-2
K
Kit
Cell Replacement . . . . . 10-3
Probe Disassembly . . . . 10-5
http://www.raihome.com
M
Maintenance . . . . . . . . . .
Material Safety Data Sheet
Membrane Keypad . . . . .
Menu Tree
HART . . . . . . . . . . .
LOI . . . . . . . . . . . . .
Menu Tree, LOI . . . . . . . .
. . . 9-1
. . A-15
. . . 5-2
. . . 7-5
. . . 6-4
. . . 6-4
P
Parts, Replacement . . . . . . . 10-1
Power Up . . . . . . . . . . . . . . . 5-1
Product Matrix . . . . . . . . . . . 1-18
R
Reference Air . . . . . . . . . . . . 5-2
Replacement Parts . . . . . . . 10-1
Returning Material . . . . . . . . . B-1
S
Service . . . . . . . . . . .
Specifications . . . . . .
SPS 4001B . . . . . . . .
System Configuration
System Description . .
System Features . . . .
. . . . . . 9-1
. . . . . 1-16
. . . . . 11-4
. . . . . . 1-4
. . . . . . 1-3
. . . . . . 1-6
T
Troubleshooting . . . . . . . . . . 8-1
Instruction Manual
Oxymitter 4000
Index-2
IM-106-340, Rev 4.0
February 2006
WARRANTY
Rosemount Analytical warrants that the equipment manufactured and sold by
it will, upon shipment, be free of defects in workmanship or material. Should
any failure to conform to this warranty become apparent during a period of
one year after the date of shipment, Rosemount Analytical shall, upon prompt
written notice from the purchaser, correct such nonconformity by repair or
replacement, F.O.B. factory of the defective part or parts. Correction in the
manner provided above shall constitute a fulfillment of all liabilities of
Rosemount Analytical with respect to the quality of the equipment.
THE FOREGOING WARRANTY IS EXCLUSIVE AND IN LIEU OF ALL
OTHER WARRANTIES OF QUALITY WHETHER WRITTEN, ORAL, OR
IMPLIED (INCLUDING ANY WARRANTY OF MERCHANTABILITY OF
FITNESS FOR PURPOSE).
The remedy(ies) provided above shall be purchaser's sole remedy(ies) for
any failure of Rosemount Analytical to comply with the warranty provisions,
whether claims by the purchaser are based in contract or in tort (including
negligence).
Rosemount Analytical does not warrant equipment against normal
deterioration due to environment. Factors such as corrosive gases and solid
particulates can be detrimental and can create the need for repair or
replacement as part of normal wear and tear during the warranty period.
Equipment supplied by Rosemount Analytical Inc. but not manufactured by it
will be subject to the same warranty as is extended to Rosemount Analytical
by the original manufacturer.
At the time of installation it is important that the required services are supplied
to the system and that the electronic controller is set up at least to the point
where it is controlling the sensor heater. This will ensure, that should there be
a delay between installation and full commissioning that the sensor being
supplied with ac power and reference air will not be subjected to component
deterioration.
3833
2/06
Instruction Manual
IM-106-340, Rev. 4.0
February 2006
Oxymitter 4000
Oxymitter 4000
Part no.____________
Serial no.____________
Order no.____________
Rosemount Analytical and the Rosemount Analytical logotype are registered trademarks of Rosemount Analytical Inc.
HART is a registered trademark of the HART Communications Foundation.
All other marks are the property of their respective owners.
Emerson Process Management
Rosemount Analytical Inc.
Process Analytic Division
6565P Davis Industrial Parkway
Solon, OH 44139
T (440) 914 1261
F (440) 914 1271
E gas.csc@emersonprocess.com
Fisher-Rosemount GmbH & Co.
Industriestrasse 1
63594 Hasselroth
Germany
T +49 (0) 6055 884-0
F +49 (0) 6055 884-209
E info.de@emersonprocess.com
EUROPE, MIDDLE EAST,
AFRICA
Fisher-Rosemount Ltd.
Heath Place
Bognor Regis
West Sussex PO22 9SH
England
T 44-1243-863121
F 44-1243-845354
LATIN AMERICA
Fisher - Rosemount
Av. das Americas
Rio de Janeiro, RJ
Brazil 22631-003
T 55-21-2431-1882
http://www.raihome.com
© 2006 Rosemount Analytical Inc. All rights reserved.
ASIA - PACIFIC
Fisher-Rosemount
Singapore Private Ltd.
1 Pandan Crescent
Singapore 128461
Republic of Singapore
T +65 6777-8211
F +65 6777-0947
E AP.RMT-Specialist@emersonprocess.com