OCX 8800 O2 / Combustibles Transmitter General Purpose with Remote Electronics-Rev 1.2
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Loading...Rosemount OCX 8800 O2 / Combustibles Transmitter General Purpose with Remote Electronics-Rev 1.2 Manuals & Guides
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
OCX 8800
Oxygen/Combustibles Transmitter
General Purpose OCX 8800 Oxygen/Combustibles Analyzer with Remote Electronics
http://www.raihome.com
HIGHLIGHTS OF CHANGES
Effective December 2007, Rev 1.1
Page/Section Summary
Throughout Updated manual number suffixes in page headers to indicate OCX configuration.
Changed references to HART Communicator te read Field Communicator in text and
illustrations.
Page 1-10 Added new illustration Figure 1-6
Page 1-14 Updated Product Matrices.
Page 1-15 Revised/updated Table 1-2 .
Page 2-2 Deleted obsolete CAUTION statement.
Page 2-14 Revised paragraph 4 listing of gases for calibration.
Page 2-18 Revised Figure 2-11 to indicate minimum pressure for actuation of the blowback valve.
Page 2-19 Revised Figure 2-12 to indicate minimum pressure for actuation of the blowback valve.
Page 4-4 Revised 1st paragraph.
Page 4-5 Revised HART menu items in Figure 4-3, Sheet 1 of 4
Page 4-9 Added new step 4 to both D/A Trim Procedures.
Page 5-2 Replaced steps 6 through 10 with a repeat of step 4 instruction.
Page 5-3 Revised steps 2 and 3.
Page 7-3 Revised "Ref Current Err" fault indication heading.
Page 7-7 Revised probable cause statements of "Cal Warning/Cal Failed" fault indication.
Page 8-5 Revised parts list for Sensor Housing Components.
Appendix A Updated multi-lingual safety pages.
Effective July 2008, Rev 1.2
Page/Section Summary
General Updated manual to synchronize revision levels.
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
OCX 8800
Table of Contents
Essential Instructions. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . i
Preface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ii
Definitions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ii
Symbols . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ii
SECTION 1
escription and
D
Specifications
SECTION 2
Installation
SECTION 3
Configuration and
Startup
SECTION 4
Using HART
Communications
SECTION 5
alibration
C
Component Checklist. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-1
System Overview. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-1
Specifications. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-12
Mechanical
Installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-2
Electrical Installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-8
Pneumatic Installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-14
Initial Startup . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-20
Verify Installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-1
Initial Power Up . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-3
Set Test Gas Values . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-4
OCX 8800 Reset Procedure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-4
Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-1
Field Communicator Signal Connections. . . . . . . . . . . . . . . . . . . . . . . 4-1
Field Communicator PC Connections . . . . . . . . . . . . . . . . . . . . . . . . . 4-4
HART Menu Tree. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-5
D/A Trim Procedures . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-9
Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-1
Fully Automatic Calibration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-1
Operator - Initiated Autocalibration . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-3
Manual Calibration. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-3
SECTION 6
Maintenance and Service
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Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-1
OCX 8800 Removal
and Installation. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-1
OCX with
Remote Electronics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-2
Repair Sensor Housing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-8
Sensor Housing Disassembly. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-8
Sensor Housing Assembly . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-18
Repair Electronics Housing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-28
Electronics Housing Disassembly . . . . . . . . . . . . . . . . . . . . . . . . 6-28
OCX 8800
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
Electronics Housing Assembly . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-30
Replace Tube Fittings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-34
Remove Tube Fittings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-34
Install Tube Fittings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-35
SECTION 7
oubleshooting
Tr
SECTION 8
Replacement Parts
APPENDIX A
Safety Data
APPENDIX B
SPA with HART Alarm
APPENDIX C
eturn of Materials
R
Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7-1
Grounding. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7-1
Electrical Noise. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7-1
Electrostatic Discharge. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7-1
Total Power Loss . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7-2
Diagnostic Alarms . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7-2
Fault Isolation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7-3
Alarm Relay Events . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7-11
Sensor Housing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8-2
Electronics Housing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8-6
O2 Cell and Heater Strut Assembly. . . . . . . . . . . . . . . . . . . . . . . . . . . 8-9
Safety Instructions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . A-2
Safety Data Sheet for Ceramic Fiber Products . . . . . . . . . . . . . . . . . A-24
High Pressure Gas Cylinders . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .A-30
Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . B-1
Description. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . B-1
Installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .B-2
Setup . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .B-2
Returning Material . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .C-1
TOC-2
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
OCX 8800
OCX 8800
Oxygen/Combustibles Transmitter
ESSENTIAL INSTRUCTIONS
READ THIS PAGE BEFORE PROCEEDING!
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
Emerson’s 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
Emerson Process Management 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 Emerson Process Management.
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.
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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 Emerson Process Management Service Group or National
Response Center at 1-800-654-7768.
Instruction Manual
:EARTH(GROUND)TERMINAL
:PROTECTIVECONDUCTORTERMINAL
:RISKOFELECTRICAL SHOCK
:WARNING:REFERTOINSTRUCTIONBULLETIN
IM-106-880ASB, Rev 1.2
OCX 8800
July 2008
PREFACE The purpose of this manual is to provide a comprehensive understanding of
the OCX 8800 components, functions, installation, and maintenance.
We recommend that you thoroughly familiarize yourself with the Introduction
and Installation sections before installing your transmitter.
The introduction presents the basic principles of the transmitter along with its
performance characteristics and components. The remaining sections contain
detailed procedures and information necessary to install and service the
transmitter.
Before contacting Emerson Process Management concerning any questions,
first consult this manual. It describes most situations encountered in your
equipment's operation and details necessary action.
DEFINITIONS The following definitions apply to WARNINGS, CAUTIONS, and NOTES
und throughout this publication.
fo
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.
SYMBOLS
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.
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.
ii
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
OCX 8800
Section 1 Description and Specifications
Component Checklist . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 1-1
System Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 1-1
Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 1-12
COMPONENT CHECKLIST
A typical OCX 8800 Oxygen/Combustibles Transmitter package should
contain the items shown in Figure 1-1.
Use the product matrix in Table 1-1 at the end of this section to verify your
order number. The first part of the matrix defines the model. The last part
defines the various options and features of the OCX 8800. Check the model
number against the transmitter features and options, making sure options
specified by this number are on or included with the unit. Use this complete
model number for any correspondence with Emerson Process Management.
A list of accessories for use with the OCX 8800 is provided in Table 1-2.
SYSTEM OVERVIEW Scope
This Instruction Manual supplies details needed to install, startup, operate,
and maintain the OCX 8800. Signal conditioning electronics outputs separate
4-20 mA signals representing oxygen (O2) and combustibles (COe) values.
This information, plus additional details, can be accessed with the HART
Model 275/375 handheld communicator or Rosemount Analytical AMS
software.
System Description
The OCX 8800 is designed to measure oxygen and combustible
concentrations in flue gas temperatures up to 2600°F (1427°C). Electrical
connections, power and communications are made through two 3/4 NPT ports
in the flameproof electronics enclosure using fittings and cables provided by
the customer. Cable installation must meet NEC, IEC and/or other applicable
national or local codes for Class I, Zone 1, Group IIB +H2 T3/T6 permanently
mounted equipment. The transmitter is close coupled to the process and
requires minimal sample conditioning requirements.
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OCX 8800
4
6
1
37390076
2
o
HART Communicator
FISHER-ROSEMOUNT
TM
MAN4275A00
English
October1994
3
5
A
n
a
l
y
t
i
c
a
l
Figure 1-1. Typical System Package
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
1. Instruction Manual
2. Field Communicator Package (optional)
3. Adapter Plate with Mounting Hardware and Gasket
4. Reference Air and Calibration Set
5. Blowback Hardware (optional)
6. OCX 8800 with Remote Electronics
1-2
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
OCX 8800
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 of the cell is given by the following Nernst equation:
EMF = KT log10 (P
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 OCX 8800 to provide
exceptional sensitivity at low oxygen concentrations.
1/P2
) + C
The OCX 8800 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.
The OCX 8800 combustibles sensor is a catalytic sensor consisting of two
Resistance Devices (RTD). One RTD is the reference element covered with
an inert coating. The other RTD element is active, coated with a catalyst. As
the sample gases flow by the sensor, the combustible gases oxidize on the
surface of the active element. The oxidation that occurs produces heat and a
temperature rise in the active element. The temperature difference produces
a resistance relationship between the two elements that is directly
proportional to the concentration of combustibles in the sample gases.
1-3
OCX 8800
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
The catalyst is specifically designed to detect carbon monoxide (CO), but the
sensor responds to other combustible gases. The sensor is calibrated using
CO, thus the output should be expressed in terms of CO. However, since the
sensor detects other combustible gases, the output cannot just be labeled
CO. The response of the sensor to other combustible gases gives an output
that is equivalent to the sensor detecting CO. The term COe is used in this
manual to describe the sensor output. This term indicates that the sensor is
calibrated in terms of CO, and that the sensor output is equivalent to CO but
not specific to CO.
Dilution air is provided to the COe sensor to ensure there is adequate oxygen
to fully oxidize any combustible gases regardless of the concentration of
oxygen in the process.
System Configuration
Transmitters are available in four lengths, giving the user the flexibility to use
a penetration appropriate to the size of the stack or duct. The length options
are 18 in. (457 mm), 3 ft (0.91 m), 6 ft (1.83 m), or 9 ft (2.7 m). Probes are
available in three material options, 316L stainless steel, inconel 600, and
ceramic to accommodate higher temperatures.
The electronics are contained in a separate housing from the sensors. The
electronics housing may be mounted up to 150 feet away from the sensor
housing.
The electronics control both sensor temperatures and provide individual 4-20
mA isolated outputs that are proportional to the measured oxygen and
combustibles concentrations. The power supply can accept voltages of 100 to
240 VAC and 50 to 60 Hz. The electronics accepts millivolt signals generated
by the sensors and produces the outputs to be used by remotely connected
devices. The outputs are isolated 4-20 mA linearized currents. Refer to
Section 3, Configuration and Startup for specific instructions upon initial
power up.
System Features
1. The O
concentration decreases.
2. HART communication is standard. To use the HART capability, you
must have either:
a. Model 275/375 Field Communicator.
b. AMS software for the PC.
3. Oxygen cell and heater/thermocouple assembly are field replaceable.
4. Electronics are automatically configured for line voltages from 100 to
240 VAC.
cell output voltage and sensitivity increase as the oxygen
2
1-4
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
OCX 8800
5. An operator can calibrate and diagnostically troubleshoot the OCX 8800
using the HART Interface. Each of the OCX 8800's 4-20 mA output lines
transmit an analog signal proportional to oxygen or combustible levels
detected. The HART output is superimposed on the oxygen 4-20 mA
output line only. This information can be accessed through the following:
• Model 275/375 Handheld Communicator - The handheld
communicator requires Device Description (DD) software specific
to the OCX 8800. The DD software will be supplied with many
Model 275/375 units, but can also be programmed into existing
units at most Emerson Process Management service offices.
Refer to Section 4, Using HART Communications, for additional
information.
• Personal Computer (PC) - The use of a personal computer
requires AMS software available from Emerson Process
Management.
• Selected Distributed Control Systems - The use of distributed
control systems requires input/output (I/O) hardware and AMS
software which permit HART communications.
6. Optional Blowback System. The blowback system periodically blows
instrument air back through the sample line filter and out the sample
tube. This clears out particulate and keeps the sample line filter from
clogging.
System Operation
Figure 1-2 shows the relationship between the components of the OCX 8800.
The sensors and the electronics are contained in separate housings. The
sensor housing and probe mounts to a duct or process wall so that the probe
protrudes into the flue gas stream. An air powered eductor continuously pulls
samples of the process flue gas through the probe to a chamber in front of the
sensor housing where the sample passes the O
the COe sensor. Dilution air is provided to the COe sensor and reference air
to the O2 sensor. After the gas sample flows past the O2 sensor and through
the COe sensor, it is drawn through the eductor where it mixes with the
eductor air and exits through exhaust back into the system. The electronics
housing contains the CPU and HART boards which convert the sensor inputs
into 4-20 mA analog output signals. The CPU can also initiate and perform
calibrations. Three test gasses and instrument air can be turned on and off by
solenoids. Test gas flow to the sensors is regulated by a flow meter between
the electronics and sensor housings. Instrument air is separated into eductor
air, reference air, and dilution air. The instrument air solenoid does not allow
air flow until the heaters are up to temperature. This minimizes the amount of
sampled process flue gas being pulled into cold sensors causing
condensation.
sensor and continues on to
2
1-5
OCX 8800
Low O
Test Gas
2
COe
Combustibles
Sensor
O
Sensor
2
Eductor
Probe
Exhaust
CPU
HART
Board
Optional
Test Gas
Solenoids
Instrument Air
Solenoid
High O
Test Gas
2
CO
Test Gas
Instrument
Air
Dilution Air
Reference Air
Eductor Air
Flow Meter
50 cc/min.
(0.1 scfh)
SENSOR
HOUSING
ELECTR
ONICS
HOUSING
Flow Meter
7 scfh
37390001
Sample
Gas
Power
Supply
Figure 1-2. System Operation Diagram
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
Handling the OCX 8800
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 OCX 8800 is designed for industrial application. Treat each component of the system
with care to avoid physical damage. The probe may contain components made from
ceramics, which are susceptible to shock when mishandled.
System Considerations
Prior to installing your OCX 8800, 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.
1-6
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
OCX 8800
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 1-3 shows a typical system wiring. Simplified
installations for the OCX 8800 are shown in Figure 1-4. Figure 1-6 shows the
dimensions for the optional sample tube support.
A source of instrument air is required at the OCX 8800 for reference air,
dilution air, and eductor air. Since the OCX 8800 is equipped with an in-place
calibration feature, provision should be made for connecting test gas tanks to
the OCX 8800 when it is to be calibrated.
NOTE
The electronics module is designed to meet NEMA 4 (IP66) and the electronic
components are rated to temperatures up to 185°F (8 5°C).
Retain packaging in which the unit arrived from the factory in case any
components are to be shipped to another site. This packaging has been
designed to protect the product.
Figure 1-3. OCX 8800 HART
Connections and AMS Application
1-7
OCX 8800
OCX 8800 with
REMOTE
ELECTRONICS
4-20 mA Outputs
(2 Twisted Pairs)
Heater
P
ower Cable
[up to 150 ft (46 m)]
Pressure
Regulator
Duct
Stack
Gases
Line Voltage
Signal Cable
[up to 150 ft (46 m)]
37390064
Low O Test Gas
2
High O Test Gas
2
CO Test Gas
Instrument Air
Supply
(Ref
erence Gas)
Test Gas
Flow Meter
Dilution
Air
Flow
Meter
Figure 1-4. Typical System
Installation
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
Figure 1-5. OCX 8800 HART
1-8
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
Connections and AMS Application
OCX 8800
1-9
OCX 8800
Figure 1-6. Sample Tube Support
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
1-10
Instruction Manual
OCX 8800 with
REMOTE
ELECTRONICS
4-20 mA Outputs
(2 Twisted Pairs)
Heater
P
ower Cable
[up to 150 ft (46 m)]
Pressure
Regulator
Duct
Stack
Gases
Line Voltage
Signal Cable
[up to 150 ft (46 m)]
37390064
Low O Test Gas
2
High O Test Gas
2
CO Test Gas
Instrument Air
Supply
(Ref
erence Gas)
Test Gas
Flow Meter
Dilution
Air
Flow
Meter
IM-106-880ASB, Rev 1.2
July 2008
Figure 1-7. Typical System
Installation
OCX 8800
1-11
OCX 8800
SPECIFICATIONS General Purpose OCX
Specifications
Net O2 Range 0-1% to 0-40% O2, fully field selectable
Combustibles 0-1000 ppm to 0-5%, fully field selectable
Accuracy
Oxygen ± 0.75% of reading or 0.05% O2 (whichever is greater)
Combustibles ± 2% range
System Response to
Test Gas
Oxygen 10 sec T90
Combustibles 25 sec T90
Temperature Limits
Process 32° to 2600°F (0° to 1427°C)
Sensors Housing -40° to 212°F (-40° to 100°C), ambie nt
Electronics Housing -40° to 149°F (-40° to 65°C), ambient
Nominal and Approximate
Shipping Weights
18 in. (457 mm)
probe package
3 ft (0.91 m) probe
package
6 ft (1.83 m) probe
package
9 ft (2.74 m) probe
package
Mounting and Mounting
Positions
Sensors Housing Flange
Electronics Housing Wall/Pipe
Materials
Probes 316L stainless steel - 1300°F (704°C)
Enclosures Low-copper aluminum
Calibration Semi-automatic or automatic
Calibration Gas Mixtures
Recommended
(Ref. test gas bottles
kit #1A99119G04)
Calibration Gas Flow 7 scfh (3.3 l/m)
Reference Air 2 scfh (1 l/m), clean, dry instrument-quality air (20.95% O2),
Eductor Air 5 scfh (2.5 l/m), clean, dry, instrument-quality air 20.95% O2),
Dilution Air 0.1 scfh (0.5 l/m), clean, dry, instrument-quality air (20.95% O2)
Blowback Air (optional) Clean, dry, instrument-quality air (20.95% O2), regulated to 55 psi
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
-40° to 185°F (-40° to 85°C), internal - operating temperature of
electronics inside instrument housing, as measured by a HART
communicator or AMS software
54 lbs (20 kg)
55 lbs (20.5 kg)
57 lbs (21 kg)
59 lbs (22 kg)
Inconel 600 - 1832°F (1000°C)
Ceramic - 2600°F (1427°C)
0.4% O2, Balance N2
8% O2, Balance N2
1000 ppm CO, Balance Air
regulated to 35 psi (241 kPa)
regulated to 35 psi (241 kPa)
regulated to 35 psi (241 kPa)
(379 kPa)
Table continued on next page
1-12
Instruction Manual
APPROVED
CUS
IM-106-880ASB, Rev 1.2
July 2008
OCX 8800
Specifications
Sensors Housing NEMA 4, IP66 with fitting and pipe on reference exhaust port to
clean, dry atmosphere, two 3/4-14 NPT conduit ports
Electronics Housing NEMA 4, IP66 with fitting and pipe on reference exhaust port to
Electrical Noise EN 61326-1, Class A
Certifications
Line Voltage Universal 100 to 240 VAC ±10%, 50 to 60 Hz, no switches or
Pollution Degree 2
Over Voltage Category II
Relative Humidity 5 to 95% (non-condensing)
Isolated Output
Oxygen 4-20 mAdc, 950 ohm maximum, with HART capability
Combustibles 4-20 mAdc, 950 ohm maximum
Alarm Alarm output relay - dry contact, form C, 30mA, 30VDC capacity
Power Consumption 750 W maximum
Mounting and Mounting
Positions
Sensor Housing Flange
Electronics Housing Wall/Pipe
NOTE
ll static performance characteristics are with operating variables constant. Specifications subject to change
A
without notice.
clean, dry atmosphere, two 3/4-14 NPT conduit ports
jumpers required, 3/4-14 NPT conduit port
1-13
Instruction Manual
IM-106-880ASB, Rev 1.2
OCX 8800
Table 1-1. Product Matrix - General Purpose OCX 8800
OCX88A O2/Combustibles Transmitter
Code Probe Length and Material
00 No Probe or Exhaust Tube
11 18 in. (457 mm) 316 SST up to 1300°F (704°C) (3)
21 18 in. (457 mm) Inconel 600 up to 1832°F (1000°C)
31 18 in. (457 mm) Ceramic up to 2600°F (1427°C)
12 3 ft (0.91 m) 316 SST up to 1300°F (704°C)
22 3 ft (0.91 m) Inconel 600 up to 1832°F (1000°C) (3)
32 3 ft (0.91 m) Ceramic up to 2600°F (1427°C)
13 6 ft (1.83 m) 316 SST up to 1300°F (704°C)
23 6 ft (1.83 m) Inconel 600 up to 1832°F (1000°C) (3)
14 9 ft (2.7 m) 316 SST up to 1300°F (704°C)
24 9 ft (2.7 m) Inconel 600 up to 1832°F (1000°C) (3)
Code Probe Mounting Assembly
10 (ANSI 2 in. 150 lb) 6" dia. flange, 4.75" BC with 4 x 0.75" dia. holes
20 (DIN) 185 mm dia. flange, 145 mm BC with 4 x 18 mm dia. holes
Code Mounting Hardware - Stack Side
0 No Adapter Plate (“0” must be chosen under “Mounting Adapter - Probe Side” below)
1 New Installation - Square weld plate with studs
2 Model 218/240 Mounting Plate (with Model 218/240 Shield Removed)
3 Existing Model 218/240 Support Shield
4 Special Mounting
5 Model 132 Adapter Plate
Code Mounting Hardware - Probe Side
0 No Adapter Plate
1 Probe Only (ANSI)
2 Probe Only (DIN)
OCX88A 11 10 1 1 H3 06 02 Example
NOTES:
(1)
Provide details of the existing mounting plate as follows:
Plate with studs Bolt circle diameter, number, and arrangement of studs, stud thread, stud height above mounting plate.
Plate without studs Bolt circle diameter, number, and arrangement of holes, thread, depth of stud mounting plate with accessories.
(2)
For use with stainless steel sample tube only.
(3)
For high temperature applications that require a filter, please order 1A99762H03 separately.
(1)
Code Electronics Housing - Communications
H1 HART Communications
H2 HART Communications with Local Operator Interface
H3 HART Communications with Calibration Solenoids
H4 HART Communications with Local Operator Interface and Calibration Solenoids
Code Electronics Mounting
01 Integral to Sensor Housing
02 Remote Electronics and no cable
03 Remote Electronics and 20 ft (6 m) cable
04 Remote Electronics and 40 ft (12 m) cable
05 Remote Electronics and 60 ft (18 m) cable
06 Remote Electronics and 80 ft (24 m) cable
07 Remote Electronics and 100 ft (30 m) cable
08 Remote Electronics and 150 ft (46 m) cable
Code Accessories
00 None
01 Flow meters & Ref. Air Set
02 In-Situ Filter (Stainless Steel only) (2)
03 In-Situ Filter (SST), Flow meters & Ref. Air Set (2)
11 Flow meters, and Ref. Air Set with Blowback
12 In-Situ Filter (SST) with Blowback (2)
13 In-Situ Filter (SST), Flow meters & Ref. Air Set with Blowback (2)
July 2008
1-14
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
Table 1-2. Accessories
PART NUMBER DESCRIPTION
1A99119H01 Oxygen test gas bottle; 0.4% O2, balance N
1A99119H02 Oxygen test gas bottle; 8.0% O2, balance N
1A 99119H07 CO test gas bottle; 1000 ppm CO, balance air
1A99120H02 Regulator for Oxygen (may need 2)
1A99120H03 Regulator for CO test gas
1A99119G06 Wall mount bracket for test gas bottles
1A99119G05 Test gas regulators kit
1A99119G04 Test gas bottles kit
1A99292H01
1A99339H03 Blowback valve, air operated
1A99762H03 Hasteloy In Situ Filter, High Temperature
1A99784H02
6A00171G01 Power line filter kit
6A00288G01 Sample Tube Support, 18 in. (457 mm)
6A00288G02 Sample Tube Support, 3 Ft. (0.91 m)
6A00288G02 Sample Tube Support, 6 Ft. (1.83 m)
6A00288G04 Sample Tube Support, 9 Ft. (2.7 m)
6P00162H02 Flange Insulator
Moore Industries SPA for Low O2 Alarm, High COe Alarm,
Calibration Status, and Unit Fail
375 Field Communicator with 12 Megabyte buffer,
model no. 375HR1EKLU
OCX 8800
2
2
1-15
OCX 8800
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
1-16
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
Section 2 Installation
Mechanical Installation . . . . . . . . . . . . . . . . . . . . . . . . . . . page 2-2
Electrical Installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 2-8
Pneumatic Installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 2-14
Initial Startup . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 2-20
Before installing this equipment, read the "Safety instructions for the wiring and installation
of this apparatus" in Appendix A: Safety Data. Failure to follow the safety instructions could
result in serious injury or death.
OCX 8800
The OCX88A can be installed in general purpose areas only. Do not install the OCX88A in
hazardous areas.
http://www..raihome.com
OCX 8800
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
MECHANICAL INSTALLATION
Selecting Location
1. The location of the OCX 8800 in the stack or flue is most important for
maximum accuracy in the oxygen analyzing process. The probe must
be positioned so the gas it measures is representative of the process.
Best results are normally obtained if the transmitter is positioned near
the center of the duct (40-60% insertion). Longer ducts may require
several transmitters since the oxygen and combustibles 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 the range of probe material used.
Figure 2-1 through Figure 2-4 provide mechanical installation
references. The ambient temperature inside the electronics housing
must not exceed 185°F (85°C).
2. Check the flue or stack for holes and air leakage. The presence of this
condition will substantially affect the accuracy of the oxygen and
combustibles readings. Therefore, either make the necessary repairs or
install the transmitter up stream of any leakage.
3. Ensure the area is clear of internal and external obstructions that will
interfere with installation and maintenance access to the unit. Allow
adequate clearance for the removal of the OCX 8800.
Do not allow the temperature of the electronics housing to exceed 185°F (85°C) or damage
to the electronics may result.
Whenever a positive stack pressure exists at the installation site, be sure to connect all
pneumatic lines prior to installing the OCX 8800 in the stack or ductwork. Failure to connect
the pneumatic lines can allow the flow of contaminants into the OCX 8800 ports.
Installation
1. Ensure all components are available to install the OCX 8800.
2. The OCX 8800 may be installed intact as it is received.
3. Weld or bolt adapter plate (Figure 2-2) onto the duct.
4. Use the pipe or wall mounting hardware as shown in Figure 2-3 to
mount the electronics housing. Choose a location not to exceed the
length of the electronics cable ordered.
5. Ensure the conduits drop vertically from the OCX 8800 and the conduit
is routed below the level of the conduit ports on the housing to form a
drip loop. Drip loops minimize the possibility that moisture will damage
the electronics (Figure 2-4).
6. Where a positive stack pressure exists at the installation site, connect all
pneumatic lines prior to installing the OCX 8800 in the stack or
ductwork.
2-2
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
OCX 8800
NOTE
If process temperatures will exceed 392°F (200°C), use anti-seize compound
on stud threads to ease future removal of the OCX 8800.
7. Insert sample and exhaust tubes through the opening in the mounting
flange and bolt the unit to the flange.
Uninsulated stacks or ducts may cause ambient temperatures in the electronics housing to
exceed 185°F (85°C) and damage the electronics.
8. If insulation is removed to access the duct for OCX 8800 mounting,
make sure to replace insulation afterward.
Enclosures
The OCX 8800 enclosures are designed to meet ingress conditions of IP66.
Each enclosure cover is threaded to its base and sealed with an o-ring that
isolates the threads from external contaminants.
Each cover is secured by a clip attached to the base that engages the cover
between the ribs of the cover sidewall. The clip is held in place by an Allen
head cap screw and lockwasher mounted in a recess. Cover removal and
installation requires an Allen wrench to loosen and tighten the screw.
2-3
OCX 8800
B.C. Dia.
Removal Envelope
Dim “B”
37390009
Insertion Depth
Dim “A”
Flange Dia.
Hole Dia.
8.3
(211)
Allow 9 in.
(229 mm) for
Cover Removal
See Table 1
Optional
In Situ FIilter
Heater Power Cable
Signal Cable
Heater Power Cable
Signal Cable
ELECTRONICS HOUSING
SENSOR HOUSING
See Table 2
All dimensions are in inches with millimeters in parentheses.
NOTE
Insulate if exposed to adverse weather or extreme temperature
changes, install a protective housing and/or insulation
around the unit.
Flange
Dia.
DIN
ANSI
5R10244H025R10244H01
6.00
(152)
Table 1. Mounting Flange
Hole
Dia.
(4) Holes
equally
spaced on
B
.C
. dia
7.28
(185)
0.75
(19)
0.71
(18)
4.75
(121)
5.71
(145)
Dim "B”
3 ft
9 ft
6 ft
Probe
18 in.
Dim "A”
(2235)
88
(3150)
124
(2743)
108
72
(1829)
(914)
36
(1321)
52
(864)
34
(457)
18
Table 2. Installation/Removal
3535B18H02
3535B45H01
DIN
ANSI
0.06 In. Thick Gasket
Figure 2-1. Installation, OCX 8800
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
2-4
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
Figure 2-2. Adapter Plate Installation
OCX 8800
2-5
OCX 8800
37020021
*Pipe
Mounting
Clamp
Electronics
Housing
*Wall or Pipe
Mounting Bracket
and Screws
1/4-20 UNC x 2 in. M-F Standoffs.
Recommended for rear piping
clearance when wall mounting.
(4 each by customer)
Wall Mounting Bolts
or Lag Screws
(4 each by customer)
* Indicates items are included
in mounting kit P/N 4851B40G01.
Note:
Figure 2-3. Wall or Pipe Mounting
of Electronics Housing
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
2-6
Instruction Manual
37020004
Conduit Drip Loops
Duct Wall
Conduit Drip Loop Conduit Drip Loop
Duct Wall
IM-106-880ASB, Rev 1.2
July 2008
Figure 2-4. Installation
with Drip Loops
OCX 8800
2-7
OCX 8800
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
ELECTRICAL INSTALLATION
All wiring must conform to local and national codes. For reference, factory
wired solenoid power connections are shown in Figure 2-5.
Disconnect and lock out power before connecting the unit to the power supply. Failure to
lock out power 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.
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) in close proximity and marked for this equipment 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.
The OCX88A can be installed in general purpose areas only. Do not install the OCX88A in
hazardous areas.
2-8
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
OCX 8800
NOTE
To maintain proper earth grounding, ensure a positive connection exists
between the sensor housing, the electronics housing, and earth. The
connecting ground wire must be 14 AWG minimum. Refer to Figure 2-5.
NOTE
Line voltage, signal, and relay wiring must be rated for at least 105ºC (221ºF).
Electrical Connections
Electrical connections, power and communications are made to the electronic
enclosure. The connections are made through two 3/4 NPT ports in the
enclosure using fittings and cables provided by the customer. Cable
installation must meet NEC, IEC and/or other applicable national or local
codes for Class I, Zone 1, IIB +H2 T3/T6 permanently mounted equipment.
Connect Line Voltage
The OCX 8800 operates on 100 to 240 VAC line voltage at 50 to 60 Hz. The
power supply requires no setup. Connect the line (L wire) to the L terminal,
and the neutral (N wire) to the N terminal on the AC power input terminal
block in the electronics housing. Connect the ground (G wire) to the ground
stud in the electronics housing as shown in Figure 2-5.
Connect 4-20 mA Signals
Connect the 4-20 mA current loop to the 4-20 mA signal output terminals in
the electronics housing as shown in Figure 2-5. Use individual shielded
twisted wire pairs. Terminate the shield at the electronics housing.
4-20 mA Signal
O
2
One 4-20 mA signal represents the O2 value. Superimposed on the O2
signal is the HART information accessible through a Model 275/375
Handheld Communicator or AMS software. The O2 signal is at the AOUT 1
terminals.
COe 4-20 mA Signal
Another 4-20 mA signal at the AOUT 2 terminals represents the COe
value. HART information is not available on the COe signal.
Alarm Output Relay
Connect any customer-supplied relay input to the alarm output relay terminal.
Use shielded wire and terminate the shield at the electronics housing. The
alarm output relay terminal is a set of dry, no. 2, form C, contacts with 30 mA,
30 VDC capacity.
2-9
OCX 8800
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
Remote Electronics Connections to Sensor Housing
Make the following connections between the electronics and sensor housings
with the electronics cable ordered with the package (Figure 2-6). Braided
cable is available in lengths up to 150 ft. (46 m).
NOTE
Interconnect wiring shown is for Rosemount Analytical supplied cables. For
customer furnished interconnect wiring or cables, refer to Figure 2-7.
Signal Connections
Connect the electronics housing terminals to the corresponding terminals
in the sensor housing. The twisted wire pairs are numbered on the inner
plastic wrapper. Keep twisted pairs together and match the numbers and
wire colors shown in Figure 2-6.
Heater Power Connections
Use the blue, white, orange black, red, and yellow stranded wires in the
heater power cable to connect power to the three heaters in the sensor
housing. Match the wire colors to the corresponding heater power terminal
blocks in the sensor and electronics housings as shown in Figure 2-6.
2-10
Instruction Manual
37390013
TOP VIEW
(1/2 SIZE)
Ground Stud
Earth Ground
Typical for Electronics and
Sensor Housing
NC
COM
NO
Alarm Output Relay
Terminal Block
#1
AOUT2+
AOUT2AOUT1-
AOUT1+
O Signal
2
COeSignal
{
{
Ground
Stud
4-20 mA Signal Output
Terminal Block
Power Port
3/4 NPT
Signal Port
3/4 NPT
External Tooth
Lockwasher
#1
G
G
Terminal
Block
N
G
L1
EMI Filter
Customer
Wiring
IM-106-880ASB, Rev 1.2
July 2008
Figure 2-5. Line Voltage, Earth,
and 4-20 mA Connections
OCX 8800
2-11
OCX 8800
37390014
RED
BLK
WHT
GRN
BLK
BLK
BLU
BLK
YEL
BRN
RED
BLK
BLK
ORG
BLK
WHT
T/C CO+
T/C CO-
T/C SB+
T/C SBT/C O2+
T/C O2-
O2 CELL+
O2 CELL-
EXC
+
+
-
+
-
EXC-
-
+
-
2
1
1
2
2
1
BLU
ORG
YEL
RED
SHIELD
To
ground
screw
GRN
BLK
WHT
BLK
YEL
RED
BLU
WHT
BLK
BLK
GRN
BLK
BLK
BLK
ORG
WHT
RED
BLK
BRN
To ground screw
GRN
ELECTRONICS HOUSING
SENSOR HOUSING
Heater Power Cable
Signal Cable
O Sensor and
Thermocouple
Connector (J5)
2
COe Sensor
and
Cold Junction
Connector (J4)
EXC+
CO A
CT+
CO ACT-
CO REF+
CO REFCJC+
CJCEXC-
O2
HTR
O2
HTR
CO
HTR
SB
CO
REF
CO
ACT
CJC
T/C SB
T/C CO
T/C O2
+
-
+
-
+
-
+
#1
#1 #1
#1
#1
To ground
screw
SHLD
WHT
ORG
BLU
BLK
YEL
RED
Heater Power
Connector (J3)
#1
2HTR SB
1HTR O
2
1HTR SB
2HTR CO
1HTR CO
2HTR O
2
Figure 2-6. Electrical Connections Between Remote Electronics and Sensor Housing
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
2-12
Instruction Manual
A
#2
#1
3/4 NPT Hub Size,
Liquid-tight
Strain Relief
Connector
Heat Shrink
Tubing
2” Long
1/2” Size
7.0” Long Teflon Tubing,
0.042” ID (Cut off drain
wire at probe end of
shield).
8 twisted pairs 24 AWG,
stranded, insulated,
tinned copper
conductors, 200 C, 300
volts, with overall braid
of 34 AWG tinned
copper, 90% coverage
and 24 AWG tinned
copper, uninsulated
drain wire.
o
7.25
±0.10
Strip Wire
Ends 3/16”
Typical
7.25 ±0.10
9.25 ±0.10
Overall Cable Length
By Customer
150’ Maximum
3.875
±0.10
4.625
±0.10
5.375
±0.10
6.125
±0.10
6.875 ±0.10
8.625 ±0.10
10.375 ±0.10
12.5 ±0.10
Ferrule,
Uninsulated
2.0 ±0.25
Typical
DETAIL
A
Heat Shrink Tubing
1” Long, 3/16” Size
(typical on both ends of wiring)
SIGNAL WIRING OR CABLE
ELECTRONICS END
PROBE END
0.5
Typ.
3/4 NPT Hub Size,
Liquid-tight
Strain Relief
Connectors
Heat Shrink Tubing
2” Long, 1/2” Size
4.25” Long Teflon Tubing,
0.042” ID. (Cut off drain wire
at probe end of shield).
8 Conductors, 16 AWG, Stranded,
200 C, 600 volts.
Braided shield - tinned copper, 90%
coverage with 18 AWG 24 tinned copper,
uninsulated, drain wire.
O
4.0 ±0.10
Stud Size
#10
4.5 ±0.10
5.5 ±0.10
Ferrule, Uninsulated
2.0 ±0.25 Typical
Heat Shrink Tubing
2” Long, 1/2” Size
HEATER WIRING OR CABLE
ELECTRONICS END
PROBE END
Green,
16 AWG
0.5
Typ.
Stud Size #6
Green, 16 AWG
Strip Wire
Ends 3/16”
Typical
Heat Shrink
Tubing
2” Long
1/2” Size
See Note
See Note
NOTE: For RFI/CE compliance, the connector
must provide 360 degrees of electrical
contact to the cable shield.
Stud Size
#10
37390061
IM-106-880ASB, Rev 1.2
July 2008
Figure 2-7. Customer-Furnished
Interconnect Wiring or Cables
OCX 8800
2-13
OCX 8800
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
PNEUMATIC INSTALLATION
Pneumatic system connections depend on whether reference air set,
calibration solenoids, and/or blowback equipment options are equipped on
your transmitter. Refer to the following paragraphs and select the option that
applies to your transmitter configuration.
Reference Air Set Option (only)
When no options or only the reference air set option is equipped, use the
following procedure to install the pneumatic system components.
1. Refer to Figure 2-8. Connect the reference air set (regulator/filter and
pressure gage) to the instrument air inlet on the electronics housing and
to the inlet side of the dilution air flow meter.
2. Connect the dilution air flow meter output to the dilution air inlet fitting on
the sensor housing.
3. Install an air line between the instrument air outlet fitting on the
electronics housing and the tee fitting on the sensor housing.
.
Do not use 100% nitrogen as an O2 low gas. It is suggested that O2 low gas 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.
4. One CO gas and two O2 gases are used to calibrate the OCX 8800:
CO - 1000 ppm or up to 4%, Balance air
low gas - 0.4% , Balance N
O
2
O2 high gas - 8%, Balance N
2
2
Connect the output of the test gas sources to the inlet port of the CAL
GAS flow meter. Install an air line between the flow meter outlet port and
the CAL GAS inlet fitting on the sensor housing.
2-14
Instruction Manual
37390011
Electronics
Housing
Eductor
Air In
Sensor
Housing
Dilution Air In
Reference Air In
CAL Gas In
CAL Gas
Flow Meter
7 scfh, 20-30 psig
Recommended
Dilution Air
Flow Meter
0.1 scfh
Instrument
Air Supply
Pressure Reguator/Filter
35 psig - General Purpose
45 psig - Hazardous Area
(
(
2-Stage
Regulators
CO
HI O
2
LO O
2
Instrument
Air Out
IM-106-880ASB, Rev 1.2
July 2008
Figure 2-8. Pneumatic
Installation, OCX with Reference
Air Set (without Autocalibration)
OCX 8800
2-15
OCX 8800
Electronics
Housing
Dilution
Air In
Reference
Air In
CAL Gas In
CAL Gas
Flow Meter
7 scfh, 20-30 psig
Recommended
Dilution Air
Flow Meter
0.1 scfh
Instrument
Air Supply
Pressure Regulator/Filter
35 psig - General Purpose
45 psig - Hazardous Area
2-Stage
Regulators
CO
HI O
2
LO O
2
CAL Gas Out
Eductor
Air In
Sensor
Housing
Instrument Air Out
(
(
37390012
Figure 2-9. Pneumatic
Installation, OCX with Reference
Air Set and Solenoids (with
Autocalibration)
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
Reference Air Set and Solenoids Option
When the reference air set and test gas solenoids are included with your
OCX 8800, use the following procedure to install the pneumatic system
components.
1. Install the reference air set according to the instructions in Reference Air
2. Refer to Figure 2-9. Connect the O
3. Connect the O
Set Option, steps 1 through 3.
low gas source to the CAL GAS LO
2
O2 inlet fitting on the electronics housing. Install a shutoff valve and
pressure regulator with gage in the O2 low supply line, as shown.
high gas source to the CAL GAS HI O2 inlet fitting.
2
Install a shutoff valve and pressure regulator with gage in the O2 high
supply line.
2-16
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
OCX 8800
4. Connect the CO high gas to the CAL GAS HI COe inlet fitting. Install a
shutoff valve and pressure regulator with gage in the CO high supply
line.
5. Connect the CAL GAS outlet fitting of the electronics housing to the inlet
port of the CAL GAS flow meter. Install an air line between the flow
meter outlet port and the CAL GAS inlet fitting on the sensor housing.
Reference Air Set, Solenoids, and Blowback Option
The blowback system blows instrument air back through the blowback filter
and out the sample tube of the transmitter. This removes built up dirt and
particulate from the filter and sample line. The blowback option is normally
used in systems that have a dirty process stream.
Installing an OCX 8800 with the blowback option requires the addition of air
operated blowback valve, regulator and gage, and check valve.
Figure 2-10 shows the piping arrangement for the OCX 8800 with the
blowback and autocalibration options. Figure 2-11 shows the piping
arrangement for the OCX 8800 with the blowback option, but without
autocalibration (without test gas solenoids).
When the reference air set, calibration gas solenoids, and blowback options
are included with your transmitter, use the following procedure to install the
pneumatic system components.
1. Connect the calibration gas sources according to the instructions in the
previous paragraph “Reference Air Set and Solenoids Option”, steps 2
through 5.
2. Connect a clean, dry, instrument-quality supply of air (20.95% O
35/45 psig and 55 psig pressure regulators. The inlet to the 35/45 psig
regulator accepts a 1/8" NPT fitting. The inlet to the 55 psig regulator
accepts a 1/4" NPT fitting.
3. See the upper leg of the instrument air supply. Connect the output of the
35/45 psi regulator/filter to one port of the normally-closed air-operated
solenoid valve, and to the inlet side of the dilution air flow meter.
4. Connect the dilution air flow meter output to the DILUTION AIR inlet
fitting on the sensor housing.
5. Install an instrument air line between the open port of the normally-open
air-operated solenoid valve and the tee fitting on the sensor housing.
6. Connect the output of the 55 psi regulator/filter to one port of the
normally-open air-operated solenoid valve, and to the instrument air
inlet on the back of the electronics housing.
7. Install an air line between the open port of the normally-closed
air-operated solenoid valve and the check valve inlet fitting on the
sensor housing.
) to the
2
2-17
OCX 8800
Figure 2-10. Piping Arrangement,
Blowback with Autocalibration
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
2-18
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
Figure 2-11. Piping Arrangement,
Blowback without Autocalibration
OCX 8800
2-19
Instruction Manual
IM-106-880ASB, Rev 1.2
OCX 8800
July 2008
8. Install an air line between the instrument air outlet fitting on the
electronics housing and the control air inlet fitting on the air-operated
solenoid valve.
9. There are three settings that need to be specified to set up the blowback
option. These are the blowback interval, duration, and purge time.
Interval - Length of time between blowback events.
(60 minutes recommended.)
Duration - Length of time blowback air is activated.
(5 seconds recommended.)
Purge - Length of time after blowback is complete before
oxygen/combustibles readings are considered valid.
(Set as required by the application.)
These settings are available through HART from the DEVICE SETUP >
DETAILED SETUP > OUTPUT CONDITIONS > BLOWBACK menu.
INITIAL STARTUP Observe the following Caution and Note. Refer to Section 3: Configuration
nd Startup, for OCX 8800 startup information.
a
Upon completing installation, make sure that the OCX 8800 is turned on and operating prior
to firing up the combustion process. Damage can result from having a cold OCX 8800
exposed to the process gases.
If ducts will be washed down during outages, make sure to power down the OCX 8800 units
and remove them from the wash area.
NOTE
During outages, and whenever possible, leave OCX 8800 units running to
prevent condensation and premature aging from thermal cycling.
2-20
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
OCX 8800
Section 3 Configuration and Startup
Verify Installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 3-1
Initial Power Up . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 3-3
Set Test Gas Values . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 3-4
OCX 8800 Reset Procedure . . . . . . . . . . . . . . . . . . . . . . . . page 3-4
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.
VERIFY INSTALLATION Ensure the OCX 8800 is installed correctly. Verify mechanical installation and
all electrical and pneumatic connections. Refer to Section 2, Installation.
Make sure that the OCX 8800 is turned on and operating prior to firing up the combustion
process. Damage can result from having a cold OCX 8800 exposed to the process gases.
NOTE
During outages, and whenever possible, leave all OCX 8800 units running to
prevent condensation and premature aging from thermal cycling.
http://www..raihome.com
OCX 8800
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
Verify Configuration
There are three switches on the microprocessor board which are user
configurable for the OCX 8800 (Figure 3-1). SW1 determines if the O2 4-20
mA signal is internally or externally powered. SW2 determines if the COe 4-20
mA signal is internally or externally powered. SW3 sets the rail limits for the
and COe 4-20 mA signals and configures the sample line heater control
O
2
circuit. All switches are accessible through holes in the electronics box.
Remove power from the OCX 8800 before changing defaults. If defaults are changed under
power, damage to the electronics may occur.
Verify that the following switch settings are correct for your OCX 8800
installation:
SW1 The two settings are internally or externally powering the O2 4-20
mA signal. The factory setting is for the O2 4-20 mA signal to be internally
powered.
SW2 The two settings are internally or externally powering the COe 4-20
mA signal. The factory setting is for the COe 4-20 mA signal to be
internally powered.
SW3 The factory sets this switch as follows:
• Position 1 determines the O
4-20 mA signal rail limit. The settings are
2
high, 21.1 mA, or low, 3.5 mA. The factory setting is low, 3.5 mA.
• Position 2 determines the COe 4-20 mA signal rail limit. The settings
are high, 21.1 mA, or low, 3.5 mA. The factory setting is high, 21.1 mA.
• Positions 3 and 4 must be set as shown for proper software control of
the device heaters.
3-2
Instruction Manual
1 234
Internal:
O 4-20 mA
is Internally
Powered
2
External:
O 4-20 mA
Requires an External
Power Supply
(Default)
2
O 21.1 mA/3.5 mA:2O 4-20 mA Signal
Rail Limits:
High - 21.1 mA
Lo
w - 3.5 mA
2
COe 4-20 mA Signal
Rail Limits:
High- 21.1 mA
Low - 3.5 mA
COe 21.1 mA/3.5 mA:
1
1223344
SW3
3.5 mA
Switch
Default Postions
Shown
COe
SW1
SW2
37390026
O
2
21.1 mA
Closed
External:
COe 4-20 mA
Requires an External
Power Supply
(Default)
Internal:
COe 4-20 mA
is Internally
Powered
Open
Closed
Open
Open
Closed
Open
Closed
IM-106-880ASB, Rev 1.2
July 2008
Figure 3-1. OCX 8800 Defaults
OCX 8800
INITIAL POWER UP Allow adequate time (approximately 60 minutes) for the heaters to begin
peration and for the OCX 8800 to reach normal operating temperature on
o
power up. Normal operating temperature for the O2 cell is 736°C. Normal
operating temperature for the combustibles cell is 300°C. The normal sample
line temperature is 170°C. During this time the edu ctor air solenoid will remain
closed so no sample is pulled through the analyzer. When the OCX reaches
operating temperature the solenoid will energize, eductor air will begin to flow,
and the unit will begin normal operation.
3-3
Instruction Manual
IM-106-880ASB, Rev 1.2
OCX 8800
July 2008
SET TEST GAS VALUES Use HART/AMS to set test gas values for calibration. Refer to Section 4,
Using HART Communications for more information.
Setting Test Gas Values with HART
1. Use the 275/375 Field Communicator or AMS software to access the
HART menu.
2. From the DETAILED SETUP menu, select O2 CALIB PARAMS.
3. From O2 CALIB PARAMS, select O2 High Gas. Enter the percent O
used for the high O2 test gas.
4. From O2 CALIB PARAMS, select Low TG. Enter the percent O2 used
for the low O2 test gas.
5. From the DETAILED SETUP menu, select COe CALIB PARAMS.
6. From COe CALIB PARAMS, select COe Test Gas. Enter the CO
concentration (ppm) used for COe test gas.
2
OCX 8800 RESET PROCEDURE
Whenever you correct an equipment alarm or fault condition, the OCX 8800
will either revert to normal operation or continue to indicate an alarm status
condition. If the equipment does not revert to normal operation when a fault
condition is cleared, or if instructed to do so in Section 7, Troubleshooting,
use the following procedure to reset the OCX 8800.
OCX Reset with HART
Remove the OCX 8800 from the process loop and recycle power.
3-4
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
OCX 8800
Section 4 Using HART Communications
Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 4-1
Field Communicator Signal Connections . . . . . . . . . . . . page 4-1
Field Communicator PC Connections . . . . . . . . . . . . . . . page 4-4
HART Menu Tree . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 4-5
D/A Trim Procedures . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 4-9
OVERVIEW The Field Communicator is a handheld communications interface device. It
provides a common communications link to all microprocessor-based
instruments that are HART compatible.
To interface with the OCX 8800, the Field Communicator requires a
termination point along the O2 4-20 mA current loop and a minimum load
resistance of 250 ohms between the communicator and the power supply.
The Field 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 4-20 mA oxygen output
signal. The communicator does not disturb the 4-20 mA signal since no net
energy is added to the loop. HART information is not available on the COe
output signal.
FIELD COMMUNICATOR
IGNAL CONNECTIONS
S
The Field Communicator may be interfaced with a personal computer (PC),
providing special software has been installed. To connect the Field
Communicator may to a PC, an interface adapter is required. Refer to the
proper Field Communicator documentation in regard to the PC interface
option.
The Field Communicator can connect to the OCX 8800 oxygen analog output
signal line at any wiring termination in the O2 4-20 mA current loop. There are
two methods of connecting the Field 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.
http://www..raihome.com
OCX 8800
Figure 4-1. Signal Line Connections,
≥ 250 Ohms Load Resistance
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
Method 1, for Load Resistance ≥ 250 Ohms
efer to Figure 4-1 and the following steps to connect the Field
R
Communicator to a signal line 250 ohms or more of load resistance.
Do not make connections to the Field Communicator 's serial port, 4-20 mA signal lines, or
NiCad recharger jack in an explosive atmosphere. Explosions can result in death or serious
injury.
Using the supplied lead set, connect the Field Communicator in parallel to the
OCX 8800. Use any wiring termination points in the oxygen analog output
4-20 mA signal line.
4-2
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
Figure 4-2. Signal Line Connections,
< 250 Ohms Load Resistance
OCX 8800
Method 2, for Load Resistance < 250 Ohms
Refer to Figure 4-2 and the following steps to connect the Field
Communicator to a signal line with less than 250 ohms load resistance.
Do not make connections to the Field Communicator's serial port, 4-20 mA signal lines, or
NiCad recharger jack in an explosive atmosphere. Explosions can result in death or serious
injury.
1. At a convenient point, break the oxygen 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 Field Communicator).
4-3
OCX 8800
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
Field Communicator PC Connections
There is an option to interface the Field Communicator with a personal
computer. Load the 375 Easy Upgrade Programming Utility software into the
PC. Then link the Field Communicator to the PC through the IRDA Interface.
Refer to the proper Field Communicator documentation in regard to the PC
interface option.
Off-line and On-line Operations
The Field Communicator can be operated both off-line and on-line.
Off-line operations are those in which the communicator is not connected to
the OCX 8800. Off-line operations can include interfacing the Field
Communicator with a PC. (Refer to applicable documentation regarding
HART/PC applications.)
In the on-line mode, the communicator is connected to the oxygen 4-20 mA
analog output signal line. The Field Communicator is connected in parallel to
the OCX 8800 or in parallel to the 250 ohm load resistor.
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 Field
Communicator manual for detailed menu information.
4-4
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
OCX 8800
HART MENU TREE This section consists of a menu tree for the Field Communicator. This menu is
specific to OCX 8800 applications.
Figure 4-3. HART Menu Tree
(Sheet 1 of 4)
4-5
OCX 8800
DIAG/SERVICE
BCSR0 BCSR3
BCSR1 BCSR4
BCSR2 BCSR5
STATUS
CPLD REGS
D/A TRIM
CAL METHODS
O2OutTracks
COeOutTracks
Cal Step
Cal Time
O2
COe
PERFORM
CAL
CALIBRATE
Cal Step
Cal Time
CAL
STATUS
FAILED CAL
VALUES
Reset O2 CalConsts
Reset COe CalConsts
RESET CAL
CONST
O2 Calibration
COe Calibration
O2 and COe Calib
(CONTINUED FROM
SHEET 1 )
(CONTINUED ON
SHEET 3)
Snsr Housing
Model Number
O2 AO Saturated
COe AO Saturated
O2 AO Fixed
COe AO Fixed
AO fixed
AO saturated
Status group 4
Status group 3
Status group 2
Operate Mode
Status group 6
Status group 5
HW STATUS
Status group 1
LOOP TEST
O2 Loop Test
COe Loop Test
O2 D/A Trim
COe D/A Trim
O2 Slope
O2 Const
O2 Snsr R
COe Slope
COe Const
CAL VALUES
Bad O2 Slope
Bad O2 Const
Bad COe Slope
Bad COe Const
PREV CAL
VALUES
Prev O2 Slope
O2 Const
O2 Snsr R
COe Slope
COe Const
Prev
Prev
Prev
Prev
VERIFY CALIB
Verify Calibration
Status
TimeRemain
O2
COe
BlBk State
Blowback
BLOWBACK
MAX TEMP
O2TempMax
COeTempMax
SBTempMax
BrdTempMax
CJCTempMax
O2 Prop
O2 Int
O2 DutyCyc
O2 SetPt
O2 Temp
HEATER PID
O2 PID
COE PID
SB PID
COe Prop
Int
DutyCyc
SetPt
Temp
COe
COe
COe
COe
SB Prop
SB Int
SB DutyCyc
SB SetPt
SB Temp
37390039
Line Freq
Line Volt
PCN Counter
PCD Counter
Status group 4
RTD Current Err
COe Temp Low
COe Temp Hi
COe Temp Very Hi
COe T/C Open
COe T/C Shorted
COe T/C Reversed
SB T/C Reversed
Status group 3
Cal Failed
Cal Warning
SB T/C Open
SB T/C Shorted
SB Temp Low
SB Temp Hi
SB Temp Very Hi
ADC Ref Error
Status group 2
O2 Temp Low
O2 Temp Hi
O2 Snsr Open
O2 Snsr R Hi
EEPRM Chksm Fail
O2 Htr Ramp Rate
COe Htr Ramp Rate
SB Htr Ramp Rate
Status group 6
O2 Slope Error
O2 Constant Error
O2 Cal Failed
COe Slope Error
COe Constant Error
COe Cal Failed
Status group 5
COe Htr Failure
SB Htr Failure
Line Voltage Low
Line Voltage Hi
Htr Relay Failed
Output Board Failure
Status group 1
O2 T/C Open
O2 T/C Shorted
O2 T/C Reversed
ADC Failure
Line Freq Error
O2 Htr Failure
O2 Temp Very Hi
Board Temp Hi
(procedures)
Figure 4-3. HART Menu Tree (Sheet 2 of 4)
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
4-6
Instruction Manual
BASIC SETUP
DEVICE
INFORMATION
DETAILED
SETUP
(CONTINUED FROM
SHEET 2)
37390040
(CONTINUED ON
SHEET 4)
Tag
Poll addr
Dev id
Num req preams
Fld dev rev
OUTPUT
CONDITION
Trig 1 Event
Trig 2 Event
Trig 3 Event
Alarm State
O2 AO Type
O2 URV
O2 LRV
O2 Alarm Level
COe CALIB
PARAMS
BlBk Enabled
BlBk Intrvl
BlBk Period
BlBk PurgeTm
BlBk State
ANALOG
OUTPUT
ALARM
RELAY
DEVICE
PARAMS
LOI
PARAMS
O2 CALIB
PARAMS
BLOWBACK
COe AO Type
COe URV
COe LRV
COe Alarm Level
O2 ANALOG
OUTPUT
COe ANALOG
OUTPUT
O2OutTracks
O2 High Gas
O2 Low Gas
Gas Time
Purge Time
Solenoids
O2 CalIntv
O2NxtCalTm
COeOutTracks
COe Test Gas
Gas Time
Purge Time
Solenoids
COe CalIntv
COeNxtCalTm
COe Slope Warn
O2 Slope
O2 Const
O2 T90
COe Slope
COe Const
COe T90
PCNC Enable
PCDC Enable
User Intface
Luminance
Lockout Time
Revert Time
Date
Descriptor
Message
Final asmbly num
O2 Sensor s/n
COe Sensor s/n
HART
INFORMATION
S/W VERSION
INFO
Version
Chksum
Bld Num
Bld Date
Restart Cntr
IM-106-880ASB, Rev 1.2
July 2008
Figure 4-3. HART Menu Tree
(Sheet 3 of 4)
OCX 8800
4-7
OCX 8800
O2 Slope
O2 Const
O2 T90
COe Slope
COe Const
COe T90
O2 CALIB
O2 DEVICE
CONFIG
REVIEW
DEVICE
INFORMATION
HART
INFORMATION
CAL INFO
OUTPUTS
CONFIG
Manufacturer
Model
Date
Descriptor
Message
Final asmbly num
O2 Sensor s/n
COe Sensor s/n
Hardware rev
Software rev
(CONTINUED FROM
SHEET 3)
37390041
Tag
Poll addr
Dev id
Num req preams
Fld dev rev
Universal rev
DEVICE
CONFIG
COE CALIB
O2OutTracks
O2 High Gas
O2 Low Gas
Gas
Time
Purge Time
Solenoids
O2 CalIntv
O2NxtCalTm
COeOutTracks
COe Test Gas
Gas Time
Purge Time
Solenoids
COe CalIntv
COeNxtCalTm
COe Slope Warn
COE DEVICE
CONFIG
DEVICE CONFIG
Trig 1 Event
Trig 2 Event
Trig 3 Event
BlBk Enabled
BlBk Intrvl
BlBk Period
BlBk PurgeTm
PCNC Enable
PCDC Enable
Luminance
Lockout Time
Revert Time
O2 URV
O2 LRV
COe URV
COe LRV
O2 AO Type
COe AO Type
O2 Alarm Level
COe Alarm Level
Figure 4-3. HART Menu Tree
(Sheet 4 of 4)
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
4-8
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
OCX 8800
D/A TRIM PROCEDURES O
D/A trim procedure using HART
2
Use the following procedure to perform the O2 D/A trim procedure using the
Field Communicator. Refer to the HART menu tree, Figure 4-3.
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 DIAG/SERVICE menu, select D/A TRIM. The Field
Communicator displays O2 D/A Trim.
2. Press the right arrow key to start the procedure. (If you wish to exit D/A
Trim with no changes, select ABORT.)
3. The Field Communicator displays WARNING: Loop should be
removed from automatic control. Remove the OCX 8800 from any
automatic control loops to avoid a potentially dangerous operating
condition and press OK.
4. The Field Communicator displays Connect reference meter to O2
output.
5. Remove the electronics housing cover.
6. Refer to Figure 2-5. Connect a digital multimeter to read the milliamp
output from the O2 D/A converter circuit. Connect the positive lead to
the AOUT1+ terminal and connect the negative lead to the AOUT1terminal. Then, press OK at the Field Communicator.
7. The Field Communicator displays Setting Fld dev output to 4 mA.
Press OK. Read the O
the reading at the Field Communicator and press ENTER. (Select
ABORT to exit without changes).
8. The Field Communicator displays Setting Fld dev output to 20 mA.
Press OK. Read the O2 millamp output at the digital multimeter. Enter
the reading at the Field Communicator and press ENTER. (Select
ABORT to exit without changes).
9. The Field Communicator displays Setting Fld dev output to 4 mA.
Press OK.
10. The Field Communicator displays Fld dev output 4.00 mA equal to
reference meter? Using the up or down arrow, select 1 Yes or 2 No
and Press ENTER. If No, the process repeats from step 6.
11. The Field Communicator displays Setting Fld dev output to 20 mA.
Press OK.
12. The Field Communicator displays Fld dev output 20.00 mA equal to
reference meter? Using the up or down arrow, select 1 Yes or 2 No
and Press ENTER. If No, the process repeats from step 7.
13. The Field Communicator displays NOTE: Loop may be returned to
automatic control.
millamp output at the digital multimeter. Enter
2
4-9
OCX 8800
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
COe D/A trim procedure using HART
Use the following procedure to perform the COe D/A trim procedure using the
Field Communicator. Refer to the HART menu tree, Figure 4-3.
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 DIAG/SERVICE menu, select D/A TRIM. The Field
Communicator displays O2 D/A Trim. Press the up or down arrow to
select COe D/A Trim.
2. Press the right arrow key to start the procedure. (If you wish to exit D/A
Trim with no changes, select ABORT.)
3. The Field Communicator displays WARNING: Loop should be
removed from automatic control. Remove the OCX 8800 from any
automatic control loops to avoid a potentially dangerous operating
condition and press OK.
4. The Field Communicator displays Connect reference meter to
Combustibles output.
5. Remove the electronics housing cover.
6. Refer to Figure 2-5. Connect a digital multimeter to read the milliamp
output from the COe D/A converter circuit. Connect the positive lead to
the AOUT2+ terminal and connect the negative lead to the AOUT2terminal. Then, press OK at the HART communicator.
7. The Field Communicator displays Setting Fld dev output to 4 mA.
Press OK. Read the COe
the reading at the Field Communicator and press ENTER. (Select
ABORT to exit without changes).
8. The Field Communicator displays Setting Fld dev output to 20 mA.
Press OK. Read the COe millamp output at the digital multimeter. Enter
the reading at the Field Communicator and press ENTER. (Select
ABORT to exit without changes).
9. The Field Communicator displays Setting Fld dev output to 4 mA.
Press OK.
10. The Field Communicator displays Fld dev output 4.00 mA equal to
reference meter? Using the up or down arrow, select 1 Yes or 2 No
and Press ENTER. If No, the process repeats from step 6.
11. The Field Communicator displays Setting Fld dev output to 20 mA.
Press OK.
12. The Field Communicator displays Fld dev output 20.00 mA equal to
reference meter? Using the up or down arrow, select 1 Yes or 2 No
and Press ENTER. If No, the process repeats from step 7.
13. The Field Communicator displays NOTE: Loop may be returned to
automatic control.
millamp output at the digital multimeter. Enter
4-10
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
Section 5 Calibration
Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 5-1
Fully Automatic Calibration . . . . . . . . . . . . . . . . . . . . . . . . page 5-1
Operator - Initiated Autocalibration . . . . . . . . . . . . . . . . . page 5-3
Manual Calibration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 5-3
OCX 8800
OVERVIEW During a calibration, two calibration gases with known O
one calibration gas with a known COe concentration are applied to the OCX
8800. Slope and constant values are calculated to determine if the OCX 8800
is correctly measuring net concentrations of O2 and combustibles in the
industrial process.
Before calibrating the OCX 8800, verify that the calibration gas parameters
are correct by setting the test gas values used when calibrating the unit. Refer
to Section 3, Configuration and Startup.
There are three calibration methods available to the OCX 8800; automatic,
operator-initiated automatic, and manual. Calibration commands and menus
can be accessed by HART/AMS.
FULLY AUTOMATIC CALIBRATION
If the OCX 8800 is equipped with calibration solenoids, the unit can be
programmed to automatically calibrate without any operator action. Refer to
the following paragraphs for using HART/AMS to set up the OCX 8800 for
fully automatic calibration.
Autocalibration Setup using HART
NOTE
Automatic calibration is only available on units equipped with calibration
solenoids.
Use the following procedure to specify a time interval (in hours) at which the
OCX 8800 will automatically calibrate.
concentrations and
2
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1. From the DEVICE SETUP screen, select DETAILED SETUP.
2. From the DETAILED SETUP screen, select O2 CALIB PARAMS or
COE CALIB PARAMS.
3. If the unit is equipped with calibration solenoids and timed automatic
calibrations are desired, select Solenoids, then select Yes. Select No to
disable the calibration solenoids.
OCX 8800
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
4. Select O2 CalIntrvl (O2 calibration interval) and enter the desired time
in hours between automatic O2 calibrations. Select COE Callintrvl and
enter the desired time between automatic COe calibrations. To disable
automatic calibration for O2 and COe, enter 0 for both CalIntrvl
parameters.
5. If desired, the O2NxtCalTm and the COeNxtCalTm (next calibration
time) parameters can be changed to synchronize a calibration at a
specific day or time.
When setting automatic calibration times, CalIntrvl and NxtCalTm should be set so that O2
and COe are NOT calibrated simultaneously.
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.
6. Select O2 CalIntrvl (O2 calibration interval) and enter the desired time
in hours between automatic O2 calibrations. Select COE Callintrvl and
enter the desired time between automatic COe calibrations. To disable
automatic calibration for O2 and COe, enter 0 for both CalIntrvl
parameters.
5-2
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
OCX 8800
OPERATOR - INITIATED AUTOCALIBRATION
An operator can initiate an automatic calibration at any time provided that the
unit is equipped with calibration solenoids.
Autocalibration using HART
To initiate an automatic calibration using HART/AMS, perform the following
steps on the HART menu tree. Refer to Section 4, Using HART
Communications, for the HART menu tree.
1. Select DIAG/SERVICE from DEVICE SETUP menu.
2. Select CALIBRATION from the DIAG/SERVICE menu.
3. Select PERFORM CAL from the CALIBRATION menu.
4. Select CAL METHODS from the PERFORM CAL menu.
5. From the CAL METHODS menu, select the type of calibration desired:
O2 Calibration, COe Calibration, or O2 and COe Calibration.
MANUAL CALIBRATION If a unit is not equipped with calibration solenoids, a calibration must be
erformed by an operator following prompts from the unit. Refer to the
p
following paragraphs for manual calibration.
Manual O2 Calibration using HART
To perform a manual O2 calibration using the Field Communicator or AMS,
use the following procedure. If necessary, refer to Section 4, Using HART
Communications, for the HART menu tree.
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 DIAG/SERVICE menu, select CALIBRATION. From the
CALIBRATION menu, select PERFORM CAL.
2. From the PERFORM CAL menu, select CAL METHODS. Select O2
CALIBRATION to start O2 calibration.
3. In the first O2 Calibration screen, a Loop should be removed from
automatic control warning appears. Remove the OCX 8800 from any
automatic control loops to avoid a potentially dangerous operating
condition and press OK.
4. The main Calibration screen should look like the following. Press OK to
continue.
OCX: TAG NAME
STATUS: Idle
TIME REMAIN: 0s
O2: 0.4 %, 85.95mV
OK/NEXT to Select
ABORT/CANCEL to Exit
5-3
OCX 8800
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
5. From the SELECT ACTION screen, select START/NEXT CALSTEP to
continue calibration, select ABORT CAL to abort calibration or EXIT
CAL to exit calibration. Select one item from the list and press ENTER.
OCX: TAG NAME
SELECT ACTION
1. START/NEXT CALSTEP
2. ABORT CAL
3. EXIT CAL
6. When the Calibration Status is at the AppO2Low step, switch on O
Low Gas. Verify the O2 concentration measured matches the O2 LOW
GAS parameter in the Setup. Press OK when ready.
7. Select Start/Next Cal Step to start applying the O2 Low Gas. The time
to apply the test gas is specified by the Gas Time.
8. The Calibration Status should be automatically changed to FlowO2Low
and then ReadO2Low for a period of time. During this period, if an
attempt is made to go to the next calibration step by pressing OK and
selecting Start/Next Cal Step, you will be prompted with Operator step
command is not accepted at this time. The Next Cal Step command
is not accepted at this time.
9. When ready, Calibration Status will stop at the AppO2Hi. Switch off the
O2 Low Gas and switch on the O2 High Gas. Verify the O2 concentration
measured matches the O2 HIGH GAS parameter in the Setup. Press
OK when ready.
10. Select Start/Next Cal Step to start applying the O2 High Gas. The time
to apply the test gas is specified by the Gas Time.
11. The Calibration Status should be automatically changed to FlowO2Hi
and then ReadO2Hi for a period of time. During this period, if an attempt
is made to go the next calibration step by pressing OK and selecting
Start/Next Cal Step, you will be prompted with Operator step
command is not accepted at this time. The Next Cal Step command
is not accepted at this time.
12. When ready, Calibration Status will stop at STOP GAS. Switch off the
High Gas. Press OK when ready. Select Start/Next Cal Step to start
O
2
purging gas. The time to purge gas is specified by the Purge Time.
13. When the Purge step is complete, the Calibration Status will be at IDLE
if the calibration is successful or CAL RECOMMENDED if the
calibration has failed. A Calibration Failed alarm will be set if the
calibration has failed.
14. When calibration is complete. Select Exit Cal to exit the calibration
method.
2
5-4
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
OCX 8800
Manual COe Calibration using HART
To perform a manual COe calibration using the Field Communicator or AMS,
use the following procedure. If necessary, refer to Section 4, Using HART
Communications, for the HART menu tree.
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 DIAG/SERVICE menu, select CALIBRATION. From the
CALIBRATION menu, select PERFORM CAL.
2. From the PERFORM CAL menu, select CAL METHODS. Select COe
CALIBRATION to start COe calibration.
3. In the first COe Calibration screen, a Loop should be removed from
automatic control warning appears. Remove the OCX 8800 from any
automatic control loops to avoid a potentially dangerous operating
condition and press OK.
4. The main Calibration screen should look like the following. Press OK to
continue.
OCX: TAG NAME
STATUS: Idle
TIME REMAIN: 0s
COe: 0.20 ppm, 0.00 mV
OK/NEXT to Select
ABORT/CANCEL to Exit
5. From the SELECT ACTION screen, select START/NEXT CALSTEP to
continue calibration, select ABORT CAL to abort calibration or EXIT
CAL to exit calibration. Select one item from the list and press ENTER.
OCX: TAG NAME
SELECT ACTION
1. START/NEXT CALSTEP
2. ABORT CAL
3. EXIT CAL
6. The unit samples reference air as the COe
Status should automatically change to ReadCOLow for a period of time.
During this period, if an attempt is made to go to the next calibration
step by pressing OK and selecting Start/Next Cal Step, you will be
prompted with Operator step command is not accepted at this time.
The Next Cal Step command is not accepted at this time.
7. When ready, Calibration Status will stop at the AppCOeHi. Switch on
the COe High Gas. Verify the COe concentration measured matches the
COe HIGH GAS parameter in the Setup. Press OK when ready.
8. Select Start/Next Cal Step to start applying the COe High Gas. The
time to apply the test gas is specified by the Gas Time.
Low Gas. The Calibration
5-5
OCX 8800
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
9. The Calibration Status should be automatically changed to FlowCOeHi
and then ReadCOeHi for a period of time. During this period, if an
attempt is made to go the next calibration step by pressing OK and
selecting Start/Next Cal Step, you will be prompted with Operator step
command is not accepted at this time. The Next Cal Step command
is not accepted at this time.
10. When ready, Calibration Status will stop at STOP GAS. Switch off the
COe High Gas. Press OK when ready. Select Start/Next Cal Step to
start purging gas. The time to purge gas is specified by the Purge Time.
11. When the Purge step is complete, the Calibration Status will be at IDLE
if the calibration is successful or CAL RECOMMENDED if the
calibration has failed. A Calibration Failed alarm will be set if the
calibration has failed.
12. When calibration is complete. Select Exit Cal to exit the calibration
method.
Manual O
To perform a manual O2 and COe calibration using the Field Communicator or
AMS, use the following procedure. If necessary, refer to Section 4, Using
HART Communications, for the HART menu tree.
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 DIAG/SERVICE menu, select CALIBRATION. From the
2. From the PERFORM CAL menu, select CAL METHODS. Select 02 &
3. In the first Calibration screen, a Loop should be removed from
4. The main Calibration screen should look like the following. Press OK to
and COe Calibration using HART
2
CALIBRATION menu, select PERFORM CAL.
COe CALIBRATION to start O2 and COe calibration.
automatic control warning appears. Remove the OCX 8800 from any
automatic control loops to avoid a potentially dangerous operating
condition and press OK.
continue.
OCX: TAG NAME
STATUS: Idle
TIME REMAIN: 0s
O2: 0.4 %, 85.95mV
COe: 0.20 ppm, 0.00 mV
OK/NEXT to Select
ABORT/CANCEL to Exit
5-6
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
OCX 8800
5. From the SELECT ACTION screen, select START/NEXT CALSTEP to
continue calibration, select ABORT CAL to abort calibration or EXIT
CAL to exit calibration method. Select one from the list and press
ENTER.
OCX: TAG NAME
SELECT ACTION
1. START/NEXT CALSTEP
2. ABORT CAL
3. EXIT CAL
6. When the Calibration Status is at the AppO2Low step, switch on O
Low Gas. Verify the O2 concentration measured matches the O2 LOW
GAS parameter in Setup. Press OK when ready.
7. Select Start/Next Cal Step to start applying the O2 Low Gas. The time
to apply the test gas is specified by the Gas Time.
8. The Calibration Status should automatically change to FIowO2Low and
then ReadO2Low for a period of time. During this period, if an attempt
is made to go to the next calibration step by pressing OK and selecting
Start/Next Cal Step, you will be prompted with Operator step
command is not accepted at this time. The Next Cal Step command
is not accepted at this time.
9. When ready, Calibration Status will stop at AppO2Hi. Switch off the O2
Low Gas and switch on the O2 High Gas. Verify the O2 concentration
measured matches the O2 HIGH GAS parameter in Setup. Press OK
when ready.
10. Select Start/Next Cal Step to apply the O2 High Gas. The time to apply
the test gas is specified by the Gas Time.
11. The Calibration Status should automatically change to FlowO2Hi, then
ReadO2Hi, and then ReadCOeLo for a period of time. During this
period, if an attempt is made to go the next calibration step by pressing
OK and selecting Start/Next Cal Step, you will be prompted with
Operator step command is not accepted at this time. The Next Cal
Step command is not accepted at this time.
12. When ready, Calibration Status will stop at AppCOeHi. Switch off the O
High Gas and switch on the COe Gas. Verify the COe concentration
measured matches the COe TEST GAS parameter in the Setup. Press
OK when ready.
13. Select Start/Next Cal Step to start applying the COe Gas. The time to
apply the test gas is specified by the Gas Time.
14. The Calibration Status should automatically change to FlowCOeHi and
then ReadCOeHi for a period of time. During this period, if an attempt is
made to go the next calibration step by pressing OK and selecting
Start/Next Cal Step, you will be prompted with Operator step
command is not accepted at this time. The Next Cal Step command
is not accepted at this time.
15. When ready, Calibration Status will stop at STOP GAS. Switch off the
COe gas. Press OK when ready. Select Start/Next Cal Step to start
purging gas. The time to purge gas is specified by Purge Time.
2
2
5-7
OCX 8800
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
5-8
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
OCX 8800
Section 6 Maintenance and Service
Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 6-1
OCX 8800 Removal and Installation . . . . . . . . . . . . . . . . . page 6-1
Repair Sensor Housing . . . . . . . . . . . . . . . . . . . . . . . . . . . page 6-8
Repair Electronics Housing . . . . . . . . . . . . . . . . . . . . . . . . page 6-28
Replace Tube Fittings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 6-34
OVERVIEW This section contains the procedures to maintain and service the OCX 8800.
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.
OCX 8800 REMOVAL
ND INSTALLATION
A
It is recommended that the OCX 8800 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 may be
voltage up to 264 VAC.
Use the following procedures to remove or install the OCX 8800.
http://www..raihome.com
OCX 8800
Heater
Power Cable
Low O Test Gas
2
High O Test Gas
2
CO Test Gas
Instrument Air
(Reference Gas)
Test Gas
Reference Air
Dilution Air
Eductor Air
Instrument Air
Duct
Stack
AC Power
Input
Signal Cable
37390044
Sensor
Housing
Electronics
Housing
4-20 mA
Outputs
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
OCX with Remote Electronics
Figure 6-1. OCX with
Remote Electronics
Remove Sensor Housing
1. Turn off power to the system.
2. Shut off the test gasses at the cylinders and close the instrument air
valve.
3. Disconnect the calibration gas, reference air, eductor air, and dilution air
lines from the sensor housing, Figure 6-1.
6-2
Instruction Manual
BLU
ORG
YEL
RED
BLK
WHT
BLK
YEL
RED
BLU
WHT
BLK
BLK
GRN
BLK
BLK
BLK
ORG
WHT
RED
BLK
BRN
To
Ground
Screw
GRN
SENSOR HOUSING
Signal Cable
Heater Power Cable
T/C O2
T/C CO
T/C SB
EXC
CJC
CO REF
CO ACT
+
-
+
-
+
-
+
-
+
-
+
-
+
EXC
-
O2
HTR SB
2
2
1
-
+
HTR 02
2
1
HTR CO
1
NOTE: Wire colors shown are for cables
supplied by Emerson Process
Management.
IM-106-880ASB, Rev 1.2
July 2008
Figure 6-2. Sensor
Housing Terminals
OCX 8800
4. Remove the cover from the sensor housing to expose the sensor
housing terminal blocks, Figure 6-2.
5. Disconnect the signal cable from the O2 and T/C terminal blocks, and
from the CO and CJC terminal blocks.
6. Disconnect the heater power cable from the HTR terminal blocks.
7. If moving the sensor housing to another work site, disconnect and
remove the power and signal cables from the sensor housing.
8. Remove insulation to access the mounting bolts. Unbolt the sensor
housing from the stack and take it to a clean work area.
9. Allow the sensor housing to cool to a comfortable working temperature.
6-3
OCX 8800
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
Install Sensor Housing
1. Connect the test gas, reference air, eductor air, and dilution air lines to
the sensor housing.
2. Remove the sensor housing cover.
3. If removed, install the power and signal cables and the customer power
and signal conduits and wiring at the sensor housing.
4. Connect the signal cable to O
and CJC terminal blocks, Figure 6-2. Connect the heater power cable to
the HTR terminal blocks.
5. Refer to Figure 6-1 and make sure all test gas lines and electrical
connectors are complete.
6. Install the sensor housing cover.
7. Restore power to the system. Allow OCX to reach normal operating
temperature before installing in a hot process stack.
8. Insert and bolt the sensor housing in the stack and install insulation.
9. Turn on the test gases at the cylinders and open the instrument air
supply valve.
and T/C terminal blocks and to the CO
2
Remove Remote Electronics Housing
1. Turn off power to the system.
2. Shut off the test gases at the cylinders and close the instrument air
supply valve, Figure 6-1.
3. Disconnect the test gas and instrument air lines from the remote
electronics housing.
4. Remove the cover from the electronics housing to expose the
electronics housing terminal blocks, Figure 6-3.
5. Disconnect and remove the power leads from the AC power input
terminal block. Remove the ground lead from the ground stud.
6. Disconnect and remove the O
signal output terminal block.
7. If used, disconnect and remove the external relay leads from the alarm
output relay terminal block.
8. Disconnect the signal cable leads from O2 cell and thermocouple
connector (J4), and from COe and CJC connector (J5), Figure 6-4.
9. Disconnect the heater cable leads from the heater power connector
(J3).
10. If moving the electronics housing to another work site, disconnect and
remove the power and signal cables and customer wiring conduits from
the housing.
11. Remove the remote electronics housing from its mounting and move it
to a suitable work area.
and COe signal leads from the 4-20 mA
2
6-4
Instruction Manual
37390013
TOP VIEW
(1/2 SIZE)
Ground Stud
Earth Ground
Typical for Electronics and
Sensor Housing
NC
COM
NO
Alarm Output Relay
Terminal Block
#1
AOUT2+
AOUT2AOUT1-
AOUT1+
O Signal
2
COeSignal
{
{
Ground
Stud
4-20 mA Signal Output
Terminal Block
Power Port
3/4 NPT
Signal Port
3/4 NPT
External Tooth
Lockwasher
#1
G
G
Terminal
Block
N
G
L1
EMI Filter
Customer
Wiring
IM-106-880ASB, Rev 1.2
July 2008
Figure 6-3. Electronics Housing
Terminal Blocks
OCX 8800
6-5
OCX 8800
37390016
RED
BLK
WHT
GRN
BLK
BLK
BLU
BLK
YEL
BRN
RED
BLK
BLK
ORG
BLK
WHT
T/C CO+
T/C CO-
T/C SB+
T/C SBT/C O2+
T/C O2-
O2 CELL+
O2 CELL-
SHIELD
To
Ground
Screw
GRN
ELECTRONICS HOUSING
O2 Cell
& Thermocouple
Connector (J5)
COe Sensor
& CJC
Connector (J4)
EXC+
CO ACT+
CO ACT-
CO REF+
CO REFCJC+
CJCEXC-
Heater
Power Cable
Signal Cable
NOTE: Wire colors shown are for cables supplied
by Emerson Process Management.
1
#1
#1 #1
#1
#1
To Ground
Screw
SHLD
Heater Power
Connector (J3)
#1
2HTR SB
1HTR O
2
1HTR SB
2HTR CO
1HTR CO
2HTR O
2
WHT
ORG
BLU
BLK
YEL
RED
Figure 6-4. Remote Electronics
Housing Cable Connections
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
6-6
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
OCX 8800
Install Remote Electronics Housing
1. Mount remote electronics housing on wall or pipe within distance of
signal and heater cables in use.
2. Remove the electronics housing cover.
3. If removed, install the power and signal cables and the customer power
and signal conduits and wiring at the electronics housing.
4. Connect the signal cable leads to the O
connector (J4), and to the COe and CJC connector (J5), Figure 6-4.
5. Connect the heater cable leads to the heater power connector (J3).
6. Connect the line (L1 wire) to the L1 terminal, and the neutral (N wire) to
the N terminal on the AC power input terminal block, Figure 6-4.
7. Connect the ground lead to the ground stud. Secure the connection with
two nuts. Attach a separate ground lead (G wire) from the ground stud
to the G terminal on the power input terminal block.
8. If used, connect external relay leads to the alarm output relay terminal.
9. Connect the test gas and instrument air lines to the remote electronics
housing. Connect the calibration gas line and instrument air line to the
remote electronics housing.
10. Refer to Figure 6-1 and Figure 6-4. Make sure all test gas lines and
electrical connections are complete.
11. Install the cover on the electronics housing.
12. Turn on the test gasses at the cylinders and open the instrument air
valve.
13. Restore power to the system.
cell and thermocouple
2
6-7
OCX 8800
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
REPAIR SENSOR HOUSING
Sensor Housing Disassembly
Use the following procedures to remove damaged components from the OCX
8800 sensor housing and to install new replacement parts. Disassemble the
unit only as needed to replace damaged components. Use the assembly
procedures that apply to install replacement parts and reassemble the unit.
Remove Cover and Terminals Insulator
1. Loosen screw (1, Figure 6-5) and slide locking clip (2) away from cover.
Retighten screw (1).
2. With two hands or strap wrench, turn cover (3) counterclockwise to
loosen. Unthread and remove cover.
3. Inspect cover o-ring (4) for wear or damage. Replace cover o-ring if
damaged.
4. Unsnap terminal marking plates (5) and remove terminal insulator (6).
6-8
Instruction Manual
5
6
12
11
10
9
1
2
4
3
7
8
13
37390067
1. Screw
2. Locking Clip
3. Cover
4. O-ring
5. Marking Plate
6. Terminal Insulator
7. Reference Air Tube
8. Sensor Housing
9. Heater Strut Assembly
10. Gasket
11. Screw
12. Heater Clamp
13. Heater Rod
IM-106-880ASB, Rev 1.2
July 2008
Figure 6-5. Removal of O2 Cell
and Heater Strut Assembly
OCX 8800
6-9
OCX 8800
+ +
+
+
O2
Thermocouple Wires
ORG
RED
T/C O2
T/C CO
T/C SB
EXC
CJC
O
Cell Wires
2
O Heater Wires
2
Return Wire
O Cell and Heater Strut
Assembly
2
CO REF
CO ACT
Sensor Housing Terminals
+
-
HTR 02
HTR SB
2
GRN
2
1
+
-
+
-
+
-
+
-
+
-
+
YEL
-
+
+
37390068
HTR 02
2
1
Sample Block
Heater Rods
HTR CO
1
EXC
-
Sample
Block
Thermo-
couple
Figure 6-6. O2 Cell,
Thermocouple, and
Heater Connections
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
6-10
Remove O
Remove Sample Block Heater Rods
1. Remove reference air tube (7, Figure 6-5) from sensor housing (8).
2. See Figure 6-6. Disconnect and tag O2 heater wires, O2 cell and return
wires, and thermocouple wires at the sensor housing terminals.
3. Remove the O2 cell and heater strut assembly (9, Figure 6-5) from
sensor housing (8). Remove and discard gasket (10).
1. Disconnect sample block heater rod wires from terminal block. Refer to
Figure 6-6.
Cell and Heater Strut Assembly
2
Instruction Manual
O2
RED
T/C O2
T/C CO
T/C SB
EXC
CJC
COe Sensor Wires
COe Heater Wires
COe Sensor
Assembly
CO REF
CO ACT
Sensor Housing Terminals
+
-
HTR 02
HTR SB
2
2
1
+
-
+
-
+
-
+
-
+
-
+
YEL
-
+
37390018
HTR 02
2
1
HTR CO
1
WHT
BLU
RED
RED
WHT
COe Thermocouple Wires
-
EXC
RED
BLU
CJC Sensor
NOTE: All wires
at these terminals
are in the CJC
current loop.
IM-106-880ASB, Rev 1.2
July 2008
Figure 6-7. COe Sensor,
Thermocouple, and Heater
Connections
OCX 8800
2. Loosen screws (11, Figure 6-5) and rotate heater clamps (12) to release
heater rods (13). One heater clamp secures each heater rod.
3. Slide sample block heater rods (13) out of housing (8).
Remove COe Sensor Assembly
1. Disconnect COe heater, thermocouple, and sensor wires from terminal
blocks. Refer to Figure 6-7.
2. Remove insulator (1, Figure 6-8).
6-11
OCX 8800
1
5
6
7
8
9
10
11
12
13
14
1. Insulator
2. Dilution Air Tube
3. COe Extractive Tube
4. Eductor Air Tube
5. COe Sensor Assembly
6. Eductor
7. Sensor Housing
8. COe Thermocouple
9. Heater Insulator
10. COe Band Heater
11. Sensor Holder
12. Eductor Elbow
13. Terminal Block Mounting
14. Eductor Holder
15. Tube Fitting
16. CJC Sensor
16
2
3
4
15
Figure 6-8. Removal of
COe Sensor Assembly
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
NOTE
For easier access, you may remove two screws from base of terminal block
mounting (13) and move terminal block assembly out of the way.
3. Remove tubes (2, 3, and 4) from COe sensor assembly (5), eductor
fittings (12 and 15), and sensor housing (7).
4. Unfasten bayonet connector of COe thermocouple (8) and remove
thermocouple.
5. Loosen clamp screw of COe band heater (9) until heater rotates freely
on sensor holder (11).
6-12
Instruction Manual
37390035
Sensor
Holder
Flat
Matchmark
Straightedge
Matchmark
IM-106-880ASB, Rev 1.2
July 2008
Figure 6-9. Alignment of
COe Sensor Assembly
OCX 8800
6. See Figure 6-9. Using straightedge on the sensor holder flat, as shown,
matchmark upper flange of sensor housing to show correct alignment of
sensor holder.
7. With one wrench holding eductor elbow (12, Figure 6-8), and one
wrench on flats of sensor holder (11), unthread and remove COe sensor
assembly (5). Do not allow eductor elbow to turn.
8. Slide band heater (10) and heater insulator (9) from sensor holder (11).
6-13
OCX 8800
37390036
EductorFlat
Matchmark
Straightedge
Figure 6-10. Eductor Alignment
Matchmarks
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
Remove Eductor
The O2 cell and heater strut assembly (9, Figure 6-5) and the COe sensor
assembly (5, Figure 6-8) must be removed before you start this procedure.
1. Use straightedge to matchmark alignment of eductor flat and elbow, as
shown in Figure 6-10.
6-14
2. Unscrew terminal block mounting (13, Figure 6-8). Move terminal block
mounting away from eductor (6).
3. Unscrew eductor holder (14) with eductor (6) and fittings (12 and 15)
from sensor housing (7).
4. Clamp flats of eductor (6) in jaws of bench vise.
Use heat resistant gloves when removing mating parts from the eductor. The mating parts
are bonded with a thread sealing compound. The compound softens at 450°F (232°C). The
heated parts can cause severe burns.
5. Use a propane torch to heat the eductor (6) to 450°F (232°C), minimum.
Apply the heat near the screw threads.
6. While heating the eductor (6), use wrench to apply removal torque to
elbow (12), eductor holder (14), or tube fitting (15) until the thread
sealant softens. Remove mating parts (12, 14, and 15).
7. Use MEK or methylene chloride solvent to clean thread sealant residue
from the pipe threads of the mating parts. Refer to applicable MSDS
sheet for solvent handling precautions.
Instruction Manual
37390048
1
2
3
4
1. Sensor Housing
2. Sample Tube
3. Exhaust Tube
4. In Situ Filter
IM-106-880ASB, Rev 1.2
July 2008
OCX 8800
Figure 6-11. Removal of Sample
and Exhaust Tubes
Remove Sample and Exhaust Tubes
Use heat resistant gloves when removing the probe tube or exhaust tube. The tubes are
bonded with a thread sealing compound. The compound softens at 450°F (232°C). The
heated parts can cause severe burns.
1. Secure the sensor housing (1, Figure 6-11) in soft (plastic, wood, or
brass) vice jaws.
2. Use a propane torch to heat the sample tube (2) or exhaust tube (3) to
450°F (232°C), minimum. Apply the heat near the thr eaded end of the
tube.
3. While heating the tube, use a pipe wrench to apply removal torque to
part being removed. Apply torque until the pipe thread sealant softens.
Remove and discard the used sample tube (2), exhaust tube (3), or
in-situ filter (4).
4. Use MEK or methylene chloride solvent to clean thread sealant residue
from the internal pipe threads in the housing. Refer to applicable MSDS
sheet for solvent handling precautions.
6-15
OCX 8800
37390032
10
11
12
4
6
7
8
9
3
5
2
1
1. Screw
2. O Cell
3. Heater Tube
4. Contact/
Thermocouple
Assembly
5. Gasket
6. Screw
7. Lockwasher
8. Return Wire
9. Heater Strut
Assembly
10. Spring Clip
11. Spring
12. Strut Bracket
2
Test Gas
Passage
Holes
Figure 6-12. O2 Cell, Heater,
and Thermocouple, Exploded
View
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
Do not remove the O2 cell unless you are certain it needs to be replaced. Removal may
damage the cell and platinum pad. Remove the O2 cell for cell replacement only.
Disassemble O
Cell and Heater Strut Assembly
2
Do not attempt to replace the O2 cell until all other possibilities for poor
performance have been considered. If cell replacement is needed, order the
O2 cell replacement kit (Refer to Section 8, Replacement Parts).
The O2 cell replacement kit contains an O2 cell and flange assembly, gaskets,
socket head cap screws, and anti-seize compound. The items are carefully
packaged to preserve precise surface finishes.
Do not remove items from the package until they are ready to be used.
1. Remove the four allen cap screws (1, Figure 6-12) from the O2 cell (2).
Remove the O2 cell. The cell flange has a notch that may be used to
gently pry the flange away from heater tube (3).
NOTE
The pad on the end of contact/thermocouple assembly (4) will sometimes
fuse to the O2 cell (2).
2. If the O2 cell is fused to the contact pad, push the O2 cell back into the
heater tube (against spring pressure) and quickly twist the O2 cell. The
cell and contact pad should separate. If the contact pad stays fused to
the cell, a new contact/thermocouple assembly (4) must be installed.
3. Remove and discard gasket (5). Clean the mating surface of heater
tube (3). Remove burrs and raised surfaces with a block of wood and
crocus cloth.
6-16
Use care when handling contact and thermocouple assembly. The ceramic rod in this
assembly is fragile.
4. Remove screws (6), lockwashers (7), return wire (8), and heater strut
assembly (9).
5. If replacing contact and thermocouple assembly (4), use a pencil to
mark location of spring clip (10) before removing. Squeeze tabs on
spring clip to remove. Retain spring clip and spring (11); replace if
damaged.
6. While carefully handling new contact and thermocouple assembly (4)
lay old assembly next to new one. Transfer match marks to new
assembly.
7. Carefully guide new contact and thermocouple assembly (4) through
strut bracket (12), spring (11), and spring clip (10) until spring clip
reaches pencil mark.
Instruction Manual
37390030
8
9
4
5
6
1
2
3
7
1. Screw
2. Lockwasher
3. COe Sensor
4. Sensor Holder
5. Gasket
6. Thermocouple Adapter
7. Pre-Heater
8. Plug
9. Stainless Steel Balls
IM-106-880ASB, Rev 1.2
July 2008
Figure 6-13. COe Sensor,
Exploded View
OCX 8800
Disassemble COe Sensor Assembly
1. Carefully remove screws (1, Figure 6-13), lockwashers (2), and COe
sensor (3) from sensor holder (4). Remove and discard gasket (5).
2. If damaged, use the following procedure to remove thermocouple
adaptor (6) from sensor holder (4):
a. Use a propane torch to heat the thermocouple adaptor to 450°F
(232°C), minimum.
b. While heating, use a flat-head screwdriver to apply removal torque.
Apply torque until the pipe thread sealant softens. Remove and
discard the thermocouple adaptor.
c. Use MEK or methylene chloride solvent to clean thread sealant
residue from the internal pipe threads in the sensor holder. Refer to
applicable MSDS sheet for solvent handling precautions.
6-17
OCX 8800
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
Always remove the stainless steel balls (approximately 200) from sensor holder before
removing or installing pre-heater. Turning pre-heater in the sensor holder with the stainless
steel balls in place will cause permanent damage to the pre-heater.
3. If pre-heater (7) is to be removed, clamp flats of sensor holder (4) in vise
jaws with plug (8) pointing up. Remove plug. Unclamp sensor holder
and pour stainless steel balls (9) into a container.
NOTE
Pre-heater should only be removed when pre-heater or sensor holder is
damaged. If removal is not required, leave the pre-heater installed in the
sensor holder.
4. Unthread and remove pre-heater (7).
5. Use a cleaning solvent to thoroughly clean stainless steel balls (9) and
pre-heater chamber in sensor housing (4). Refer to applicable MSDS
sheet for solvent handling precautions.
Sensor Housing Assembly
Assemble COe Sensor Assembly
Always remove the stainless steel balls (approximately 200) from sensor holder before
removing or installing pre-heater. Turning pre-heater in the sensor holder with the stainless
steel balls in place will cause permanent damage to the pre-heater.
1. If pre-heater (7, Figure 6-13) was removed, apply pipe thread sealant
(Loctite #567) to the external pipe threads of pre-heater (7) and plug (8).
Do not apply sealant to the first turn of the pipe threads.
2. Clamp flats of sensor holder (4) in vise jaws with pre-heater port
pointing up.
3. Install and tighten pre-heater (7). Align pre-heater to flat of sensor
holder (4) as shown in Figure 6-14.
4. Invert sensor holder (4, Figure 6-13) in vise and pour stainless steel
balls (9) into plug port. Press down on stainless steel balls and tap
sensor holder with plastic hammer to compact balls in pre-heater
chamber.
5. Install and tighten plug (8).
6-18
Use care when installing the combustibles (COe) sensor. The RTD elements are fragile and
correct alignment in sensor holder is required for proper OCX operation.
6. Lubricate and install COe sensor gasket (5). Apply anti-seize compound
to threads of screws (1).
Instruction Manual
37390034
Pre-Heater
Flat
COe
SENSORASSEMBLY
T
OP VIEW
Sensor
Holder
Flat
COeSensor
Flat
Sensor
Holder
Flat
Sensor
Holder
2to2-1/4in.
(51to57mm)
THERMOCOUPLE
IM-106-880ASB, Rev 1.2
July 2008
Figure 6-14. COe Sensor and
Pre-Heater Alignment
OCX 8800
7. Install COe sensor (3), lockwashers (2), and screws (1). Rotate flat of
COe sensor (3) to center of sensor holder (4).
8. Align COe sensor flat parallel to sensor holder flat, as shown in
Figure 6-14. Tighten screws (1, Figure 6-13).
9. If replacing thermocouple adaptor (6), apply anti-seize to the pipe
threads. Install and tighten thermocouple adaptor.
Assemble O
Sensor and Heater Strut Assembly
2
1. See Figure 6-12. Assemble O2 cell (2), gasket (5), and heater tube (3).
Make sure the test gas passage holes line up with each other in all
components.
2. Apply a small amount of anti-seize compound to the screw threads and
use screws (1) to secure assembly. Torque to 35 in-lbs (4 N·m).
3. Carefully slide O2 heater strut assembly (9) into heater tube (3).
4. Press down on the back plate of strut bracket (12) to ensure spring (11)
tension is present to hold contact pad against O2 cell (2).
5. Secure strut bracket (12) and return wire (8) with four screws (6) and
lockwashers (7). Make sure return wire (8) is tightly fastened. This is the
ground side connection for the O2 cell.
Install Sample and Exhaust Tubes
1. See Figure 6-11. Apply pipe thread sealant (Loctite #567) to the
replacement sample tube (2) or exhaust tube (3) pipe threads. Do not
apply sealant to the first turn of the pipe threads.
2. Thread the sample tube (2) or exhaust tube (3) into the housing (1). Use
a pipe wrench to tighten the tube.
3. If used, install and tighten in-situ filter (4).
6-19
OCX 8800
37390047
1
5
6
7
8
9
10
11
12
13
14
1. Insulator
2. Dilution Air Tube
3. COe Extractive Tube
4. Eductor Air Tube
5. COe Sensor Assembly
6. Eductor
7. Sensor Housing
8. COe Thermocouple
9. Heater Insulator
10. COe Band Heater
11. Sensor Holder
12. Eductor Elbow
13. Terminal Block Mounting
14. Eductor Holder
15. Tube Fitting
16. CJC Sensor
16
2
3
4
15
Figure 6-15. Installation of
Eductor and COe Sensor
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
Install Eductor
If installed, the O2 cell and heater strut assembly (9, Figure 6-5) must be
removed from sensor housing (8), before you install the eductor.
1. Apply pipe thread sealant (Loctite #567) to the external pipe threads of
eductor (6, Figure 6-15). Do not apply sealant to the first turn of the pipe
threads.
6-20
Instruction Manual
37390036
EductorFlat
Matchmark
Straightedge
IM-106-880ASB, Rev 1.2
July 2008
Figure 6-16. COe Sensor
Parts Alignment
OCX 8800
2. Install and tighten eductor (6) in eductor holder (14).
3. Install and tighten elbow (12) on eductor (6). Male port of elbow must
point up and be in line with long axis of eductor.
4. Apply anti-seize compound to the external pipe threads of eductor
holder (14).
5. Install and tighten eductor holder (14) in sensor housing (7). Align
eductor with matchmarks, as shown in Figure 6-16.
6-21
Instruction Manual
37390058
0.37 in.
(9,4 mm)
COe Sensor
Band Heater
Insulator
IM-106-880ASB, Rev 1.2
OCX 8800
Install COe Sensor Assembly
Figure 6-17. Band Heater Height 1. Apply pipe thread sealant (Loctite #567) to the exposed pipe threads
of eductor elbow (12, Figure 6-15). Do not apply sealant to the first turn
of the pipe threads.
2. Screw sensor holder (11) onto eductor elbow (12).
3. With wrenches on eductor elbow (12) and on flats of sensor holder (11),
tighten sensor holder. Do not allow eductor elbow to turn.
4. Tighten sensor holder (11) to align outside flat with matchmark on
sensor housing flange, as shown in Figure 6-18.
The heater insulator prevents current leakage between the band heater and the sensor
holder. Failure to properly install the insulator may cause the device to trip a ground fault
interrupt circuit.
5. Wrap heater insulator (9) around sensor holder (11). Make sure the
insulator joint lines up with the band gap of the COe band heater (10).
6. Slide COe band heater (10, Figure 6-15) up onto sensor holder (11). Do
not tighten the band heater at this time. Heater must rotate freely around
sensor holder.
7. Check for proper height of COe heater thermocouple (Figure 6-14).
Thread bayonet connector up or down to adjust height.
8. Install and fasten thermocouple (8, Figure 6-15).
9. Position band heater as shown in Figure 6-17 and Figure 6-18 and
tighten band heater clamp screw. The heater insulator (9) end joint must
line up with the band gap of the COe band heater (10).
July 2008
6-22
Instruction Manual
37390035
Sensor
Holder
Flat
Matchmark
Straightedge
Matchmark
IM-106-880ASB, Rev 1.2
July 2008
Figure 6-18. COe Sensor
Holder Alignment
OCX 8800
6-23
OCX 8800
O2
RED
T/C O2
T/C CO
T/C SB
EXC
CJC
COe Sensor Wires
COe Heater Wires
COe Sensor
Assembly
CO REF
CO ACT
Sensor Housing Terminals
+
-
HTR 02
HTR SB
2
2
1
+
-
+
-
+
-
+
-
+
-
+
YEL
-
+
37390018
HTR 02
2
1
HTR CO
1
WHT
BLU
RED
RED
WHT
COe Thermocouple Wires
-
EXC
RED
BLU
CJC Sensor
NOTE: All wires
at these terminals
are in the CJC
current loop.
Figure 6-19. COe Sensor,
Thermocouple, and Heater
Connections
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
10. Reconnect the COe sensor, thermocouple, and heater wires at the
sensor housing terminal blocks. Refer to Figure 6-19.
11. Install and fasten the COe insulator (1, Figure 6-15) around COe sensor
assembly (5). All wiring must remain outside of the insulator.
12. If terminal block mounting (13, Figure 6-15) was moved, reinstall with
two base mounting screws.
6-24
Instruction Manual
5
6
12
11
10
9
1
2
4
3
7
8
13
37390067
1. Screw
2. Locking Clip
3. Cover
4. O-ring
5. Marking Plate
6. Terminal Insulator
7. Reference Air Tube
8. Sensor Housing
9. Heater Strut Assembly
10. Gasket
11. Screw
12. Heater Clamp
13. Heater Rod
IM-106-880ASB, Rev 1.2
July 2008
Figure 6-20. Installation of O2 Cell
and Heater Strut Assembly
OCX 8800
Install Sample Block Heater Rods
1. Before installing sample block heater rods (13, Figure 6-20), evenly coat
the heater rods with Watlube heater release agent.
6-25
OCX 8800
+ +
+
+
O2
Thermocouple Wires
ORG
RED
T/C O2
T/C CO
T/C SB
EXC
CJC
O Cell Wires
2
O Heater Wires
2
Return Wire
O Cell and Heater Strut
Assembly
2
CO REF
CO ACT
Sensor Housing Terminals
+
-
HTR 02
HTR SB
2
GRN
2
1
+
-
+
-
+
-
+
-
+
-
+
YEL
-
+
+
37390068
HTR 02
2
1
Sample Block
Heater Rods
HTR CO
1
EXC
-
Sample
Block
Thermo-
couple
Figure 6-21. O2 Cell,
Thermocouple, and
Heater Connections
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
6-26
2. Install the heater rods (13), heater clamps (12), and screws (11).
3. Reconnect the heater rod leads at the sensor housing terminal blocks,
(Figure 6-21).
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
OCX 8800
Install O2 Cell and Heater Strut Assembly
1. Rub a small amount of anti-seize compound on both sides of new
gasket (10, Figure 6-20).
2. Apply anti-seize compound to threads of O2 cell and heater strut
assembly (9) and sensor housing (8).
Stripped threads on the O2 cell and heater strut assembly can allow gas leakage. Gas
leakage can affect the O2 measurements and calibration. Avoid over-tightening the O2 cell
and heater strut assembly.
3. Install O
cell and heater strut assembly (9) in sensor housing (8). Snug
2
up, but do not over-tighten the assembly.
4. Reconnect the lead wires from O2 cell, heater, and thermocouple to the
sensor housing terminal blocks. Refer to Figure 6-21.
5. Install reference air tube (7, Figure 6-20) in sensor housing (8). Make
sure that the open end of reference air tube extends into heater tube of
O2 cell and heater strut assembly (9).
Install Terminals Insulator and Cover
1. Install insulator (6, Figure 6-20) over uppermost terminal blocks.
Position one side of insulator against terminal blocks and snap terminal
marking plate (5) to mating stand-off.
2. Position opposite side of insulator (6) and secure with related marking
plate (5).
3. If removed, install cover gasket (4). Screw cover (3) onto sensor
housing (8). Tighten cover firmly.
4. Align locking clip (2) with gap between cover ribs.
5. Loosen screw (1) and slide locking clip (2) fully into gap between cover
ribs. Retighten screw (1).
Sensor Housing Leak Test
1. Install 1/4 NPT cap on dilution air inlet fitting. Install a 1/4 NPT cap on
sample tube (2, Figure 6-11) or plug 1/4 NPT sample inlet port. Capped
or plugged ports must be air tight.
2. If not in place, install exhaust tube (3, Figure 6-11) in exhaust port
according to the instructions provided.
3. Connect a calibrated manometer to the CAL GAS inlet port.
4. Connect and apply clean instrument air at 35 psig (241 kPa gage) to the
instrument air inlet fitting.
5. Observe the manometer reading. The reading should be from 10 to 13
inches, Water Column. Locate and correct leaks if the reading is less
than 10 inches WC.
6-27
OCX 8800
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
REPAIR ELECTRONICS HOUSING
Electronics Housing Disassembly
Use the following procedures to remove damaged components from the OCX
8800 electronics housing and to install new replacement parts. Disassemble
the unit only as needed to replace damaged components. Use the assembly
procedures that apply to install replacement parts and reassemble the unit.
Remove Cover
1. See Figure 6-22. Loosen screw (1) and slide locking clip (2) away from
cover (3). Retighten screw (1).
2. With two hands or strap wrench, turn cover (3) counterclockwise to
loosen. Unthread and remove cover.
3. Inspect cover gasket (4) for wear or damage. Replace cover gasket if
damaged.
Remove Flash PROM
Electrostatic discharge (ESD) protection is required to avoid damage to the electronic
circuits.
1. Locate Flash PROM access port in electronics stack (5, Figure 6-22).
2. Use suitable IC removal tool to remove Flash PROM (6).
6-28
Instruction Manual
37390037
1. Screw
2. Locking Clip
3. Cover
4. O-ring
5. Electronics Stack
6. Flash PROM
7. thru 12. Not used
13. Screw
14. Lockwasher
15. Solenoid Valve (3 way)
16. Solenoid Valve
1
2
3
4
5
6
13
14
15
16
IM-106-880ASB, Rev 1.2
July 2008
Figure 6-22. Removal/Installation of
Electronics Housing Components
OCX 8800
Remove Electronics Stack
1. Unplug power cable, signal cable, and solenoid lead connectors from
terminals of electronics stack (5, Figure 6-22).
2. Remove two screws (13) and lockwashers (14).
3. Remove electronics stack (5).
6-29
OCX 8800
1
2
3
37390083
Brown
Blue
Green
Green
Green
Brown
Blue
Figure 6-23. Removal/
Installation of EMI Filter
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
Remove Solenoid Valves
1. Disconnect solenoid leads from mating terminal connector.
2. Remove top nut of solenoid valve (15 or 16, Figure 6-22).
3. Remove the solenoid coil assembly and washer.
4. Unthread and remove solenoid valve base.
Remove EMI Filter and Terminal Block
1. Disconnect EMI filter wiring (Figure 6-23) at terminal block (3).
2. Disconnect EMI filter wiring at AC power input terminal block on
electronic stack.
3. Unbolt and remove EMI filter (1) from electronic stack.
4. Remove ground wire (2) from terminal block (3).
5. Unbolt and remove terminal block (3) from electronic stack.
Electronics Housing
ssembly
A
6-30
Install EMI Filter and Terminal Block
1. Install replacement EMI filter (1, Figure 6-23) and/or terminal block (3)
on electronic stack.
2. Refer to wiring details in Figure 6-23. Connect EMI filter wiring and
ground wire (2) at terminal block (3).
3. Connect EMI filter wiring at AC power input terminal block on electronic
stack.
Instruction Manual
37390060
Flash
PROM
Access
Port
Corner
Bevel
IM-106-880ASB, Rev 1.2
July 2008
OCX 8800
Install Solenoid Valves
1. Disassemble replacement solenoid valve (15 or 16, Figure 6-22).
2. Install new solenoid valve base. Be careful not to overtighten.
3. Install new washer and solenoid coil assembly and secure with nut.
4. Connect the solenoid leads to the proper terminations on the solenoid
power terminal block (Figure 6-26).
Install Electronics Stack
1. Install electronics stack (5, Figure 6-22) and secure with lockwashers
(14) and screws (13).
2. See Figure 6-25 and Figure 6-26. Reconnect power cable, signal cable,
and solenoid lead connectors to electronics stack terminals.
Figure 6-24. Flash PROM
Alignment
Install Flash PROM
Electrostatic discharge (ESD) protection is required to avoid damage to the electronic
circuits.
1. Locate Flash PROM access port in electronics stack (5, Figure 6-22).
2. See Figure 6-24. Align Flash PROM (6, Figure 6-22) with mating
receptacle in access port of electronics stack as shown. Flash PROM
corner bevel must be in upper left corner of receptacle.
3. Install Flash PROM (6).
6-31
OCX 8800
37390016
RED
BLK
WHT
GRN
BLK
BLK
BLU
BLK
YEL
BRN
RED
BLK
BLK
ORG
BLK
WHT
T/C CO+
T/C CO-
T/C SB+
T/C SBT/C O2+
T/C O2-
O2 CELL+
O2 CELL-
SHIELD
To
Ground
Screw
GRN
ELECTRONICS HOUSING
O2 Cell
& Thermocouple
Connector (J5)
COe Sensor
& CJC
Connector (J4)
EXC+
CO ACT+
CO ACT-
CO REF+
CO REFCJC+
CJCEXC-
Heater
Power Cable
Signal Cable
NOTE: Wire colors shown are for cables supplied
by Emerson Process Management.
1
#1
#1 #1
#1
#1
To Ground
Screw
SHLD
Heater Power
Connector (J3)
#1
2HTR SB
1HTR O
2
1HTR SB
2HTR CO
1HTR CO
2HTR O
2
WHT
ORG
BLU
BLK
YEL
RED
Figure 6-25. Electronics Housing
Cable Connections
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
6-32
Instruction Manual
37390033
Instrument Air
SOL 1
CO Test Gas
High O Test Gas
2
Low O Test Gas
2
SOL 4
SOL 3
SOL 2
TOP VIEW
SOL 4
SOL 3
SOL 2
SOL 1
SOL 3
#1
#1
IM-106-880ASB, Rev 1.2
July 2008
Figure 6-26. Solenoid
Power Terminals
OCX 8800
Install Cover
1. If removed, install cover gasket (4, Figure 6-22). Screw cover (3) onto
electronics housing. Tighten cover firmly. Align locking clip (2) with gap
between cover ribs.
2. Loosen screw (1) and slide locking clip (2) fully into gap between cover
ribs. Retighten screw (1).
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OCX 8800
Instruction Manual
IM-106-880ASB, Rev 1.2
July 2008
REPLACE TUBE FITTINGS
The OCX transmitter housings have special tube fittings that, if clogged or
damaged, must be replaced with the same type of fitting. The special tube
fittings have alpha or numeric codes etched on the fitting. Unetched tube
fittings are standard 1/4 inch, stainless steel fittings.
‘E’ Type Fitting
The ‘E’ type fitting is an eductor drive air fitting for the OCX 8800 general
purpose sensor housing. It is a 1/8 inch tube fitting with a built-in 0.011
inch restrictor orifice. It seats in a threaded base port inside the housing.
‘R’ Type Fitting
The ‘R’ type fitting is a reference air line fitting for the general purpose and
hazardous area sensor housings. This is a 1/4 inch tube fitting with a
built-in 0.007 inch restrictor orifice.
Remove Tube Fittings The OCX construction includes pipe thread sealant to seal fittings in all ports
at pass through to an outer wall of the instrument housing base. Use the
th
following instructions to loosen and remove tube fittings that are secured with
pipe thread sealant.
Use heat resistant gloves when removing a damaged tube fitting. The pipe threads are
bonded with a pipe thread sealant. The thread sealant softens at 450°F (232°C). The
heated parts can cause severe burns.
1. Secure sensor housing (1, Figure 6-27) or electronics housing (2) in soft
(plastic, wood, or brass) vice jaws.
2. To soften the pipe thread sealant, use a propane torch to heat the tube
fitting (3, 4, or 5) to 450°F (232°C), minimum.
3. While heating the tube fitting, use a wrench to apply removal torque until
the pipe thread sealant softens. Remove and discard the used fitting.
4. Use MEK or methylene chloride solvent to clean thread sealant residue
from the internal pipe threads in the housing. Refer to applicable MSDS
sheet for solvent handling precautions.
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