Operator`s Manual

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Operator`s Manual | Manualzz
SS2100 H2S Analyzer
Hardware Installation and Maintenance
Manual
Hardware Installation and Maintenance
Manual
OXY4400 Oxygen Analyzer
Operator’s Manual
P/N 4900002060 rev C
OXY4400 Oxygen
Analyzer
Operator’s Manual
Use this manual with the
Oxyview Firmware CD
Products of
4333 W Sam Houston Pkwy N, Suite 100
Houston, TX 77043-1223
Tel: 800.619.2861
Fax: 713.856.6623
www.spectrasensors.com
Copyright © 2015 SpectraSensors, Inc. No part of this manual may be reproduced in
whole or in part without the express written permission of SpectraSensors, Inc.
SpectraSensors reserves the right to change product design and specifications at any
time without prior notice.
Revision History
Revision
Engineering Order
Date
A
-
10/22/09
B
EO15162
3/25/13
C
ECR16145
4/9/15
TABLE
OF
CONTENTS
List of Figures . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .v
List of Tables . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . vii
1: Introduction
Who Should Read This Manual . . . . . . . . . . . . . . . . . . . . . . .
How to Use This Manual. . . . . . . . . . . . . . . . . . . . . . . . . . . .
General Warnings and Cautions . . . . . . . . . . . . . . . . . . . .
Conventions Used in this Manual . . . . . . . . . . . . . . . . . . .
SpectraSensors Overview . . . . . . . . . . . . . . . . . . . . . . . . . .
About the OXY4400 Analyzer . . . . . . . . . . . . . . . . . . . . . . . .
Sensor Characteristics of Oxygen-Sensitive Sensors . . . . .
Temperature . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Cross-sensitivity . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Response Time . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Housing for Oxygen in Natural Gas (DP-BOS3-L5-ST5-NOP)
Trace Oxygen Probe . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Schematic drawing for the Trace Oxygen Probe . . . . . .
Safety Guidelines . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Getting Familiar with the Analyzer . . . . . . . . . . . . . . . . . . . .
Required Basic Equipment. . . . . . . . . . . . . . . . . . . . . . . .
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1-1
1-1
1-1
1-2
1-2
1-2
1-2
1-3
1-3
1-3
1-4
1-4
1-5
1-5
1-6
1-7
2: Installation
What Should be Included in the Shipping Box . . . . . . .
Inspecting the Analyzer . . . . . . . . . . . . . . . . . . . . . . .
Installing the Analyzer. . . . . . . . . . . . . . . . . . . . . . . .
Hardware and Tools for Installation. . . . . . . . . . . . . . .
Hardware . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Tools . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Mounting the Analyzer. . . . . . . . . . . . . . . . . . . . . . . .
To mount the analyzer . . . . . . . . . . . . . . . . . . . . .
Connecting Electrical Power to the Analyzer . . . . . . . . .
To connect electrical power to the analyzer . . . . . . .
Connecting Electrical Power to the Enclosure Heater . . .
To connect electrical power to the enclosure heater .
Connecting the Analog Outputs/Analog Inputs . . . . . . .
To connect the analog outputs/analog inputs . . . . .
Connecting the Gas Lines . . . . . . . . . . . . . . . . . . . . .
To connect the sample supply line . . . . . . . . . . . . .
To connect the sample bypass/sample return . . . . .
Installing the Temperature (RTD) Probe . . . . . . . . . . .
Installing the Oxygen Probe . . . . . . . . . . . . . . . . . . . .
Connecting the Calibration Gas (Optional) . . . . . . . . . .
Conditioning the SCS Tubing . . . . . . . . . . . . . . . . . . .
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. 2-1
. 2-1
. 2-1
. 2-2
. 2-2
. 2-2
. 2-2
. 2-3
. 2-3
. 2-4
. 2-5
. 2-5
. 2-6
. 2-7
. 2-7
. 2-8
. 2-8
. 2-9
2-10
2-14
2-14
............
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............
............
............
process sample.
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3: Sample Conditioning System (SCS) Operation
About the SCS . . . . . . . . . . . . . . . . . . . . .
Checking the SCS Installation. . . . . . . . . . .
To perform SCS installation checks . . . .
Starting up the SCS . . . . . . . . . . . . . . . . .
To prepare for SCS startup . . . . . . . . . .
To start up the sample bypass stream on
OXY4400 Operator’s Manual
3-1
3-2
3-2
3-2
3-2
3-2
i
Oxygen Analyzer
To start up the analyzer on process sample . . . . . . . . . . . . . . . . . . . . . . . . 3-3
Shutting Down the SCS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-3
4: Configuration
Powering up the Instrument . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-1
Menu Selection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-2
Pre-Calibration Procedure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-3
Sensor Type . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-3
Sensor Constants. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-5
Measurement . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-6
Sampling Rate . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-6
Temperature . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-6
Sensor Protect . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-8
Signal Averaging . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-8
Oxygen Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-8
Signal Intensity . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-9
Calibration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-9
Status . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-10
Calibrate . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-10
Calibration of the oxygen sensor with Temperature compensation
(Preferred Method) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-11
Calibration of the oxygen sensor without Temperature compensation . . . 4-14
Calibration of the oxygen sensor with Manual Temperature compensation 4-15
Data Logging . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-17
Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-18
Status . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-18
Analog Out . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-18
Analog In . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-20
Clock/Date . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-21
Display . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-21
Reset Config.. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-21
Diag & Test . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-21
System . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-22
Outputs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-22
Inputs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-22
5: PC Operations
Installing the Software . . . . .
Function and Description . . . .
Menu Bar . . . . . . . . . . . .
Menu Bar Definitions . .
Control Bar . . . . . . . . . . .
Control Buttons . . . . . . . .
Measurement Assistant
Calibration Assistant . .
Data Logging . . . . . . .
Settings . . . . . . . . . . . . .
Instrument Info . . . . .
Analog Output . . . . . .
Analog Input . . . . . . .
LED Intensity . . . . . . .
Oxygen Unit . . . . . . . .
Warning Lights . . . . . . . .
Graphical Display Window .
Zoom function . . . . . .
Status Bar . . . . . . . . .
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. 5-1
. 5-2
. 5-3
. 5-4
. 5-5
. 5-5
. 5-6
. 5-7
. 5-7
. 5-8
. 5-8
. 5-8
. 5-9
5-10
5-12
5-13
5-14
5-14
5-14
4900002060 rev. C 4-9-15
Table of Contents
Appendix A: Specifications
Technical Notes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . A-2
Spare Parts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . A-13
Appendix B: Troubleshooting
Error Codes . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Decoding example . . . . . . . . . . . . . . . . . . . . .
Recommendations for Correct Measurement . . . . .
Signal Drifts due to Oxygen Gradients . . . . . . .
Signal Drifts due to Temperature Gradients . . .
Signal Drift due to Photo-decomposition . . . . . .
Signal Drift due to Too Much Ambient Light. . . .
Oxygen Conversion Formula. . . . . . . . . . . . . . . . .
Sensor Safety. . . . . . . . . . . . . . . . . . . . . . . . . . .
Performance Improvement. . . . . . . . . . . . . . . . . .
Replacing the Oxygen Probe . . . . . . . . . . . . . .
To replace the OXY4400 probe: . . . . . . . . . . . .
Periodic SCS Maintenance . . . . . . . . . . . . . . . . . .
Regular SCS Status Check . . . . . . . . . . . . . . .
To check filters . . . . . . . . . . . . . . . . . . . . . . .
Service Contact . . . . . . . . . . . . . . . . . . . . . . . . .
Customer Service. . . . . . . . . . . . . . . . . . . . .
Return Material Authorization . . . . . . . . . . . . .
Packing and Storage . . . . . . . . . . . . . . . . . . . . . .
To prepare the analyzer for shipment or storage
Storage . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Disclaimers . . . . . . . . . . . . . . . . . . . . . . . . . . . .
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. . . . . . . . . . . . . . . . . . . B-2
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. . . . . . . . . . . . . . . . . . . B-3
. . . . . . . . . . . . . . . . . . . B-3
. . . . . . . . . . . . . . . . . . . B-3
. . . . . . . . . . . . . . . . . . . B-3
. . . . . . . . . . . . . . . . . . . B-4
. . . . . . . . . . . . . . . . . . . B-4
. . . . . . . . . . . . . . . . . . . B-4
. . . . . . . . . . . . . . . . . . . B-5
. . . . . . . . . . . . . . . . . . . B-5
. . . . . . . . . . . . . . . . . . . B-6
. . . . . . . . . . . . . . . . . . . B-7
. . . . . . . . . . . . . . . . . . . B-7
. . . . . . . . . . . . . . . . . . . B-7
. . . . . . . . . . . . . . . . . . . B-7
. . . . . . . . . . . . . . . . . . . B-8
. . . . . . . . . . . . . . . . . . . B-8
. . . . . . . . . . . . . . . . . . . B-8
. . . . . . . . . . . . . . . . . . . B-9
. . . . . . . . . . . . . . . . . . . B-9
Index . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Index-1
4900002060 rev. C 4-9-15
iii
Oxygen Analyzer
THIS PAGE INTENTIONALLY LEFT BLANK
iv
4900002060 rev. C 4-9-15
LIST
Figure 1–1.
OF
FIGURES
Figure
Figure
Figure
Figure
1–2.
1–3.
1–4.
1–5.
Response of the BOS3 sensor toward changes
oxygen concentration . . . . . . . . . . . . . . . . .
Standard fiber-optic oxygen sensors fittings. .
Trace oxygen probe . . . . . . . . . . . . . . . . . .
Trace oxygen probe schematic . . . . . . . . . . .
OXY4400 analyzer . . . . . . . . . . . . . . . . . . .
Figure
Figure
Figure
Figure
Figure
2–1.
2–2.
2–3.
2–4.
2–5.
RTD probe terminal connection. . . . . . . . . . . . .
RTD probe installed. . . . . . . . . . . . . . . . . . . . .
Removing protective plunger from oxygen probe
Inserting the oxygen probe into the OXY4400 . .
Oxygen probe installed . . . . . . . . . . . . . . . . . .
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Figure
Figure
Figure
Figure
Figure
Figure
Figure
4–1.
4–2.
4–3.
4–4.
4–6.
4–7.
4–8.
Analyzer LCD display. . . .
Main display view . . . . . .
Alternate display view . . .
Main menu. . . . . . . . . . .
Configuration menu . . . .
Analog Out: select Output
Diagnostic and test menu
Figure
Figure
Figure
Figure
Figure
Figure
5–1.
5–2.
5–3.
5–4.
5–5.
5–6.
OXY4400 Main window . . .
Control bar . . . . . . . . . . .
Measurement assistant . . .
Instrument info display . . .
Analog Output choice . . . .
Analog Input configuration.
Figure
Figure
Figure
Figure
A–1.
A–2.
A–3.
A–4.
Outline and mounting dimensions - panel mount . . . . . . . . . .
Sample system schematic - panel mount. . . . . . . . . . . . . . . .
Power and signal wiring diagram - panel mount . . . . . . . . . . .
Outline and mounting dimensions - Unheated
enclosure mounted . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Sample system schmatic - Unheated enclosure mounted . . . .
Power and signal wiring diagram - Unheated
enclosure mounted . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Outline and mounting dimension - Heated enclosure mounted
Sample system schematic - Heated enclosure mounted . . . . .
Power and signal wiring diagram - Unheated
enclosure mounted . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Figure A–5.
Figure A–6.
Figure A–7.
Figure A–8.
Figure A–9.
OXY4400 Operator’s Manual
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4-18
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4-21
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5-10
. . . A-4
. . . A-5
. . . A-6
. . . A-7
. . . A-8
. . . A-9
. . A-10
. . A-11
. . A-12
v
Oxygen Analyzer
THIS PAGE INTENTIONALLY LEFT BLANK
vi
4900002060 rev. C 4-9-15
LIST
OF
TABLES
Table 2–1.
Terminal layout and description . . . . . . . . . . . . . . . . . . . . . . . . . 2-5
Table 4–1.
Default sensor constants . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-6
Table A-1.
Table A–2.
OXY4400 analyzer specifications. . . . . . . . . . . . . . . . . . . . . . . . . A-1
Replacement parts for OXY4400 analyzer . . . . . . . . . . . . . . . . . A-13
Table B–1.
Table B–2.
Table B–3.
Potential instrument problems and their solutions. . . . . . . . . . . . . B-1
Error value definitions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . B-2
Sensor drift at 0% air saturation (0 ppb)
recording 3600, 50000 and 100000 data points . . . . . . . . . . . . . . B-3
OXY4400 Operator’s Manual
vii
Oxygen Analyzer
THIS PAGE INTENTIONALLY LEFT BLANK
viii
4900002060 rev. C 4-9-15
1 - INTRODUCTION
SpectraSensors’ OXY4400 product is a stand-alone fiber optic oxygen meter
based on fluorescence quenching technology that creates very stable,
internally referenced measured values. This technology enables a more flexible
use of oxygen sensors (also called optodes) in a variety of sensor fittings, if
required.
Who Should Read This Manual
This manual should be read and referenced by anyone installing, operating or
having direct contact with the analyzer.
How to Use This Manual
Take a moment to familiarize yourself with this Operator’s Manual by reading
the "Table of Contents".
There are a number of options and accessories available for the OXY4400
analyzers. This manual has been written to address the most common options
and accessories. Images, tables and charts have been included to provide a
visual understanding of the analyzer and its functions. Special symbols are also
used to provide the user with key information regarding the system
configuration and/or operation. Pay close attention to this information.
General Warnings and Cautions
Instructional icons are provided in this manual to alert the user of potential
hazards, important information and valuable tips. Following are the symbols
and associated warning and caution types to observe when servicing the
analyzer.
General notes and important information concerning the
installation and operation of the analyzer.
Warning statement for hazardous voltage. Contact may cause
electric shock or burn. Turn off and lock out system before
servicing.
Failure to follow all directions may result in damage or
malfunction of the analyzer.
OXY4400 Operator’s Manual
1–1
Oxygen Analyzer
Conventions Used in this Manual
In addition to the symbols and instructional information, this manual is created
with “hot links” to enable the user to quickly navigate between different
sections within the manual. These links include table, figure and section
references and are identified by a pointing finger cursor
when rolling
over the text. Simply click on the link to navigate to the associated reference.
SpectraSensors Overview
SpectraSensors, Inc. is a leading manufacturer of technologically advanced
electro-optic gas analyzers for the industrial process, gas distribution and
environmental monitoring markets. Headquartered in Houston, Texas,
SpectraSensors was incorporated in 1999 as a spin-off of the NASA/Caltech Jet
Propulsion Laboratory (JPL) for the purpose of commercializing space-proven
measurement technologies initially developed at JPL. SpectraSensors was
acquired by the Endress + Hauser Group in 2012 and remains a USA-based
technology manufacturer.
About the OXY4400 Analyzer
The OXY4400 is a stand-alone precision, temperature compensated system
enclosed in a NEMA 4X stainless steel case. The rugged design and low power
consumption makes the OXY4400 ready for an indoor or outdoor application in
Class 1, Division II, Groups A, B, C and D environments.
The OXY4400 is designed for three types of sensor ranges; 0 to 5% v/v, 0 to
50% v/v or 0 to 1000 ppm. This system was specifically designed for natural
gas measurements using a flow through fiber-optic oxygen sensor mounted in
a 1/4” compression tee. The instrument LCD and data-logger are integrated
into the system. The analog outputs are programmable to provide data for
oxygen, temperature, phase angle or signal amplitude. The digital interface
(RS-232) and PC software (included) are used for data storage and external
data logging that can store up to 26,000 data samples. Complete control,
including all calibration and adjustments, can be completed through the PC.
Sensor Characteristics of Oxygen-Sensitive Sensors
The operation principle of the optical oxygen sensor is based on the
fluorescence quenching of luminescence caused by a collision between
molecular oxygen and luminescent dye molecules in the excited state. Figure
1–1 shows a typical response curve of the oxygen-sensitive sensor. In the
presence of oxygen, the signal (in this case, the phase angle ) decreases.
1–2
4900002060 rev. C 4-9-15
Introduction
Figure 1–1 Response of the BOS3 sensor
toward changes in the oxygen concentration
Temperature
SpectraSensors’ optical oxygen sensors must be used with a PT1000
temperature sensor in the temperature range between -10 to 50 C. Each
instrument is supplied with the PT1000 temperature sensor for compensation
and to record temperature variations.
Cross-sensitivity
There exists no cross-sensitivity for carbon dioxide (CO2), hydrogen sulfide
(H2S), sulfur dioxide (SO2), pH, any iconic species like sulfide (S2-), sulfate
(SO42-), chloride (CI-) or salinity. Turbidity and changes in the flow rate (DO)
have little or no influence on the measurement.
The sensors can also be used in methanol- and ethanol-water mixtures, as well
as in pure methanol and ethanol.
SpectraSensors recommends avoiding other organic solvents, such as acetone,
chloroform or methylene chloride, which may swell the sensor matrix rendering
it unusable.
Response Time
The response time to t90 (90% of full scale) in the gas phase for the oxygen
sensor is less than eight seconds.
OXY4400 Operator’s Manual
1–3
Oxygen Analyzer
Housing for Oxygen in Natural Gas (DP-BOS3-L5-ST5-NOP)
SpectraSensors’ fiber-optic oxygen sensors are based on 2 mm polymer optical
fibers. The sensing portion is a 4 mm stainless steel probe. Depending on the
application, SpectraSensors offers a set of different standard fitting designs.
Refer to Figure 1–2. Custom designs are also available. Please contact your
sales representative.
1/4” compression “tee” flowthrough fitting
4 mm oxygen dipping
probe mounts in the
compression “tee”
Figure 1–2 Standard fiber-optic oxygen sensors
fittings
Trace Oxygen Probe
The oxygen sensor consists of a polymer optical fiber (POF) with a polished
distal tip that is coated with a planar oxygen-sensitive foil. The end of the
polymer optical fiber is covered with a high-grade steel tube to protect both the
sensor material and the POF. Refer to Figure 1–3. Typically, the fiber is coated
with an optical isolated sensor material in order to exclude ambient light from
the fiber tip.
Figure 1–3 Trace oxygen probe
1–4
4900002060 rev. C 4-9-15
Introduction
Schematic drawing for the Trace Oxygen Probe
Refer to Figure 1–4 for a schematic of the trace oxygen probe.
POF
p olymer optical f iber
(L = 2.5 m)
sensor spot
4 mm
steel tube
2 mm
SMA connector
Figure 1–4 Trace oxygen probe schematic
This probe has a very rugged sensor with excellent long-term stability (more
than 100000 data points without drift) and is usable for process applications.
Safety Guidelines
Please read these instructions carefully before working with this
instrument.
This device has been carefully tested of all functions, complying with safety
requirements, prior to leaving the factory. The correct functional and
operational safety of this instrument can only be ensured if the user observes
the necessary safety precautions and specific guidelines presented in this
manual. Refer to Appendix A, Specifications, and the list outlined below.
•
Before connecting the device to the electrical supply network, ensure
that the operating voltage stated on the power supply corresponds to
the main voltage input as described on page A–1.
•
If the instrument is moved from cold to warm surroundings,
condensation may form and interfere with the functioning of the
system. In this event, wait until the instrument temperature reaches
room temperature before putting the analyzer back into operation.
•
Calibration, maintenance and repair work must only be completed by
a qualified technician, trained by SpectraSensors, Inc.
•
In the case of any damage to current-carrying parts, such as power
supply cable or the power supply itself, take the device out of
operation and protect it against being returned to operation.
•
If there is any reason to assume that the instrument can no longer
be operated without a risk, it must be set aside and appropriately
marked to prevent further use.
•
The safety of the user may be endangered if:
OXY4400 Operator’s Manual
1–5
Oxygen Analyzer
–
the instrument is visibly damaged,
–
no longer operates as specified,
–
has been stored under adverse conditions for a lengthy period of
time,
–
has been damaged in transport.
•
If there is any doubt as to the working condition of the analyzer,
return the instrument to SpectraSensors for repair and maintenance.
•
The operator of this measuring instrument must ensure that the
following laws and guidelines are observed when using dangerous
substances:
–
National protective labor legislation,
–
safety regulations for accident prevention,
–
safety data sheets from the chemical manufacturer.
The OXY4400 transmitter assembly is not for use in atmospheres
containing an oxygen concentration greater than 50% by volume.
Getting Familiar with the Analyzer
Figure 1–5 shows a sample OXY4400 analyzer from a front view. Signal wiring
and analyzer power are connected from the right side of the analyzer (facing
the unit). On the front panel of the analyzer, the LCD serves as the user
interface to the analyzer. The analyzer control electronics drive the sensor,
collect the signal and provide measurement output signals.
The sample conditioning system (SCS) contains flow devices for the bypass
loop and to control the flow to the oxygen sensor. A pressure reducing device
is also installed to reduce the pressure of the sample going to the oxygen
sensor. Depending on the application and/or ambient conditions, the SCS may
also contain a heater and thermostat to maintain the interior of the enclosure
at a constant temperature. Refer to Appendix A for specifications and system
drawings.
1–6
4900002060 rev. C 4-9-15
Introduction
LCD
Power input
Programming
buttons
Signal
input/probe
connection
Probe connection
Figure 1–5 OXY4400 analyzer
Required Basic Equipment
The following are the basic requirements for installing and operating the
OXY4400:
•
•
•
•
OXY4400 oxygen instrument
Flow-through Tee fitting with probe
PC / Laptop (optional). Refer to “PC Operations” on page 5-1”.
RS-232 cable (optional)
OXY4400 Operator’s Manual
1–7
Oxygen Analyzer
THIS PAGE INTENTIONALLY LEFT BLANK
1–8
4900002060 rev. C 4-9-15
2 - INSTALLATION
This section describes the processes used to install and setup your OXY4400.
Once the analyzer arrives, you should take a few minutes to examine the
contents before installing the unit.
What Should be Included in the Shipping Box
The contents of the crates should include:
•
•
The SpectraSensors OXY4400 analyzer
•
•
One external serial cable
A document CD, which includes this manual and other system
documents
Additional accessories or options as ordered
If any of these contents are missing, contact your sales representative.
Inspecting the Analyzer
Unpack and place the unit on a flat surface. Carefully inspect all enclosures for
dents, dings, or general damage. Inspect the supply and return connections for
damage, such as bent tubing. Report any damage to the carrier.
Avoid jolting the instrument by dropping it or banging it against a
hard surface which may disturb the optical alignment.
Each analyzer is custom configured with various accessories and options. If
there is any discrepancy, please contact your sales representative.
Installing the Analyzer
Installing the analyzer is relatively easy requiring only a few steps that, when
carefully followed, will ensure proper mounting and connection. This section
includes information regarding:
•
•
•
•
•
•
Hardware and Tools for Installation
Mounting the Analyzer
Connecting Electrical Power to the Analyzer
Connecting Electrical Power to the Enclosure Heater
Connecting the Analog Outputs/Analog Inputs
Connecting the Gas Lines
OXY4400 Operator’s Manual
2–1
Oxygen Analyzer
Hardware and Tools for Installation
Depending on the particular configuration of accessories and options ordered,
you may need the following hardware and tools to complete the installation
process.
Hardware:
•
•
3/8” Unistrut® (or equivalent) bolts and spring nuts
•
•
•
3/4” conduit
Stainless steel tubing (SpectraSensors recommends using 1/4” O.D.
x 0.035” wall thickness, seamless stainless steel tubing)
Source of plant nitrogen gas (4 SCFH) for purge unit(s), if applicable
3/8” x 1-1/2” machine screws and nuts
Tools:
•
•
•
•
•
•
•
•
•
Hand drill and bits
Tape measure
Level
Pencil
9/16” socket wrench
Screw driver
9/16” open-end wrench
Needle-nose pliers
Crescent wrench
Mounting the Analyzer
The OXY4400 analyzer is manufactured for wall or Unistrut® (or equivalent)
metal framing installations. Depending on your application and configuration,
the analyzer will come mounted on a plate or Unistrut frame. Refer to
Appendix A for drawings with detailed mounting dimensions.
When mounting the analyzer, be sure not to position the
instrument so that it is difficult to operate adjacent devices. Allow
3 feet (1 m) of room in front of the analyzer and any switches.
It is critical to mount the analyzer so that the supply and return
lines reach the supply and return connections on the chassis while
still maintaining flexibility so that the sample lines are not under
excessive stress.
2–2
4900002060 rev. C 4-9-15
Installation
To mount the analyzer:
1. Select a suitable location to mount the analyzer. Choose a shaded
area or use an optional analyzer hood (or equivalent) to minimize
sun exposure.
SpectraSensors analyzers are designed for operation within the
specified ambient temperature range. Intense sun exposure in
some areas may cause the analyzer temperature to exceed the
maximum.
2. Locate the mounting holes on your unit.
3. For wall installations, mark the centers of the top mounting holes.
Mounting dimensions are shown in Appendix A.
4. Drill the appropriate size holes for the screws you are using.
5. Hold the analyzer in place and fasten with the top screws.
6. Repeat for the bottom mounting holes.
Once all four screws are tightened the analyzer should be very secure and
ready for the electrical connections.
Connecting Electrical Power to the Analyzer
Depending on your configuration, your analyzer will be configured for
120VAC/240VAC @ 50/60 Hz single-phase input, or optionally 24VDC input.
Check the manufacturing data label or the terminal block labels to determine
the power input requirements. All work must be performed by personnel
qualified in electrical conduit installation. Conduit seals should be used where
appropriate in compliance with local regulations.
Hazardous voltage and risk of electric shock. Before
attaching the wiring to the analyzer, make sure all power to the
wires is off.
Careful consideration should be taken when grounding. Properly
ground the unit by connecting ground leads to the grounding
studs provided throughout the system that are labeled with the
ground symbol .
Do not exceed the 24VDC power rating or electronics will be
damaged.
Depending on your configuration, the electrical wiring can be connected to the
analyzer through an opening located at the right of the electronics enclosure
(facing the front). Refer to Figure 1–5 on page 1–7.
OXY4400 Operator’s Manual
2–3
Oxygen Analyzer
Units with an enclosure heater in the sample conditioning system (SCS) will
have an additional power connection through a conduit hub located at the
bottom right of the heater enclosure (refer to Appendix A).
To connect electrical power to the analyzer:
1. Open the OXY4400 analyzer electronics enclosure door. Take care
not to disturb the electrical assembly inside.
Hazardous voltage and risk of electric shock. Failure to
properly ground the analyzer may create a high-voltage shock
hazard.
2. Run conduit from the power distribution panel to the conduit hub on
the analyzer electronics enclosure labeled for power input.
Conduit seals should be used where appropriate in compliance
with local regulations.
Because the breaker in the power distribution panel or switch will
be the primary means of disconnecting the power from the
analyzer, the power distribution panel should be located in close
proximity to the equipment and within easy reach of the operator,
or within 10 feet of the analyzer.
An approved switch or circuit breaker rated for 15 amps should be
used and clearly marked as the disconnecting device for the
analyzer.
3. For AC systems, pull ground, neutral and hot wires into the
electronics enclosure.
For DC systems, pull ground, plus and minus wires.
4. Strip back the jacket and/or insulation of the wires just enough to
connect to the power terminal block.
5. For single phase power connections, attach the neutral and hot wires
to the power terminal block by connecting the neutral wire to the
terminal marked “N” and the hot wire to the terminal marked “L.”
Refer to Table 2–1.
6. For AC split phase systems, attach the two hot legs to the terminal
block by connecting one of the hot wires to the terminal marked “L1"
and the other hot wire to the terminal marked “L2.”
For DC systems, connect the minus wire to the terminal marked “-,”
and the positive wire to the terminal marked “+.” Refer to Table 2–1.
7. Connect the ground wire to the ground terminal marked
2–4
.
4900002060 rev. C 4-9-15
Installation
8. Close and tighten the analyzer electronics enclosure door.
Table 2–1 Terminal layout and description
Terminal Pin
Connection
Description
Function
SMA Connector
SMA fiber connection
Connect the fiber optic oxygen cable to
SMA connector located on the bottom of
the OXY4400
Wire to Power
Supply
Line adaptor for power
supply
110/220 VAC power supply
Positive (25)
Negative (26)
9-24 VDC supply
9-24 VDC supply
Ground (4)
Positive (5)
Negative (6)
Connector for PT1000
temperature sensor
Connect the PT1000 temperature sensor
for temperature compensated measurements here
TxD (23)
RxD (24)
Gnd (22)
RS-232 interface
Connect the device with a RS-232 data
cable to the PC/Laptop here (optional)
Ch1 +10/-7
Ch2 -13/-14
Analog out/input
(channel 1/2)
Voltage output (0-10 V) from terminal
board to external recording device or DCS
system
Ch1 +19/-17
Ch2 -18/-20
Analog out
(channel 1/2)
Current output (4-20 mA) from terminal
board to external recording device or DCS
system.
NOTE: This is a powered output.
Connecting Electrical Power to the Enclosure
Heater
Analyzers configured with an optional sample conditioning system (SCS) in a
heated enclosure will have an additional power connection for the heater
through a conduit hub located at the lower right of the enclosure. Refer to
Figure A–7 on page A–10.
To connect electrical power to the enclosure heater:
1. Open the heated enclosure door. Take care not to disturb anything
inside.
2. Open the power terminal box inside the heated enclosure.
OXY4400 Operator’s Manual
2–5
Oxygen Analyzer
3. Run conduit from the power distribution panel to the conduit hub on
the lower right side of the heated enclosure labeled for power input.
Conduit seals should be used where appropriate in compliance
with local regulations.
Because the breaker in the power distribution panel or switch will
be the primary means of disconnecting the power from the
analyzer, the power distribution panel or switch should be located
in close proximity to the equipment and within easy reach of the
operator.
An approved switch or circuit breaker rated for 15 amps should be
used and clearly marked as the disconnecting device for the
analyzer.
4. Pull ground, neutral and hot wires (#14 AWG minimum) into the
power terminal box inside the heated enclosure.
5. Strip back the jacket and/or insulation of the wires just enough to
connect to the power terminal block.
6. For AC systems, attach the neutral and hot wires to the power
terminal by connecting the neutral wire to the terminal marked “N,”
the hot wire to the terminal marked “L.”
7. Connect the ground wire to the ground terminal marked
.
8. Close and latch the heated enclosure door.
Connecting the Analog Outputs/Analog Inputs
The OXY4400 is equipped with four independent analog outputs and two analog
inputs. The 4-20 mA current loop and serial output are connected to a mating
terminal block located inside the analyzer electronics enclosure. By default, the
4-20 mA current loop analog inputs (I1/I2) are set to inactive.
The analog outputs are programmable to oxygen temperature, phase shift or
signal amplitude. To allow external data collection, two input ports are available
(i.e., external pressure sensor).
Connections can be made with customer-supplied cables for the current loop
and alarms and factory-supplied cable for the serial connection. Consult the
wiring diagram in Figure A–1 on page A–4.
Certified glands and cables should be used where appropriate in
compliance with local regulations.
2–6
4900002060 rev. C 4-9-15
Installation
Hazardous voltage and risk of electric shock. Turn off and
lock out system power before opening the electronics enclosure
and making any connections.
To connect the analog outputs/analog inputs:
1. Disconnect power from the analyzer and open the electronics
enclosure cover. Take care not to disturb the electrical assembly
inside.
2. Run conduit from the analog outputs/inputs receiving station to the
conduit hub in the right outside corner of the electronics enclosure.
3. Pull the customer-supplied cables for the source outputs and the
SpectraSensors external serial cable (included in the shipping box)
through the conduit into the electronics enclosure.
4. Strip back the jacket and insulation of the current loop output and
serial cables just enough to connect to the mating terminal block.
5. Connect the 4-20 mA current loop I1/I2 output wires to the
appropriate terminals, as indicated in Table 2–1 on page 2–5.
6. Connect the serial cable wires to the appropriate terminals according
to Table 2–1. For reference, Table 2–1 also shows the corresponding
pin numbers for configuring a nine-pin Sub-D connector for
connection to a computer serial port.
7. To complete the connection, connect the other end of the current
loop wires to a current loop receiver and the external serial cable to
a serial port on your computer.
Connecting the Gas Lines
Once you have verified that the analyzer is wired correctly, you are ready to
connect the sample supply, sample bypass and sample return lines. Consult the
layout and flow diagrams in Appendix A for guidance on connections for a
SpectraSensors provided sample conditioning system (SCS). All work must be
performed by qualified technicians.
Process samples may contain hazardous material in potentially
flammable and/or toxic concentrations. Personnel should have a
thorough knowledge and understanding of the physical properties
and safety precautions for the sample contents before installing
the sample conditioning system (SCS).
SpectraSensors recommends using 1/4” O.D x 0.035” wall thickness, seamless
stainless steel tubing.
OXY4400 Operator’s Manual
2–7
Oxygen Analyzer
To connect the sample supply line:
1. Install sample supply line to the inlet on the SCS panel. Refer to
Appendix A.
All valves, regulators, switches, etc. should be operated in
accordance with site lock-out/tag-out procedures.
2. Adjust the pressure regulator to 8 PSIG. Refer to drawings in
Appendix A for recommended settings.
3. Adjust flowmeter to 1 SLPM. Refer to drawings in Appendix A for
recommended settings.
4. Tighten all input/output fittings 1-1/4 turns with a wrench from
finger tight.
5. Check all customer connections for gas leaks. SpectraSensors
recommends using a liquid leak test.
Do not exceed 20 PSIG to sample conditioning system. Damage
to the oxygen sensor may result.
To connect the sample bypass/sample return:
1. Confirm that the atmospheric vent header shut-off valve is closed.
All valves, regulators, switches, etc. should be operated in
accordance with site lock-out/tag-out procedures.
2. Determine appropriate tubing route from the SCS to the
atmospheric vent header.
3. Run stainless steel tubing from the bypass/sample return port to the
atmospheric vent header connection. Bend tubing using industrial
grade benders, check tubing fit to ensure proper seating between
the tubing and fittings. Fully ream all tubing ends. Blow out the lines
for 10–15 seconds with clean, dry nitrogen or air prior to making the
connection.
4. Connect the sample return tube to the SCS using the 1/4” stainless
steel compression-type fitting provided.
5. Tighten all new fittings 1-1/4 turns with a wrench from finger tight.
Secure tubing to appropriate structural supports as required.
2–8
4900002060 rev. C 4-9-15
Installation
6. Check all connections for gas leaks. SpectraSensors recommends
using a liquid leak detector.
Do not exceed 20 PSIG to the sample conditioning system.
Damage to the oxygen sensor may result.
Installing the Temperature (RTD) Probe
Most configurations include an installed RTD (Resistance Temperature Device)
probe. If the OXY4400 is provided without an accompanying sample
conditioning system (SCS), use the following procedure to connect the RTD
probe to the SCS.
No other temperature sensor than the one supplied with the
unit or ordered from the factory should be used. Refer to
“Spare Parts” on page A-13. The use of any other
temperature sensor can affect the oxygen compensation
and can even damage the oxygen meter.
1. With power disconnected to the analyzer, insert the cable end of the
RTD probe into the lower right opening on the side of the analyzer
or the opening at the base of the analyzer, depending on your
configuration. Refer to Figure 1–5 on page 1–7.
2. The RTD probe will either contain (2) red wires and (1) white wire,
or (2) black wires and (1) red wire. Twist together the (2) red or
black wires and connect to terminal 6.
3. Connect the (1) white or red wire and connect to terminal 5. Refer
to Figure 2–1.
Figure 2–1 RTD probe terminal connection
OXY4400 Operator’s Manual
2–9
Oxygen Analyzer
4. Insert the opposite end of the probe into the RTD probe inlet on the
SCS panel. The final installation is reflected in Figure 2–2.
RTD cable
connection
Figure 2–2 RTD probe installed
Installing the Oxygen Probe
If the OXY4400 is provided without an accompanying sample conditioning
systems (SCS), use the following procedure to connect the oxygen probe to the
SCS. Analyzers provided with an accompanying SCS will have this probe
already installed.
Handle the probe with care and do not remove the cap
before installation. Improper handling can cause damage to
the oxygen probe.
1. Verify that power is disconnected to the analyzer.
2. Remove the new oxygen probe cable from the package.
Refer to “Spare Parts” on page A-13 for a complete list of
replaceable probe parts and part numbers.
2–10
4900002060 rev. C 4-9-15
Installation
3. Carefully remove the protective plunger from the end of the probe
taking care not to touch the optical fiber tip. Refer to Figure 2–3.
Touching the optical fiber tip will cause damage to the probe.
Optical fiber tip
DO NOT TOUCH
Figure 2–3 Removing protective
plunger from oxygen probe
4. Insert the probe tip into the analyzer opening at the base of the unit.
Refer to Figure 2–4.
Take care not to bump the probe tip against the sides of the
opening or damage will occur.
OXY4400 Operator’s Manual
2–11
Oxygen Analyzer
Figure 2–4 Inserting the oxygen probe
into the OXY4400
5. Secure the probe nut with needle nose pliers by turning clockwise.
Verify that the probe is fully inserted while tightening the probe
nut or the analyzer may provide a faulty reading.
6. Hand-tighten the strain relief holder to the analyzer unit.
7. Using a crescent wrench, complete tightening until the probe is
secured.
Do not overtighten or the plastic strain relief holder may crack.
2–12
4900002060 rev. C 4-9-15
Installation
8. Insert the opposite end of the probe into the OXY probe inlet on the
SCS panel following the diagram below.
The final installation is reflected in Figure 2–5.
Oxygen probe
cable connection
Figure 2–5 Oxygen probe installed
OXY4400 Operator’s Manual
2–13
Oxygen Analyzer
Connecting the Calibration Gas (Optional)
For systems with a manual calibration port, an appropriate calibration gas
source will need to be connected to the SCS. For more information, refer to the
drawings in Appendix A.
Conditioning the SCS Tubing
Newly installed systems invariably have some trace contaminants and/or are
intended for measuring trace amounts of gas constituents that tend to cling to
system walls resulting in erroneous readings if the constituents are not in
equilibrium with the system walls. Therefore, once the analyzer and SCS are
completely connected, the entire system (i.e., from the sample source valve to
the vent or return) should be conditioned by flowing sample gas through the
system for up to 12 hours (or until reading stabilizes) after the system is
powered up and before actual readings are taken. Progress of the system
conditioning can be monitored via the gas concentration readings. Once the
gas constituents have reached equilibrium with the system walls, the readings
should stabilize.
2–14
4900002060 rev. C 4-9-15
3 - SAMPLE CONDITIONING SYSTEM
(SCS) OPERATION
Personnel should have a thorough understanding of the
procedures presented here before operating the sample
conditioning system.
The process sample at the sample tap may be at a high
pressure. Make sure that the field pressure reducing
regulator is equipped with an appropriate pressure relief
valve. Use extreme caution when operating the sample
probe isolation valve and field pressure reducing regulator.
Each SCS has been specifically designed to deliver a sample stream to the
analyzer that is representative of the process stream at the time of sampling.
Refer to Appendix A for configuration drawings. To ensure the integrity of the
sample stream and its analysis, care must be taken to install and operate the
SCS properly. Therefore, any personnel intending to operate or service the SCS
should have a thorough understanding of the process application and the
design of the SCS.
Most problems experienced with sample systems tend to result from operating
the system differently than intended. In some cases, the actual process
conditions may be different than originally specified (e.g., flow rates, presence
of contaminants, particulates, or condensables that may only exist under upset
conditions). By establishing understanding of the application and the design of
the system, most issues can be avoided altogether or easily diagnosed and
corrected ensuring successful normal operation.
If there are any remaining questions concerning the design, operation, or
maintenance of the SCS, contact “Customer Service” on page B-7.
About the SCS
For a typical full-featured SCS, refer to Figure A–1, sample gas enters the
sample conditioning unit [at the specified supply pressure set by a customersupplied upstream regulator] via the sample supply port, passes through a
shut-off valve, pressure regulator that maintains constant pressure in the
measurement cell, and membrane separator where any liquid in the stream is
removed. Liquid removed by the membrane separator passes through the
bypass loop and collects in a filter housing. A continuous flow (set to the
specified level by a metering valve and flowmeter) not only flushes the liquid
from the membrane separator but also maintains flow through the sample
lines, which reduces sample variation.
The flow exiting the bypass loop should be vented to a safe location.
OXY4400 Operator’s Manual
3–1
Oxygen Analyzer
Checking the SCS Installation
Before operating the system for the first time, a careful check of the installation
of the entire SCS from the sample probe to the vent is recommended.
To perform SCS installation checks:
1. Confirm that the sample probe is correctly installed at the process
supply tap and that the sample probe isolation valve is closed.
2. Confirm that the field pressure reducing station is installed properly
at the sample probe.
3. Confirm that the relief valve at the field pressure reducing station
has been set to the specified setpoint.
4. Confirm that all valves are closed.
5. Confirm that the atmospheric vent is properly connected.
6. Confirm that the analyzer house atmospheric vent is properly
installed, if applicable.
7. Confirm that all sample system tubing has been thoroughly leak
checked.
Starting up the SCS
After the SCS installation has been thoroughly checked, you are ready to begin
preparing for initial SCS startup.
To prepare for SCS startup:
8. If applicable, confirm proper heating of the sample supply tubing.
9. Confirm that all sample system shut-off valves are closed.
10. Confirm that the sample bypass and analyzer flowmeter control
valves are gently closed (adjustment knob turned clockwise).
Do not overtighten the control valves or damage could
occur.
To start up the sample bypass stream on process sample:
1. Open the atmospheric vent header shut-off valve for the sample
bypass effluent from the SCS, if applicable.
2. Open the sample supply port shut-off valve and slowly open the
pressure regulator (turning knob clockwise).
3–2
4900002060 rev. C 4-9-15
Sample Conditioning System (SCS) Operation
3. Set the inlet pressure regulator on the panel to a setting that will
maintain the specified flowmeter settings and provide good control
using the analyzer and bypass flow control valves.
4. Open the bypass flowmeter control valve to establish sample flow
from the sample probe and set the flowmeter to the specified value.
Do not exceed 10 PSIG at any time in the cell.
To start up the analyzer on process sample:
1. Open the sample flowmeter control valve to approximately the
specified flow.
2. Adjust the sample flowmeter control valve to the specified flow.
The adjustment setpoints of the analyzer flowmeter and
pressure regulator will be interactive and may require
multiple adjustments until the final setpoints are obtained.
The analyzer system has been designed for the sample flow
rate specified. A lower than specified sample flow rate may
adversely affect analyzer performance. If you are unable to
attain the specified sample flow rate, contact your factory
sales representative.
3. Confirm the sample flow and pressure setpoints and readjust the
control valves and pressure regulator to the specified setpoints, if
necessary.
4. Confirm the sample bypass flow and readjust the bypass control
valve to the specified setpoint, if necessary. The SCS is now
operating with the process sample.
5. Power up the analyzer according to the procedure given in the
analyzer operator’s manual.
Shutting Down the SCS
The process sample at the sample tap is at a high pressure.
A pressure reducing regulator is located at the sample tap
to reduce the sample pressure and enable operation of the
SCS at a low pressure. Use extreme caution when operating
the sample probe isolation valve.
OXY4400 Operator’s Manual
3–3
Oxygen Analyzer
1. Close the sample supply shut-off valve.
2. Allow the sample to flow until all residual gas has dissipated from the
lines as indicated by no flow on the sample and sample bypass
flowmeters.
3. Close the atmospheric vent header shut-off valve for the combined
sample bypass and measurement cell effluent from the SCS.
3–4
4900002060 rev. C 4-9-15
4 - CONFIGURATION
The instructions provided in this chapter should be used to start-up and
configure the OXY4400. On the face of the analyzer is an LCD with
programming and data readouts. Refer to Figure 1–5.
Powering up the Instrument
Before powering up the OXY4400, refer to Appendix A, Specifications, to
confirm the proper power connections to the power supply, temperature sensor
and oxygen sensor. After power has been connected, power on the OXY4400
by pressing the POWER button to the far right below the LCD. Refer to Figure
4–1. The instrument will power up and begin to measure with the settings of
the last readings.
Figure 4–1 Analyzer LCD display
To achieve a highest accuracy, the OXY4400 should be warmed up for
approximately five minutes before taking a measurement.
Warm-up time may be extended up to 15 minutes if the optode
has been exposed to high concentrations of oxygen.
Press the VIEW button (second from the left) to select one of two different
display options. Refer to Figure 4–2 for a view of the main display and Figure
4–3 for the alternate display view.
OXY4400 Operator’s Manual
4–1
Oxygen Analyzer
Figure 4–2 Main display view
Figure 4–3 Alternate display view
Menu Selection
Operation and maintenance of the OXY4400 is controlled using the built-in
menu structure. Press the MENU button to the far left under the LCD to enter
the main menu. Refer to Figure 4–1. Use the up and down arrow buttons
located under the display to select the desired menu item. Refer to Figure 4–4
to change the settings on the analyzer. Use the BACK button to move back to
the previous menu item.
4–2
4900002060 rev. C 4-9-15
Configuration
Main Menu
Measurement
Calibration
Data Logging
Configuration
Diag & Test
BACK


ENTER
Figure 4–4 Main menu
Pre-Calibration Procedure
Before starting the measurement, perform the standard pre-calibration
procedure.
1. Set the flow to 1.5 SLPM on the analyzer with a N2 bottle.
2. Set the pressure as specified.
3. Select Menu/Measurement/Temperature to verify that the
temperature compensation is set to PT1000 (RTD probe).
4. Adjust the sensor type based on the sensor specified for the unit.
Follow the instructions for "Sensor Type" below.
5. Select Menu/Measurement/Oxygen Unit and set accordingly.
6. Allow 99.99% pure N2 flow through the system for 30 minutes to
purge the system.
Sensor Type
The OXY4400 has been pre-programmed for the BOS3 sensor (0-1000 ppm).
If a different measurement range is required, the sensor type will need to be
adjusted. To set or change the sensor type, use the following steps.
1. Press the MENU button followed by the CALIBRATION button.
2. Scroll through the Calibration menu using the up and down arrow
buttons until the ‘Sensor type’ option displays as shown below.
OXY4400 Operator’s Manual
4–3
Oxygen Analyzer
3. Press the ENTER button to change the sensor. The SENSOR
SELECTION screen displays with the current setting.
4. Press the BACK button if the correct sensor is already adjusted.
5. Press the EDIT button to change the sensor type. Use the up/down
arrows to select the correct sensor type.
4–4
4900002060 rev. C 4-9-15
Configuration
6. Press ENTER to confirm the sensor type. The following sensor types
are available.
•
BOS1: Measurement range: 0-5% oxygen
Limit of detection: 0.03%
•
BOS2: Measurement range: 0-50% oxygen
Limit of detection: 25 ppm
•
BOS3: Measurement range: 0-300 ppm (1000
ppm maximum
Limit of detection: 0.5 ppm
Sensor Constants
After adjusting the analyzer to the correct sensor type (BOS1, BOS2, BOS3),
confirm the sensor constants.
1. Press the MENU button followed by the CALIBRATION button.
2. Scroll through the Calibration menu using the up and down arrow
buttons until the ‘Sensor const.’ option displays.
3. Press the ENTER button to confirm. The ‘Sensor Constants BOSx’
and the corresponding sensor constants screen displays (BOS3 is
shown in the example below).
Verify that the correct sensor type was adjusted. Refer to “PreCalibration Procedure” on page 4-3.
The sensor constants can be located on the calibration report that
was provided with the analyzer. If sensor constants are not provided
on the calibration report, use the default values shown in Table 4–1.
OXY4400 Operator’s Manual
4–5
Oxygen Analyzer
Table 4–1 Default sensor constants
BOS3
f1 = 0.786
KSV = 0
delta Phi = -0.02400
m = 15.80
BOS1
f1 = 0.869
KSV = 0.00877
delta Phi = -0.03796
m = 28.76
BOS2
f1 = 0.808
KSV = 0.000433
delta Phi = 0.0803
m = 29.87
4. Press the EDIT button to enter new sensor constants.
Measurement
System measurements can be adjusted using the LCD and keypad. Under this
menu it is possible to adjust the sampling rate, temperature, pressure, sensor
protection, signal averaging, oxygen unit and signal intensity.
Sampling Rate
Use the following steps to change the sampling rate:
1. From the Main menu, press Measurement and ENTER.
2. Press EDIT.
3. Adjust the sampling rate using the up/down arrow buttons to select
the unit.
4. Press ENTER.
Temperature
To change the temperature compensation, use the following steps:
1. From the Main menu, press Measurement and ENTER.
2. Press EDIT.
3. Select one of the following modes:
•
4–6
PT1000: The temperature compensation has a
temperature sensor connected.
4900002060 rev. C 4-9-15
Configuration
•
Manual: This setting allows the manual input of
a constant temperature. Use the up/down arrow
buttons to select the desired temperature and
confirm by pressing the ENTER button.
•
External: This allows the user to enter the
temperature signal by analog inputs. In the
analog input channels are already configured
(see Analog Inputs), the user can activate the
temperature compensation by mean of
externally.
4. Press ENTER.
Sensor Protect
To adjust the sensor operating temperature range, follow the steps below:
1. From the Main menu, press Measurement and ENTER.
2. Press EDIT.
3. Change the oxygen unit displayed by pressing the up/down arrows
to select the desired unit
4. Confirm by pressing ENTER.
Signal Averaging
Adjust the signal averaging using the following steps:
1. From the Main menu, press Measurement and ENTER.
2. Press EDIT.
3. Select one of the following modes:
•
Auto: The instrument selects the best setting
(default).
•
Manual: The higher the running average, the
longer the sampling time that is used for
averaging. The higher the running average is
set, the smoother the measurement signal.
4. Press EDIT.
Oxygen Unit
This procedure is used to change the oxygen units.
1. From the Main menu, press Measurement and ENTER.
OXY4400 Operator’s Manual
4–8
Oxygen Analyzer
2. Press EDIT.
3. Change the oxygen unit displayed by pressing the up/down arrows
to select the desired unit
4. Confirm by pressing ENTER.
Signal Intensity
Use this procedure to adjust the signal LED intensity.
1. From the Main menu, press Measurement and ENTER.
2. Press EDIT.
3. Changes are made by pressing the up/down arrows to adjust the
settings. Values between 10 and 100% are possible.
4. Press SET to confirm the settings.
The calibration will not be valid after changing the Sig. Intensity
parameter.
Calibration
The following procedure is the same for all sensor types and ranges. The sensor
type must be set during the initial configuration of the unit and only modified
if a different range sensor is installed in the field.
For accurate measurements of oxygen in the Natural Gas stream,
SpectraSensors recommends completing a calibration on the unit upon
installation and verify at least every three months.
The OXY4400 uses a two-point calibration, zero and span. The zero calibration
point should always be performed using a zero grade of nitrogen comparable
to the range of measurement. For ppm oxygen measurement, a minimum of
99.999% pure or oxygen-free nitrogen should be used. The span calibration
point should be an oxygen/nitrogen mixture with a concentration of 80-100%
of the measuring range and greater than the expected normal concentration
(i.e., 100ppm full-scale oxygen measurement, span calibration 80-100ppm).
4–9
4900002060 rev. C 4-9-15
Configuration
To enter the Calibration menu from the Main menu, press MENU then select
Calibration. Refer to Figure 4–5 for the Calibration menu options.
Calibration menu
Status
Calibrate
Sensor Type
Sensor Const.
BACK


ENTER
Figure 4–5 Calibration menu
Status
This sub-menu displays the settings of the last calibration. Press any button to
return to the Main menu.
Calibrate
Use this sub-menu to select the calibration mode. Refer to the image below.
•
Temperature ON: Calibration with the actual temperature reading
(either PT1000 [RTD probe], external or
manual, which is defined under
“Temperature” on page 4-6). This is the
preferred method of calibration.
OXY4400 Operator’s Manual
4–10
Oxygen Analyzer
The oxygen reading is affected by temperature. If the
temperature of the gas is not considered, then accuracy can be
affected.
•
Temperature OFF: Calibration is completed without a temperature
sensor, but with manual input. Use this method
if a PT1000 probe is not connected to the unit,
or if the temperature is different than the active
measured temperature.
•
Manual:
Manual input of phase and temperature values.
A manual calibration can be used to reset the
unit to a previous calibration or when replacing
a sensor. Phase angles and temperature MUST
be known if using this option.
Calibration of the oxygen sensor with Temperature compensation
(Preferred Method)
1. From the Calibration menu, select TEMPERATURE ON.
2. Set the calibration pressure.
The luminescence detection method for oxygen can be used for
liquid or gas streams. When the unit is measuring dissolved oxygen
in a liquid, the barometric pressure must be considered during
calibration. Gaseous streams are virtually unaffected by barometric
pressure, so no adjustment needs to be made to this value.
3. Press the SET button to continue. The following screen displays.
4. Adjust the concentration of the second calibration gas using the -/+
buttons to match the value of the calibration mixture.
Calibration can be in the range between 10 and 300 ppm.
4–11
4900002060 rev. C 4-9-15
Configuration
5. Press the SET button to confirm. The following screen display shows
an example of what is viewed for BOS3 sensor type.
The screen display will vary depending on the sensor type selected.
•
BOS1 shows percent of air saturation (% a.s.)
•
BOS2 will not have this screen display.
6. Insert the sensor into the CAL0 solution when the following screen
displays.
7. Connect the nitrogen (99.99%) calibration test gas to the Calibration
inlet port on the sample system panel. Ensure that the flow is set to
1.5 l/min.
8. Select OK.
Take care not to create an overpressure and ensure that no traces
of oxygen can diffuse into your measuring system.
9. For the first calibration point, wait approximately three minutes until
the phase angle and temperature are constant. The variation of the
phase angle and the temperature should be smaller than 0.1 and
0.1C.
OXY4400 Operator’s Manual
4–12
Oxygen Analyzer
10. Press the STORE button shown in the screen below.
If the sensor has been exposed to high levels of oxygen (open to
atmosphere for BOS3 [ppm] probe). It may take up to 15 minutes
to reach a stable value.
11. Insert the sensor into the CAL2nd solution when the screen below
displays.
a. Turn off the zero calibration gas and disconnect from the
sample system.
b. Connect the “Span” calibration test gas (80-100% of range
oxygen) and confirm 1.5 l/min. of flow to start the second
calibration point.
Take care not to create an overpressure or contaminate the
calibration chamber with air.
12. For the second calibration point, wait approximately three minutes
until the phase angle and temperature are constant. The variation of
4–13
4900002060 rev. C 4-9-15
Configuration
the phase angle and the temperature should be smaller than 0.1
and 0.1C.
13. Press the STORE button as shown in the screen display below.
The calibration is now complete.
14. Turn off the regulator, disconnect the calibration gases, switch the
sample system back to the sample position and begin the online
measurement. The following screens will display.
15. Press the BACK button twice to return to the Main Menu display to
view the gas readings.
Calibration of the oxygen sensor without Temperature compensation
The procedure for calibration without Temperature compensation is very similar
to the process described above. Reference the procedure above with the
following exceptions.
1. From the Calibration menu, select Temperature OFF. Refer to the
image below.
OXY4400 Operator’s Manual
4–14
Oxygen Analyzer
2. Adjust the temperature (in  C) of the calibration standards and
confirm it by pressing the SET button.
3. Follow the remaining steps from the “Calibration of the oxygen
sensor with Temperature compensation (Preferred Method)”
on page 4-11.
Calibration of the oxygen sensor with Manual Temperature compensation
•
Manual Calibration
User-defined calibration should be applied if there is no possibility for
adjusting the second calibration value via calibration test gas or if recalibration of the sensor is not desired. SpectraSensors delivers a
calibration report with each oxygen analyzer that provides two
calibration values, which can be entered into the user-defined
calibration mode.
1. From the Calibration menu, select Manual.
2. Adjust the Cal0 phase angle.
3. Adjust the concentration of the 2nd calibration gas in parts per
million (ppm)
4. Confirm by pressing the SET button. The following screen display
shows an example of what is viewed for BOS3 sensor type.
The screen display will vary depending on the sensor type selected.
4–15
•
BOS1 shows percent of air saturation (% a.s.)
•
BOS2 will not have this screen display.
4900002060 rev. C 4-9-15
Configuration
Calibration can be in the range between 10 and 300 ppm.
5. Adjust the second calibration phase angle using the -/+ arrow
buttons. A sample display is shown below.
6. Adjust the temperature for the Cal0 calibration value using the -/+
arrow buttons and confirm by pressing the SET button.
7. Adjust the temperature for the second calibration value using the
-/+ arrow buttons and confirm by pressing the SET button.
OXY4400 Operator’s Manual
4–16
Oxygen Analyzer
8. To finish the manual calibration, adjust the atmospheric pressure
using the -/+ arrow buttons and confirm by pressing the SET button.
Data Logging
By default, the data logger is turned off. To start data logging, select Data
Logging from the Main menu and START.
To stop the recording, select Data Logging and STOP.
The data logger status is available in Data Logging and Status, and shows
details such as starting time and date, sampling rate, saved records and free
memory space. The maximum recording time possible depends on the selected
sampling rate. This is shown on the display after selecting START.
During the recording (Data Logger activated), other functions
cannot be selected from the Main menu.
It is possible to turn off and restart the oxygen instrument with the Data Logger
still activated. The data recording will continue immediately after the restart.
When the data logging function is stopped and restarted, the
previous records are overwritten.
Stored records can be uploaded with the OXY4400 software that is supplied
with the analyzer. For information on operating Data Logger through a PC
terminal, refer to “PC Operations” on page 5-1.
4–17
4900002060 rev. C 4-9-15
Configuration
Configuration
Using the display panel on the front of the analyzer, press Menu from the Main
menu and Configuration to access the Configuration menu. From this menu,
most of the instrument parameters can be set. Refer to Figure 3-6.
Configuration
Status
Analog Out
Analog In
Clock/Date
Display
Reset Config.
BACK


ENTER
Figure 4–6 Configuration menu
Status
The status function displays the main settings of the instrument. Press any
button to return to the Main menu.
Analog Out
From this menu, the user can choose which data are exported via the analog
outputs. The OXY4400 has two voltage outputs (U1, U2) and two current
output channels (I1, I2). The desired data sources (oxygen, temperature,
amplitude or phase) can be selected via the dialog box. All four output channels
work independently of one another and are programmable. Refer to Figure 3-7.
OXY4400 Operator’s Manual
4–18
Oxygen Analyzer
Analog Out
Voltage U1
Voltage U2
Current I1
Current I2
20 mA/10V Value

BACK

ENTER
Figure 4–7 Analog Out: select Output menu
•
Voltage U1/U2: Select the parameter to activate as a voltage
analog output for port 1 and port 2 using the
up/down arrow buttons. The following output
selections are available:
–
–
–
–
–
•
Current I1/I2: Select the parameter to activate as a current mA
analog output for port 1 and port 2 using the
up/down arrow buttons. The following selections
are available:
–
–
–
–
–
•
Inactive
Oxygen
Temperature
Phase
Amplitude
Inactive
Oxygen
Temperature
Phase
Amplitude
20 mA/10V value: Use this parameter to program the correlation
of the 10V/20 mA to the exported value.
If 10V is set to 100% air-saturation (20.95% v/v), then 1V
corresponds to 10% air-saturation; i.e., if 10V is set to 200 ppm
gaseous oxygen, then 1V corresponds to 20 ppm.
4–19
4900002060 rev. C 4-9-15
Configuration
Use the following procedure to configure the 4-20 mA.
1. From the Configuration menu, press Analog Output.
2. Select Current I1.
3. Press ENTER.
4. Press EDIT.
5. Choose the measurement; Inactive, Oxygen, Temperature, Phase or
Amplitude.
6. Press ENTER.
7. Select Current I2.
8. Select 20mA/10V Value.
9. Press ENTER.
10. Press EDIT.
11. Press the -/+ buttons to select the applicable 4-20 mA range.
12. Press SET.
Analog In
At this parameter the user can select the data that is imported via the analog
inputs. The OXY4400 has two voltage input channels. The desired data source
for temperature and optionally for pressure can be selected via the dialog box.
The purpose of the input channels is to compensate the oxygen value with
externally measured temperature or pressure (for liquid measurements only).
It is useful for a measurement set-up that originally integrated temperature
and/or pressure sensor. The user has the ability to export the analog data from
the external sensor into the OXY4400 via input channels. In order to initialize
the input channels correctly, a proper measurement range must be set. Once
set, the input voltage is used for oxygen calculation correction.
“Higher value” is the input voltage upper limit and is equal to 10V
for the OXY4400. For example, if the input signal of 10V
corresponds to a temperature of 60 C, set the value in the
“higher value” control window to 60.
“Lower value” is the input voltage lower limit and is equal to 0V
for the OXY4400. For example, if the input signal of 0V
corresponds to a temperature of 10 C, set the value in the “lower
value” control window to 10.
•
Example 1: Using the values given in the first note for the “higher
value” above, the temperature correction upon the input voltage is:
By input voltage = 5V, the imported temperature is 35 C
By input voltage = 7.5V, the imported temperature is 47.5 C
OXY4400 Operator’s Manual
4–20
Oxygen Analyzer
•
Example 2: Suppose that the input voltage of 0V is equal to 500hPa,
and 10V is equal to 2000hPa.
By input voltage = 3.5V, the imported pressure is 1025hPa
By input voltage = 5V, the imported pressure is 1250hPa
By input voltage = 7.5V, the imported pressure is 1625hPa
Clock/Date
Use the “+” and NEXT button to adjust the clock and date information.
Complete the change by pressing the SET button.
Display
Changes the backlight illumination of the display. The ‘Auto’ function turns on
the illumination after pressing any button, and after a few seconds switches it
back off.
Reset Config.
Sets all parameters defined in this sub-menu to default.
Diag & Test
This menu enables the user to test the analog in and out ports. From the Main
menu, select Menu followed by Diag & Test. Refer to Figure 3-8 for options of
the Diag & Test menu.
Diagnostics and Test
System
Outputs
Inputs
BACK


ENTER
Figure 4–8 Diagnostic and test menu
4–21
4900002060 rev. C 4-9-15
Configuration
System
This menu displays the most important information of the instrument. Press
any key to return to the Main menu.
Outputs
Select the channel to be tested using the up/down arrow buttons. Confirm the
selection by pressing ENTER. Adjust the test output value and check the value
with the external data logger or voltmeter.
Inputs
Select the channel to be tested using the up/down arrow buttons. Confirm the
selection by pressing ENTER. The actual reading of the channel is displayed
based on the input value.
OXY4400 Operator’s Manual
4–22
Oxygen Analyzer
THIS PAGE INTENTIONALLY LEFT BLANK
4–23
4900002060 rev. C 4-9-15
5 - PC OPERATIONS
The OXY4400 PC software is compatible with the following operating systems:
•
•
•
•
•
•
•
Windows 98
Windows 2000
Windows Millennium\
Windows NT 4.0
Windows XP
Vista
Windows 7
Installing the Software
The software will be provided with the system on CD.
1. Insert the supplied CD into the respective drive.
2. Copy the software file (*.exe) onto your hard drive.
The executable file may also be copied as a link (icon) on the
desktop.
3. Connect the OXY4400 via the supplied serial cable to a serial port on
the computer.
4. Secure the cable and connect the cable wire pins as follows:
Pin
Connection
22
Ground
23
TxD
24
RxD
5. Apply power to the OXY4400.
Close any open applications as they may interfere with the
software.
OXY4400 Operator’s Manual
5–1
Oxygen Analyzer
6. Start the software by double-clicking on the *.exe file. The following
window displays.
If the correct COM port is selected, this information window closes within a
few seconds. If the wrong COM port is selected, the software will prompt
for a change.
a. Left-click the mouse on the down arrow to the right of the field
showing the COM port assignment.
b. Select the COM port.
c. Confirm setting and click the OK button. The window closes when
the correct COM port is selected. The program launches.
Function and Description
The window shown in displays after launching the OXY4400 software. The
program has four main areas:
•
•
•
•
5–2
Menu bar
Graphical window
Status bar
Control bar; divided into numerical display, control buttons and
warning lights
4900002060 rev. C 4-9-15
PC Operations
Menu
Control buttons
Warning lights
Control bar Numerical display
Graphical window
Figure 5–1 OXY4400 Main window
Menu Bar
The following actions are available under the Menu bar.
File
-> Exit
Charts
Display
->
->
->
->
-> Zoom
-> Auto ScaleY1
-> Undo Zoom
-> Clear Charts
-> Dimensions
Oxygen
Phase
Amplitude
Temperature
OXY4400 Operator’s Manual
Pri
nt
-> Charts
Setting
->
->
->
->
->
->
COM port
Instrument Info
Analog Output
Analog Input
LED Intensity
Sensor
BOS3
BOS1
BOS2
-> Oxygen Unit
% air saturation
% oxygen
hPa (mBar)
Torr
ppm
mol/L
5–3
Oxygen Analyzer
Menu Bar Definitions
•
File
–
•
•
•
Charts
–
Oxygen: Oxygen content in the selected unit.
–
Phase: Phase angle, raw data.
–
Amplitude: Magnitude of the sensor signal.
–
Temperature: Measured temperature.
Display
–
Zoom/AutoScaleY: AutoScaleY1 is the default setting, which
means the y-axis is scaled automatically.
–
Zoom/Undo Zoom: Original display is recovered. Also see
Graphical display.
–
Clear Charts: Graphs shown on the display are cleared.
–
Dimensions: Used to adjust the number of measurement points
(x/y). When used, the autoScaleY1 function is off.
Print
–
•
Exit: Closes the program.
Charts: Displayed charts can be printed.
Settings
–
ComPort: The serial COM port (com1-com20) for the serial
interface (RS-232) can be selected. COM 1 is the default. If the
wrong COM port is selected, a pop-up window will display with
instructions to select the correct COM port.
–
Instrument Info: Displays the software version and additional
setting information for the instrument.
If a problem arises with the OXY4400 oxygen meter, refer to
“Service Contact” on page B-7.
5–4
4900002060 rev. C 4-9-15
PC Operations
Control Bar
The actual content in the chosen unit is displayed in the oxygen field at the top
left of the Main window (refer to Figure 5–1).
The actual temperature value of the sample is displayed in the Temperature
window. If measurement is performed without temperature compensation, the
manually entered temperature is displayed and that temperature
measurement is shown offline. Refer to Figure 5–2.
Figure 5–2 Control bar
Control Buttons
Located at the top center of the Main window (refer to Figure 5–1), the Control
buttons provide the user access to the device functions.
To begin a system measurement, use the following procedure:
1. Calibrate the instrument with the Calibration Assistant.
2. Start the measurement with the Measurement Assistant.
3. Read-out Data Logger.
OXY4400 Operator’s Manual
5–5
Oxygen Analyzer
Measurement Assistant
1. From the Main window (refer to Figure 5–1), click on the
MEASUREMENT tab. The Measurement Assistant window opens, as
shown in Figure 5–3.
Figure 5–3 Measurement assistant
2. Select the desired measurement mode in the drop-down menu of
the Sampling field by clicking on the down-arrow. The choices
range from 30 seconds to 60 minutes where a measurement point
is recorded each hour. Selecting ‘Other’ allows the user to enter a
sample time.
The sensor shelf life can be increased using a slower sampling rate
since the effect of photo-bleaching is reduced. The illumination
light is turned off between sampling. Another advantage of using
a higher measuring mode is that huge amounts of data for longtime measurements can be avoided.
5–6
4900002060 rev. C 4-9-15
PC Operations
If the settings have not yet been entered, the following pop-up window displays:
The date of the last calibration displays in the window.
3. To measure with the last sensor calibration, click the CONTINUE
button.
4. To perform a sensor measurement before calibration, click the NEW
CALIBRATION button.
SpectraSensors strongly recommends performing a new sensor
calibration to obtain reliable results.
5. Refer to “Calibration” on page 4-9 for calibration process
instructions.
6. To exit from this menu, click on the CANCEL button.
Calibration Assistant
1. Click on the CALIBRATION tab and the Calibration Assistant window
will open.
2. Refer to the section on “Pre-Calibration Procedure” on page 4-3
for calibration instructions.
Data Logging
Stored records can be uploaded with the supplied software by clicking on the
DATA LOGGER tab. Refer to Figure 5–1.
1. After choosing the folder where the data will be stored (file location),
click the SCAN button. The software will show the stored number of
data and the estimated download time.
2. Click the YES button to start the download automatically after
confirming the displayed details.
OXY4400 Operator’s Manual
5–7
Oxygen Analyzer
Settings
The following settings can be accessed from the Main menu at the top of the
screen. Refer to Figure 5–1.
Instrument Info
1. From the menu bar at the top of the Main window, click SETTINGS
and “Instrument Info”. The Instrument Info displays. Refer to Figure
5–4 for a sample system display.
Figure 5–4 Instrument info display
To revert to the graphical window, click on the MEASURE CHART
button.
Analog Output
In this window, the type of data exported via the analog outputs is determined.
The OXY4400 device has two voltage outputs and two current output channels.
The desired data sources (oxygen, temperature, amplitude, phase) can be
selected. All four output channels work independent of one another.
1. From the Main menu bar, click SETTINGS and “Analog Output”. The
Analog Output Choice window displays. Refer to Figure 5–5.
2. Make the appropriate selection for each Voltage channel.
5–8
4900002060 rev. C 4-9-15
PC Operations
3. Enter the “Oxygen (Max Scale)”. This field provides an entry by the
user for the correlation of the 10 V/20 mA value to the exported
value. For example:
–
if 10 V is set to 500% oxygen, then 1 V corresponds to 50%
–
if 10 V is set to 200 ppm oxygen, then 1 V corresponds to 20
ppm
Figure 5–5 Analog Output choice
4. When complete, click the OK button.
Analog Input
Use these fields to select the data that is imported via the analog inputs. The
OXY4400 device has two voltage input channels. The desired data sources
temperature and pressure (*option) can be chosen via the dialog box.
1. From the menu bar at the top of the Main window, click SETTINGS
and “Analog Input”. The Analog Input Configuration window
displays. Refer to Figure 5–6.
OXY4400 Operator’s Manual
5–9
Oxygen Analyzer
Figure 5–6 Analog Input configuration
LED Intensity
The amount of light illuminating the sensor spot can be adjusted with the
current of the LED. Adjustments can be made automatically by selecting “Auto
Adjust,” which adjusts the OXY4400 LED to the optimal LED current, or
manually by selecting “Advanced”.
If the LED current is increased, the signal amplitude increases, since a higher
light density illuminates the sensor spot.
Auto Adjust
To make the adjustment of the LED intensity automatically, use the following
procedure:
1. Verify that the oxygen sensor has been connected to the instrument.
2. From the menu bar on the Main window (Figure 5–1), click
SETTINGS and “LED Intensity.”
3. Click the START AUTO ADJUST button.
5–10
4900002060 rev. C 4-9-15
PC Operations
4. The automatic adjustment of the LED intensity is completed when
the Status window displays the message “Auto adjustment finished”.
5. Click the CLOSE button to confirm the settings.
Advanced
Use the following procedures to adjust the LED intensity manually.
1. Click the ‘Advanced’ tab for manual LED settings. Enter a value
between 10 and 100%.
2. Click the CONFIRM button. The setting displays in the LED Intensity
field.
After changing the LED intensity, SpectraSensors recommends
re-calibrating the oxygen micro-sensor.
A warning window displays to prompt the user to re-calibrate the
sensor.
3. Click on the CALIBRATION button to re-calibrate or the I WILL
RECALIBRATE LATER button to bypass the operation.
4. Click the CLOSE button to complete the change.
The amplitude of the oxygen sensor is increased by increasing the
light intensity. This leads to smoother signals. However,
increasing the light intensity can increase photo-bleaching, which
decreases the shelf-life of the sensor.
OXY4400 Operator’s Manual
5–11
Oxygen Analyzer
Oxygen Unit
This is used to adjust the desired oxygen unit.
1. From the Main menu bar, click SETTINGS and “Oxygen Unit.”
2. Click on the down-arrow to the right of the field to select the unit to
be used.
Temperature compensated oxygen measurements
To measure with temperature compensation, use the following procedure:
1. Verify that the temperature sensor PT1000 (RTD probe) is connected
to the OXY4400.
2. Click on the ON radio button in the Temperature Compensation fields
of the Oxygen Unit window.
The field for entering a measurement temperature will be disabled
if this function is selected.
3. Click the START button to begin measurement.
To measure without temperature compensation, follow the steps below:
1. Click on the OFF radio button in the Temperature Compensation
fields of the Oxygen Unit window.
2. Manually enter the temperature during the measurement in the
field.
The temperature will be measured in degrees Celsius.
3. Click the START button to begin measurement.
External Temperature Compensation
If the analog input channels are already configured (refer to “Analog Input”
on page 5-9), the user can activate temperature compensation by externally
importing the value. Here, channel 1 or 2 can be selected.
Before starting the external compensation, check the quality of
the electrical signals. This can be done when the OXY4400 is NOT
in PC mode. The input voltage can be controlled directly on the
LCD by entering “Diag & Test/Analog In.
5–12
4900002060 rev. C 4-9-15
PC Operations
Logging Setup
To start the measurement without logging data, use the following procedure:
1. Click on the MEASURE radio button in the Logging Setup fields of the
Oxygen Unit window.
2. Click on the START button.
To store the measurement data, follow the steps below:
1. Click on the MEASURE & LOG radio button in the Logging Setup fields
of the Oxygen Unit window.
2. Click the CHOOSE FILE button. The Data File Selection pop-up
window displays. Browse the folders to select the file location to
store the data.
3. Select “.txt” for the file extension and create a file name.
4. Click the SAVE button to confirm the settings. The pop-up window
closes.
5. In the Logging Setup field, enter a file description for the text file.
6. To begin the measurement, click the START button.
Stopping the Measurement
The measurement is ended by a left-click of the mouse on the STOP button in
the Control Bar of the Main window.
Warning Lights
At the top right corner of the Main window (refer to Figure 5–1), the warning
lights are viewable. These lights are defined as follows:
•
Amplitude:
Red
Yellow
Green
•
Amplitude is too low, the sensor tip may be damaged or sensor
cable may not be connected.
Amplitude is critically low. Replacement of the sensor is
recommended.
Amplitude level is good.
Phase:
Red
Green
Phase angle is out of limits.
Phase angle is in normal range.
OXY4400 Operator’s Manual
5–13
Oxygen Analyzer
•
Ambient light:
Red
Green
Background light (e.g., direct light, lamp) is too high. Decrease
background light.
Ratio of sensor signal to false light is acceptable.
Click on the DISPLAY RAW VALUES button to display on the screen the data
next to the warning lights.
Graphical Display Window
The respective sensor signal is displayed according to the selection of the four
control radio buttons; oxygen, phase, amplitude and temperature (menu
chart). The oxygen content is displayed in the chosen unit and the temperature
is shown in degrees Celsius. The raw values (the phase angle in degrees and
the sensor amplitude in mV) can also be displayed by clicking the DISPLAY RAW
VALUES button.
Zoom function
1. Left-click and hold the mouse button, and drag from left to right to
enlarge a certain area of the graphical window. The graphical
window displays the selected data points and is not actualized with
new data.
2. Left-click and hold the mouse button, and drag from right to left to
recover the original display. The UNDO ZOOM button can also be
clicked in the Display menu under Zoom.
Status Bar
Refer to the definitions below of the features on the status bar.
SW1
SW2
5–14
SW3
•
SW1:Displays the serial port, which is used for communication of the
OXY4400 device with the PC.
•
SW2: Displays the file name in which the measurement data are
stored. “No storage file selected” is displayed when no file was
selected (no data storage).
•
•
SW3:Displays the start time of the measurement.
SW4
SW4:Displays the actual time.
4900002060 rev. C 4-9-15
Appendix A: Specifications
Table A-1
OXY4400 analyzer specifications
Instrument OXY4400
Channels
Temperature (PT1000)
1x optical channel (SMA connector), designed for mini-sensors
1x PT1000 connector
Range
Resolution
Accuracy
 0.2 C
 0.1 C
0-50 C
Digital Interfaced
RS-232 interface with galvanic isolation (19200 Baud, Data-bits 8),
(Tinned leads to SUB-D9 cable for RS-232 PC)
Analog Outputs
Four independent, programmable 12-bit analog I/O channels with
galvanic isolation (2x voltage output 0-10 V, 2x current output 420mA
Analog Inputs
Two independent, programmable 12-bit analog I/O channels with
galvanic isolation (voltage input 0-10 V)
Analog Output
(Temperature, PT1000)
0-50 C
 0.5 C
Sample Flow Rate
1.5 slpm (0.05 scfm)
Power Supply
120/240 VAC, 50/60 Hz
24 VDC/max 0.83 Amps at 24 VDC
 1.5 C
Software OxyView
Oxygen Units
User selectable from oxygen saturation, ppm, %
Compatibility
Windows 95/98/2000/Millennium/NT4.0/XP/Vista/Windows 7
Calibration
Conventional two-point calibration in oxygen-free environment
(nitrogen) and a second calibration value of 80-100% of range
Environmental Conditions

Operating Temperature (C)
0-50
Storage Temperature (C)
-10 to 65
Relative Humidity (%)
up to 95%, non-condensing (IP 64)
Dimensions (not including
sample conditioning system)
10”H x 8”W x 6”D (inches)
254 H x 203 W x 152 D (mm)
Weight (not including
sample conditioning system)
2.2 (kg)

Trace Oxygen Sensor Type
Measurement Range
0-300 ppm nominal (maximum range 1000 ppm)
Limit of Detection (LOD)
0.5 ppm
Resolution
<10 ppm X.XX, >10 ppm XXXX.X ppm
Accuracy (20 C)
5% of the oxygen concentration
OXY4400 Operator’s Manual
A–1
Oxygen Analyzer
Table A-1 Oxy4400 analyzer specifications (Continued)
Oxygen Sensor Type BOS3
Measurement Range
0-1000 ppmv
Limit of Detection (LOD)
0.5 ppmv
Resolution
0.01%
Accuracy (20 C)
 5% of Reading
Oxygen Sensor Type BOS2
Measurement Range
0-50%
Limit of Detection (LOD)
0.03%
Resolution
0.01%
Accuracy (20 C)
 2% of Reading
Oxygen Sensor Type BOS2
Measurement Range
0-5%
Limit of Detection (LOD)
25 ppm
Resolution
0.01%
Accuracy (20 C)
 3% of Reading
Technical Notes
•
Power: OXY4400 is available in power from 80-253 VAC or 9-24
VDC. The OXY4400 can be powered by an external battery via
connection directly to the terminal board. AC powered is wired
directly to the power supply mounted to the back plate.
•
Analog Outputs:
Hazardous voltage and risk of electric shock. The analog
outputs are not protected against any input voltage. Any voltage
applied to the analog outputs can cause irreversible damage to
the circuit.
A–2
•
RS-232 Interface: The unit uses crossed interface cable. The use
of anything other than the serial cable provided with the instrument
can cause the unit’s malfunction.
•
Optical Output: The SMA connector is high precision optical
component. Please keep it dry and clean. Always use rubber cap to
close the output when not in use.
•
Waterproof Enclosure: The OXY4400 enclosure meets NEMA 4X
standards. However, make sure that all cable plugs are installed in
the enclosure cable grips if not used (Analog I/O). Care should be
taken to avoid water ingress into the enclosure via the unused cable
grips to cause device failure. OXY4400 has no internal dew fuse.
4900002060 rev. C 4-9-15
Specifications
•
Approvals: The OXY4400 has been approved for use in Hazardous
locations by FM and tested according to the NEC standards for Class
1, Division 2, Groups A, B, C and D for use in the U.S. and Canada.
For a complete listing of new or updated certificates, please visit
the product page at www.spectrasensors.com.
OXY4400 Operator’s Manual
A–3
Oxygen Analyzer
A–4
4900002060 rev. C 4-9-15
Figure A–1 Outline and mounting dimensions - panel mount
OXY4400 Operator’s Manual
Specifications
A–5
Figure A–2 Sample system schematic - panel mount
Oxygen Analyzer
A–6
4900002060 rev. C 4-9-15
Figure A–3 Power and signal wiring diagram - panel mount
OXY4400 Operator’s Manual
Specifications
A–7
Figure A–4 Outline and mounting dimensions - Unheated enclosure mounted
Oxygen Analyzer
A–8
4900002060 rev. C 4-9-15
Figure A–5 Sample system schmatic - Unheated enclosure mounted
OXY4400 Operator’s Manual
Specifications
A–9
Figure A–6 Power and signal wiring diagram - Unheated enclosure mounted
Oxygen Analyzer
A–10
4900002060 rev. C 4-9-15
Figure A–7 Outline and mounting dimension - Heated enclosure mounted
OXY4400 Operator’s Manual
Specifications
A–11
Figure A–8 Sample system schematic - Heated enclosure mounted
Oxygen Analyzer
A–12
4900002060 rev. C 4-9-15
Figure A–9 Power and signal wiring diagram - Unheated enclosure mounted
Specifications
Spare Parts
Below is a list of spare parts for the Oxygen Analyzer analyzer with
recommended quantities for 2 years of operation. Due to a policy of continuous
improvement, parts and part numbers may change without notice. Not all parts
listed are included on every analyzer. When ordering, please specify the system
serial number to ensure that the correct parts are identified.
Table A–2 Replacement parts for OXY4400 analyzer
Part
Number
Description
2 YR
QTY
Analyzer Electronics
3100002157
BOS3 Sensor Probe 0.7 meter
-
3100002156
BOS3 Sensor Probe 2.5 meter
-
3100002213
BOS2 Sensor Probe 0.7 metet
-
3100002201
BOS2 Sensor Probe 2.5 meter
-
3100002214
BOS1 Sensor Probe 0.7 meter
-
3100002177
BOS1 Sensor Probe 2.5 meter
-
0190217106
RS-232 Serial Data Cable
-
5500002018
Temperature (RTD) Sensor with Flexible Metal Jacket
-
4000002042
Power Supply 100-240 VAC input 15 VDC output
-
Sample Conditioning System
61303042S4
Ball Valve, 1/4” TF (SS) Swagelok SS-42GS4
-
6101520074
Filter, Tee-type, 7m, 1/4” TF (SS) Swagelok SS-4TF-7
-
6100002186
Filter Element, 7m Swagelok SS-4F-K4-7
-
6134100274
Flowmeter w/ Valve 0-2 SLPM 1/4” NPTF (SS) King
74C123G081123810
-
6100002373
Flowmeter ARM, w/ Valve, 2.6 SLPM, 1/4” FNPT (SS) King
7101361003A
6101671208
Membrane Separator, 1/4” NPTF (SS) A+ Corp 120-005-SS
61016120X5
Membrane Replacement Filter A+ Corp 120-5X5
-
6101510004
Liquid Trap (Glass Filter Bowl) 1/4” NPTF (SS) UFS/Headline
117G
-
6101614001
Liquid Trap Filter Element UFS/Headline 12-32-70K
-
61322-10102
Pressure Regulator, 10psig, 18” NPTF (SS) GO CPR11A01A3C111
-
OXY4400 Operator’s Manual
A–13
Oxygen Analyzer
Table A-2 Replacement parts for OXY4400 analyzer (Continued)
Part
Number
2 YR
QTY
Description
Sample Conditioning System (Continued)
1400402310
Heater, Div. 1, 200W, 120 VAC Intertec CPA 200T3100-120V
-
5300002030
Thermostat, Div. 1, Preset 40 C Intertec AT-40/Z
-
General
1100002129
100 ppm O2 balance N2 Cal Gas Bottle 103 liters @ 1000 psi
-
1100002130
99.9999% N2 UHP Cal Gas Bottle 103 liters @ 1000 psi
-
1100002131
Regulator, Calibration Gas 1.5 LPM
-
4900002060
OXY4400 Operator’s Manual, additional copies
-
A–14
4900002060 rev. C 4-9-15
Appendix B: Troubleshooting
The OXY4400 is a maintenance-free instrument. The housing should be
cleaned only with a moist cloth. Never use benzene, acetone, alcohol or other
organic solvents. The SMA-fiber connector of the sensor can be cleaned only
with a lint-free cloth. The sensor tip may be rinsed only with distilled water or
ethanol.
Refer to Table B–1 for frequently asked questions related to troubleshooting
the OXY4400 before contacting the service department. To contact the service
department, refer to “Service Contact” on page B-7.
Table B–1 Potential instrument problems and their solutions
Indication
Suspected Cause
Solution
Fiber optic cable is not connected
Make sure that the SMA connector is
connected properly to the connector.
Oxygen sensor damaged
Check the amplitude (signal) of the
sensor; it must read above 1500.
Check the flow to make sure that the
line is not plugged, preventing the
sample from reaching the sensor.
Oxygen readings incorrect
Incorrect sensor selected
Check to make sure that the proper
sensor is selected: BOS1, 0-5%;
BOS2, 0-50%; BOS3, 0-1000 ppm
Oxygen reading unstable
Oxygen sensor
Check for Low Amplitude (signal) to
make sure that it is >1500. Check for
low or unstable flow on sensor.
Temp sensor
not detected
PT1000 sensor (RTD probe)
Check to make sure that the temperature sensor is connected.
Out of range
Oxygen sensor
Sensor flow is blocked. Clear the
sample line and reset flow to 1.0 LPM
Phase value
too low
Oxygen sensor out of range
Check for blockage on the sample
line and reset flow to 1.0 LPM
Unable to read
oxygen
Current loop open
Connect current loop to recording or
monitoring device.
No sensor
detected
OXY4400 Operator’s Manual
B–1
Oxygen Analyzer
Error Codes
The error value is binary coded. This means each bit corresponds to a specific
error or warning. Refer to Table B–2 for a summary of error bits.
Table B–2 Error value definitions
Error
Value
Bit
256
Bit 7
System restart
128
Bit 6
Overheat
32
Bit 5
Current output 2 open
loop error
16
Bit 4
Current output 1 open
loop error
8
Bit 3
No temperature sensor
4
Bit 2
No oxygen sensor
2
Bit 1
Ambient light
1
Bit 0
ADC overflow
Error Description
Decoding example
If the Error Value received from a device is 10, the error bits can be determined
by using Table B–2 to locate the entry for a value less than or equal to the error
value received. For example:
•
8 < 10 = No temperature sensor
Subtract the error value and repeat the process.
10-8 = 2, “Ambient light”
In this example, Bit 1 (ambient light) and Bit 3 (no temperature sensor) are
“1”. This error code would display if there was too much ambient light (sun
illuminating the sensor) and the temperature sensor PT1000 is not connected
to the device.
Recommendations for Correct Measurement
Calibration of the sensor is recommended before each new application. As an
alternative, the calibration values of the last measurement can be used. If
temperature compensation is not used, ensure that the temperature of the
sample is known and is constant during measurement. With temperature
compensated measurements, the temperature sensor PT1000 (RTD probe)
should be positioned as close as possible to the oxygen mini-sensor to avoid
temperature differences. Refer to the SpectraSensors website at
www.spectrasensors.com for more information.
B–2
4900002060 rev. C 4-9-15
Troubleshooting
Signal Drifts due to Oxygen Gradients
It is important to remember that the sensor only measures the oxygen content
near its surface. The formation of a bio-film during long-term measurements,
or the accumulation of other sample components like oil or solid substances,
may lead to an oxygen gradient.
Signal Drifts due to Temperature Gradients
A further source of imprecise measurement is insufficient temperature
compensation. If temperature compensation is used, ensure that no
temperature gradients exist between the oxygen sensor and the temperature
sensors. If measurement is conducted without temperature compensation,
bear in mind that the OXY4400 only measures correctly if the sample
temperature is constant during measurement and the temperature is the same
as the entry at the beginning of the measurement. If the temperature is
measured with a precision of 0.2C, there is a variation in the measuring
value at 100% air-saturation of 0.7% air-saturation. Select the measurement
with the temperature compensation to minimize temperature gradients.
Signal Drift due to Photo-decomposition
The oxygen-sensitive material may be subject to photo-decomposition
resulting in a signal drift. Photo-decomposition takes place only during
illumination of the sensor tip and depends on the intensity of the excitation
light. Therefore, the excitation light should be minimized. Continuous
illumination of a BOS2 oxygen sensor over a period of 24 hours may lead to a
phase drift of up to + 0.4% air-saturation measured at 100% air-saturation at
20C. However, this effect of photo-decomposition can even be minimized by
changing the measuring mode to the 30-second or minute interval mode. In
these modes, the software switches off the excitation light after recording the
data point and switches it on after the interval chosen. Use the interval method
whenever possible to increase the operational life of the sensor. Refer to
Table B–3 below.
Table B–3 Sensor drift at 0% air saturation (0 ppb)
recording 3600, 50000 and 100000 data points
Drift per 3600 points
Drift per 50000 points
Drift per 100000 points
BOS2
<0.15% air-sat.
<0.15% air-sat.
<0.25% air-sat.
BOS1
<1 ppb
<2 ppb
< 3 ppb
Signal Drift due to Too Much Ambient Light
A source of error is the detector overload due to too much ambient light. A
detector overload can be recognized by the display of the red warning light
OXY4400 Operator’s Manual
B–3
Oxygen Analyzer
“Overload” that can be found on the Main window of the PC program. Refer to
See “Warning Lights” on page 5-13.
The measurement will not be reliable if the “Overload” warning
light displays red. A detector overload causes a decrease in both
amplitude and phase angle.
The sensor should be shielded from ambient light to obtain reliable data. A
black overcoat, called optical isolation, is strongly recommended to reduce
ambient light.
Oxygen Conversion Formula
These conversion formulas are only valid in aqueous solutions and humidified
air. These formulas have to be modified if measurements have to be performed
in organic solvents or solutions with high salinity.
% O2 = % air - saturation
•
20.95
------------100
0.2095: volume content of oxygen in air
ppm in gaseous phase:
ppm[O2] = % air-saturation
1
1000000
1ppm = --------------------- =
•
1mg
----------- =
1kg
20.95
------------100
•
1
--------------- =
10000
1L
---------1L
= --------------- %
% O2
--------------10000
1
10000
Sensor Safety
The oxygen-sensitive membrane can withstand gamma-sterilization,
sterilization by etheylene oxide, steam autoclaving (140 C, 1.5 atm), CIP
conditions (cleaning-in-place, 5% NaOH, 90 C), as well as 3% H2O2
(Hydrogen Peroxide) solution, if this is required for inline cleaning.
Performance Improvement
To improve the performance over past measurements, check the calibration
values by using the calibration test gases for “0” (UHP Nitrogen 99.9999%) and
the Span test gas (100 ppm oxygen/N2). This can be completed by using a 3way valve connected to the test gas enabling the user to switch back and forth
between bottles. This can assist in verifying proper operation.
B–4
4900002060 rev. C 4-9-15
Troubleshooting
Replacing the Oxygen Probe
These instructions can be used to replace the probe for BOS1, BOS2 or BOS3
when mounted independently or to a panel.
To replace the OXY4400 probe:
1. Close the sample conditioning panel (SCS) line and turn off power to
the analyzer.
2. Disconnect the probe cable from SCS the panel.
3. Remove the existing probe and cable at the strain relief holder from
the base of the analyzer.
a. Using a standard crescent wrench, loosen the strain relief holder
by turning counterclockwise.
b. Complete the connector removal by turning the strain relief
holder by hand until it separates from the analyzer.
4. With needle nose pliers, loosen the probe nut counterclockwise.
Complete removal of the probe nut by hand.
OXY4400 Operator’s Manual
B–5
Oxygen Analyzer
5. Gently pull the probe out of the probe opening on the analyzer.
6. Remove the opposite end of the probe from the union tee on the SCS
panel.
7. Install the new oxygen probe following the instructions provided in
“Installing the Oxygen Probe” on page 2-10.
Periodic SCS Maintenance
The status of the SCS should be checked regularly to confirm proper operation
(pressures, flows, etc.) and detect potential problems or failures before
damage occurs. If maintenance is required, isolate the part of the system to be
serviced by following the appropriate procedure under “Shutting Down the
SCS” on page 3-3.
All filter elements should be checked periodically for loading. Obstruction of a
filter element can be observed by a decreasing supply pressure or bypass flow.
If loading of a filter is observed, the filter should be cleaned and the filter
element replaced. After observation for some time, a regular schedule can be
determined for replacement of filter elements.
No other regularly scheduled maintenance should be required for the system.
Preventive and On-Demand SCS Maintenance
Preventive and on-demand maintenance will be required when components
and parts deteriorate or fail as a result of continuous use. The performance of
the entire SCS and individual components should be monitored regularly so
that maintenance may be performed on a scheduled basis in order to prevent
a failure that could take the system out of operation.
The SCS is designed for convenient removal and replacement of component
parts. Complete spare components should always be available. In general, if a
problem or failure occurs, the complete part should be removed and replaced
to limit system down time. Some components may be repaired (replacement
of seats and seals, etc.) and then reused.
If the sample supply line does not appear to completely clear during normal
operation, it may be necessary to clean the sample transport line to remove
any liquid that may adhere to the wall of the tubing. The sample transport line
should be purged dry with air or nitrogen before the system is placed back in
operation.
The system must be taken out of service during any
cleaning of the sample transport line.
If liquid makes it into the SCS, a filter element may become obstructed leading
to a decreasing supply pressure or bypass flow. If obstruction of a filter is
observed, the filter should be cleaned and the filter element replaced.
B–6
4900002060 rev. C 4-9-15
Troubleshooting
Regular SCS Status Check
1. Open the enclosure door, if analyzer is mounted in an enclosure.
2. Read and record the flowmeter settings while the gas is flowing.
3. Close the enclosure door, if applicable.
If your SCS is contained within a heated cabinet, do not
leave the door open any longer than absolutely necessary.
SpectraSensors recommends no more than 60 seconds.
Opening the door may affect the temperature reading until
the temperature is stabilized.
4. Compare the current readings with the past readings to determine
any variations. Reading levels should remain consistent.
5. If reading levels decrease, check the filters.
To check filters:
1. Shut down the system following the procedure in “Shutting Down
the SCS” on page 3-3.
2. Inspect, repair or replace the filter as required.
For additional information, contact SpectraSensors’
Technical Service Group at 800-619-2861.
3. Restart the system following the procedure in “Starting up the
SCS” on page 3-2.
Service Contact
If the troubleshooting solutions do not resolve the problem, contact customer
service. To return the unit for service or replacement, refer to "Return
Material Authorization".
Customer Service
4333 W Sam Houston Pkwy N, Suite 100
Houston, TX 77043-1223
United States of America
For SpectraSensors North America Service:
Phone: 1-800-619-2861, and press 2 for Service
Fax: 1-713-856-6623
E-mail: [email protected]
OXY4400 Operator’s Manual
B–7
Oxygen Analyzer
For SpectraSensors International Service, please contact the
SpectraSensors distributor in your area, or contact:
Phone: +1-713-466-3172, and press 2 for Service
Fax: +1-713-856-6623
E-mail: [email protected]
Return Material Authorization
If returning the unit is required, obtain a Return Materials Authorization
(RMA) Number from Customer Service before returning the analyzer to the
factory. Your service representative can determine whether the analyzer can be
serviced on site or should be returned to the factory. All returns should be
shipped to:
11027 Arrow Rte.
Rancho Cucamonga, CA 91730-4866
United States of America
1-909-948-4100
Packing and Storage
SpectraSensors’ OXY4400 analyzers and auxiliary equipment are shipped from
the factory in appropriate packaging. Depending on the size and weight, the
packaging may consist of a cardboard-skinned container or a wooden crate. All
inlets and vents are capped and protected when packaged for shipment.
If the equipment is to be shipped or stored for any length of time, it should be
packed in the original packaging when shipped when shipped from the factory.
If analyzer has been installed and or operated (even for purposes of a
demonstration), the system should first be decontaminated (purged with an
inert gas) before powering down the analyzer.
Process samples may contain hazardous material in potentially
flammable and/or toxic concentrations. Personnel should have a
thorough knowledge and understanding of the physical properties
of the sample and prescribed safety precautions before installing,
operating or maintaining the analyzer.
To prepare the analyzer for shipment or storage:
1. Shut off the process gas flow.
2. Allow all residual gas to dissipate from the lines.
3. Connect a purge supply, regulated to the specified sample supply
pressure, to the sample supply port.
4. Confirm that any valves controlling the sample flow effluent to the
low pressure flare or atmospheric vent are open.
B–8
4900002060 rev. C 4-9-15
Troubleshooting
5. Turn on the purge supply and purge the system to clear any residual
process gases.
6. Turn off the purge supply.
7. Allow all residual gas to dissipate from the lines.
8. Close any valves controlling the sample flow effluent to the low
pressure flare or atmospheric vent.
9. Disconnect power to the system.
10. Disconnect all tubing and signal connections.
11. Cap all inlets and outlets to prevent foreign material such as dust or
water from entering the system).
12. Pack the equipment in the original packaging in which it was
shipped, if available. If the original packaging material is no longer
available, the equipment should be adequately secured (to prevent
excessive shock or vibration).
13. If returning the analyzer to the factory, complete the
Decontamination Form provided by SpectraSensors "Customer
Service" and attach to the outside of the shipping package as
instructed before shipping.
Storage
The packaged analyzer should be stored in a sheltered environment that is
temperature controlled between -20C (-4F) and 50C (122F), and should
not be exposed to direct sun, rain, snow, condensing humidity or corrosive
environments.
Disclaimers
SpectraSensors accepts no responsibility for consequential damages arising
from the use of this equipment. Liability is limited to replacement and/or repair
of defective components.
This manual contains information protected by copyright. No part of this guide
may be photocopied or reproduced in any form without prior written consent
from SpectraSensors.
OXY4400 Operator’s Manual
B–9
Oxygen Analyzer
THIS PAGE INTENTIONALLY LEFT BLANK
B–10
4900002060 rev. C 4-9-15
INDEX
Numerics
4-20 mA current loop 2–6
A
Analyzer overview 1–2
B
G
Gas leaks 2–9
Gas lines
Connection 2–7
Sample supply line 2–8
Graphical window display
Status 5–14
Zoom 5–14
Ground wire 2–4, 2–6
H
Basic equipment requirements 1–7
C
Calibration
Temperature
Manual 4–15
Off 4–14
On 4–11
Cautions 1–1
Conditioning the analyzer tubing 2–14
Connecting the optional automatic
validation 2–14
Connecting the sample return line 2–8
Connecting the sample supply line 2–8
Current loop 2–6, 2–7
D
DC systems 2–4
Diagrams and schematics A–4, A–5, A–6
E
Enclosure
Electronics 2–4, 2–7
Heated 2–5
Heater 2–4, 2–5
Erroneous readings 2–14
Error codes B–2
F
Field pressure reducing regulator 3–1
Field pressure reducing station 3–2
Flowmeter 3–1, 3–3, 3–4
Sample 3–2
OXY4400 Operator’s Manual
Hardware 2–2
Heated enclosure 2–4, 2–5, 2–6
I
Installation
Hardware 2–1
Software 5–1
L
Leak detector 2–9
M
Mating terminal block 2–6, 2–7
Measurement
Sampling Rate 4–6
System 4–6
Temperature 4–6, 4–8, 4–9
Measurement recommendations B–2
Membrane separator 3–1
Menu
Main 4–2
Calibration 4–9
Calibrate 4–10
Status 4–10
Configuration 4–18
Analog In 4–20
Analog Out 4–18
Clock/Date 4–21
Display 4–21
Reset Config 4–21
Status 4–18
Data logging 4–17
Diag & Test 4–21
Index–1
Oxygen Analyzer
Inputs 4–22
Outputs 4–22
System 4–22
O
Optional analyzer hood 2–3
Output Signal
4-20 mA current loop 2–6
Serial output 2–6
P
PC Operation
Control Bar 5–5
LED intensity 5–10
Advanced 5–11
Auto adjust 5–10
Menu bar 5–3
Menu Bar Definitions 5–4
Oxygen unit adjustment 5–12
PC Operations
Analog Input 5–9
Analog Output 5–8
Calibration Assistant 5–7
Control Buttons 5–5
Data Logging 5–7
Instrument Info 5–8
Measurement Assistant 5–6
Pin numbers 2–7
Port
Bypass/sample return 2–8
Sample supply 3–1
Power connections 4–1
Power terminal box 2–5
Pre-calibration 4–3
Pressure regulator 3–1, 3–3
Start-up 3–2
Sample gas 3–1
Sample probe 3–1, 3–2, 3–3
Sensor Constants 4–5
Sensor safety B–4
Sensor Type 4–3
Serial cable 2–7
Serial connection 2–6
Service contact B–8
Signal drift B–3
Stainless steel tubing 2–7
System conditioning 2–14
T
Technical notes A–2
Tools 2–2
V
Valve
Control 3–3
Flowmeter control 3–3
Isolation 3–1, 3–2, 3–3
Metering 3–1, 3–3
Relief 3–2
Shut-off 3–1, 3–2, 3–4
W
Warning lights 5–13, B–3
Warnings
General 1–1
R
Return materials authorization (RMA)
number B–8
S
Safety 1–5
Sample bypass 3–2, 3–4
Start-up 3–2
Sample conditioning system (SCS)
Periodic maintenance B–6
Preventative and demand
maintenance B–6
Shut down 3–3
Index–2
4900002060 rev. C 4-9-15

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