Advanced Instruments GPR-1800 IS Manual (IS)

Technical Specifications *

Accuracy: < 2% of FS range under constant conditions
Analysis:

Application:

Approvals: Certified for use in hazardous areas - see lower right

Area Classification: Certified for use in hazardous areas - see lower right
Alarms: None

Calibration:

Compensation: Temperature
Connections: 1/8" compression tube fittings
Controls:

Display:

Enclosure: NEMA Type 3R suitable for rain in outdoor applications
Flow: Not flow sensitive; recommended flow rate 1-2 SCFH

Linearity: ±1% of full scale
Pressure:

Power: 18-24 VDC
Response Time: 90% of final reading in 10 seconds
Sample System: Sample flow meter; options available, see other side
Sensitivity: < 0.5% of FS range
Sensor Model:

Sensor Life: 24 months in < 1000 PPM O2 at 25ºC and 1 atm
Signal Output: 4-20mA non-isolated or 1-5V

Operating Range: 5ºC to 45ºC (GPR sensor); -10º to 45ºC (XLT sensor)
Warranty: 12 months analyzer; 12 months sensor

Wetted Parts: Stainless steel

0-10, 0-100, 0-1000 PPM, 0-1%, 0-25% (CAL) FS
Auto-ranging or manual lock on a single range

Oxygen analysis in inert, hydrocarbon, helium, hydro­gen, mixed and acid (CO2) gas streams

UL: United States: UL 1203, UL 913, UL 508
Canada: CAN/CSA C22.2 No. 30-M1986,
CAN/CSA C22.2 No. 157-92,
CAN/CSA C22.2 No. 14-10
ATEX: Directive 94/9/EC

Max interval—3 months. Use certified span gas with O2
content (balance N2) approximating 80% of full scale
for fast 20-30 minute recovery to online use. Alterna­tively, air calibrate with clean source of compressed or
ambient (20.9% O2) air on 0-25% range and allow 60
minutes on zero gas to recover to 10 ppm. For opti­mum accuracy, calibrate one range higher than the
range of interest.

Water resistant keypad; menu driven range selection,
calibration and system functions

Graphical LCD 2.75” x 1.375”; resolution 0.01 PPM;

displays real time ambient temperature and pressure

Inlet - regulate to 5-30 psig to deliver 1-2 SCFH flow;
vent - atmospheric

GPR-12-333 for non-acid (CO2) gas streams
XLT-12-333 for gases containing > 0.5% CO2

UL or ATEX Certified for Hazardous Areas

GPR-1800 IS

PPM Oxygen Transmitter

Loop Powered PPM O2 Transmitter

Optional Modular Sample Systems

Exia

UL Certified

File E343386

Class I, Division 1, Groups C and D

T4 T

ATEX Certified - Directive 94/9/EC

Examination Cert: INERIS 07ATEX0025X

II 2 G
Ex d [ib] ib IIB T4 Gb
Tamb –20ºC to +50ºC

-20⁰C to +50⁰C

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0080

Optional Equipment

Sample conditioning systems (see back page) - Contact factory

* Specifications subject to change without notice

2855 Metropolitan Place, Pomona, CA 91767 USA ♦ Tel: 909-392-6900, Fax: 909-392-3665, www.aii1.com, e-mail: info@aii1.com Rev 10/15

ISO 9001:2008 Certified

INTERTEK Certificate No. 485

Advanced Instruments Inc.

GPR 1800 IS

PPM OXYGEN ANALYZER

Shown with optional Sampling System

Owner's Manual

Revised Sep 16,, 2015

2855 Metropolitan Place, Pomona, California 91767 USA ♦ Tel: 909-392-6900, Fax: 909-392-3665, e-mail:

info@aii1.com

Table of Contents

R

Introduction

Quality Control Certification

Safety

Features & Specifications

Operation

Maintenance

Spare Parts

Troubleshooting

Warranty

Material Safety Data Sheets

Drawings

Advanced Instruments, Inc

1

2

3

4

5

6

7

8

9

1
0

A
/

Explosion Proofing Electrical Connections Appendix

Correlating readings – LCD display to 4-20mA signal Appendix
output

H2S Scrubber, Sample System, Media MSDS Appendix

Maintenance H2S Scrubber & Coalescing Filter Appendix

ppendices referenced above are an integral part of the documentation, installation and maintenance of this anaThe a lyzer

to comply with all applicable directives. It is important that users review these documents before proceeding.

A

B

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Advanced Instruments, Inc

1. Introduction

Your new oxygen analyzer incorporates an advanced electrochemical sensor specific to oxygen along with state-of-the-art
digital electronics designed to give you years of reliable precise oxygen measurements in a variety of industrial oxygen
applications. More importantly, it has been constructed as explosion proof/intrinsically safe in accordance with Safety
Standards: UL 913 Seventh Edition, Referencing UL 60079-0:2005 and UL 60079-11:2009 and CSA C22.2 No. 157-92
Third Edition for use in Class I, Div 1, Groups C and D hazardous locations and the ATEX Directives 94/9/EC for zone 1
Group IIB.

Please refer to Appendix A for making electrical connections that maintains the desired level of protection.

To obtain maximum performance from your new oxygen analyzer, please read and follow the guidelines provided in this
Owner’s Manual.

Every effort has been made to select the most reliable state of the art materials and components, to design the analyzer for
superior performance and minimal cost of ownership. This analyzer was tested thoroughly by the manufacturer prior to
shipment for best performance.

However, modern electronic devices do require service from time to time. The warranty included herein plus a staff of
trained professional technicians to quickly service your transmitter is your assurance that we stand behind every
transmitter sold.

The serial number of this analyzer may be found on the inside the analyzer enclosure. You should note the serial number
in the space provided and retains this Owner’s Manual as a permanent record of your purchase, for future reference and
for warranty considerations.

Serial Number: _______________________

Advanced Instruments Inc. appreciates your business and pledges to make every effort to maintain the highest possible
quality standards with respect to product design, manufacturing and service.

Analytical Industries Inc.

dba Advanced Instruments Inc.

2855 Metropolitan Place, Pomona, CA 91767 USA

GPR-1800 IS/2800 IS

0080

Serial No.:

Year of Manufacture:

INERIS 08ATEX0036

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-20⁰C to +50⁰C

amb

WARNING: POTENTIAL ELECTROSTATIC CHARGING HAZARD – SEE
INSTRUCTIONS

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3. General Safety & Installation

This section summarizes the essential precautions applicable to the GPR-1500 IS Oxygen Analyzer. Additional
precautions specific to individual transmitter are contained in the following sections of this manual. To operate the
transmitter safely and obtain maximum performance follow the basic guidelines outlined in this Owner’s Manual.

Caution: This symbol is used throughout the Owner’s Manual to Caution and alert the user to recommended
safety and/or operating guidelines.

Warning: This symbol is used throughout the Owner’s Manual to Warn and alert the user of the presence of
electrostatic discharge.

Danger: This symbol is used throughout the Owner’s Manual to identify sources of immediate Danger such as
the presence of hazardous voltages.

Read Instructions: Before operating the transmitter read the instructions.

Retain Instructions: The safety precautions and operating instructions found in the Owner’s Manual should be retained

for future reference.

Heed Warnings: Follow all warnings on the transmitter, accessories (if any) and in this Owner’s Manual.

Follow Instructions: Observe all precautions and operating instructions. Failure to do so may result in personal injury or

damage to the transmitter.

Analyzer label ULc

WARNING – Potential Explosion Hazard: The devices are not intended for use in atmospheres or with sample gas streams
containing oxygen concentration greater than 21 percent by volume (ambient air) and are only intended for use in gases or
gas mixtures classified as Class I, Div 1, Groups C and D hazardous locations or in non-hazardous locations, when used in
the United States or Canada.

4

2. Quality Control Certification

See packing slip

Advanced Instruments, Inc

5

Advanced Instruments, Inc

Maintenance

Serviceability: Except for replacing the oxygen sensor, there are no parts inside the analyzer for the operator to service.

Only trained personnel with the authorization of their supervisor should conduct maintenance.

WARNING- Substitution of Components May Impair Intrinsic Safety

Oxygen Sensor: DO NOT open the sensor. The sensor contains a corrosive liquid electrolyte that could be harmful if
touched or ingested, refer to the Material Safety Data Sheet contained in the Owner’s Manual appendix. Avoid contact with
any liquid or crystal type powder in or around the sensor or sensor housing, as either could be a form of electrolyte.
Leaking sensors should be disposed of in accordance with local regulations.

Troubleshooting: Consult the guidelines in Section 8 for advice on the common operating errors before concluding that
your analyzer is faulty. Do not attempt to service the analyzer beyond those means described in this Owner’s Manual.

Do not attempt to make repairs by yourself as this will void the warranty as per Section 10 and may result in electrical
shock, injury or damage. All other servicing should be referred to qualified service personnel.

Cleaning: The analyzer should be cleaned only as recommended by the manufacturer. Wipe off dust and dirt from the
outside of the unit with a soft damp cloth then dry immediately. Do not use solvents or chemicals.

Nonuse Periods: If the analyzer is equipped with a range switch advance the switch to the OFF position and disconnect
the power when the transmitter is left unused for a long period of time.

Installation

This analyzer has been constructed in compliance with

EN 60079-0 : 2009

EN 60079-1 : 2007

EN 60079-11 : 2012

For USA and Canada

UL 913, 7

CSA C22.2 No. 157-92

It must be installed in accordance with

EN 60079-14

For USA - NEC and Canada – CEC Standards

WARNING - Potential Explosion Hazard – See Warning in Section 4 – Features and Specifications

Gas Sample Stream: Ensure the gas stream composition of the application is consistent with the specifications and

if in doubt, review the application and consult the factory before initiating the installation. Note: In natural gas applications
such as extraction and transmission, a low voltage current is applied to the pipeline itself to inhibit corrosion of the pipeline.
As a result, electronic devices connected to the pipeline can be affected unless they are adequately grounded.

Contaminant Gases: A gas scrubber and flow indicator with integral metering valve are required upstream of the

analyzer to remove any interfering gases such as oxides of sulfur and nitrogen or hydrogen sulfide that can interfere with
measurement and cause reduction in the expected life of the sensor. Consult the factory for recommendations concerning
the proper selection and installation of components.

Expected Sensor Life: With reference to the publish specification located at the last page of this manual, the

expected life of all oxygen sensors is predicated on oxygen concentration (< 1000 PPM for trace sensor or air for %
sensor), temperature (77°F/25°C) and pressure (1 atmosphere) in “normal” applications. Deviations from standard
conditions will affect the life of the sensor. As a rule of thumb sensor life is inversely proportional to changes in the
pressure and temperature.

Accuracy & Calibration: Refer to section 5 Operation.
Materials: Assemble the necessary zero, sample and span gases and optional components such as valves, coalescing

or particulate filters, and pumps as dictated by the application. Stainless steel tubing is essential for maintaining the
integrity of the gas stream for low % or PPM O

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Operating Temperature: The sample must be sufficiently cooled before it enters the analyzer and any

optional components. A coiled 10 foot length of ¼” stainless steel tubing is sufficient for cooling sample gases
as high as 1,800 ºF to ambient. The recommended operating temperature is below 35 ºC. However, the

analyzer may be operated at temperature up to 45 ºC on an intermittent basis but the user is expected to
accept a reduction in expected sensor life –as a rule of thumb, for every degree ºC increase in temperature (above 25 ºC),
the sensor life is reduced by approximately 2.5%. If the analyzer is to be in a cold environment (below 0oF, install the
analyzer ina heated enclosure to prevent the sensor from freezing).

Warning – Sample Stream entering unit must never exceed 50

0

C

Heat: Situate and store the analyzer away from direct sources of heat.
Liquid and Object Entry: The analyzer should not be immersed in any liquid. Care should be taken so that liquids

are not spilled into and objects do not fall into the inside of the analyzer.

Handling: Do not use force when using the switches, knobs or other mechanical components. Before moving your

analyzer be sure to disconnect the wiring/power cord and any cables connected to the output terminals of the analyzer.

Sample Pressure and Flow

All electrochemical oxygen sensors respond to partial pressure changes in oxygen. The sensors are equally capable of
analyzing the oxygen content of a flowing sample gas stream or monitoring the oxygen concentration in ambient air (such
as a confined space in a control room or an open area around a landfill or bio-pond). The following is applicable to
analyzers equipped with fuel cell type oxygen sensors.

Analyzers designed for in-situ ambient or area monitoring has no real sample inlet and vent. The sensor is exposed directly
to the sample gas and it is intended to operate at atmospheric pressure. The analyzer has a built-in pressure sensor and
the sensor output is automatically compensated for any atmospheric pressure changes.

Inlet Pressure: For the analyzers designed to measure oxygen in a flowing gas stream, the inlet sample pressure

must be regulated between 5-30 psig. Although the rating of the SS tubing and tube fittings/valves itself is considerably
higher (more than 100 psig), a sample pressure of 5-30 psig is recommended for ease of control of sample flow.

The analyzer equipped with a sample system has designated SAMPLE and VENT ports. Connect SAMPLE gas to
SAMPLE and the vent to the VENT ports only.

Caution: If the analyzer is equipped with an optional H2S scrubber, sample inlet pressure must not exceed 30
psig.

Outlet Pressure: In applications where sample pressure is positive, the sample must be vented to an exhaust pipe at

a pressure less than the inlet pressure so that the sample gas can flow through the sensor housing. Ideally, the sample
must be vented to atmospheric pressure.

Note: The sensor may be used at a slight positive pressure (e.g., when sample is vented to a common exhaust where the
pressure might be higher than 1 atmosphere). However, the pressure at the sensor must be maintained at all times
including during the span calibration. This may be accomplished by using a back-pressure regulator at vent line of the
analyzer. Caution: A sudden change in pressure at the sensor may result in the sensor electrolyte leakage.

Flow rates of 1-5 SCFH cause no appreciable change in the oxygen reading. However, flow rates above 5 SCFH may
generate a slight backpressure on the sensor resulting in erroneous oxygen readings.

Caution: Do not place your finger over the vent (it pressurizes the sensor) to test the flow indicator when gas is flowing to
the sensor. Removing your finger (the restriction) generates a vacuum on the sensor and may damage the sensor (voiding
the sensor warranty).

Application Pressure - Positive: A flow indicator with integral metering valve positioned upstream of the

sensor is recommended for controlling the sample flow rate between 1-5 SCFH. If a separate flow control valve and a flow
indicator is used, position flow control valve upstream of the sensor and position a flow indicator downstream of the sensor.
If necessary, a pressure regulator upstream of the flow control valve should be used to regulate the inlet pressure between
5-30 psig.

Caution: If the analyzer is equipped with a H2S scrubber as part of an optional sample conditioning system,
inlet pressure must not exceed 30 psig.

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Advanced Instruments, Inc

Application Pressure - Atmospheric or Slightly Negative: For % oxygen measurements, an

optional external sample pump may be used upstream of the sensor to push the sample across the sensor and out to
atmosphere. For PPM oxygen measurements, an optional external sampling pump should be positioned downstream of
the sensor to draw the sample from the process, by the sensor and out to atmosphere. A flow meter is generally not
necessary to obtain the recommended flow rate with most sampling pumps. However, if the sample pump can pull/push
more than 5 SCFH, a flow control must be used to control the sample flow. The flow control valve must be positioned in
such a way that it does not generate any vacuum on the sensor.

Caution: If the analyzer is equipped with a flow indicator with integral metering valve or a metering flow
control valve upstream of the sensor and the pump is installed downstream of sensor- open the metering
valve completely before turning the pump ON to avoid drawing a vacuum on the sensor and placing an u
burden on the pump.

If pump loading is a consideration, a second throttle valve on the pump’s inlet side may be necessary to provide a bypass
path so the sample flow rate is within the above parameters.

ndue

Moisture & Particulates: Installation of a suitable coalescing or particulate filter is required to remove

condensation, moisture and/or particulates from the sample gas to prevent erroneous analysis readings and damage to the
sensor or other optional components. Moisture and/or particulates do not necessarily damage the sensor. However,
collection of moisture/particulate on the sensing surface can block or inhibit the diffusion of sample gas into the sensor
resulting in a reduction of sensor signal output – and the appearance of a sensor failure. Consult the factory for
recommendations concerning the proper selection and installation of optional components.

Moisture and/or particulates generally can be removed from the sensor by opening the sensor housing and either blowing
on the sensing surface or gently wiping or brushing the sensing surface with damp cloth. Caution: Minimize the exposure
of PPM sensors to air during this cleaning process. Air calibration followed by purging with zero or a gas with a low PPM
oxygen concentration is recommended after the cleaning process is completed.

Mounting: The analyzer is approved for indoor as well as outdoor use. However, avoid mounting in an area where

direct sun might heat up the analyzer beyond the recommended operating temperature range. If possible, install a small
hood over the analyzer for rain water drain and to prevent over-heating of analyzer.

Gas Connections: The Inlet and outlet vent gas lines require 1/8” or ¼” stainless steel compression type tube

fittings. The sample inlet tubing must be metallic, preferably SS. The sample vent line may be of SS or hard plastic tubing
with low gas permeability.

Power: Supply power to the analyzer only as rated by the specification or markings on the analyzer enclosure. The

GPR-1500 IS is powered by 12-28 VDC supply. The wiring that connects the analyzer to the power source should be
installed in accordance with recognized electrical standards. Ensure that the analyzer case is properly grounded and
meets the requirements for area classification where the analyzer is installed. Never yank wiring to remove it from a
terminal connection.

The maximum power the analyzer consumes is no more than 7 Watts.

8

4. Features & Specifications

Advanced Instruments, Inc

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*WARNING - Potential Explosion Hazard : The devices are not intended for use in atmosphere or with sample gas

streams containing more than 21% oxygen (ambient air) and are only intended for use with or in gases or gas mixtures
classified as Class I, Div 1 Groups C and D hazardous location gases or in non-hazardous locations when used in the
United States or Canada.

**NOTE 1: Optional Sampling system shown is not part of UL/cUL Classification.

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Advanced Instruments, Inc

5. Operation
Principle of Operation

The GPR-1800 IS Oxygen Analyzer incorporates a variety of advanced galvanic fuel cell type oxygen sensors. These
sensors are very specific to oxygen and generate an electrical signal proportional to the amount of oxygen present in a gas
stream. The selection of A particular type of sensor depends on the composition of the sample gas stream. Consult the
factory for recommendation.

The analyzer is configured in two sections. The signal processing electronics and sensor are housed in a general purpose
NEMA 4X rated enclosure. The terminals for incoming power, signal output and intrinsic safety barriers are mounted on a
PCB housed in an explosion proof enclosure.

The two sets of electronics are interconnected using an explosion proof Y-fitting, explosion proof packing fiber and sealing
cement – see Appendix A. Once connected, the intrinsic safety barriers limit the amount of power that flows to and from
the signal processing electronics effectively preventing an explosive condition. The analyzer design conforms to the ATEX
directive for equipment as intrinsically safe and has been approved by an independent body:

The analyzer carries the following area classification

II 2 G

Ex d ib IIB T4 Gb

T

For USA and Canada

UL 913, 7

CSA C22.2 No. 157-92

It must be installed in accordance with

EN 60079-14

For USA - NEC and Canada – CEC Standards

The GPR-1800 IS also meets the intrinsic safety standards required for use in Class I, Division 1, Groups C, D hazardous
areas.

-20⁰C to +50⁰C

amb

WARNING: POTENTIAL ELECTROSTATIC CHARGING HAZARD-SEE INSTRUCTION

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Advanced Instruments, Inc

Advanced Galvanic Sensor Technology

All galvanic type sensors function on the same principle and are specific to oxygen. They measure the partial pressure of
oxygen from low PPM to 100% levels in inert gases, gaseous hydrocarbons, helium, hydrogen and mixed gases

Oxygen, the fuel for this electrochemical transducer, diffusing into the sensor, reacts electrochemically at the sensing
electrode to produce an electrical current output proportional to the oxygen concentration in the gas phase. The sensor’s
signal output is linear over all measuring ranges and remains virtually constant over its useful life. The sensor requires no
maintenance and is easily and safely replaced at the end of its useful life.

Proprietary advancements in design and chemistry add significant advantages to this extremely versatile oxygen sensing
technology. Sensors for low % analysis recover from air to low % levels in seconds, exhibit longer life and reliable quality.
The expected life of our new generation of percentage range sensors now range from 32 months to ten years with faster
response times and greater stability. Another significant development involves expanding the operating temperature range
for percentage range sensors from -30°C to 50°C. Contact factory for more specific information about your application.

NOTE- Check the product label for safe operating conditions

The PPM sensors recover from an upset condition to low PPM level in a matter of few minutes. These sensors show
excellent stability over its useful life.

Electronics

The signal generated by the sensor is processed by state of the art low power micro-processor based digital circuitry. The
first stage amplifies the signal. The second stage eliminates the low frequency noise. The third stage employs a high
frequency filter and compensates for signal output variations caused by ambient temperature changes. The result is a very
stable signal. Sample oxygen is analyzed very accurately. Response time of 90% of full scale is less than 10 seconds
(actual experience may vary due to the integrity of sample line connections, dead volume and flow rate selected) on all
ranges under ambient monitoring conditions. Sensitivity is typically 0.5% of full scale of the low range. Oxygen readings
may be recorded by an external device via the 4-20 mA or 1-5V signal output.

Sample System

See Section 4, Features and Specification, Note 1 for exclusions.

The standard GPR-1800-IS is supplied without a sample conditioning system thereby giving users the option of adding
their own or purchasing a factory designed sample conditioning system, see section 2 QC Certification for optional
equipment ordered. Whatever the choice, the sample must be properly conditioned before introducing it to the sensor to
ensure an accurate oxygen measurement.

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The GPR-1800 IS is generally supplied with a minimum of a sample flow control valve and a flow meter. Users interested
in adding their own sample conditioning system should consult the factory. Advanced Instruments Inc. offers a full range of
sample handling, conditioning and expertise to meet your application requirements. Contact us at 909-392-6900 or e-mail
us at info@aii1.com

.

Calibration & Accuracy Overview

Single Point Calibration: As previously described the
galvanic type oxygen sensor generates an electrical
current proportional to the oxygen concentration in the
sample gas. In the absence of oxygen the sensor
exhibits an absolute zero, e.g. the sensor does not
generate a current output in the absence of oxygen.
Given these linearity and absolute zero properties,
single point calibration is possible.

Pressure: Because sensors are sensitive to the

partial pressure of oxygen in the sample gas, their
output is a function of the number of molecules of
oxygen 'per unit volume'. Readouts in percent are
permissible only when the total pressure of the sample
gas being analyzed remains constant. The pressure of
the sample gas and that of the calibration gas must be
the same.

Temperature: The rate at which oxygen molecules diffuse into the sensor is controlled by a Teflon membrane

otherwise known as an 'oxygen diffusion limiting barrier' and all diffusion processes are temperature sensitive, the fact the
sensor's electrical output will vary with temperature is normal. This variation is relatively constant (2.5% per ºC). A
temperature compensation circuit employing a thermistor and a network of resisters offsets this effect with an accuracy of

5% or better over a wide operating temperature range e.g., 5-45 oC can be obtained thus the signal output remains

+
virtually independent of ambient temperature. There is extremely low error in measurement if the calibration and sampling
are performed at similar temperatures (within +/- 5 ºC. Conversely, a temperature variation of 10 ºC may produce an error
of < 2% of full scale.

Accuracy: In light of the above parameters, the overall accuracy of an analyzer is affected by two types of errors: 1)

'percent of reading errors', illustrated by Graph A below, is contributed by the temperature compensation circuit (tolerance
in the thermistor value, variation in temperature coefficient of the thermistor, tolerances in resistors values and the
accuracy in the measuring devices, e.g., LCD display and 2) 'percent of full scale errors', illustrated by Graph B, such as1­2% offset errors in readout and calibration devices. Other errors are 'spanned out' during calibration, especially when
analyzer is calibrated close to the top end of the measuring range.

Graph C illustrates these 'worse case' specifications that are typically used to develop an overall accuracy statement of <
1% of full scale at constant temperature or < 5% over the operating temperature range. The QC testing error is typically <

0.5% prior to shipment of analyzer from the factory.

Example 1: As illustrated by Graph A, any error during a span adjustment at lower end of the scale, e.g., 20.9% (air) on a
100% full scale range, would be multiplied by a factor of 4.78 (100/20.9) when making measurements close to 100% O2.
Conversely, an error during a span adjustment close to the top end of the range, e.g., at 100% is reduced proportionately
for measurements of oxygen concentrations near the bottom end of the range.

Graph B represents a constant error over the entire measuring range. This error is generally associated with the measuring
e.g., LCD and or calibrating devices, e.g., current simulator or current/voltage measuring devices.

Potential Explosion Hazard – See warning in Section 4 – Features and Specifications

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Mounting the Transmitter

The GPR-1800 IS analyzer consists of two interconnected enclosures (without the optional sample conditioning system
and panel) and measures 8”H x 15-3/4”W x 7”D. This configuration is designed to be mounted directly to any flat vertical
surface, wall or bulkhead plate by using eight (4)
of the appropriate screws.

To facilitate servicing the interior of the
transmitters, secure the back plate to a vertical
surface approximately 5 feet from the floor or a
level accessible to service personnel. This
requires the user to supply four (4) additional
proper size screws and anchors.

Caution: Do not remove or discard

the gaskets from either the Ex

enclosure or the fiberglass enclosure.

Failure to reinstall either of the
gaskets will void the NEMA 4, UL Type 3R rating
and the immunity to RFI/EMI.

Transmitter without a sample conditioning system

The transmitters design provides immunity from RFI/EMI by maintaining a good conductive contact between the two halves
of the enclosures via a conductive gasket (the smaller enclosure containing signal processing electronics) The surfaces
contacting the conductive gasket are unpainted. Do not paint these areas. Painting will negate the RFI/EMI protection.

Note: If equipped with the optional H2S sample conditioning system, the transmitter and sample system are mounted to a
back panel 15-3/4”H x 15-3/4”W with four
mounting holes. Mount the entire panel to any
vertical flat surface.

See Section 4 – Features and Specifications, for
exclusions

If the ambient temperature is expected to fall
below -18 degree C (0 degree F), install the
analyzer in a heated enclosure to prevent sensor
from freezing.

Transmitter with sample conditioning system

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Advanced Instruments, Inc

Gas Connections

The GPR-1800 IS with its standard flow through configuration is designed for positive pressure samples and requires
connections for incoming sample and outgoing vent lines. Zero and span inlet ports are offered as part of the optional
sample systems. The user is responsible for calibration gases and other required components, follow procedure below to
establish gas connections.

Procedure

Caution: Do not change the factory setting until instructed to do in this manual.

Before introducing sample gas to the analyzer

• Regulate the sample pressure as described in “Pressure and Flow” section above.

• Connect a 1/8” or ¼” vent line to the compression fitting to be used for venting the sample.

• Connect a 1/8” or ¼” sample line to the compression fitting to be used to bring SAMPLE gas to the analyzer.

• If equipped with optional SPAN and/or ZERO ports, connect the SPAN and the ZERO gas lines to the respective

SPAN and ZERO ports of the analyzer

• Set the SAMPLE, SPAN and the ZERO gas pressure between 5-30 psig..

• Select sample gas and allow it to flow through the transmitters and set the flow rate to1- 2 SCFH.

Note: If equipped with the optional H2S sample conditioning system: Regulate the pressure so that it does not exceed 30
psig.

Flow rates of 1-5 SCFH cause no appreciable change in the oxygen reading. However, flow rates above 5 SCFH may
generate a backpressure and cause erroneous oxygen readings due to fact that the smaller diameter of the integral
sample system tubing cannot vent the sample gas quickly at higher flow rates. If the analyzer is not equipped with an
integral flow control valve, a flow control metering valve with a flow indicator upstream of the sensor must be installed to
control the flow rate of the sample gas. A flow rate of 1-2 SCFH or 0.5-1 liter per minute is recommended for optimum
performance.

Caution: Do not place your finger over the vent (it pressurizes the sensor) to test the flow indicator when gas is

flowing to the sensor. Removing your finger (the restriction) generates a sudden vacuum on the sensor and

may lead to electrolyte leakage thus causing damage to the sensor (will void sensor warranty).

15

Electrical Connections

Incoming power/signal output connections are
made to terminal block mounted on a PCB located
in the explosion proof enclosure.

Do not supply voltage more than specified in this
manual and noted near the power input terminal of the
analyzer.

The PCB in the explosion proof enclosure contains a power
limiting intrinsic safety barrier that limit the total power
available at the PCB electronics mounted in the general
purpose enclosure.

With proper insulation of the incoming power (see Appendix
A), this configuration of the GPR-1800 IS conforms to the
ATEX directives for equipments for use in hazardous area. The
analyzer meets the following area classification:

Ex/Explosion proof enclosure for power/signal output

Advanced Instruments, Inc

II 2 G

Ex d ib IIB T4 Gb

T

The GPR-1800-IS also meets the intrinsic safety standards required for use in Class I, Division 1, Group C, D hazardous
areas.

The A-1166 IS PCB in the Ex enclosure contains 2 fuses, one plug-in (brown color) rated at 100 mA and the rest mounted
on the PCB (after the DC voltage is regulated to lower safe value, these fuse meet barrier network standard EN 50020).

Analyzer ground terminal must be connected to a ground

-20⁰C to +50⁰C

amb

Avoid electrostatic discharge – Clean all surfaces with a damp cloth only.

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Advanced Instruments, Inc

Hazardous Area Installation

The GPR-1800-IS may be installed in a hazardous area with proper insulation of the incoming power, see Appendix A. A
18-28 VDC power supply with a shielded power cable is recommended. The power cable to the Ex enclosure must be
supplied through a conduit approved for use in hazardous area. Secure the wires to the power input terminal block by
using the integral screws of the terminal block. Do not substitute terminal screws.

CAUTION: Check the QC for the proper power requirement. Incorrect power will severely damage the

analyzer

Output Connections

The analyzer is a two
same power loop..

o not exceed the recommended power requirement..

D

Power Sourc

Power IN/4-2

Explosion P Fiber Glass

NOTE: There are three interconnec

Clarity, only two wires are sho

18-28 VDC

wire loop powered transmitter and requires 18-28 VDC. 4-20 mA or 1-5 VDC is transmitted on the

e

0 mA Signal Out

roof

Enclosure Enclosure

ting wires between the explosion proof enclosure and the fiber glass enclosure, for

wn.

Procedure

Power require
requirement.

• Unscrew the cone shaped cover from the lower enc

• Separate the shielding from the wires of the cable.

• Ensure the positive and negati

• Connect the shieldin

• Replace the cover.

Note: The male and female power terminals snap together, making it difficult to detach them when connecting the shi
the ground. However, a
female terminal block.

ments consist of a 18-24 VDC power supply. Check the QC and analyzer cover plate for proper power

losure.

ve terminals of the power supply are connected to the appropriate terminals of the

terminal block as marked.

g of the cable to the ground screw inside the enclosure.

fter connecting the shield, ensure that the male terminal is fully inserted and secured into the

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Installing the Oxygen Sensor

The GPR-1800 IS Oxygen Analyzer is equipped with a SS sensor housing. This housing offers ease of replacement of
sensor and at the same time prevents any leakage into the system. The two sections of the sensor are held together be a
metal clamp secured in place by easily accessed bolt. The integrity of the sensor housing has been tested at the factory
prior to shipment and is fully operational from the shipping container.

Caution: All analyzers must be calibrated once the installation has been completed and periodically thereafter
as described below. Following the initial installation and calibration, allow the transmitters to stabilize for 12-24

hours and re-calibrate the transmitter with a certified span gas.

Caution: DO NOT dissect the oxygen sensor. The sensor contains a corrosive liquid electrolyte that could be
harmful if touched or ingested, refer to the Material Safety Data Sheet contained in the Owner’s Manual

appendix. Avoid contact with any liquid or crystal type powder in or around the sensor or sensor housing, as
either could be a form of electrolyte. Leaking sensors should be disposed off in a manner similar to that of a common
battery in accordance with local regulations.

Avoid electrostatic discharge – Clean all surfaces with a damp cloth only.

Procedure

• Remove the two (2) clamps securing the right side corners and open
the door of the fiber glass enclosure.

• Loosen the bolt at the bottom of the sensor housing by using 5/16
ranch provided.

• Twist the upper section of the housing 90 degree and pull it up until it
clears the bottom section of the sensor housing.

• Remove the old sensor (if previously installed) from the sensor
housing

• Remove the oxygen sensor from the bag and remove the two red
shorting taps from the two ring gold color contact plate of the sensor.

• Insert the sensor into the upper section of the sensor housing with
gold contact plate facing towards two gold contact pins of the sensor
housing

• By holding the sensor and the upper section of the sensor housing in
your hand, allow 2-3 minutes for the analyzer to respond to the new
sensor. The analyzer should display oxygen around 21% with factory
default span setting (see below)

• You may perform a quick air calibration to ensure that the analyzer
accepts the air calibration confirming that the sensor out put is within the recommended limits.

• Place the sensor in the bottom section of the sensor housing with the two ring gold contact plate facing up. Place
the upper section of the sensor housing over the sensor. Slightly push it down and twist 90 degree.

• By using the 5/16 ranch, tighten the bolt securing the two section together.

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Span Gas Preparation

See Section 4 – Features and Specifications, for exclusions

Note: The GPR-1800 IS can be calibrated by using ambient air. However, it can also be calibrated by using a certified

span gas. Air calibration can be achieved right after installing the sensor in the housing. Subsequent calibration, where the
sensor has been exposed to a sample gas, air calibration can be achieved by either removing the sensor from the sensor
housing or by pushing the air through the sensor housing.

Caution: Do not contaminate the span gas cylinder when installing the pressure regulator on the span gas
cylinder. Further, bleed the air filled regulator and span gas tubing before connecting the span gas to the

analyzer and attempting the initial calibration.

Required Components

• Certified span gas cylinder with an oxygen concentration, balance nitrogen, approximating 80% of the full scale of
the measuring range or one range above the intended measuring range.

• A pressure regulator to set the span gas pressure between 5 and 30 psig.

• A flow meter to set the flow between 1-5 SCFH (only if the transmitter is not equipped with integral flow meter),

• Suitable tube fittings and a 4-6 ft. length of 1/8” dia. metal tubing to connect the regulator to the flow meter inlet

• Suitable tube fittings and a 4-6 ft. length of 1/8” dia. metal tubing to connect from the flow meter vent to tube fitting

designated as SAMPLE IN or SPAN IN at the analyzer.

Procedure

• With the span gas cylinder valve closed, install the pressure regulator on the cylinder.

• Open the regulator’s exit valve and partially open the pressure regulator’s control knob.

• Open slightly the cylinder valve.

• Loosen the nut connecting the regulator to the cylinder and bleed the pressure regulator.

• Retighten the nut connecting the regulator to the cylinder

• Adjust the regulator exit valve and slowly bleed the pressure regulator.

• Open the cylinder valve completely.

• Set the pressure between 5-30 psig using the pressure regulator’s control knob.

Caution: Do not exceed the recommended flow rate. Excessive flow rate could cause the backpressure on the sensor and
may result in erroneous readings and damage the sensor

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Establishing Power to Electronics

Once the two power input wires of the shielded cable are properly connected to the terminals inside the Ex enclosure as
described above, connect the other end of the two wires to a suitable 18-28 VDC power supply such as a battery, PLC,
DCS, etc.

The digital display responds instantaneously. When power is applied, the transmitter performs several self-diagnostic
system status checks termed as “START-UP TEST” as illustrated below:

START-UP TEST

ELECTRONICS – PASS
TEMP SENSOR – PASS

BAROMETRIC SENSOR – PASS

REV.S1010.1.17

After self diagnostic tests, the analyzer turns itself into the sampling mode. And displays oxygen contents the sensor is

exposed to, the analysis range, the ambient temperature and pressure and the software rev level.

20.9 %

AUTO SAMPLING
25% RANGE

76 F 100 KPA

Menu Navigation

The four (4) pushbuttons located on the front of the transmitter control the micro-processor functions:

Blue ENTER (select)

Yellow UP ARROW

Yellow DOWN ARROW

Green MENU (escape)

Main Menu

To access the MAIN MENU, press the MENU (ESC) key and the following screen will appear.

MAIN MENU

SELECT RANGE

CALIBRATION

VIEW HISTORY

SYSTEM OPTIONS

This screen show various option available. You can use the UP and DOWN arrow key to move the cursor and highlight the
desired function. After moving the cursor to the desired function, you can press ENTER to get to that function.

Range Selection

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The GPR-1800-IS transmitter is equipped with five (5) standard measuring ranges (see specification) and provides users
with a choice of sampling modes. By accessing the MAIN MENU, users may select either the AUTO SAMPLING (ranging)
or MANUAL SAMPLING (to lock on a single range) mode.

Note: For calibration purposes, use of the AUTO SAMPLE mode and ambient air (20.9% oxygen on the 0-25% range
which meets the 80% of FS recommendation described below) is recommended. However, the user can select the full
scale MANUAL SAMPLE RANGE for calibration as dictated by the accuracy of the analysis required – for example, a span
gas with an 80 PPP oxygen concentration in nitrogen would dictate the use of the 0-100 PPM full scale range for
calibration and a 0-100 PP measuring range.

Auto/ Manual Sampling

Access the MAIN MENU by pressing the MENU key.

Advance the reverse shade cursor using the ARROW keys to highlight SELECT RANGE and press ENTER

The display will show *AUTO and the actual range of analysis. Press the ENTER to select MANUAL RANGE and advance
the cursor to the desired RANGE and press ENTER.

The following display appears:

The display returns to the sampling mode:

MAIN MENU

SELECT RANGE

CALIBRATION

VIEW HISTORY

SYSTEM OPTIONS

The display will shift to the next higher range when the oxygen reading exceeds 99.9% of the upper limit of the current
range. The display will shift to the next lower range when the oxygen reading drops to 85% of the upper limit of the next
lower range.

For example, if the transmitter is reading 5 PPM on the 0-10 PPM range and an upset occurs, the display will shift to the 0­100 PPM range when the oxygen reading exceeds 9.99 PPM. Conversely, once the upset condition is corrected, the
display will shift back to the 0-10 PPM range when the oxygen reading drops to 8.5 PPM.

Pressing SELECT RANGE and then pressing ENTER will toggle between AUTO and MANUAL sampling

When MANUAL range is selected and If the oxygen value goes above the selected range, display will not shift to the next
higher range. Instead, when the oxygen reading exceeds 110% of the upper limit of the current range, an OVER RANGE
warning will be displayed.

30.0 PPM

AUTO SAMPLING

100 PPM RANGE

76 F 100 KPa

12.5 PPM

OVER RANGE

MANUAL SAMPLING

10 PPM RANGE

76 F 100 KPa

Once the OVER RANGE warning appears the user must advance the transmitter to the next higher range.

NOTE: With oxygen reading above 110% of the selected range, the mA signal output will increase but will freeze at a
maximum value of 24 mA. After the oxygen reading falls below the full scale range, the mA signal will become normal.

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Analyzer Calibration

The electrochemical oxygen sensors generate an electrical current that is linear or proportional to the oxygen
concentration in a sample gas. In the absence of oxygen the sensor exhibits an absolute zero, i.e., the sensor does not
generate a current output in the absence of oxygen. Given the properties of linearity and an absolute zero, a single point
calibration is possible.

The analyzer is equipped with “Zero Calibration” feature. However, as described below, zero calibration is recommended
only when the application (or user) demands optimum accuracy of below 5% of the most sensitive or lowest range
available on the analyzer. For example, if the user requires analysis of a sample gas below 0.05%, zero calibration may be
required.

Span calibration, it is necessary to adjust the analyzer sensitivity for accurate measurements of oxygen by using a
standardized (certified) oxygen or by using ambient air (20.9%).

Zero Calibration

Ideally, with no oxygen, the sensor should have zero signal but in reality, the analyzer may display oxygen reading with a
sample gas containing no oxygen (zero gas). Under such circumstance, it may be necessary to perform a Zero calibration
to remove any offset with oxygen free sample gas. The maximum zero offset correction is limited to a maximum of 10% of
the lowest (most sensitive) range for positive zero offset and 10% of the lowest range for negative zero offset.

Zero calibration could be carried out before or after the span calibration. Normally, zero calibrations are performed when a
new sensor is installed or changes are made in the sample system connections. Allow the ZERO gas to flow through the
analyzer and wait until the signal has dropped to a low value and is stable.

Access the MAIN MENU by pressing the MENU key.

Advance the reverse shade cursor using the ARROW keys to highlight CALIBRATION.

Press the ENTER key to select the highlighted menu option.

The following displays appear:

MAIN MENU

SELECT RANGE

CALIBRATE

VIEW HISTORY

SYSTEM OPTIONS

Advance the reverse shade cursor using the ARROW keys to highlight ZERO CALIBRATE.

Press the ENTER key to select the highlighted menu option.

The following displays appear:

>>>

CALIBRATION

SPAN CALIBRATE

ZERO CALIBRATE

DEFAULT SPAN

DEFAULT ZERO

OUTPUT CALIBRATE

OUTPUT SIMULATE

0.15 PPM

ZERO CALIBRATION

WAIT FOR STEADY RDG

ENTER TO CALIBRATE

MENU TO ABORT

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Wait until the analyzer reading stabilizes (depending on the history of the sensor, it may take a few minutes to several
hours) and then press the ENTER key to calibrate (or MENU key to abort).

If the offset is less than 10% of the lowest range, by pressing ENTER will pass the calibration and the analyzer will return
to the Sample mode. On the other hand, if the offset is above 10%, pressing ENTER will fail calibration and the analyzer
will return to Sample mode without completing the Zero calibration.

Both the Zero Calibrate and Span Calibrate functions result in the following displays:

PASSED

CALIBRATION

OR

FAILED

CALIBRATION

Default Zero

This feature will eliminate any previous zero calibration adjustment and display the actual signal output of the sensor at a
specified oxygen concentration. This feature allows the user to ensure that the accumulative zero offset never exceeds
10% of the lowest range limit. To perform Default Zero,

• Access the MAIN MENU by pressing the MENU key.

• Advance the reverse shade cursor using the ARROW keys to highlight CALIBRATION.

• Press the ENTER key to select the highlighted menu option.

The following displays appear:

MAIN MENU

SELECT RANGE

CALIBRATE

VIEW HISTORY

SYSTEM OPTIONS

Advance the reverse shade cursor using the ARROW keys to highlight DEFAULT ZERO.

Press the ENTER key to select the highlighted menu option.

The following display appears and after 3 seconds the system returns to the SAMPLING mode:

FACTORY

DEFAULTS

SET

>>>

>>>

CALIBRATION

SPAN CALIBRATE

ZERO CALIBRATE

DEFAULT SPAN

DEFAULT ZERO

OUTPUT CALIBRATE

OUTPUT SIMULATE

0.25 PPM

AUTO SAMPLING

10 PPM RANGE

76 F 100 KPa

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Analyzer Calibration-Span Calibration
Air Calibration

This procedure requires only a source of clean ambient air and removal of the sensor from its flow housing.

Access the interior of the analyzer by removing the 4 clamps securing the door of the analyzer.

Caution: Do not remove the gaskets from the enclosure. Failure to do so will void the NEMA rating.

• Remove the sensor from the screw-in sensor housing or push the air through the analyzer SAMPLE IN thus
exposing the sensor to ambient air or alternatively, flow a certified span gas through the analyzer.

• Advance the cursor on the MAIN MENU to CALIBRATE and press ENTER.

• Advance the cursor to SPAN CALIBRATION and press ENTER

The following displays appear:

MAIN MENU

SELECT RANGE

CALIBRATE

VIEW HISTORY

SYSTEM OPTIONS

SPAN GAS CONCENTRATION

20.09%

PRESS UP OR DOWN

TO CHANGE VALUE

ENTER TO SAVE

MENU TO RETURN

• By using the UP or DOWN arrow keys, enter the appropriate digit where the cursor is blinking

• Press the ENTER key to advance the underline cursor right or press the MENU key to advance the underline

cursor left to reach to the desired digit of the gas value.

• Repeat until the complete span value has been entered.

In the example above, a span value of 20.09% has been entered.

After the span value has been entered, the analyzer will display the actual oxygen reading and prompt to press the ENTER
key to accept SPAN CALIBRATION or MENU to abort.

Caution: Allow the analyzer reading to stabilized before accepting calibration.

After successful calibration, the analyzer will display a message “Passed Calibration” and return to the Sample mode.

NOTE: The analyzer is allowed to accept calibration when O2 reading is within the acceptable value. If the O2 reading is
outside of this limit, by pressing ENTER to accept calibration will result in “Failed Calibration” and return to the Sample
mode without completing Span calibration. After pressing ENTER either of the following two messages will be displayed
and the analyzer will return to SAMPLE mode.

>>>

>>>

CALIBRATION

SPAN CALIBRATE

ZERO CALIBRATE

DEFAULT SPAN

DEFAULT ZERO

OUTPUT CALIBRATE

OUTPUT SIMULATE

20.01%

SPAN CALIBRATION

WAIT FOR STEADY RDG

ENTER TO CALIBRATE

MENU TO ABORT

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Advanced Instruments, Inc

PASSED

CALIBRATION

OR

FAILED

CALIBRATION

Span Gas Calibration

This procedure assumes a span gas under positive pressure. Connect the span gas to the analyzer Sample input port and
set the span gas flow 1-2 SCFH

NOTE: To assure an accurate calibration, the temperature and pressure of the span gas must closely approximate the
sample conditions.

For calibration purposes, use of AUTO SAMPLE mode is recommended.

• Access the MAIN MENU by pressing the MENU key.

• Advance the reverse shade cursor using the ARROW keys to highlight AUTO SAMPLE.

• Press the ENTER key to select the highlighted menu option.

The following displays appear:

MAIN MENU

SELECT RANGE

CALIBRATE

VIEW HISTORY

SYSTEM OPTIONS

GAS CONCENTRATION

5.0 PPM

8

PRESS UP OR DOWN

TO CHANGE VALUE

ENTER TO SAVE

MENU TO RETURN

• By using the UP or DOWN arrow keys, enter the appropriate digit where the cursor is blinking

• Press the ENTER key to advance the underline cursor right or press the MENU key to advance the underline

cursor left to reach to the desired digit of the gas value.

• Repeat until the complete span value has been entered.

In the example above, a span value of 85.0 PPM has been entered.

After the span value has been entered, the analyzer will display the actual oxygen reading and prompt to press the ENTER
key to accept SPAN CALIBRATION or MENU to escape.

Caution: Allow the analyzer reading to stabilized before accepting calibration.

After successful calibration, the analyzer will display a message “Passed Calibration” and return to the Sample mode.

>>>

>>>

CALIBRATION

SPAN CALIBRATE

ZERO CALIBRATE

DEFAULT SPAN

DEFAULT ZERO

OUTPUT CALIBRATE

OUTPUT SIMULATE

87.4 PPM

SPAN CALIBRATION

WAIT FOR STEADY RDG

ENTER TO CALIBRATE

MENU TO ABORT

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NOTE: The analyzer is allowed to accept calibration when O2 reading is within the acceptable value. If the O2 reading is
outside of this limit, by pressing ENTER to accept calibration will result in “Failed Calibration” and return to the Sample
mode without completing Span calibration. After pressing ENTER either of the following two messages will be displayed
and the analyzer will return to SAMPLE mode.

PASSED

CALIBRATION

OR

FAILED

CALIBRATION

Default Span

The software will set the SPAN adjustment based on the average output of the oxygen at a specific oxygen concentration
and erase any previous span calibration data. For example, with factory default settings, when a span gas is introduced,
the micro-processor will display oxygen reading within + 30-50% of the span gas value, indicating that the sensor output is
within the specified limits. This feature allows the user to check the sensor’s signal output at a specified oxygen
concentration without removing it from the sensor housing.

• Access the MAIN MENU by pressing the MENU key.

• Advance the reverse shade cursor using the ARROW keys to highlight CALIBRATION.

• Press the ENTER key to select the highlighted menu option.

The following display appears:

MAIN MENU

SELECT RANGE

CALIBRATE

VIEW HISTORY

SYSTEM OPTIONS

• Advance the reverse shade cursor using the ARROW keys to highlight DEFAULT SPAN.

• Press the ENTER key to select the highlighted menu option.

The following displays appear and after 3 seconds the system returns to the SAMPLING mode and display the current
oxygen reading.

FACTORY

DEFAULTS

SET

>>>

CALIBRATION

SPAN CALIBRATE

ZERO CALIBRATE

DEFAULT SPAN

DEFAULT ZERO

OUTPUT CALIBRATE

OUTPUT SIMULATE

5.10 PPM

AUTO SAMPLING

10 PPM RANGE

76 F 100 KPa

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Analog Output Check- Output Simulate

This feature allows the user to simulate the electronics and the signal output. A know current is added to the analyzer
electronics internally to generate equivalent analog signal output. This feature allows the user to check all interconnections
from the analyzer to the signal output recording device before installation of sensor thus preventing the user to open the
sensor bag before the analyzer installation is complete and satisfactory. To simulate signal output

• Access the MAIN MENU by pressing the MENU key.

• Advance the reverse shade cursor using the ARROW keys to highlight CALIBRATION and then select OUTPUT

SIMULATE.

• Press the ENTER key to select the highlighted menu option.

The following displays appear:

MAIN MENU

SELECT RANGE

CALIBRATE

VIEW HISTORY

SYSTEM OPTIONS

>>>

CALIBRATION

SPAN CALIBRATE

ZERO CALIBRATE

DEFAULT SPAN

DEFAULT ZERO

OUTPUT CALIBRATE

OUTPUT SIMULATEI

OUTPUT SIMULATE

0% SPAN

4.00 mA

PRESS UP OR DOWN TO
ADJUST OUTPUT
ENTER/MENU TO RETURN

Pressing UP or DOWN key will increase or decrease the output by 5% of the full scale signal each time. Check the output
on the external recording device or voltmeter/ammeter. The output on the external recording would be the % of the full
scale signal selected, for example, 0% will represent 4.00 mA, 25% value will represent 8 mA and 50% span value will
represent 12.0 mA of the 4-20 mA full scale. After SIMULATION is complete, press ENTER/MENU key to return to
SAMPLE mode.

Note: To perform "Calibrate-Output Simulation", an external recording device must be connected between the negative
terminal of the power source and negative terminal of the transmitter.

Analog Output Check- Output Calibrate

In certain cases, the full scale analog may not match with full scale display. This feature allows the user to adjust the
electronics so that the full scale display matches with full scale analog signal output. To calibrate full scale signal output

• Access the MAIN MENU by pressing the MENU key.

• Advance the reverse shade cursor using the ARROW keys to highlight CALIBRATION and then select OUTPUT

SIMULATE.

• Press the ENTER key to select the highlighted menu option.

The following displays appear:

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MAIN MENU

SELECT RANGE

CALIBRATE

VIEW HISTORY

SYSTEM OPTIONS

OUTPUT SPAN

20.0 mA ADJUST

PRESS UP OR DOWN TO
ADJUST OUTPUT
ENTER/MENU TO RETURN

Pressing UP or DOWN key will increase or decrease the full scale output signal each time. Check the output on the
external recording device or voltmeter/ammeter. Repeat this step until the out equals the full scale analog signal expected,
for example 20 mA in the present case. After OUTPUT CALIBRATION is complete, press ENTER/MENU key to return to
SAMPLE mode.

>>>

CALIBRATION

SPAN CALIBRATE

ZERO CALIBRATE

DEFAULT SPAN

DEFAULT ZERO

OUTPUT CALIBRATE

OUTPUT SIMULATE

Sampling a Gas

GPR-1800 IS Oxygen Analyzer requires a positive pressure to flow the sample gas across the sensor to measure the
oxygen concentration in a sample gas. If a positive sample pressure is not available, install a high quality external sample
pump to push the sample through the analyzer; see the option of using a sample pump as described above.

Procedure

Following calibration, the analyzer will return to the SAMPLE mode and ready for sampling the gas.

Select the desired sampling mode - auto or manual – as described above.

Use a suitable tubing to transport the sample gas to the analyzer

The main consideration is to eliminate any air leaks which can affect oxygen measurements.

For sample gases under positive pressure, the user must provide a means of controlling the inlet pressure between 5-30
psig. For sample gases under atmospheric or slightly negative pressure, an external pump is necessary to push the
sample through the sensor housing. Generally, when using a low voltage DC pump, no pressure regulation is necessary
but a flow control device is recommended; a flow meter upstream of analyzer is recommended to ensure that the sample
flow is adequate and steady.

Assure the sample is adequately vented for optimum response and recovery – and safety.

Allow the oxygen reading to stabilize for approximately 2 minutes at each sample point.

View History

This feature allows the user to view

Maximum PPM O2

Minimum PPM O2

Average PPM O2

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Maximum ambient temperature

Number of days the sensor has been in service (at the time of installation and first calibration, the user must enter YES to
confirm "new sensor") and

Number of days since the last calibration was done.

System Options

This features allows the user to

• Set security; password protected operation

• Define ranges; choose a range between two ranges, for example, 200 PPM full scale instead of 1000 PPM full

scale.

• Display signal below 0.00; Negative signal, YES or NO.

Security

PASSCODE LOCK- Prevents un-authorized access to the analyzer menu options. Selecting PASSCODE LOCK will put
the analyzer in Sample Mode and accessing the menus will require a valid pass-code.

To enter pass code, from SYSTEN OPTIONS menu, select SECURITY, select PASSCODE LOCK and then enter four digit
PASS CODE, numeral numbers only and press ENTER. Then select AUTO LOCK option and enter the number of minutes
after which access to MENU options will be locked (access allowed only after entering the PASS CODE).

In the vent the PASS CODE is lost, enter the factory default PASS CODE 2855 to access the MENU and then renter the
new PASS CODE.

Choosing the option to display negative number will allow the user to see the display below 0.00 but the output will not go
below 3.80 mA.

Standby

The transmitter has no special storage requirements.

The sensor should remain inside of the sensor housing and connected to the electronics during storage periods. Before
turning the sample gas OFF, ensure that sample/bypass valve (if analyzer equipped) is at the BYPASS position. This will
keep the sensor isolated from ambient air and would be ready to use again when required with very short down time.

NOTE: Under isolated conditions, some oxygen will diffuse into the sample system/sensor housing and the sensor out will
slowly climb up but after 2-3 hours, it will reach a Plato, generally less than 400 PPM

Store the transmitter with the power OFF at a safe location and away from a direct heating source.

If storing for an extended period of time, protect the analyzer from dust, heat and moisture.

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6. Maintenance

Generally, cleaning the electrical contacts inside of the upper section of the sensor housing or replacing filter element of
the coalescing filter is the extent of the maintenance requirements of this transmitter.

Serviceability: Except for replacing the oxygen sensor, there are no parts inside the transmitter for the operator to service.

Only trained personnel with the authorization of their supervisor should conduct maintenance.

7. Spare Parts

Recommended spare parts for the GPR-1500 IS Oxygen Analyzer:

Item No. Description

GPR-12-333 Oxygen Sensor, for measuring O2 in inert gases

XLT-12-333 Oxygen Sensor, for measuring O2 in gases

containing CO2

Other spare parts:

Item No. Description

B-2762-A-2-14 Sensor Housing Upper Section

The Factory must be
consulted for any other
questions/maintenance

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8. Troubleshooting

Symptom Possible Cause Recommended Action

Slow recovery

High O2 reading

after installing

or replacing sensor

High O2 reading

Sampling

At installation, defective
sensor

Air leak in sample system
connection(s)

Abnormality in zero gas

Damaged in service ­prolonged exposure to air,
electrolyte leak

Sensor nearing end of life

Analyzer calibrated before
sensor stabilized caused by:

1) Prolonged exposure to
ambient air, worse if sensor
was un-shorted

2) Air leak in sample
system connection(s)

3) Abnormality in zero gas

Flow rate exceeds limits

Pressurized sensor

Improper sensor selection

Replace sensor if recovery unacceptable

reading fails to reach 10% of lowest

or O

2

range

Leak test the entire sample system: Vary
the flow rate, if the O
inversely with the change in flow rate
indicates an air leak - correct source of
leak

Qualify zero gas (using portable
transmitter)

Replace sensor

Replace sensor

Allow O2 reading to stabilize before
making the span/calibration adjustment

Continue purge with zero gas

Leak test the entire sample system
(above)

Qualify zero gas (using portable
transmitter)

Correct pressure and flow rate

Remove restriction on vent line

Replace GPR sensor with XLT sensor
when CO

or acid gases are present

2

reading changes

2

Response time slow

O

reading doesn’t

2

agree to expected
O2 values

Erratic O

reading

2

Air leak, dead legs, distance
of sample line, low flow rate,
volume of optional filters and
scrubbers

Pressure and temperature of
the sample is different than
span gas

Abnormality in gas

Change in sample pressure

31

Leak test (above), reduce dead volume or
increase flow rate

Calibrate the transmitter (calibrate at
pressure and temperature of sample)

Qualify the gas (use a portable analyzer as
a second check)

Calibrate the transmitter (calibrate at
pressure and temperature of sample)

or

reading

No O

2

Erratic O

reading

2

or

Negative O

reading

2

or

reading

No O

2

accompanied by
electrolyte leakage

Dirty electrical contacts in
upper section of sensor
housing

Corroded solder joints on
sensor PCB from corrosive
sample or electrolyte leakage
from sensor

Corroded spring loaded
contact in upper section of
sensor housing from liquid in
sample or electrolyte leakage
from sensor

Liquid covering sensing area

Improper sensor selection

Presence of interference
gases

Unauthorized maintenance

Sensor nearing end of life

Pressurizing the sensor by
flowing gas to the sensor with
the vent restricted or SHUT
OFF valve closed and
suddenly removing the
restriction draws a vacuum
on the sensor

or

partially opened valves
upstream of the analyzer
when using a pump
downstream of the analyzer
to draw sample from a
process at atmospheric
pressure or under a slight
vacuum. Placing a vacuum
on the sensor in excess 10”
of water column is strongly
discouraged.

A premature adjustment of
the ZERO OFFSET is a
common problem

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Advanced Instruments, Inc

Clean contacts with alcohol (minimize
exposure time of MS sensor to ambient air
to extent possible)

Replace sensor and return sensor to the
factory for warranty determination

Upper section of sensor housing: Clean
contacts with water, wipe contacts with
clean paper towel and flush system and
sensor housing with dry gas

Sensor: Replace if leaking and return it to
the factory for warranty determination

Wipe with lint free towel or flow dry sample
or zero gas for 2-3 hours to flush out
condensation

Consult factory for recommendation.

Replace sensor and install scrubber

Consult factory.

Replace sensor

Zero the transmitter. If not successful
replace the sensor

Avoid drawing a vacuum on the sensor, a
pressurized sensor may not leak but still
produce negative readings.

From MAIN MENU select DEFAULT ZERO

Advanced Instruments, Inc

9. Warranty

The design and manufacture of GPR Series oxygen transmitters/analyzers, monitors and oxygen sensors are performed
under a certified Quality Assurance System that conforms to established standards and incorporates state of the art
materials and components for superior performance and minimal cost of ownership. Prior to shipment every analyzer is
thoroughly tested by the manufacturer and documented in the form of a Quality Control Certification that is included in the
Owner’s Manual accompanying every analyzer. When operated and maintained in accordance with the Owner’s Manual,
the units will provide many years of reliable service.

Coverage

Under normal operating conditions, the monitor, analyzers and sensor are warranted to be free of defects in materials and
workmanship for the period specified in accordance with the most recent published specifications, said period begins with
the date of shipment by the manufacturer. The manufacturer information and serial number of this analyzer are located on
the rear of the analyzer. Advanced Instruments Inc. reserves the right in its sole discretion to invalidate this warranty if the
serial number does not appear on the analyzer.

If your Advanced Instruments Inc. monitor, analyzer and/or oxygen sensor is determined to be defective with respect to
material and/or workmanship, we will repair it or, at our option, replace it at no charge to you. If we choose to repair your
purchase, we may use new or reconditioned replacement parts. If we choose to replace your Advanced Instruments Inc.
analyzer, we may replace it with a new or reconditioned one of the same or upgraded design. This warranty applies to all
monitors, analyzers and sensors purchased worldwide. It is the only one we will give and it sets forth all our
responsibilities. There are no other express warranties. This warranty is limited to the first customer who submits a claim
for a given serial number and/or the above warranty period. Under no circumstances will the warranty extend to more than
one customer or beyond the warranty period.

Limitations

Advanced Instruments Inc. will not pay for: loss of time; inconvenience; loss of use of your Advanced Instruments Inc.
analyzer or property damage caused by your Advanced Instruments Inc. analyzer or its failure to work; any special,
incidental or consequential damages; or any damage resulting from alterations, misuse or abuse; lack of proper
maintenance; unauthorized repair or modification of the analyzer; affixing of any attachment not provided with the analyzer
or other failure to follow the Owner’s Manual. Some states and provinces do not allow limitations on how an implied
warranty lasts or the exclusion of incidental or consequential damages, these exclusions may not apply.

Exclusions

This warranty does not cover installation; defects resulting from accidents; damage while in transit to our service location;
damage resulting from alterations, misuse or abuse; lack of proper maintenance; unauthorized repair or modification of the
analyzer; affixing of any label or attachment not provided with the analyzer; fire, flood, or acts of God; or other failure to
follow the Owner’s Manual.

Service

Call Advanced Instruments Inc. at 909-392-6900 (or e-mail info@aii1.com) between 7:30 AM and 5:00 PM Pacific Time
Monday thru Thursday or 8:00 AM to 12:00 pm on Friday. Trained technicians will assist you in diagnosing the problem
and arrange to supply you with the required parts. You may obtain warranty service by returning you analyzer, postage
prepaid to:

Advanced Instruments Inc.

2855 Metropolitan Place

Pomona, Ca 91767 USA

Tel: +1 909 392 6900

Be sure to pack the analyzer securely. Include your name, address, telephone number, and a description of the operating
problem. After repairing or, at our option, replacing your Advanced Instruments Inc. analyzer, we will ship it to you at no
cost for parts and labor.

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Advanced Instruments, Inc

10. MSDS – Material Safety Data Sheet

Product Identification

Product Name Oxygen Sensor Series - PSR, GPR, AII, XLT

Synonyms Electrochemical Sensor, Galvanic Fuel Cell

Manufacturer Advanced Instruments Inc., 2855 Metropolitan Place, Pomona, CA 91767 USA

Emergency Phone Number 909-392-6900

Preparation / Revision Date January 1, 1995

Notes Oxygen sensors are sealed, contain protective coverings and in normal conditions do not

Specific Generic Ingredients

Carcinogens at levels > 0.1% None

Others at levels > 1.0% Potassium Hydroxide or Acetic Acid, Lead

CAS Number Potassium Hydroxide = KOH 1310-58-3 or Acetic Acid = 64-19-7, Lead = Pb 7439-92-1

Chemical (Synonym) and
Family

General Requirements

Use Potassium Hydroxide or Acetic Acid - electrolyte, Lead - anode

Handling Rubber or latex gloves, safety glasses

Storage Indefinitely

Physical Properties

Boiling Point Range

Melting Point Range

Freezing Point

Molecular Weight KOH = 56 or Acetic Acid – NA, Lead = 207

Specific Gravity

Vapor Pressure

Vapor Density KOH – NA or Acetic Acid = 2.07

pH KOH > 14 or Acetic Acid = 2-3

Solubility in H

% Volatiles by Volume None

Evaporation Rate Similar to water

Appearance and Odor Aqueous solutions: KOH = Colorless, odorless or Acetic Acid = Colorless, vinegar-like

O Complete

2

Fire and Explosion Data

Flash and Fire Points Not applicable

Flammable Limits Not flammable

Extinguishing Method Not applicable

Special Fire Fighting
Procedures

present a health hazard. Information applies to electrolyte unless otherwise noted.

Potassium Hydroxide (KOH) – Base or Acetic Acid (CH

KOH = 100 to 115° C or Acetic Acid = 100 to 117° C

KOH -10 to 0° C or Acetic Acid – NA, Lead 327° C

KOH = -40 to -10° C or Acetic Acid = -40 to -10° C

KOH = 1.09 @ 20° C, Acetic Acid = 1.05 @ 20° C

KOH = NA or Acetic Acid = 11.4 @ 20° C

odor

Not applicable

H) – Acid, Lead (Pb) – Metal

3CO2

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Advanced Instruments, Inc

Unusual Fire and Explosion
Hazards

Not applicable

Reactivity Data

Stability Stable

Conditions Contributing to
Instability

Incompatibility KOH = Avoid contact with strong acids or Acetic Acid = Avoid contact with strong bases

Hazardous Decomposition
Products

Conditions to Avoid KOH = None or Acetic Acid = Heat

None

KOH = None or Acetic Acid = Emits toxic fumes when heated

Spill or Leak

Steps if material is released Sensor is packaged in a sealed plastic bag, check the sensor inside for electrolyte

Disposal In accordance with federal, state and local regulations.

leakage. If the sensor leaks inside the plastic bag or inside an analyzer sensor housing
do not remove it without rubber or latex gloves and safety glasses and a source of
water. Flush or wipe all surfaces repeatedly with water or wet paper towel (fresh each
time).

Health Hazard Information

Primary Route(s) of Entry Ingestion, eye and skin contact

Exposure Limits Potassium Hydroxide - ACGIH TLV 2 mg/cubic meter or Acetic Acid - ACGIH TLV /

Ingestion Electrolyte could be harmful or fatal if swallowed. KOH = Oral LD50 (RAT) = 2433 mg/kg

Eye Electrolyte is corrosive and eye contact could result in permanent loss of vision.

Skin Electrolyte is corrosive and skin contact could result in a chemical burn.

Inhalation Liquid inhalation is unlikely.

Symptoms Eye contact - burning sensation. Skin contact - soapy slick feeling.

Medical Conditions Aggravated None

Carcinogenic Reference Data KOH and Acetic Acid = NTP Annual Report on Carcinogens - not listed; LARC

Other Lead is listed as a chemical known to the State of California to cause birth defects or

OSHA PEL 10 % (TWA), Lead - OSHA PEL .05 mg/cubic meter

or Acetic Acid = Oral LD50 (RAT) = 6620 mg/kg

Monographs - not listed; OSHA - not listed

other reproductive harm.

Special Protection Information

Ventilation Requirements None

Eye Safety glasses

Hand Rubber or latex gloves

Respirator Type Not applicable

Other Special Protection None

Special Precautions

Precautions

Transportation

Do not remove the sensor’s protective Teflon and PCB coverings. Do not
probe the sensor with sharp objects. Wash hands thoroughly after handling.
Avoid contact with eyes, skin and clothing.

Empty sensor body may contain hazardous residue.

Not applicable

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Advanced Instruments, Inc

Appendix A

Electrical connections require an approved explosion proof
sealing fitting and packing around wires and cables (for
incoming power for the analyzer electronics and 4-20mA
signal output) coming into and out of the explosion proof
enclosure that houses the power supply/signal output PCB.

Full compliance with hazardous area electrical code requires
the user to supply glands, fittings and/or conduit
commensurate with the level of protection or classification
desired. To maintain the ATEX certification of this unit, the
user must install ATEX approved components according to
ATEX directives. To meet US and Canada requirements for
use in Class I, Division 1, Groups C, D hazardous areas, the
user must install the appropriate components according to the
NEC standards (US) or CEC standards (Canada).

Note: The following instruction is supplied from information and data supplied by a reputable enclosure manufacturer

which we believe is reliable and is given in good faith. Since the methods of application and conditions under which our
products are put to use are beyond our control, we are not able to guarantee the application and/or use of same. The user
assumes all risks and liability in connection with the application and use of our products.

Directions for use of Explosion Proof Packing Fiber ( non-asbestos )

For use as packing at the hub of sealing fittings, tamp packing fiber between and around conductors where they enter
fitting to prevent leakage of the liquid cement. Leave enough space in the fitting for length equivalent to the inside
diameter of the conduit but, not less then 5/8”.

Caution: Avoid getting in eyes or breathing dust

Use barrier cream, gloves and long sleeve shirts if dust or fiber is irritating.

Prolonged contact may cause lung, eye or skin irritation. Directions for use

Explosion Proof Sealing Cement: Tamp packing fiber between and around conductors where they enter the

sealing fitting to prevent leakage of liquid cement. Make sure conductors are not in contact with each
other or with the wall of fitting. Leave space in the fitting for a sealing length equivalent to the thread
size of the conduit seal but not less than 5/8”

Fill the marked shipping container with clean cold water to the “water line” [35 ml to be precise].

Caution: Do not exceed the required amount of water.

Gradually pour cement from the plastic bag into the water and stir thoroughly for proper mixture. Fill fitting
completely within five (5) minutes after mixing, then tamp with blunt stick to expel any air bubbles. Close up

any opening in the fitting to insure integrity of the seal. Fittings requiring more than 10 oz. of cement must be
filled from a single mixture of cement and water. DO NOT POUR IN STAGES.
Water-mix sealing compound should not be poured or installed at temperature below 40F (4C). Maintain temperature at or
above 40F for at least 72 hours after pouring. CSA certified when used with any CSA certified sealing fitting. Adaco No. 1
sealing cement must be used as a part of any Adalet UL listed fitting.

Caution: At least five threads must engage on all fill plugs.

Caution: Prolonged breathing or ingestion may cause internal obstruction, seek medical care.

Do not get into eyes or on skin – if cement touches eyes or skin, flush with water for 15 minutes.

Large amounts on skin when hardening may cause skin burn.

Use adequate ventilation.

To reorder sealing cement kit, specify P/N ENCL-1071-KIT

Allow cement at least 72 hours to cure.

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Advanced Instruments, Inc

Appendix B

Matching - LCD Display with 4-20mA Output

In rare instances the 4-20mA signal output may not agree with the reading displayed on the LCD. The Output Zero and
Output Span features enable the user to adjust the 4mA and 20 mA signal output matching with the reading displayed by
the LCD.

For optimum accuracy make two separate adjustments as follows:

1. OUTPUT ZERO feature: To adjust the 4mA signal output and requires zero gas.

2. OUTPUT SPAN feature: To adjust the 20mA signal output and requires span gas near full range.

Note: In the field or in the absence of the preferred gases, use the OUTPUT SPAN feature and adjust the 20mA signal
output using the span gas available.

Procedure – regardless of type of adjustment:

1. When you select OUTPUT ZERO OR OUTPUT SPAN, the microprocessor defaults to 100% to start.

2. The “actual” 4-20mA signal output will be adjusted to the “theoretical” value of the LCD display.

3. Adjustment general rule:

a) If the actual 4-20mA value < the theoretical LCD value, the adjustment value will be > 100%.

b) If the actual 4-20mA value > the theoretical LCD value, the adjustment value will be < 100%.

4. Convert the “actual” reading of the LCD display to the “theoretical” 4-20mA as follows:

a) Divide the “actual” (% or percent) LCD reading by the value of the span gas available.

b) Multiply 16mA (20mA – 4mA) times the “result of a.”

c) Add 4mA plus the “result of b.” to obtain the “theoretical” 4-20mA signal output value.

5. Adjustment value: Divide the theoretical by the actual 4-20mA values and multiply by 100.

6. Enter the adjustment value via OUTPUT ZERO or OUTPUT SPAN routines described below.

Example: Analyzer reading is 60 PPM (on100 PPM range) with 84 PPM span gas, 4-20mA signal output at PLC is

24mA

Solution:

Use OUTPUT SPAN feature to make the adjustment.

Adjustment will be < 100% (default value of OUTPUT SPAN feature).

13.6 mA is the “theoretical” 4-20mA converted from the “actual” reading of the LCD.

60 PPM divided by 84 PPM = 0.71 or 71% of the range

16mA multiplied by 0.71 = 11.36mA

4mA plus 11.36mA = 15.36mA “theoretical” 4-20mA signal output value

15.36mA divided by 24mA the “actual” 4-20mA value = 64.0 adjustment value

4. Enter 64.0 via OUTPUT SPAN procedure below.

Adjust 4 mA with Zero O2

Access the MAIN MENU by pressing the MENU key.

Advance the reverse shade cursor using the ARROW keys to highlight CALIBRATION.

Press the ENTER key to select the highlighted menu option.

The following displays appear:

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Advanced Instruments, Inc

MAIN MENU

AUTO SAMPLE

MANUAL SAMPLE

CALIBRATE

>>>

CALIBRATION

SPAN CALIBRATE

ZERO CALIBRATE

DEFAULT SPAN

DEFAULT ZERO

OUTPUT SPAN

OUTPUT ZERO

Advance the reverse shade cursor using the ARROW keys to highlight DEFAULT ZERO.

Press the ENTER key to select the highlighted menu option.

The following display appears:

100.0

OUTPUT ZERO OFFSET

PRESS UP OR DOWN
TO CHANGE VALUE
ENTER TO SAVE
MENU TO RETURN

Enter the calculated adjustment value

NOTE: Once the initial adjustment is made and checked at the PLC it may be necessary to fine tune the initial adjustment
by repeating. Any additional percent error must be added or subtracted from the initial adjustment value

000.0

OUTPUT ZERO OFFSET

PRESS UP OR DOWN
TO CHANGE VALUE
ENTER TO SAVE
MENU TO RETURN

Press the ENTER key to advance the underline cursor right or press the MENU key to advance the underline cursor left to
reach to the desired digit of the adjustment OUTPUT ZERO OFFSET value.

Press the ARROW keys to enter each the numerical value of each digit of the adjustment OUTPUT ZERO OFFSET value.

Repeat until the complete OUTPUT ZERO OFFSET value has been entered.

Save the adjustment value by pressing the ENTER key or abort by pressing the MENU key.

The system returns to the SAMPLING mode.

Adjust 20 mA at known O2

Access the MAIN MENU by pressing the MENU key.

Advance the reverse shade cursor using the ARROW keys to highlight CALIBRATION.

Press the ENTER key to select the highlighted menu option.

The following displays appear:

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Advanced Instruments, Inc

MAIN MENU

AUTO SAMPLE

MANUAL SAMPLE

CALIBRATE

>>>

CALIBRATION

SPAN CALIBRATE

ZERO CALIBRATE

DEFAULT SPAN

DEFAULT ZERO

OUTPUT SPAN

OUTPUT ZERO

Advance the reverse shade cursor using the ARROW keys to highlight OUTPUT SPAN.

Press the ENTER key to select the highlighted menu option.

The following display appears:

100.0

OUTPUT SPAN OFFSET

PRESS UP OR DOWN
TO CHANGE VALUE
ENTER TO SAVE
MENU TO RETURN

Enter the calculated adjustment value, refer to example described above.

Note: Once the initial adjustment is made and checked at the PLC it may be necessary to fine tune the initial adjustment
by repeating. Any additional percent error must be added or subtracted from the initial adjustment value

064.0

OUTPUT SPAN OFFSET

PRESS UP OR DOWN
TO CHANGE VALUE
ENTER TO SAVE
MENU TO RETURN

.

Press the ENTER key to advance the underline cursor right or press the MENU key to advance the underline cursor left to
reach to the desired digit of the adjustment OUTPUT SPAN OFFSET value.

Press the ARROW keys to enter the numerical value of each digit of the OUTPUT SPAN OFFSET value.

Repeat until the complete OUTPUT SPAN OFFSET value has been entered.

Save the adjustment value by pressing the ENTER key or abort by pressing the MENU key.

The system returns to the SAMPLING mode.

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Advanced Instruments, Inc

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Advanced Instruments, Inc

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Advanced Instruments, Inc

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Advanced Instruments, Inc

Appendix G

Maintenance – H2S Scrubber

Servicing any of the H2S scrubbers will depend on several factors as illustrated in Appendix F and include: the (average)
H2S concentration, volume of scrubber media and flow rate through the scrubber (often times maximizing the service life
means longer system response time) see Appendix F.

Required equipment:

1. 2x 7/16” open end wrenches

2. 1x 9/16” open end wrench

3. 1x 1” open end or adjustable wrench

Procedure:

Separate the top connection to the scrubber using a 7/16” and the 9/16” open end wrenches on the two top nuts.

Hold the second nut with the 9/16” open end wrench.

With one of the 7/16” open end wrenches turn the top nut counter clockwise until the fitting disengages.

Separate the bottom connection to the scrubber using both 7/16” open end wrenches.

Hold the nut at the bottom of the scrubber with a 7/16” open end wrench.

With the other 7/16” open end wrench turn the nut below counter clockwise until the fitting disengages.

Carefully, remove the stainless tubing from the top and bottom of the scrubber.

Carefully pull the scrubber from its mounting clip which is attached to the back panel.

Once the scrubber is free, hold the scrubber with one hand and using the 1” open end or adjustable wrench with the other
hand, turn the 1” nut counter clockwise and remove the 1” nut from the scrubber.

There is no need to remove the 7/16” fitting at the bottom of the scrubber.

With the 1” nut removed, empty the spent media through the opening.

Fill the scrubber with fresh media (should be rich purple in color).

Reverse the above steps to re-assemble and install the scrubber.

Maintenance – Coalescing Filter

Servicing the coalescing filter (P/N FLTR-1002-2) depends on the cleanliness and moisture content of the sample and
maintenance intervals.

Required equipment:

Channel locks

Damp rag

Lubricant (a thin coat applied to the o-ring after cleaning helps ensure a tight seal and extend o-ring life)

Procedure:

Unscrew the clear polycarbonate bowl by turning it counter clockwise.

Note: It is probably stuck tight – use a damp rag to grip if removing by hand or to prevent damage to the bowl if using the
channel locks.

The bowl seals to the head section with an o-ring, do not lose the o-ring.

The filter element screws into the head section, carefully turn it counter clockwise and remove it from the head.

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Advanced Instruments, Inc

Using the damp cloth, clean the inside of the bowl and the o-ring before reassembling – apply a very thin coat of lubricant
to the o-ring.

Reverse the above steps to re-assemble the filter.

44