5 operation, Principle of operation – Analytical Industries GPR-2500 S Oxygen Analyzer User Manual

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5 Operation

Principle of Operation

The GPR-2500S Ambient Oxygen Monitor incorporates a variety of advanced galvanic fuel cell type sensors. The

monitor is configured in a general purpose NEMA 4X rated enclosure and meets the intrinsic safety standards
required for use in Class 1, Division 1, Groups A, B, C, D hazardous areas when operated in conjunction with the

manufacturer’s recommended optional intrinsic safety barriers.
Advanced Galvanic Sensor Technology:
The sensors function on the same principle and are specific for oxygen. They measure the partial pressure of

oxygen from low ppm to 100% levels in inert gases, gaseous hydrocarbons, helium, hydrogen, mixed gases, acid

gas streams and ambient air. Oxygen, the fuel for this electrochemical transducer, diffusing into the sensor reacts
chemically 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 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 an extremely versatile oxygen

sensing technology. Sensors for low ppm analysis recover from air to ppm levels in minutes, exhibit longer life and

reliable quality. The expected life of our new generation of percentage range sensors now range to five and 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.

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.