Monitoring gas pipelines

A new cost-effective system developed under a program sponsored by the Gas Research Institute in Chicago combines the advantages of continuous emissions-monitoring systems (CEMS) and predictive emissions-monitoring systems (PEMS). The development of a true nitrogen oxide sensor enables the user to m...

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Veröffentlicht in:	Mechanical engineering (New York, N.Y. 1919) N.Y. 1919), 1996-12, Vol.118 (12), p.68-71
Hauptverfasser:	SCHUBERT, P. F, SHERIDAN, D. R, COOPER, M. D, BANCHIERI, A. J
Format:	Magazinearticle
Sprache:	eng
Schlagworte:	Accuracy Analyzers Applied sciences Controllers Emission standards Energy Engines Environmental monitoring Exact sciences and technology Fuels Gas industry Gas transmission and distribution. Ships. Pipelines. Distribution networks. Compressors stations Microprocessors Monitoring systems Natural gas Natural gas industry Oxygen Pipelines R&D Research & development Sensors
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container_end_page	71
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container_title	Mechanical engineering (New York, N.Y. 1919)
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creator	SCHUBERT, P. F SHERIDAN, D. R COOPER, M. D BANCHIERI, A. J
description	A new cost-effective system developed under a program sponsored by the Gas Research Institute in Chicago combines the advantages of continuous emissions-monitoring systems (CEMS) and predictive emissions-monitoring systems (PEMS). The development of a true nitrogen oxide sensor enables the user to measure nitrogen oxide directly as the traditional instruments do, with the potentially lower installed cost coming from the sensor-based predictive monitoring approach. To achieve this lower cost, the array of sensors must be packaged in a system that does not require the air-conditioned shelter typically required for CEMS. Therefore, the system has been designed for direct exposure to the weather for most applications. The continuous emissions monitor, called the CEMcat analyzer, uses 2 catalytic sensors: one to measure nitrogen oxide and the other to measure carbon monoxide. Oxygen is monitored by a sensor that uses well-known electrocatalytic zirconium oxide sensor technology. All 3 sensors are placed within a single heated manifold that contains critical flow orifices to ensure constant flow across each sensor. The technology of the analyzer is examined in detail.
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subjects	Accuracy Analyzers Applied sciences Controllers Emission standards Energy Engines Environmental monitoring Exact sciences and technology Fuels Gas industry Gas transmission and distribution. Ships. Pipelines. Distribution networks. Compressors stations Microprocessors Monitoring systems Natural gas Natural gas industry Oxygen Pipelines R&D Research & development Sensors
title	Monitoring gas pipelines
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