Industrial Stack Evaluation With Ground-Based Passive FT-IR Spectrometry

The methodology for producing absorbance and transmittance spectra with a passive Fourier transform infrared (FT-IR) spectrometer from an industrial stack and blackbody source is demonstrated. The knowledge of the stack temperature is shown to be key in generating the single-beam spectral ratio of d...

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Hauptverfasser:	Combs, Roger J, Knapp, Robert B, Kroutil, Robert T, Thomas, Mark J
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Sprache:	eng
Schlagworte:	AMMONIA DETECTION Atomic and Molecular Physics and Spectroscopy BEAMS(RADIATION) BLACKBODY RADIATION DIOXIDES EMISSION FOURIER TRANSFORMATION GRAPHS INDUSTRIES INFRARED RADIATION INTERFEROGRAMS NITROUS OXIDE NITROUS OXIDE EFFLUENTS Nuclear Instrumentation Optical Detection and Detectors PASSIVE SYSTEMS SPECTRA SPECTROMETERS STACKING SULFUR DIOXIDE EMISSIONS SULFUR OXIDES TARGETS TEMPERATURE TEST AND EVALUATION TRANSMITTANCE
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creator	Combs, Roger J Knapp, Robert B Kroutil, Robert T Thomas, Mark J
description	The methodology for producing absorbance and transmittance spectra with a passive Fourier transform infrared (FT-IR) spectrometer from an industrial stack and blackbody source is demonstrated. The knowledge of the stack temperature is shown to be key in generating the single-beam spectral ratio of differences for removal of instrumental effects from the absorbance and transmittance spectra. The difference removes self emission (i.e., offset) terms, and the ratio eliminates the responsivity (i.e., gain) term. The experimental procedure for acquiring the interferograms and single-beam spectra is documented. The experimental results that are obtained for three types of industrial stack are presented in the form of summary graphs and tables. Representative spectral data are also furnished in the Appendixes. Stack target analytes in the study are sulfur dioxide, nitrous oxide, and ammonia.
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The knowledge of the stack temperature is shown to be key in generating the single-beam spectral ratio of differences for removal of instrumental effects from the absorbance and transmittance spectra. The difference removes self emission (i.e., offset) terms, and the ratio eliminates the responsivity (i.e., gain) term. The experimental procedure for acquiring the interferograms and single-beam spectra is documented. The experimental results that are obtained for three types of industrial stack are presented in the form of summary graphs and tables. Representative spectral data are also furnished in the Appendixes. 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The knowledge of the stack temperature is shown to be key in generating the single-beam spectral ratio of differences for removal of instrumental effects from the absorbance and transmittance spectra. The difference removes self emission (i.e., offset) terms, and the ratio eliminates the responsivity (i.e., gain) term. The experimental procedure for acquiring the interferograms and single-beam spectra is documented. The experimental results that are obtained for three types of industrial stack are presented in the form of summary graphs and tables. Representative spectral data are also furnished in the Appendixes. 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subjects	AMMONIA DETECTION Atomic and Molecular Physics and Spectroscopy BEAMS(RADIATION) BLACKBODY RADIATION DIOXIDES EMISSION FOURIER TRANSFORMATION GRAPHS INDUSTRIES INFRARED RADIATION INTERFEROGRAMS NITROUS OXIDE NITROUS OXIDE EFFLUENTS Nuclear Instrumentation Optical Detection and Detectors PASSIVE SYSTEMS SPECTRA SPECTROMETERS STACKING SULFUR DIOXIDE EMISSIONS SULFUR OXIDES TARGETS TEMPERATURE TEST AND EVALUATION TRANSMITTANCE
title	Industrial Stack Evaluation With Ground-Based Passive FT-IR Spectrometry
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