Remote Gas Emission Flux Sensing in a Thermal Power Plant Using Shadow Image Processing

Helmut Neff; Elmar Uwe Kurt Melcher; Joseana Macêdo Fechine Régis de Araújo; Sergio de Brito Espinola; Adalberto Gomes Teixeira Júnior; Samir Trajano Feitosa; Gustavo de Brito Espinola; Sergio Vinícius da Costa Cândido

doi:10.4028/www.scientific.net/AMM.522-524.638

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HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vols. 522-524Remote Gas Emission Flux Sensing in a Thermal...

Remote Gas Emission Flux Sensing in a Thermal Power Plant Using Shadow Image Processing

Abstract:

Total flue gas emission is a crucial quantity for control of environmental impact in thermal power plants. Direct gas flow measurements by Pitot tubes and other sensors are hampered by the very high temperature at the exhaust, high content of carbon soot and frequently turbulent flow conditions, which cause a non-parabolic flow profile across the exhaust cross section. We are developing an optical imaging method for gas flux measurements, using shadow video imaging of the dynamic hot gas emission profile at the power plant exhaust. All, high exhaust gas temperature, pressure increase and carbon soot content cause small variations of the refractive index. This deflects a considerable amount direct sunlight under inclined solar illumination conditions (at approx 38 deg inclination angle), and results in a rather sharp contrast and clear shadow image of the gas flow above the exhaust. This feature is not observable in direct transmission imaging. The distant flow shadow image pattern, as seen on the plant floor, is video monitored over a short time period and the dynamic image evolution digitally processed and analyzed. The presented method is similar to the well known optical so-called Schlieren imaging technique. Initial video processing algorithms and results are presented that provide the flue gas flow velocity directly at the exhaust exit, being close to the expected values, obtained from power plant process parameters.

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Periodical:

Applied Mechanics and Materials (Volumes 522-524)

Pages:

638-642

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.522-524.638

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Online since:

February 2014

Authors:

Helmut Neff, Elmar Uwe Kurt Melcher, Joseana Macêdo Fechine Régis de Araújo, Sergio de Brito Espinola*, Adalberto Gomes Teixeira Júnior, Samir Trajano Feitosa, Gustavo de Brito Espinola, Sergio Vinícius da Costa Cândido

Keywords:

Gas Emission, Image Processing, Power Plant

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References

[1] Programas de Transmissão http: /www. ANEEL. gov. br/area. cfm?idArea=57 (2013).

Google Scholar

[2] Donald W. Schroeder Jr., A Tutorial on Pipe Flow Equations, Stoner Associates Inc., August 16th, (2001).

Google Scholar

[3] J. Fröhlich, Druckänderungen in Rohrleitungen, Vorlesung Technische Strömungslehre I (Technische Universität Dresden, 2013).

Google Scholar

[4] M. Raffel; H. Richard; G. E. A. Meier, On the application of background oriented optical tomography for large scale aerodynamic investigations, Experiments in Fluids, Volume 28, Issue 5 (2000), pp.477-481.

DOI: 10.1007/s003480050408

Google Scholar

[5] Jason A. Volpee; Gary S. Settles, Laser-induced gas breakdown as a light source for Schlieren and shadow graph particle image velocity, Opt. Eng. 45(8), 080509. (2006).

DOI: 10.1117/1.2332867

Google Scholar

[6] Giosuè Caliano; Alessandro S. Savoia; Antonio Iula, An Automatic Compact Sclieren Imaging System for Ultrasound Transducer Testing. IEEE Trans. On Ultrasonics, Ferrroelectrics, and Frequency Control, vol. 59, no. 9, (2012).

DOI: 10.1109/tuffc.2012.2431

Google Scholar

[7] Dennis R. Jonassen, Gary S. Settles, Michael Tronosky, Schlieren PIV for turbulent flows, Optics and Lasers in Engineering, Volume 44 (2006), Issues 3–4.

DOI: 10.1016/j.optlaseng.2005.04.004

Google Scholar

[8] G. Martius, Video Stabilization - Features/Usage", http: /public. hronopik. de/vid. stab/features. php, lang=en, (2013).

Google Scholar

[9] John B. Heywood: "Internal Combustion Engine Fundamentals (1988), p.915.

Google Scholar