Double blue zones in inverse and normal laminar jet diffusion flames

Past experimental and computational works indicate that double blue zones are possible in hydrocarbon diffusion flames. This study examines these zones in inverse (IDF) and normal (NDF) laminar gas jet diffusion flames. Over 100 diffusion flames were observed with various fuels, diluents, dilution l...

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Veröffentlicht in:	Combustion and flame 2020-01, Vol.211, p.253-259
Hauptverfasser:	Wang, Zhengyang, Sunderland, Peter B., Axelbaum, Richard L.
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Sprache:	eng
Schlagworte:	Bandpass filters Broadband Carbon dioxide Chemiluminescence Deconvolution Diffusion Diffusion flames Dilution Flow velocity Fluid filters Fuels Gas jets Organic chemistry Power consumption Premixing Spectroscopy Triple flames
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description	Past experimental and computational works indicate that double blue zones are possible in hydrocarbon diffusion flames. This study examines these zones in inverse (IDF) and normal (NDF) laminar gas jet diffusion flames. Over 100 diffusion flames were observed with various fuels, diluents, dilution levels, and flow rates. Upon close examination, the IDFs and NDFs are seen to have double blue zones, separated at the flame tip by up to 1.6 and 0.9 mm, respectively, with a relatively dark region in between. By partially premixing the fuel and oxidizer streams, it was observed that, for both IDFs and NDFs, the zone toward the fuel side is rich, while that toward the oxidizer side is stoichiometric. Chemiluminescence was investigated using cameras and bandpass filters emphasizing emissions from OH* (310 nm), CH* (430 nm), CO2* (455 nm), and C2* (515 nm). The images were deconvolved using onion peeling. Broadband CO2* emissions were subtracted from the images of OH, CH, and C2* emissions to find profiles of spectral emissive power for these species. The thin, blue-green zone on the fuel side coincides with the peaks in CH* and C2* emissions in the fuel-consumption zone, while the broader, blue stoichiometric zone coincides with the peaks in OH* and CO2* emissions in the oxygen-consumption zone. The spectral emissive power peaks for C2, CO2, CH, and OH are typically 3 times as high in the IDF as in the NDF, which is attributed to the higher scalar dissipation rates.
doi_str_mv	10.1016/j.combustflame.2019.09.014
format	Article
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This study examines these zones in inverse (IDF) and normal (NDF) laminar gas jet diffusion flames. Over 100 diffusion flames were observed with various fuels, diluents, dilution levels, and flow rates. Upon close examination, the IDFs and NDFs are seen to have double blue zones, separated at the flame tip by up to 1.6 and 0.9 mm, respectively, with a relatively dark region in between. By partially premixing the fuel and oxidizer streams, it was observed that, for both IDFs and NDFs, the zone toward the fuel side is rich, while that toward the oxidizer side is stoichiometric. Chemiluminescence was investigated using cameras and bandpass filters emphasizing emissions from OH* (310 nm), CH* (430 nm), CO2* (455 nm), and C2* (515 nm). The images were deconvolved using onion peeling. Broadband CO2* emissions were subtracted from the images of OH, CH, and C2* emissions to find profiles of spectral emissive power for these species. The thin, blue-green zone on the fuel side coincides with the peaks in CH* and C2* emissions in the fuel-consumption zone, while the broader, blue stoichiometric zone coincides with the peaks in OH* and CO2* emissions in the oxygen-consumption zone. 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This study examines these zones in inverse (IDF) and normal (NDF) laminar gas jet diffusion flames. Over 100 diffusion flames were observed with various fuels, diluents, dilution levels, and flow rates. Upon close examination, the IDFs and NDFs are seen to have double blue zones, separated at the flame tip by up to 1.6 and 0.9 mm, respectively, with a relatively dark region in between. By partially premixing the fuel and oxidizer streams, it was observed that, for both IDFs and NDFs, the zone toward the fuel side is rich, while that toward the oxidizer side is stoichiometric. Chemiluminescence was investigated using cameras and bandpass filters emphasizing emissions from OH* (310 nm), CH* (430 nm), CO2* (455 nm), and C2* (515 nm). The images were deconvolved using onion peeling. Broadband CO2* emissions were subtracted from the images of OH, CH, and C2* emissions to find profiles of spectral emissive power for these species. The thin, blue-green zone on the fuel side coincides with the peaks in CH* and C2* emissions in the fuel-consumption zone, while the broader, blue stoichiometric zone coincides with the peaks in OH* and CO2* emissions in the oxygen-consumption zone. 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This study examines these zones in inverse (IDF) and normal (NDF) laminar gas jet diffusion flames. Over 100 diffusion flames were observed with various fuels, diluents, dilution levels, and flow rates. Upon close examination, the IDFs and NDFs are seen to have double blue zones, separated at the flame tip by up to 1.6 and 0.9 mm, respectively, with a relatively dark region in between. By partially premixing the fuel and oxidizer streams, it was observed that, for both IDFs and NDFs, the zone toward the fuel side is rich, while that toward the oxidizer side is stoichiometric. Chemiluminescence was investigated using cameras and bandpass filters emphasizing emissions from OH* (310 nm), CH* (430 nm), CO2* (455 nm), and C2* (515 nm). The images were deconvolved using onion peeling. Broadband CO2* emissions were subtracted from the images of OH, CH, and C2* emissions to find profiles of spectral emissive power for these species. The thin, blue-green zone on the fuel side coincides with the peaks in CH* and C2* emissions in the fuel-consumption zone, while the broader, blue stoichiometric zone coincides with the peaks in OH* and CO2* emissions in the oxygen-consumption zone. The spectral emissive power peaks for C2, CO2, CH, and OH are typically 3 times as high in the IDF as in the NDF, which is attributed to the higher scalar dissipation rates.</abstract><cop>New York</cop><pub>Elsevier Inc</pub><doi>10.1016/j.combustflame.2019.09.014</doi><tpages>7</tpages></addata></record>
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subjects	Bandpass filters Broadband Carbon dioxide Chemiluminescence Deconvolution Diffusion Diffusion flames Dilution Flow velocity Fluid filters Fuels Gas jets Organic chemistry Power consumption Premixing Spectroscopy Triple flames
title	Double blue zones in inverse and normal laminar jet diffusion flames
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