DocumentCode
2917428
Title
Numerical Simulation Study of Premixed Hydrogen-Oxygen Combustion Process in Micro-scale Rectangular Channel
Author
Aikun, Tang ; Jianfeng, Pan ; Xia, Shao ; Hong, Xue
Author_Institution
Sch. of Energy & Power Eng., Jiangsu Univ., Zhenjiang, China
fYear
2011
fDate
19-20 Feb. 2011
Firstpage
520
Lastpage
524
Abstract
Detailed 19-steps reaction mechanisms are adopted to simulate the combustion characteristics of premised hydrogen-oxygen in a 3-dimensional rectangular micro channel, and inlet velocity, channel height and wall material are changed to further study the effects of these key factors on the micro-combustion. The results indicate that the premised hydrogen-oxygen can realize stable combustion In sub millimeter rectangular channel in a wide velocity range, the reaction is rapid near the inlet and the structure of the flame core is cone-shaped. The three influential parameters all have effects on the temperature and length of flame, which causes the difference of steam mass fraction in the combustor. Adopting materials of smaller heat conductivity coefficient will result in larger nonuniformity of the temperature distribution on the outwall of the combustor and will affect its working intensity. The quenching distance of premised hydrogen oxygen combustion in the rectangular channel is less than 0.2mm. The mixture can react adequately in this type of channel with the height of 0.2~0.8mm when the flux and the length are appropriate.
Keywords
combustion; hydrogen; microchannel flow; oxygen; H-O; channel height; inlet velocity; microcombustion; microscale rectangular channel; premixed hydrogen-oxygen combustion process; reaction mechanisms; steam mass fraction; temperature distribution; three dimensional rectangular microchannel; wall material; Computers; Decision support systems; Distributed control; Monitoring; channel height; micro-scale combustion; numerical simulation; rectangular channel; wall material;
fLanguage
English
Publisher
ieee
Conference_Titel
Computer Distributed Control and Intelligent Environmental Monitoring (CDCIEM), 2011 International Conference on
Conference_Location
Changsha
Print_ISBN
978-1-61284-278-3
Electronic_ISBN
978-0-7695-4350-5
Type
conf
DOI
10.1109/CDCIEM.2011.208
Filename
5747871
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