Instability Influenced by CO2 and Equivalence Ratio in Oxyhydrogen Flames on Flat Burner
Journal article
Authors/Editors
Strategic Research Themes
No matching items found.
Publication Details
Author list: Kaewpradap A., Kadowaki S.
Publisher: Taylor and Francis Group
Publication year: 2017
Journal: Combustion Science and Technology (0010-2202)
Volume number: 189
Issue number: 3
Start page: 438
End page: 452
Number of pages: 15
ISSN: 0010-2202
eISSN: 1563-521X
Languages: English-Great Britain (EN-GB)
View in Web of Science | View on publisher site | View citing articles in Web of Science
Abstract
Oxyhydrogen (H2/O2) combustion with carbon dioxide (CO2) was used widely because the replacement of nitrogen (N2) with CO2 was applied to reduce emissions of nitrogen oxide (NOx). However, the replacement of N2 with CO2 brings about cellular premixed flames owing to intrinsic instability. This study focuses on the effects of CO2 ratio on the characteristics of cellular premixed flames on flat burner at atmospheric pressure. Oxyhydrogen flames were experimentally investigated with variation of CO2 ratio, equivalence ratio, and total gas flow rate. Then the cell size, power spectral density, and reconstructed attractor were obtained. When the CO2 ratio increased, greater cell size, lower sharp peak frequency of power spectral density, and the more complicated doughnut ring of reconstructed attractor were found. It was caused by the replacement of N2 with CO2, which affected diffusive-thermal instability. As the equivalence ratio increased, the smaller cell size, higher sharp peak frequency, and smaller doughnut ring were obtained owing to the decrease of instability intensity. Moreover, we obtained smaller cell size, higher sharp peak frequency, and smaller doughnut ring when the total gas flow rate increased. The results showed that the increase of CO2 ratio and the decrease of equivalence ratio and total gas flow rate induced greater cell size, lower sharp peak frequency, and a more complicated attractor as higher instability intensity. ฉ 2017 Taylor & Francis.
Keywords
Diffusive-thermal instability, Oxyhydrogen flame
Contact Information