The transition of ethanol flames from conventional to MILD combustion
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- 作者:Jingjing Ye ; jingjing.ye01@adelaide.edu.au" class="auth_mail" title="E-mail the corresponding author ; Paul R. Medwell ; Bassam B. Dally ; Michael J. Evans
- 关键词:MILD combustion ; Prevaporised ethanol ; Carrier gas
- 刊名:Combustion and Flame
- 出版年:2016
- 出版时间:September 2016
- 年:2016
- 卷:171
- 期:Complete
- 页码:173-184
- 全文大小:2082 K
文摘
The present paper is focused on prevaporised ethanol flames in the transition from conventional combustion to the MILD combustion regime. Photographs and imaging of OH* chemiluminescence reveal a distinctive flame structure when ethanol carried by air burns in a 3% O2 coflow (typical of MILD combustion), differing from that at higher oxygen levels. In comparison to flames carried by air in a 9% O2 coflow, the spatial gradient and the peak in the OH* signal profile are significantly reduced in the 3% O2 coflow, indicating a more uniform distribution of heat release and temperature. The use of N2 as a carrier gas renders the OH* profile for the 6% O2 coflow case similar to that of flames carried by air in the 3% O2 coflow. The experimental results indicate a transition from conventional combustion to MILD combustion with the decrease of coflow O2 level and/or the use of N2 as a carrier gas. Calculations reveal that a substantial drop in the peak heat release rate and/or overall net heat release rate might contribute to the lack of luminosity of flames in the 3% O2 coflow, suggesting a need for threshold values of these two in defining MILD combustion. A series of laminar flame calculations are performed to identify the MILD combustion regime based on the absence of a negative heat release region. The absence of a negative heat release region is found to be strain rate dependent at a given temperature and O2 level of the oxidant stream. This is mainly a result of the enhanced transportation of O2 across the reaction zone at a higher strain rate. At low strain rates, the negative heat release region is more likely to disappear in a 3% O2 oxidant flow due to a combination of low flame temperature and high availability of O2.