Experimental and numerical characterization of freely propagating ozone-activated dimethyl ether cool flames
详细信息 查看全文
- 作者:Mohammadhadi Hajiloua ; Timothy Ombrellob ; Sang Hee Wonc ; Erica Belmonta ; ebelmont@uwyo.edu
- 关键词:Cool flame ; Freely propagating ; Laminar flame ; Low temperature oxidation ; Negative temperature coefficient ; Dimethyl ether
- 刊名:Combustion and Flame
- 出版年:2017
- 出版时间:February 2017
- 年:2017
- 卷:176
- 期:Complete
- 页码:326-333
- 全文大小:1090 K
- 卷排序:176
文摘
Experimental flame characterization is necessary for the development and validation of chemical kinetics models. Low temperature oxidation produces a cool flame, which is a combustion phenomenon resulting from negative temperature coefficient (NTC) behavior. Kinematic stabilization of premixed, freely propagating, ozone-activated, cool flames of dimethyl ether (DME) has been investigated at sub-atmospheric pressure of 7.3 kPa using a laminar flat flame Hencken burner. This platform permits estimation of laminar propagation speed, as well as spatially-resolved temperature and species mole fractions along the burner axis. Stability mapping for a range of equivalence ratios (ϕ) was performed to determine the range of ozone concentrations for which a cool flame can be sustained. Based on the results of stability mapping, an ozone concentration of 6.1% in oxygen was chosen to investigate the characteristics of DME cool flames over a range of equivalence ratios from ϕ = 0.4 to 1.4. Two distinct cool flame stabilization modes were observed in experiments: a burner-stabilized mode at low reactant flow rates, and a freely propagating mode at higher flow rates. From the transition between the two modes, cool flame propagation speeds from ϕ = 0.4 to 1.4 were determined. Flame temperatures were measured at these equivalence ratios, with maximum temperatures decreasing from 885 K at ϕ = 0.4 to 779 K at ϕ = 1.4. A single equivalence ratio of ϕ = 0.6 was chosen for detailed investigation of the flame structure, including spatial measurements of temperature and species as a function of height above the burner. Experimental results were compared to numerical simulations of a ϕ = 0.6 cool flame. Experimental propagation speed was found to be within 25% of the numerical value, and significant agreement between experimental and numerical species profiles was observed.