- Author
-
Blevins, L. G.
|
Renfro, M. W.
|
Lyle, K. H.
|
Laurendeau, N. M.
|
Gore, J. P.
- Title
- Experimental Study of Temperature and CH Radical Location in Partially Premixed CH4/Air Coflow Flames.
- Coporate
- National Institute of Standards and Technology, Gaithersburg, MD
Purdue Univ., West Lafayette, IN
- Journal
-
Combustion and Flame,
Vol. 118,
No. 4,
684-696,
September 1999
- Sponsor
- National Science Foundation, Washington, DC
Office of Naval Research, Washington, DC
Purdue Univ., West Lafayette, IN
- Contract
- NSF-GRANT-CTS-915720
ONR-GRANT-N00014-94-0624
- Keywords
-
premixed flames
|
temperature
|
combustion chemistry
|
flame structure
|
temperature measurements
|
experiments
- Identifiers
- axial velocity; CH radical location
- Abstract
- As part of an ongoing investigation of an exhaust NOx, emission index minimum measured for partially premixed flames, radial temperature profiles and CH radical locations were measured in atmospheric-pressure, partially premixed, coflow, methane/air flames with fuel-side equivalence ratios of 1.6, 2.0, and 3.5, at three axial heights above the burner. The work was undertaken because of the importance of temperature and CH radical behavior in NO formation chemistry. Thin-filament pyrometry was found to be more appropriate than thermocouple thermometry for temperature measurements in partially premixed flames. Results demonstrated that the 1.6-equivalence-ratio flame exhibited classical double-flame structure, the 2.0-equivalence-ratio flame was a merged flame, and the 3.5-equivalence-ratio flame exhibited diffusion-flame structure. Signals from CH* chemiluminescence and CH laser-induced fluorescence provide evidence that, for the present measurement locations, double flames exhibit single CH peaks which can be associated with their premixed component flames. Double CH radical peaks, which were predicted to occur in low-strain-rate flames, were not found for the limited number of flame conditions and locations studied. In the near-burner region, the premixed and nonpremixed component flames of the phi b=1.6 double flame diverge radially with increasing downstream distance and merge together for larger values.