The Effect of Strain Rate on Diffusion Flames. II: Large Straining

The response of counterflow flames to oscillating strain rates is analyzed by using large activation energy asymptotics, as a potential application to turbulent combustion and acoustic instability of rocket engines. The characteristic oscillation time of practical interest is found to be of the same

The structure of a strained premixed laminar flame is examined. The flame is formed in the vicinity of a stagnation point established by the counterflow of fresh mixture and hot combustion products. This ideal configuration analyzed by Libby and Williams [18] with activation energy asymptotics is he

Laminar counterflow diffusion flames of mixtures of methyl chloride and trichloroethylene with methane have been studied. Measurements of the temperature profiles were obtained through the flames, the velocity profiles, and the profiles of major species and selected minor species such as polycyclic

The structural response of counterflowing methane/oxygen/nitrogen diffusion flames to aerodynamic straining was experimentally and computationally investigated. The temperature and major species concentration profiles were experimentally determined as functions of the applied strain rate by using sp