Extinction of premixed flames by stretch and radiative loss

An axially stretched, cylindrical premixed flame was formed by using a radial-flow nozzle burner, which made it possible to produce a highly stretched flow field in laminar conditions and to investigate the extinction characteristics of the flame over a wide range of equivalence ratios. Using this b

A theoretical analysis of diffusion flame extinction in the stagnation point region of a condensed fuel has been made including radiative heat loss from the fuel surface. In addition to the blowoff limit normally found when flame stretch rate is large, an extinction limit has been identified when th

A theory is developed to explain the experimentally observed extinction of premixed flames by steep pressure drops. The full nonlinear equations are solved numerically and it is found that for large, rapid pressure drops the flame does not recover. This is taken to be clear evidence of extinction. M

This paper reports numerical investigations on the e!ects of #ow"eld unsteadiness on the structure and extinction of strained laminar non-premixed #ames. The unsteady conservation equations of mass, momentum, energy and species were solved along the stagnation streamline of an opposed jet counter#ow

Axial and radial temperature profiles of the gaseous slab in between two symmetric counterflow premixed flames of methane are measured. The results indicate that for widely separated lean and rich flames, there exists a temperature dip which is accounted for on the basis of radiative heat loss. For