On flame speed enhancement in turbulent premixed hydrogen-air flames during local flame-flame interaction

Abstract

Given the need to develop zero-carbon combustors for power and aircraft engine applications, Sd of a turbulent premixed flame, especially for H2-air, is of immediate interest. The present study investigates 3D DNS cases of premixed H2-air turbulent flames at varied pressures for different Ret and Ka with detailed chemistry to theoretically model Sd at negative curvatures. Prior studies at atmospheric pressure showed Sd to be enhanced significantly over SL at large negative due to flame-flame interactions. 1D simulations of an imploding cylindrical H2-air laminar premixed flame used to represent the local flame surfaces undergoing flame-flame interaction in a turbulent flame at the corresponding pressure conditions are performed to understand the interaction dynamics. These simulations emphasized the transient nature of the flame structure during flame-flame interactions and enabled analytical modeling of Sd at these regions of extreme negative of the 3D DNS. The JPDF of Sd and and the corresponding conditional averages from 3D DNS showed a negative correlation between Sd and . The model successfully predicts the variation of Sd| with for the regions on the flame surface with δL \! \! -1 at all pressures, with good accuracy. This shows the aforementioned configuration to be fruitful in representing local flame-flame interaction in 3D turbulent flames. Moreover, at =0, on average Sd can deviate from SL, manifested by the internal flame structure, controlled by turbulence transport in the large Ka regime. Thus, the correlation of Sd/SL with |∇ c|c0 at =0 is explored.