Velocity fields of axisymmetric hydrogen-air counterflow diffusion flames from LDV, PIV, and numerical computation

Laminar fuel-air counterflow diffusion flames (CFDFs) were studied using axisymmetric convergent-nozzle and straight-tube opposed jet burners (OJBs). The subject diagnostics were used to probe a systematic set of H m a a i r CFDFs over wide ranges of fuel input (22 to 100% Ha), and input axial strain rate (130 to 1700 Us) just upstream of the airside edge, for both plug-flow and parabolic input velocity profiles. Laser Doppler Velocimetry (LDV) was applied along the centerline of seeded air flows from a convergent nozzle OJB (7.2 mm i.d.), and Particle Imaging Velocimetry (PIV) was applied on the entire airside of both nozzle and tube OJBs (7 and 5 mm i.d.1 to characterize global velocity structure. Data are compared to numerical results from a one-dimensional (1-D) CFDF code based on a stream function solution for a potential flow input boundary condition. Axial strain rate inputs at the airside edge of nozzle-OJB flows, using LDV and PIV, were *Research Scientist (member AIAA) , NASA Langley Research Center, Hampton, VA 23681 =Laser Applications Specialist, NASA Langley ?Research Technician, Lockheed Engineering and Sciences IAssociate Professor (member AIAA), Dept. Mechanical and Aerospace Engineering and Engineering Mechanics Copyright