Reacting Hydrogen Jet in Crossflow - Flame Dynamics Under Acoustic Forcing

TL;DR

This study investigates the flame dynamics of reacting hydrogen jets in crossflow under acoustic forcing, analyzing how different frequencies and momentum ratios influence jet behavior using high-speed imaging and POD analysis.

Contribution

It introduces a detailed experimental analysis of hydrogen jet flame dynamics under acoustic forcing, highlighting the effects of frequency and momentum ratio on jet response.

Findings

Jet responds selectively to certain forcing frequencies.

Higher momentum ratios dampen the effect of acoustic forcing.

Preferred frequency range identified for jet response.

Abstract

This paper presents experimental study of reacting hydrogen jet in crossflow. High speed shadowgraph images are used to capture flame dynamics. Unforced jets with various momentum flux ratios (q) are studied. Proper Orthogonal Decomposition (POD) analysis is used to examine the high-speed instantaneous images and characterize spatio-temporal behavior the reacting jets. Further, jet is acoustically forced with various frequencies and the effect of forcing frequency and momentum flux ratio is studied in detail. Instantaneous images, POD mode shapes and Power Spectral Density (PSD) plots are used to assess the response of jet to forcing function, and the influence of crossflow. It is observed that the jet does not equally respond to all frequencies and the preferred frequency range is identified. It is also observed that higher momentum ratio produces stronger interaction with the crossflow which dampens the effect of forcing.