A Novel Approach for Direct Measurement of the Stretch Factor in Laminar Premixed Hydrogen-Air Flames Affected by Thermodiffusive Instabilities

Abstract

This study introduces a novel experimental configuration using OH-PLIF imaging to directly determine the stretch factor (I0) in laminar premixed hydrogen flames transitioning from a quasi-stable to a thermodiffusively unstable regime. A rod-anchored V-flame is stabilised in a laminar premixed reactant flow. Near the anchoring rod, the mildly strained flame remains quasi-stable, exhibiting a smooth surface and a well-defined inclination angle (θs) to the main flow. This stable branch is associated with a burning rate Ss. Farther downstream, the flame abruptly transitions to a regime dominated by thermodiffusive (TD) instabilities, characterised by cellular structures and a wrinkled surface. The distance between this transition and the anchor decreases with increasing equivalence ratio. This TD-unstable branch exhibits a larger mean flame-surface angle (θu), enabling direct determination of the flame-speed increase, Su/Ss. It is assumed that this ratio represents the normalised flame consumption speed, Sc/SL. Determination of I0 additionally requires the increase in flame-surface area caused by the thermodiffusive instabilities. Three complementary methods are therefore used to evaluate the surface area of the TD-unstable branch (A) relative to a smooth reference area (A0), yielding consistent trends in A/A0 over the investigated equivalence-ratio range. The resulting I0 values, with the main uncertainty arising from A, decrease monotonically with increasing equivalence ratio, from about 1.1--1.3 at φ=0.35 to 0.8--0.9 at φ=0.40, consistent with theoretical predictions. Additional numerical simulations in a reduced two-dimensional representation reproduce the same transition behaviour and yield qualitatively consistent results.

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