Flashback propensity due to hydrogen blending in natural gas: sensitivity to operating and geometrical parameters

TL;DR

This study uses numerical simulations and sensitivity analysis to explore how operating and geometrical parameters influence flashback risk in hydrogen-methane burners, aiding safer burner design.

Contribution

It provides a comprehensive analysis of flashback propensity considering multiple parameters and their interactions, with new insights into the effects of hydrogen enrichment and burner geometry.

Findings

Preferential diffusion significantly affects flashback physics.

High hydrogen enrichment increases flashback risk near the burner plate.

Slit width influences flashback velocity and temperature distribution.

Abstract

Hydrogen has emerged as a promising option for promoting decarbonization in various sectors by serving as a replacement for natural gas while retaining the combustion-based conversion system. However, its higher reactivity compared to natural gas introduces a significant risk of flashback. This study investigates the impact of operating and geometry parameters on flashback phenomena in multi-slit burners fed with hydrogen-methane-air mixtures. For this purpose, transient numerical simulations, which take into account conjugate heat transfer between the fluid and the solid walls, are coupled with stochastic sensitivity analysis based on Generalized Polynomial Chaos. This allows deriving comprehensive maps of flashback velocities and burner temperatures within the parameter space of hydrogen content, equivalence ratio, and slit width, using a limited number of numerical simulations. Moreover, we assess the influence of different parameters and their interactions on flashback propensity. The ranges we investigate encompass highly H2-enriched lean mixtures, ranging from 80\% to 100\% H2 by volume, with equivalence ratios ranging from 0.5 to 1.0. We also consider slit widths that are typically encountered in burners for end-user devices, ranging from 0.5 mm to 1.2 mm. The study highlights the dominant role of preferential diffusion in affecting flashback physics and propensity as parameters vary, including significant enrichment close to the burner plate due to the Soret effect. These findings hold promise for driving the design and optimization of perforated burners, enabling their safe and efficient operation in practical end-user applications.