Litcius/Paper detail

LES flamelet modeling of hydrogen combustion considering preferential diffusion effect

Reo Kai, Taiki Tokuoka, Jun Nagao, Abhishek Lakshman Pillai, Ryoichi Kurose

2022International Journal of Hydrogen Energy45 citationsDOIOpen Access PDF

Abstract

A flamelet-generated manifold (FGM) method that explicitly considers the preferential diffusion effect, referred to as FGM-PD method, is employed for large-eddy simulations (LESs) of a lean-premixed H2/air low-swirl lifted flame, and the validity is examined by comparing with the experiment. First, the applicability of the FGM-PD method is investigated by one-dimensional numerical simulations of planar laminar premixed H2/air flames. Next, LESs of a lean-premixed H2/air low-swirl lifted flame are performed employing the FGM-PD and conventional FGM methods. Results of the one-dimensional numerical simulations show the importance of considering preferential diffusion to accurately predict species concentrations near the flame front. The FGM-PD method accurately predicts this, and therefore, reproduces the laminar burning velocity and spatial distributions of temperature and mixture fraction. Three-dimensional LES results confirm that the prediction accuracy of the velocities near the flame front is improved by employing this FGM-PD method. Additionally, the OH mass fraction distribution predicted by the FGM-PD method exhibits the inhomogeneous finger-like structure, which has been observed in previous experiments. This inhomogeneity of OH mass fraction distribution, which corresponds to that of the reaction rate, predicted by the FGM-PD method, strongly affects the flame front structure.

Topics & Concepts

Laminar flowMaterials scienceDiffusion flameCombustionDiffusionMass fractionMechanicsFlame structureLaminar flame speedPremixed flameHydrogenThermodynamicsComposite materialChemistryPhysicsPhysical chemistryCombustorOrganic chemistryCombustion and flame dynamicsAdvanced Combustion Engine TechnologiesCombustion and Detonation Processes