Litcius/Paper detail

Numerical investigation of unconfined hydrogen explosions using an embedded large eddy simulation (ELES) approach with detailed chemical reaction mechanisms

Wimukthi Senarathna, Damith Mohotti, Kasun Wijesooriya, Edward Chern Jinn Gan, Zhongyan Huang, Alex Remennikov, C.K. Lee

2025International Journal of Hydrogen Energy7 citationsDOIOpen Access PDF

Abstract

This paper presents the development of an innovative Embedded-Large Eddy Simulation (ELES) numerical approach incorporating detailed chemical reaction mechanisms with a polyhedral meshing approach to enhance the understanding of explosion dynamics. ELES with detailed reaction mechanisms emerges as a hybrid model that ensures the balance between accuracy and computational efficiency in complex explosion scenarios. This research uses small-scale soap bubble experiments with two ignition methods to assess the effect of ignition source, validate numerical models, and evaluate explosion overpressures. The evolution of the flame, flame speed, and species is analysed, revealing the dynamics of intermediate species in the explosion process. The ELES model predicts peak overpressure with a mean absolute error ranging from 0.1 to 1.87 kPa compared to experimental results while maintaining computational efficiency. The numerical model was also validated for predicting overpressures in large-scale hydrogen-air explosions. This approach provides an effective framework for hazard assessment and safety strategy development, contributing to improved safety protocols and infrastructure design in hydrogen industries.

Topics & Concepts

HydrogenLarge eddy simulationMaterials scienceMechanicsChemistryPhysicsTurbulenceOrganic chemistryCombustion and Detonation ProcessesEnergetic Materials and CombustionRisk and Safety Analysis