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Main Authors: Li, Shengnan, Li, Shangpeng, Xie, Shumeng, Xu, Yong, Gao, Ke, Zhang, Huangwei
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2503.01853
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author Li, Shengnan
Li, Shangpeng
Xie, Shumeng
Xu, Yong
Gao, Ke
Zhang, Huangwei
author_facet Li, Shengnan
Li, Shangpeng
Xie, Shumeng
Xu, Yong
Gao, Ke
Zhang, Huangwei
contents The mechanisms of direct detonation initiation (DDI) in methane/air mixtures containing coal particles are investigated through simulations conducted using the Eulerian-Lagrangian method in a two-dimensional configuration. Methane-air combustion is modelled with a detailed chemical mechanism involving 36 species and 219 reactions, while coal particle surface reactions are computed using a kinetic/diffusion-limited rate model. The findings indicate that shock waves generated from the hotspot can initiate detonation through heterogeneous and homogeneous reactions, with contributions from both methane and particle combustion. Coal particle surface reactions provide the dominant energy for detonation initiation, whereas gas-phase reactions enhance detonation stability during propagation. The difficulty of achieving detonation initiation exhibits a non-linear dependence on particle concentrations and gas equivalence ratios. An optimal particle concentration and gas equivalence ratio for successful DDI is identified. Smaller particles are found to facilitate detonation initiation more effectively. Key processes in DDI of two-phase mixtures are identified, including particle heating, methane combustion, and particle burning. Three DDI modes, critical, stable, and cell-free, are observed based on particle concentration. As particle concentration increases, the temperatures of both particles and gas become close, initially rising and then decreasing with further increases in particle concentration. Additionally, the introduction of coal particles gives rise to two distinct stages in gas-phase reactions.
format Preprint
id arxiv_https___arxiv_org_abs_2503_01853
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Direct detonation initiation and propagation in methane/air mixtures containing coal particles
Li, Shengnan
Li, Shangpeng
Xie, Shumeng
Xu, Yong
Gao, Ke
Zhang, Huangwei
Chemical Physics
Fluid Dynamics
The mechanisms of direct detonation initiation (DDI) in methane/air mixtures containing coal particles are investigated through simulations conducted using the Eulerian-Lagrangian method in a two-dimensional configuration. Methane-air combustion is modelled with a detailed chemical mechanism involving 36 species and 219 reactions, while coal particle surface reactions are computed using a kinetic/diffusion-limited rate model. The findings indicate that shock waves generated from the hotspot can initiate detonation through heterogeneous and homogeneous reactions, with contributions from both methane and particle combustion. Coal particle surface reactions provide the dominant energy for detonation initiation, whereas gas-phase reactions enhance detonation stability during propagation. The difficulty of achieving detonation initiation exhibits a non-linear dependence on particle concentrations and gas equivalence ratios. An optimal particle concentration and gas equivalence ratio for successful DDI is identified. Smaller particles are found to facilitate detonation initiation more effectively. Key processes in DDI of two-phase mixtures are identified, including particle heating, methane combustion, and particle burning. Three DDI modes, critical, stable, and cell-free, are observed based on particle concentration. As particle concentration increases, the temperatures of both particles and gas become close, initially rising and then decreasing with further increases in particle concentration. Additionally, the introduction of coal particles gives rise to two distinct stages in gas-phase reactions.
title Direct detonation initiation and propagation in methane/air mixtures containing coal particles
topic Chemical Physics
Fluid Dynamics
url https://arxiv.org/abs/2503.01853