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Upscaling coal self-heating reaction models from the laboratory to field applications

Xuebin Wu, Guangyao Si, J. Zhang, Jingyu An, Zexin Yu, Yu Jing, Peyman Mostaghimi, Ting Ren

2025International Journal of Heat and Mass Transfer13 citationsDOIOpen Access PDF

Abstract

• Impact of temperature-induced coal property variations on oxidation. • Indicator gases for different coal self-heating stages. • The highest temperature points migration under the impact of coupling Multiphysics coupling in goaf. • Reduction of thermal hotspots and gases concentration area. During the coal mining process, real-time monitoring and analysis of gases are crucial for preventing and controlling coal spontaneous combustion (sponcom). Laboratory-based gas evolution tests and reaction models on coal for sponcom prevention are often difficult to be scaled up in field goaf conditions. Computational fluid dynamics modelling addresses these challenges but faces issues with temperature impacts on coal properties and upscaling to goaf environments. Addressing these issues, this study has developed a novel coal oxidation model that accounts for variation in coal properties with temperature and introduces oxidation products of C 2 H 4 and C 2 H 6 as key gas indicators. This model uses gas composition and concentration changes to assess the progression of sponcom in longwall goaf. Compared to previous models, this approach significantly improves accuracy by incorporating key gas indicators and better capturing the temperature-dependent behaviours of coal. Simulation results indicate a clear localisation trend of coal sponcom in the goaf: as the reaction intensifies, the highest-temperature points initially move deeper into the goaf and then migrate towards face areas with higher oxygen concentrations. The decrease in O 2 concentration, changes in the Graham's ratio, and the generation of C 2 H 4 and C 2 H 6 can all indicate different stages of coal self-heating. This phenomenon reveals the complex interactions between temperature, oxygen concentration, and coal properties. The findings highlight the critical role of temperature and gas components in sponcom, providing a basis for optimising monitoring locations in goaf areas to improve early detection and real-time risk assessment, ultimately enhancing sponcom early-warning accuracy and coal mine safety.

Topics & Concepts

CoalField (mathematics)Nuclear engineeringMaterials scienceMechanicsEnvironmental scienceProcess engineeringWaste managementPhysicsMathematicsEngineeringPure mathematicsCoal Properties and UtilizationMining and Gasification TechnologiesHydrocarbon exploration and reservoir analysis
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