二氧化碳对煤尘爆炸的抑制作用研究：实验与模拟讨论

IF 6.4 2区工程技术 Q1 THERMODYNAMICS

Case Studies in Thermal Engineering Pub Date : 2025-05-13 DOI:10.1016/j.csite.2025.106321

Bingyou Jiang , Jing-Jing Li , Mingqing Su , Kunlun Lu , Qi Yao , Xuerong Liang

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引用次数: 0

摘要

本研究从宏观和微观两方面系统探讨了CO2抑制煤粉爆炸的效果和机理。实验和动力学模拟结果表明，当有效抑制浓度为15%时，煤粉的爆炸压力随CO2体积分数的增加而降低。CO2增强了煤粉的热稳定性，使燃烧阶段的活化能由72.577 kJ/mol提高到76.541 kJ/mol。此外，固体爆炸产物的微观结构和主要形态表明，CO2有效地抑制了煤粉爆炸过程中碳链结构的断裂和CH4等气体的释放。C-O和羟基-π官能团的相对含量分别降低了28.29%和10.43%。这与数值模拟结果一致，总OH产率降低了0.048 mol /cm3·s，明确了CO2阻断连锁反应的关键步骤：H + O2→OH + o，建立了CO2对煤粉爆炸的抑制机理。

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Study on the suppressive effects of carbon dioxide on coal dust explosions: Experimental and simulation discussion

This study systematically investigates the effectiveness and mechanism of CO₂ in suppressing coal powder explosions from both macroscopic and microscopic perspectives. Experimental and kinetic modeling results reveal that the explosion pressure of coal powder decreases with increasing CO₂ volume fraction, with an effective suppression concentration of 15 %. CO₂ enhances the thermal stability of coal powder, raising the activation energy of the combustion stage from 72.577 kJ/mol to 76.541 kJ/mol. In addition, the microstructure and predominant forms of the solid explosion products show that CO₂ effectively suppresses the breakage of carbon chain structures and the release of CH₄ and other gases during coal powder explosions. It also significantly suppresses the formation of C-O and hydroxyl-π functional groups, with their relative contents decreasing by 28.29 % and 10.43 %, respectively. This is consistent with the numerical simulation results, which show a decrease of 0.048 mole/cm³·s in the total OH production rate, clearly identifying the key step in the chain reaction blocked by CO₂: H + O₂ → OH + O. This establishes the suppression mechanism of CO₂ on coal powder explosions.

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来源期刊

Case Studies in Thermal Engineering Chemical Engineering-Fluid Flow and Transfer Processes

CiteScore

8.60

自引率

11.80%

发文量

812

审稿时长

76 days

期刊介绍： Case Studies in Thermal Engineering provides a forum for the rapid publication of short, structured Case Studies in Thermal Engineering and related Short Communications. It provides an essential compendium of case studies for researchers and practitioners in the field of thermal engineering and others who are interested in aspects of thermal engineering cases that could affect other engineering processes. The journal not only publishes new and novel case studies, but also provides a forum for the publication of high quality descriptions of classic thermal engineering problems. The scope of the journal includes case studies of thermal engineering problems in components, devices and systems using existing experimental and numerical techniques in the areas of mechanical, aerospace, chemical, medical, thermal management for electronics, heat exchangers, regeneration, solar thermal energy, thermal storage, building energy conservation, and power generation. Case studies of thermal problems in other areas will also be considered.