中国安全科学学报 ›› 2026, Vol. 36 ›› Issue (6): 73-81.doi: 10.16265/j.cnki.issn1003-3033.2026.06.1023

• 安全技术与工程 • 上一篇    下一篇

低温下焦煤瓦斯吸附与扩散特性分子模拟研究

马宏宇1(), 王龙2,**(), 万文1, 肖尧2, 胡龙生2, 赵鹏涛3   

  1. 1 湖南科技大学 资源环境与安全工程学院, 湖南 湘潭 411201
    2 湘潭大学 环境与资源学院, 湖南 湘潭 411105
    3 湖南省瓦斯治理和利用工程研究中心有限公司, 湖南 长沙 410004
  • 收稿日期:2026-01-10 修回日期:2026-03-21 出版日期:2026-06-28
  • 通信作者:
    ** 王龙(1989—),男,河南平顶山人,博士,副教授,主要从事矿井瓦斯灾害防治方面的研究。E-mail:
  • 作者简介:

    马宏宇 (1983—),男,河北唐山人,博士,副研究员,主要从事煤矿安全方面的研究。E-mail:

    万文, 教授

    赵鹏涛,高级工程师

  • 基金资助:
    国家自然科学基金资助(52104224); 国家自然科学基金资助(52274194); 湖南省自然科学基金资助(2023JJ40632)

Molecular simulation of gas adsorption and diffusion characteristics in coking coal at low temperatures

Ma Hongyu1(), Wang Long2,**(), Wan Wen1, Xiao Yao2, Hu Longsheng2, Zhao Pengtao3   

  1. 1 School of Resource, Environment and Safety Engineering, Hunan University of Science and Technology, Xiangtan Hunan 411201, China
    2 College of Environment and Resources, Xiangtan University, Xiangtan Hunan 411105, China
    3 Hunan Gas Control andUtilization Engineering Research Center Co., Ltd., Changsha Hunan 410004, China
  • Received:2026-01-10 Revised:2026-03-21 Published:2026-06-28

摘要:

为研究低温(尤其是<273.15 K)下瓦斯(CH4)的吸附/解吸特性,采用巨正则蒙特卡罗(GCMC)和分子动力学(MD)方法,系统模拟238.15~368.15 K下CH4在焦煤大分子模型中的吸附、扩散行为,并揭示CH4吸附增强与扩散抑制效应在分子尺度上的内在关联。结果表明:低温下CH4吸附量显著大于高温下的吸附量,7 MPa时238.15 K的CH4吸附量8.417 mmol/g,较368.15 K时(3.568 mmol/g)提升135.9%;CH4的等量吸附热介于11.365~13.604 kJ/mol之间,且随吸附量增加而降低,为物理吸附;随着温度由368.15 K降至238.15 K,焦煤的自由体积分数(FFV)呈线性减小趋势;同时,CH4分子的自扩散系数呈幂函数下降,238.15 K时的自扩散系数(0.37×10-8 m2/s)较368.15 K时(4.417×10-8m2/s)降低1个数量级。低温促吸抑解效应的微观本质在于热力学与结构动力学的协同耦合作用:低温削弱CH4分子的动能,导致其平均吸附能增大,脱附能垒显著升高;同时诱导煤基质收缩(FFV减小),致使CH4扩散通道的有效尺寸缩减,扩散阻力增大。

关键词: 低温环境, 瓦斯(CH4)吸附, 促吸抑解, 自由体积分数(FFV), 自扩散系数, 分子动力学(MD)

Abstract:

To investigate CH4 adsorption/desorption characteristics at low temperatures (particularly < 273.15 K), Grand Canonical Monte Carlo (GCMC) and MD methods were employed to systematically simulate the adsorption and diffusion behavior of CH4 in a coking coal macromolecular model from 238.15 to 368.15 K. Additionally, the intrinsic molecular-scale relationship between the adsorption enhancement and diffusion inhibition effect of CH4 was revealed. The results show that the CH4 adsorption capacity at low temperatures is significantly higher than that at high temperatures. At 7 MPa, the CH4 adsorption capacity at 238.15 K (8.417 mmol/g) is 135.9% higher than that at 368.15 K (3.568 mmol/g). The isosteric heat of adsorption for CH4 ranged from 11.365 to 13.604 kJ/mol and decreases with increasing adsorption amount, indicating physical adsorption. As temperature decreases from 368.15 to 238.15 K, the FFV of coking coal shows a linear decreasing trend. Meanwhile, the self-diffusion coefficient of CH4 molecules decreases as a power function, with the value at 238.15 K (0.37×10-8 m2/s) being an order of magnitude lower than at 368.15 K (4.417×10-8 m2/s). The microscopic essence of the low-temperature promotion of adsorption and inhibition of desorption lies in the synergistic coupling of thermodynamic and structural-dynamic factors. Low temperature weakens the kinetic energy of CH4 molecules, which leads to an increase in their average adsorption energy and significant raise in the desorption energy barrier. Simultaneously, it induces coal matrix contraction (reduced in FFV), leading to a decrease in the effective size of CH4 diffusion pathways and an increase in diffusion resistance.

Key words: low-temperature environment, CH4 adsorption, adsorption promotion and desorption inhibition, fractional free volume(FFV), self-diffusion coefficient, molecular dynamics(MD)

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