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Full-scale pore structure characterization of different rank coals and its impact on gas adsorption capacity: A theoretical model and experimental study

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  • Li, Zhongbei
  • Ren, Ting
  • Li, Xiangchun
  • Cheng, Yuanping
  • He, Xueqiu
  • Lin, Jia
  • Qiao, Ming
  • Yang, Xiaohan

Abstract

Microscopic pores significantly impact the coalbed methane (CBM) storage, hence gas energy recovery and gas-related problems mitigation. However, the quantitative relationship between microscopic pore properties and CBM storage dictated by gas adsorption capacity remains unclear. In this study, high-pressure isothermal gas adsorption experiments were conducted using differently ranked coal samples to investigate gas adsorption characteristics. High-pressure mercury injection (HPMI), low-pressure nitrogen adsorption (LPGA-N2), low-pressure carbon dioxide adsorption (LPGA-CO2) and scanning electron microscopy (SEM) tests were employed for full-scale microscopic pore structure characterization. Considering potential energy induced by CH4 molecules and microscopic pore wall interaction, an improved method was proposed to quantitatively characterize gas adsorption capacity and obtain CH4 occurrence characteristics for different-scale pores. The results show that microscopic properties of differently ranked coal samples vary remarkably with evident heterogeneity. The micropore specific surface area (SSA) is 79.396–232.253 m2/g, accounting for 90.03%–99.45% of the total specific surface area (TSSA). The adsorption capacities of differently ranked coal samples present significant differences and range between 13.38 and 20.08 cc/g, and shows an asymmetric U-shaped trend as coal metamorphism deepens. Based on microscopic pore properties, the Langmuir volume theoretically calculated using the new method ranges between 12.29 and 20.85 cc/g. The calculated results agree well with experimental results with a relative error of less than 10%, proving that this theoretical model can predict gas adsorption capacity with sufficient confidence.

Suggested Citation

  • Li, Zhongbei & Ren, Ting & Li, Xiangchun & Cheng, Yuanping & He, Xueqiu & Lin, Jia & Qiao, Ming & Yang, Xiaohan, 2023. "Full-scale pore structure characterization of different rank coals and its impact on gas adsorption capacity: A theoretical model and experimental study," Energy, Elsevier, vol. 277(C).
    • Handle: RePEc:eee:energy:v:277:y:2023:i:c:s0360544223010150
    DOI: 10.1016/j.energy.2023.127621
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    References listed on IDEAS

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    1. Liu, Ting & Lin, Baiquan & Fu, Xuehai & Gao, Yabin & Kong, Jia & Zhao, Yang & Song, Haoran, 2020. "Experimental study on gas diffusion dynamics in fractured coal: A better understanding of gas migration in in-situ coal seam," Energy, Elsevier, vol. 195(C).
    2. Chen, Kang & Liu, Xianfeng & Nie, Baisheng & Zhang, Chengpeng & Song, Dazhao & Wang, Longkang & Yang, Tao, 2022. "Mineral dissolution and pore alteration of coal induced by interactions with supercritical CO2," Energy, Elsevier, vol. 248(C).
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    Cited by:

    1. Zang, Jie & Liu, Jialong & He, Jiabei & Zhang, Xiapeng, 2023. "Characterization of the pore structure in Chinese anthracite coal using FIB-SEM tomography and deep learning-based segmentation," Energy, Elsevier, vol. 282(C).
    2. Ji, Bingnan & Pan, Hongyu & Pang, Mingkun & Pan, Mingyue & Zhang, Hang & Zhang, Tianjun, 2023. "Molecular simulation of CH4 adsorption characteristics in bituminous coal after different functional group fractures," Energy, Elsevier, vol. 282(C).
    3. He, Jun & Wang, Bohao & Lu, Zhongliang, 2023. "Experimental study on the effect of magma intrusion and temperature on the pore structure of coal," Energy, Elsevier, vol. 284(C).

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