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高阶煤吸附孔结构特征及其对甲烷吸附能力的影响

张黎明 林健云 司磊磊 赵琼祥 王沉 武国鹏

张黎明,林健云,司磊磊,等. 高阶煤吸附孔结构特征及其对甲烷吸附能力的影响[J]. 工矿自动化,2024,50(7):147-155.  doi: 10.13272/j.issn.1671-251x.2024040083
引用本文: 张黎明,林健云,司磊磊,等. 高阶煤吸附孔结构特征及其对甲烷吸附能力的影响[J]. 工矿自动化,2024,50(7):147-155.  doi: 10.13272/j.issn.1671-251x.2024040083
ZHANG Liming, LIN Jianyun, SI Leilei, et al. Features of adsorption pore structure in high-rank coal and its influence on methane adsorption capability[J]. Journal of Mine Automation,2024,50(7):147-155.  doi: 10.13272/j.issn.1671-251x.2024040083
Citation: ZHANG Liming, LIN Jianyun, SI Leilei, et al. Features of adsorption pore structure in high-rank coal and its influence on methane adsorption capability[J]. Journal of Mine Automation,2024,50(7):147-155.  doi: 10.13272/j.issn.1671-251x.2024040083

高阶煤吸附孔结构特征及其对甲烷吸附能力的影响

doi: 10.13272/j.issn.1671-251x.2024040083
基金项目: 贵州省科技支撑计划项目(黔科合支撑〔2023〕一般482);国家自然科学基金资助项目(52364010,52174072)。
详细信息
    作者简介:

    张黎明(1990—),女,四川巴中人,实验师,硕士,主要研究方向为煤矿瓦斯灾害防治,E-mail:lmzhang1@gzu.edu.cn

  • 中图分类号: TD712

Features of adsorption pore structure in high-rank coal and its influence on methane adsorption capability

  • 摘要: 孔隙结构对煤层吸附甲烷的能力有显著影响,但目前对高阶煤吸附孔结构特征及其对甲烷吸附能力的影响研究较少。以贵州兴安煤业有限公司糯东煤矿高阶煤样为研究对象,采用低温N2吸附和低温CO2吸附试验,结合分形理论研究了高阶煤吸附孔的孔隙结构特征,并通过高压等温甲烷吸附试验,分析了煤储层物性、孔隙结构特征和分形维数对甲烷吸附能力的影响。结果表明:① 高阶煤储层孔隙形态较为单一,多数为两端开放的平行板孔和狭缝型孔,微孔在煤的孔隙结构中占主导地位,其孔体积和孔比表面积占比均大于98%,为气体的富集提供了空间。② 以不同孔径段的孔体积占比为权重计算高阶煤孔隙的综合分形维数,微孔分形维数在综合分形维数中占主导地位;煤样孔隙结构具有明显的分形特征,孔隙非均质性较强。③ Langmuir模型能很好地描述高阶煤的吸附行为,煤储层物性、孔隙结构和分形维数对甲烷吸附能力影响显著,Langmuir体积与最大镜质体反射率、镜质组含量、灰分含量和水分含量呈线性正相关关系,与惰质组含量呈线性负相关关系;Langmuir体积与吸附孔的孔比表面积和孔体积均呈线性正相关关系,Langmuir体积与分形维数呈弱线性关系。研究结果可为黔西南地区高阶煤层气勘探开发及煤矿瓦斯灾害防治提供理论指导。

     

  • 图  1  低温N2吸附/解吸等温线

    Figure  1.  Low temperature N2 adsorption/desorption isotherm

    图  2  不同煤样的低温CO2吸附试验结果及孔径分布特征

    Figure  2.  Low temperature CO2 adsorption experiment results and pore size distribution features of different coal samples

    图  3  FHH模型分形拟合

    Figure  3.  Fractal fitting of frenkel halsey hill(FHH) model

    图  4  V−S模型分形拟合

    Figure  4.  Fractal fitting of V-S model

    图  5  分形维数与最大镜质体反射率、显微组分的关系

    Figure  5.  Relationship between fractal dimension and the maximum vitrinite reflectance or maceral

    图  6  甲烷吸附等温线

    Figure  6.  Methane adsorption isotherm

    图  7  甲烷吸附性能与煤储层物性的关系

    Figure  7.  Relationship between methane adsorption performance and physical properties of coal reservoirs

    图  8  甲烷吸附性能与吸附孔结构特征的关系

    Figure  8.  Relationship between methane adsorption performance and pore structure features

    图  9  甲烷吸附性能与分形维数的关系

    Figure  9.  Relationship between methane adsorption performance and fractal dimension

    表  1  煤样基础参数

    Table  1.   Basic parameters of coal samples

    煤样Ro,max/%镜质组/%惰质组/%壳质组/%水分/%灰分/%挥发分/%固定碳/%煤类
    糯东1号2.5787.0012.800.200.6414.748.3077.60无烟煤
    糯东2号2.6893.006.800.200.8828.8311.8161.99贫煤
    糯东3号2.6289.0010.700.300.5814.378.5477.79无烟煤
    下载: 导出CSV

    表  2  低温N2吸附试验煤样孔比表面积分布特征

    Table  2.   Distribution features of pore specific surface area of coal samples for low temperature N2 adsorption experiment

    煤样 平均孔径/nm BET孔比表面积/(m2·g−1 孔比表面积/(m2·g−1 孔比表面积占比/%
    <10 nm 10~100 nm >100 nm <10 nm 10~100 nm >100 nm
    糯东1号 7.949 1.293 1.145 0.147 0.001 88.55 11.37 0.08
    糯东2号 6.057 1.695 1.575 0.118 0.002 92.92 6.96 0.12
    糯东3号 9.700 0.534 0.450 0.083 0.001 84.27 15.54 0.19
    下载: 导出CSV

    表  3  低温N2吸附试验煤样孔体积分布特征

    Table  3.   Distribution features of pore volume of coal samples for low temperature N2 adsorption experiment

    煤样 BJH孔体积/(10−3 cm3·g−1 孔体积/(10−3 cm3·g−1 孔体积占比/%
    <10 nm 10~100 nm >100 nm <10 nm 10~100 nm >100 nm
    糯东1号 2.373 1.208 1.132 0.033 50.91 47.70 1.39
    糯东2号 2.232 1.320 0.850 0.062 59.14 38.08 2.78
    糯东3号 1.245 0.452 0.768 0.025 36.31 61.68 2.01
    下载: 导出CSV

    表  4  低温CO2吸附试验煤样孔隙结构参数

    Table  4.   Pore structure parameters of coal samples for low temperature CO2 adsorption experiment

    煤样 孔比表面积/
    (m2·g−1
    孔体积/
    (10−3 cm3·g−1
    峰值点
    孔径/nm
    糯东1号 190.520 61.900 0.524
    糯东2号 146.755 51.415 0.548
    糯东3号 146.943 48.145 0.599
    下载: 导出CSV

    表  5  不同煤样吸附孔的孔隙结构参数

    Table  5.   Pore structure parameters of adsorption pores of different coal samples

    煤样 孔体积/(10−3 cm3·g−1 总孔体积/
    (10−3 cm3·g−1
    孔比表面积/(m2·g−1 总孔比表面积/
    (m2·g−1
    0.3~1.5 nm 1.5~10 nm 10~100 nm 0.3~1.5 nm 1.5~10 nm 10~100 nm
    糯东1号 61.900 1.208 1.132 64.240 190.520 1.145 0.147 191.812
    糯东2号 51.415 1.320 0.850 53.585 146.755 1.575 0.118 148.448
    糯东3号 48.145 0.452 0.768 49.365 146.943 0.450 0.083 147.476
    下载: 导出CSV

    表  6  不同煤样的分形维数

    Table  6.   Fractal dimension of different coal samples

    煤样 10~100 nm孔径段(低温N2吸附) 1.5~10 nm孔径段(低温N2吸附) 0.3~1.5 nm孔径段(低温CO2吸附) 综合分形维数Dz
    D1 R2 D2 R2 D3 R2
    糯东1号 2.489 0.825 2.651 0.995 2.453 0.998 2.457
    糯东2号 2.562 0.876 2.758 0.987 2.476 0.999 2.483
    糯东3号 2.647 0.676 2.506 0.996 2.492 0.999 2.494
    下载: 导出CSV

    表  7  甲烷吸附拟合结果

    Table  7.   Fitting results of methane adsorption

    煤样Ro,amx/%VL/(cm3·g−1PL/MPaR2
    糯东1号2.5725.5341.7030.995
    糯东2号2.6832.5901.3710.994
    糯东3号2.6228.3141.1980.996
    下载: 导出CSV
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  • 收稿日期:  2024-04-24
  • 修回日期:  2024-07-23
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