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不同粒度高阶煤的孔隙大小分布特征

Pore Size Distribution Characteristics of High Rank Coal with Various Grain Sizes.

作者信息

Liu Ling-Li, Cui Ze-Hong, Wang Jian-Jun, Xia Zhao-Hui, Duan Li-Jiang, Yang Yong, Li Ming, Li Teng

机构信息

Research Institute of Petroleum Exploration & Development, Beijing 100083, China.

College of Petroleum Engineering, Xi'an Shiyou University, Xi'an 710065, China.

出版信息

ACS Omega. 2020 Jul 27;5(31):19785-19795. doi: 10.1021/acsomega.0c02569. eCollection 2020 Aug 11.

DOI:10.1021/acsomega.0c02569
PMID:32803074
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7424709/
Abstract

Particle void filling effects ( ) under low pressure and coal matrix compressibility effects ( ) at high pressure should not be ignored when using mercury intrusion porosimetry (MIP) to study the pore size distribution of coal. In this study, two coal samples (FX and HF) collected from western Guizhou were crushed into three different grain sizes; then, the subsamples were analyzed by MIP and low-pressure nitrogen adsorption to study the pore size distribution characteristics. The micro- and transition pore volumes contribute to the total pore volume of the FX and HF subsamples. With decreasing subsample grain sizes, the macropore volume of FX subsamples tends to increase, while mesopore volume decreases; the volumes of micropores and transition pores first increase and then decrease. In regard to the HF subsamples, the volumes of macropores and mesopores do not reveal any distinctive changes, while the 40-60 mesh subsample contains the greatest volume of micropores and transition pores. Fractal theory was introduced to determine and . barely changed as grain size decreased; it ranged from 0.1 to 0.15 MPa. However, increased with reduced coal grain sizes. The coal matrix compressibility coefficients of the subsamples were calculated from the cumulative mercury volume curve, and the true pore volume was also modified. The modified volume of macropores does not change markedly, while the volumes of mesopores and transition pores decrease significantly, clearly indicating the coal matrix compressibility under high mercury injection pressure. The modified pore volume shows that the pore (<10,000 nm) still harbors fractal characteristics.

摘要

在使用压汞法(MIP)研究煤的孔径分布时,低压下的颗粒孔隙填充效应( )和高压下的煤基质压缩性效应( )不容忽视。在本研究中,将从贵州西部采集的两个煤样(FX和HF)粉碎成三种不同粒度;然后,通过MIP和低压氮吸附对各子样进行分析,以研究孔径分布特征。微孔和过渡孔体积对FX和HF子样的总孔体积有贡献。随着子样粒度减小,FX子样的大孔体积趋于增加,而中孔体积减小;微孔和过渡孔体积先增加后减小。对于HF子样,大孔和中孔体积没有明显变化,而40-60目子样的微孔和过渡孔体积最大。引入分形理论来确定 和 。 随粒度减小变化不大;范围为0.1至0.15MPa。然而, 随着煤粒度减小而增加。根据累积汞体积曲线计算子样的煤基质压缩系数,并对真实孔体积进行修正。修正后的大孔体积变化不明显,而中孔和过渡孔体积显著减小,清楚地表明了高注汞压力下的煤基质压缩性。修正后的孔体积表明,孔径小于10000nm的孔隙仍具有分形特征。

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本文引用的文献

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Mercury Porosimetry: Contact Angle Hysteresis of Materials with Controlled Pore Structure.压汞法:具有可控孔隙结构材料的接触角滞后现象
J Colloid Interface Sci. 2001 Jul 1;239(1):178-189. doi: 10.1006/jcis.2001.7531.