鄂尔多斯盆地低阶煤孔隙空间拓扑结构定量表征

doi:10.11799/ce202103026

煤炭工程 ›› 2021, Vol. 53 ›› Issue (3): 129-134.doi: 10.11799/ce202103026

鄂尔多斯盆地低阶煤孔隙空间拓扑结构定量表征

车禹恒

中煤科工集团重庆研究院有限公司

收稿日期:2020-08-24 修回日期:2020-10-05 出版日期:2021-03-20 发布日期:2021-05-10
通讯作者: 车禹恒 E-mail:1129945343@qq.com

Quantitative Characterization of Spatial Topology by Pore Network Model of Low-rank Coal

Received:2020-08-24 Revised:2020-10-05 Online:2021-03-20 Published:2021-05-10

摘要/Abstract

摘要： 通过X-ray μCT三维重构的煤微观孔隙结构极其复杂，等效孔隙网络模型能从拓扑学的角度简化其空间网络结构。为了使用该方法定量表征煤微观孔隙空间结构，对鄂尔多斯盆地低阶煤进行X-ray μCT扫描，重建煤孔隙微观空间结构模型，构建PNM空间拓扑结构，分析其孔隙和喉道的结构特征。结果表明：羊场湾褐煤内部发育有体积较大的微裂隙，斜沟气煤内部微裂隙较少，但孔隙数量多、体积大、均质性高。羊场湾褐煤体积大于0.25μm的孔隙占23%，半径0.1～0.7μm的孔隙占比超过90%，配位数均值7，喉道等效半径和长度均值分别为0.13μm和1.69μm。而斜沟气煤孔隙体积主要分布在0～0.06μm，等效半径主要分布在0.11～0.26μm，配位数均值4，喉道等效半径和长度均值分别为0.09μm和0.63μm。羊场湾褐煤孔隙体积更大，连通性更强，且喉道更宽、更长，是其渗透性能强的本质原因。

关键词: 低阶煤, 煤微观孔隙, 等效孔隙网络模型, 拓扑结构

Abstract: The microscopic pore structure of coal reconstructed by X-ray μCT is extremely complex. The pore network model (PNM) can simplify its spatial network structure from topology. In order to quantitatively characterize the space structure of coal micro-pore by this method, X-ray μCT scanning was performed on low-rank coal in the Ordos Basin. The spatial structure model of coal micro-pores was reconstructed. The PNM spatial topology structure was constructed. The structural characteristics of its pores and throats were analyzed. The results show that: larger micro-cracks are developed inside lignite. There are few micro-cracks in gas coal, but there are many pores, large volume and high homogeneity. Pores with a volume greater than 0.25μm3 in YCW lignite account for 23%, and pores with a radius of 0.1~0.7μm account for more than 90%. Its average coordination number is 7, and the average equivalent radius and length of the throat are 0.13μm and 1.69μm, respectively. However, the pore volume of XG gas coal is mainly distributed in 0~0.06μm3, and the equivalent radius is mainly distributed in 0.11~0.26μm. Its average coordination number is 4, and the average equivalent radius and length of the throat are 0.09μm and 0.63μm, respectively. Pores in lignite has larger volume and stronger connectivity. Its throats are wider and longer. This is the essential reason for its strong permeability.

车禹恒. 鄂尔多斯盆地低阶煤孔隙空间拓扑结构定量表征[J]. 煤炭工程, 2021, 53(3): 129-134.

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鄂尔多斯盆地低阶煤孔隙空间拓扑结构定量表征

Quantitative Characterization of Spatial Topology by Pore Network Model of Low-rank Coal

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