Analysis of gas migration patterns in fractured coal rocks under actual mining conditions

Analysis of gas migration patterns in fractured coal rocks under actual mining conditions

Fracture fields in coal rocks are the main channels for gas seepage, migration, and extraction. The development, evolution, and spatial distribution of fractures in coal rocks directly affect the permeability of the coal rock as well as gas migration and flow. In this work, the Ji-15-141...

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Main Authors: Gao Mingzhong, Ai Ting, Qiu Zhiqiang, Zhang Zetian, Xie Jing
Format: Article
Language:English
Published: VINCA Institute of Nuclear Sciences 2017-01-01
Series:Thermal Science
Subjects:
gas-flow
field test
fracture network
evolution characteristics
Online Access:http://www.doiserbia.nb.rs/img/doi/0354-9836/2017/0354-983617275G .pdf
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spelling doaj-3ed1581e922e4b15b4c3378b8b424af72021-01-02T02:19:44ZengVINCA Institute of Nuclear SciencesThermal Science0354-98362334-71632017-01-0121suppl. 127528410.2298/TSCI17S1275G0354-983617275GAnalysis of gas migration patterns in fractured coal rocks under actual mining conditionsGao Mingzhong0Ai Ting1Qiu Zhiqiang2Zhang Zetian3Xie Jing4Sichuan University, State Key Laboratory of Hydraulics and Mountain River Engineering, Chengdu, China + Sichuan University, College of Water Resources and Hydropower, Chengdu, ChinaSichuan University, College of Architecture and Environment, Chengdu, ChinaSichuan University, State Key Laboratory of Hydraulics and Mountain River Engineering, Chengdu, China + Sichuan University, College of Water Resources and Hydropower, Chengdu, ChinaSichuan University, State Key Laboratory of Hydraulics and Mountain River Engineering, Chengdu, China + Sichuan University, College of Water Resources and Hydropower, Chengdu, ChinaSichuan University, State Key Laboratory of Hydraulics and Mountain River Engineering, Chengdu, China + Sichuan University, College of Water Resources and Hydropower, Chengdu, ChinaFracture fields in coal rocks are the main channels for gas seepage, migration, and extraction. The development, evolution, and spatial distribution of fractures in coal rocks directly affect the permeability of the coal rock as well as gas migration and flow. In this work, the Ji-15-14120 mining face at the No. 8 Coal Mine of Pingdingshan Tian’an Coal Mining Co. Ltd., Pingdingshan, China, was selected as the test site to develop a full-parameter fracture observation instrument and a dynamic fracture observation technique. The acquired video information of fractures in the walls of the boreholes was vectorized and converted to planarly expanded images on a computer-aided design platform. Based on the relative spatial distances between the openings of the boreholes, simultaneous planar images of isolated fractures in the walls of the boreholes along the mining direction were obtained from the boreholes located at various distances from the mining face. Using this information, a 3-D fracture network under mining conditions was established. The gas migration pattern was calculated using a COMSOL computation platform. The results showed that between 10 hours and 1 day the fracture network controlled the gas-flow, rather than the coal seam itself. After one day, the migration of gas was completely controlled by the fractures. The presence of fractures in the overlying rock enables the gas in coal seam to migrate more easily to the surrounding rocks or extraction tunnels situated relatively far away from the coal rock. These conclusions provide an important theoretical basis for gas extraction.http://www.doiserbia.nb.rs/img/doi/0354-9836/2017/0354-983617275G .pdfgas-flowfield testfracture networkevolution characteristics
collection DOAJ
language English
format Article
sources DOAJ
author Gao Mingzhong
Ai Ting
Qiu Zhiqiang
Zhang Zetian
Xie Jing
spellingShingle Gao Mingzhong
Ai Ting
Qiu Zhiqiang
Zhang Zetian
Xie Jing
Analysis of gas migration patterns in fractured coal rocks under actual mining conditions
Thermal Science
gas-flow
field test
fracture network
evolution characteristics
author_facet Gao Mingzhong
Ai Ting
Qiu Zhiqiang
Zhang Zetian
Xie Jing
author_sort Gao Mingzhong
title Analysis of gas migration patterns in fractured coal rocks under actual mining conditions
title_short Analysis of gas migration patterns in fractured coal rocks under actual mining conditions
title_full Analysis of gas migration patterns in fractured coal rocks under actual mining conditions
title_fullStr Analysis of gas migration patterns in fractured coal rocks under actual mining conditions
title_full_unstemmed Analysis of gas migration patterns in fractured coal rocks under actual mining conditions
title_sort analysis of gas migration patterns in fractured coal rocks under actual mining conditions
publisher VINCA Institute of Nuclear Sciences
series Thermal Science
issn 0354-9836
2334-7163
publishDate 2017-01-01
description Fracture fields in coal rocks are the main channels for gas seepage, migration, and extraction. The development, evolution, and spatial distribution of fractures in coal rocks directly affect the permeability of the coal rock as well as gas migration and flow. In this work, the Ji-15-14120 mining face at the No. 8 Coal Mine of Pingdingshan Tian’an Coal Mining Co. Ltd., Pingdingshan, China, was selected as the test site to develop a full-parameter fracture observation instrument and a dynamic fracture observation technique. The acquired video information of fractures in the walls of the boreholes was vectorized and converted to planarly expanded images on a computer-aided design platform. Based on the relative spatial distances between the openings of the boreholes, simultaneous planar images of isolated fractures in the walls of the boreholes along the mining direction were obtained from the boreholes located at various distances from the mining face. Using this information, a 3-D fracture network under mining conditions was established. The gas migration pattern was calculated using a COMSOL computation platform. The results showed that between 10 hours and 1 day the fracture network controlled the gas-flow, rather than the coal seam itself. After one day, the migration of gas was completely controlled by the fractures. The presence of fractures in the overlying rock enables the gas in coal seam to migrate more easily to the surrounding rocks or extraction tunnels situated relatively far away from the coal rock. These conclusions provide an important theoretical basis for gas extraction.
topic gas-flow
field test
fracture network
evolution characteristics
url http://www.doiserbia.nb.rs/img/doi/0354-9836/2017/0354-983617275G .pdf
work_keys_str_mv AT gaomingzhong analysisofgasmigrationpatternsinfracturedcoalrocksunderactualminingconditions
AT aiting analysisofgasmigrationpatternsinfracturedcoalrocksunderactualminingconditions
AT qiuzhiqiang analysisofgasmigrationpatternsinfracturedcoalrocksunderactualminingconditions
AT zhangzetian analysisofgasmigrationpatternsinfracturedcoalrocksunderactualminingconditions
AT xiejing analysisofgasmigrationpatternsinfracturedcoalrocksunderactualminingconditions
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