In situ Stress–Coal Structure Relationship and Its Influence on Hydraulic Fracturing: A Case Study in Zhengzhuang Area in Qinshui Basin, China

In situ stress (comprised of minimum horizontal principal stress ( σ h ), maximum horizontal principal stress ( σ H ) and vertical principal stress ( σ v )) and coal structure are the key control factors of hydraulic fracturing. In this work, 80 coalbed methane wells data were selected to explore th...

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Bibliographic Details
Published in:Natural resources research (New York, N.Y.) N.Y.), 2022-06, Vol.31 (3), p.1621-1646
Main Authors: Ren, Pengfei, Wang, Qiong, Tang, Dazhen, Xu, Hao, Chen, Shida
Format: Article
Language:English
Subjects:
Anisotropy
Area
Chemistry and Earth Sciences
Coal
Coalbed methane
Computer Science
Data logging
Earth and Environmental Science
Earth Sciences
Fossil Fuels (incl. Carbon Capture)
Geography
Granulation
Height
Hydraulic fracturing
Identification methods
Mathematical Modeling and Industrial Mathematics
Mineral Resources
Original Paper
Physics
Principal components analysis
Statistics for Engineering
Stress
Stress distribution
Sustainable Development
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Summary:In situ stress (comprised of minimum horizontal principal stress ( σ h ), maximum horizontal principal stress ( σ H ) and vertical principal stress ( σ v )) and coal structure are the key control factors of hydraulic fracturing. In this work, 80 coalbed methane wells data were selected to explore the in situ stress–coal structure relationship and its influence on hydraulic fracturing. The results showed that the coal structure identification method based on principal components analysis is an effective tool in simplifying logging data and improving the recognition accuracy. Fracturing pressure ( P f ) and σ H are correlated positively with the content of undeformed coal, correlated negatively with the content of cataclastic coal and have a weaker relationship with the content of granulated coal. The coal seams in the southwest of the study area, which belong to I stress field (i.e., low vertical stress anisotropy ( VSAI ) and high horizontal stress anisotropy ( HSAI )) are composed mainly of undeformed coal, and easily form planar fractures with long major fracture length and shorter major fracture height. The coal seams in the northwest–southeast study area, which belongs to II stress field (high VSAI and low HSAI ), are composed mainly of cataclastic coal, and easily form complex plane fractures with second minister major fracture length and long major fracture height. The coal seams in the northeast study area, which belongs to III stress field (low VSAI and high HSAI ), are composed mainly of granulated coal, and easily form complex fractures with shorter major fracture length and shorter major fracture height.
ISSN:1520-7439
1573-8981
DOI:10.1007/s11053-022-10036-9