Numerical Simulation of Fracture Propagation Characteristics of Hydraulic Fracturing in Multiple Coal Seams, Eastern Yunnan, China

Kaifeng Wang; Kaifeng Wang; Kaifeng Wang; Shuheng Tang; Shuheng Tang; Shuheng Tang; Songhang Zhang; Songhang Zhang; Songhang Zhang; Yingying Guo; Yingying Guo; Yingying Guo; Donglin Lin; Donglin Lin; Donglin Lin; Zhichao Niu; Zhichao Niu; Zhichao Niu

doi:10.3389/feart.2022.854638

Frontiers in Earth Science (Feb 2022)

Numerical Simulation of Fracture Propagation Characteristics of Hydraulic Fracturing in Multiple Coal Seams, Eastern Yunnan, China

Kaifeng Wang,
Kaifeng Wang,
Kaifeng Wang,
Shuheng Tang,
Shuheng Tang,
Shuheng Tang,
Songhang Zhang,
Songhang Zhang,
Songhang Zhang,
Yingying Guo,
Yingying Guo,
Yingying Guo,
Donglin Lin,
Donglin Lin,
Donglin Lin,
Zhichao Niu,
Zhichao Niu,
Zhichao Niu

Affiliations

Kaifeng Wang: School of Energy Resources, China University of Geosciences (Beijing), Beijing, China
Kaifeng Wang: Coal Reservoir Laboratory of National Engineering Research Center of CBM Development & Utilization, Beijing, China
Kaifeng Wang: Beijing Key Laboratory of Unconventional Natural Gas Geological Evaluation and Development Engineering, Beijing, China
Shuheng Tang: School of Energy Resources, China University of Geosciences (Beijing), Beijing, China
Shuheng Tang: Coal Reservoir Laboratory of National Engineering Research Center of CBM Development & Utilization, Beijing, China
Shuheng Tang: Beijing Key Laboratory of Unconventional Natural Gas Geological Evaluation and Development Engineering, Beijing, China
Songhang Zhang: School of Energy Resources, China University of Geosciences (Beijing), Beijing, China
Songhang Zhang: Coal Reservoir Laboratory of National Engineering Research Center of CBM Development & Utilization, Beijing, China
Songhang Zhang: Beijing Key Laboratory of Unconventional Natural Gas Geological Evaluation and Development Engineering, Beijing, China
Yingying Guo: School of Energy Resources, China University of Geosciences (Beijing), Beijing, China
Yingying Guo: Coal Reservoir Laboratory of National Engineering Research Center of CBM Development & Utilization, Beijing, China
Yingying Guo: Beijing Key Laboratory of Unconventional Natural Gas Geological Evaluation and Development Engineering, Beijing, China
Donglin Lin: School of Energy Resources, China University of Geosciences (Beijing), Beijing, China
Donglin Lin: Coal Reservoir Laboratory of National Engineering Research Center of CBM Development & Utilization, Beijing, China
Donglin Lin: Beijing Key Laboratory of Unconventional Natural Gas Geological Evaluation and Development Engineering, Beijing, China
Zhichao Niu: School of Energy Resources, China University of Geosciences (Beijing), Beijing, China
Zhichao Niu: Coal Reservoir Laboratory of National Engineering Research Center of CBM Development & Utilization, Beijing, China
Zhichao Niu: Beijing Key Laboratory of Unconventional Natural Gas Geological Evaluation and Development Engineering, Beijing, China

DOI: https://doi.org/10.3389/feart.2022.854638
Journal volume & issue: Vol. 10

Abstract

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As a reservoir reconstruction technology, hydraulic fracturing is a key method to improve the production of coalbed methane (CBM) wells. The CBM reservoir in eastern Yunnan, an important CBM exploration and development zone in China, is characterized by multiple thin coal seams. Compared to the fracturing of the single-layer coal seam, the combined seam fracturing technology is more difficult and complex. To study the fracture propagation characteristics and influencing factors of hydraulic fracturing in multiple coal seams, taking No. 9 and No. 13 coal seams as the research objects, the fracturing process was numerically simulated by using the finite element method and ANSYS software in this work. Based on the mathematical model of low permeable coal-rock mass, a two-dimensional hydraulic fracture model was established. In addition, the fracture geometries of combined seam fracturing were studied quantitatively. The results indicate that although No. 9 coal and No. 13 coal seams have similar rock mechanical properties, the propagation process and final geometry of a fracture are different. The reliability of the simulation results is verified by the comparison of experimental parameters and field investigation. The results prove the feasibility of combined seam fracturing in eastern Yunnan. The high Young’s modulus and thickness of the coal seam make the fracture geometry longer, but the fracture height is smaller. The low Young’s modulus, high Poisson’s ratio, and thickness of the No. 13 coal seam result in an increase in the length and height of the No. 9 coal seam. The increase in Young’s modulus of interlayer inhibits the propagation of fractures, while the high thickness and low Poisson’s ratio of interlayers facilitate the extension of the length and inhibit the extension of the height. This work provides a case reference for combined seam fracturing of coal reservoirs and has practical significance for the development of CBM characterized by multiple coal seams in eastern Yunnan.

Published in Frontiers in Earth Science

ISSN: 2296-6463 (Online)
Publisher: Frontiers Media S.A.
Country of publisher: Switzerland
LCC subjects: Science
Website: https://www.frontiersin.org/journals/earth-science

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