Analysis of Hydraulic Fracture Propagation Using a Mixed Mode and a Uniaxial Strain Model considering Geomechanical Properties in a Naturally Fractured Shale Reservoir

Analysis of Hydraulic Fracture Propagation Using a Mixed Mode and a Uniaxial Strain Model considering Geomechanical Properties in a Naturally Fractured Shale Reservoir

This study proposes a hydraulic fracture propagation model with a mixed mode comprising opening and sliding modes to describe a complex fracture network in a naturally fractured shale gas formation. We combine the fracture propagation model with the mixed mode and the uniaxial strain model with tect...

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Main Authors: Youngho Jang, Gayoung Park, Seoyoon Kwon, Baehyun Min
Format: Article
Language:English
Published: Hindawi-Wiley 2020-01-01
Series:Geofluids
Online Access:http://dx.doi.org/10.1155/2020/6690848
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spelling doaj-4d552bfa29364d429048a1af02357c022021-01-04T00:00:53ZengHindawi-WileyGeofluids1468-81232020-01-01202010.1155/2020/6690848Analysis of Hydraulic Fracture Propagation Using a Mixed Mode and a Uniaxial Strain Model considering Geomechanical Properties in a Naturally Fractured Shale ReservoirYoungho Jang0Gayoung Park1Seoyoon Kwon2Baehyun Min3Center for Climate/Environment Change Prediction ResearchDepartment of Climate and Energy Systems EngineeringDepartment of Climate and Energy Systems EngineeringCenter for Climate/Environment Change Prediction ResearchThis study proposes a hydraulic fracture propagation model with a mixed mode comprising opening and sliding modes to describe a complex fracture network in a naturally fractured shale gas formation. We combine the fracture propagation model with the mixed mode and the uniaxial strain model with tectonic impacts to calculate the stress distribution using geomechanical properties. A discrete fracture network is employed to realize the fracture network composed of natural and hydraulic fractures. We compare the fracture propagation behaviours of three cases representing the Barnett, Marcellus, and Eagle Ford shale gas formations. Sensitivity analysis is performed to investigate the effects of the geomechanical properties of the reservoir on the sliding mode’s contribution to the mixed mode. The numerical results highlight the significance of the mixed mode for the accurate assessment of fracture propagation behaviours in shale gas formations with high brittleness.http://dx.doi.org/10.1155/2020/6690848
collection DOAJ
language English
format Article
sources DOAJ
author Youngho Jang
Gayoung Park
Seoyoon Kwon
Baehyun Min
spellingShingle Youngho Jang
Gayoung Park
Seoyoon Kwon
Baehyun Min
Analysis of Hydraulic Fracture Propagation Using a Mixed Mode and a Uniaxial Strain Model considering Geomechanical Properties in a Naturally Fractured Shale Reservoir
Geofluids
author_facet Youngho Jang
Gayoung Park
Seoyoon Kwon
Baehyun Min
author_sort Youngho Jang
title Analysis of Hydraulic Fracture Propagation Using a Mixed Mode and a Uniaxial Strain Model considering Geomechanical Properties in a Naturally Fractured Shale Reservoir
title_short Analysis of Hydraulic Fracture Propagation Using a Mixed Mode and a Uniaxial Strain Model considering Geomechanical Properties in a Naturally Fractured Shale Reservoir
title_full Analysis of Hydraulic Fracture Propagation Using a Mixed Mode and a Uniaxial Strain Model considering Geomechanical Properties in a Naturally Fractured Shale Reservoir
title_fullStr Analysis of Hydraulic Fracture Propagation Using a Mixed Mode and a Uniaxial Strain Model considering Geomechanical Properties in a Naturally Fractured Shale Reservoir
title_full_unstemmed Analysis of Hydraulic Fracture Propagation Using a Mixed Mode and a Uniaxial Strain Model considering Geomechanical Properties in a Naturally Fractured Shale Reservoir
title_sort analysis of hydraulic fracture propagation using a mixed mode and a uniaxial strain model considering geomechanical properties in a naturally fractured shale reservoir
publisher Hindawi-Wiley
series Geofluids
issn 1468-8123
publishDate 2020-01-01
description This study proposes a hydraulic fracture propagation model with a mixed mode comprising opening and sliding modes to describe a complex fracture network in a naturally fractured shale gas formation. We combine the fracture propagation model with the mixed mode and the uniaxial strain model with tectonic impacts to calculate the stress distribution using geomechanical properties. A discrete fracture network is employed to realize the fracture network composed of natural and hydraulic fractures. We compare the fracture propagation behaviours of three cases representing the Barnett, Marcellus, and Eagle Ford shale gas formations. Sensitivity analysis is performed to investigate the effects of the geomechanical properties of the reservoir on the sliding mode’s contribution to the mixed mode. The numerical results highlight the significance of the mixed mode for the accurate assessment of fracture propagation behaviours in shale gas formations with high brittleness.
url http://dx.doi.org/10.1155/2020/6690848
work_keys_str_mv AT younghojang analysisofhydraulicfracturepropagationusingamixedmodeandauniaxialstrainmodelconsideringgeomechanicalpropertiesinanaturallyfracturedshalereservoir
AT gayoungpark analysisofhydraulicfracturepropagationusingamixedmodeandauniaxialstrainmodelconsideringgeomechanicalpropertiesinanaturallyfracturedshalereservoir
AT seoyoonkwon analysisofhydraulicfracturepropagationusingamixedmodeandauniaxialstrainmodelconsideringgeomechanicalpropertiesinanaturallyfracturedshalereservoir
AT baehyunmin analysisofhydraulicfracturepropagationusingamixedmodeandauniaxialstrainmodelconsideringgeomechanicalpropertiesinanaturallyfracturedshalereservoir
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