Investigation of multiple hydraulic fractures evolution and well performance in lacustrine shale oil reservoirs considering stress heterogeneity

Investigation of multiple hydraulic fractures evolution and well performance in lacustrine shale oil reservoirs considering stress heterogeneity

•Our integrated model helps to design fracturing treatment and optimize well performance.•The fracture propagation model considers the stress heterogeneity.•Fracture length is probably positively correlated with b-value.•Large brittleness index enhances the fracture geometry complexity. Giant Ordos...

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Bibliographic Details
Published in:Engineering fracture mechanics Vol. 218; p. 106569
Main Authors: Tang, Jizhou, Li, Jiawei, Tang, Meirong, Du, Xianfei, Yin, Jun, Guo, Xuyang, Wu, Kan, Xiao, Lizhi
Format: Journal Article
Language:English
Published: New York Elsevier Ltd 01-09-2019
Elsevier BV
Subjects:
Computational fluid dynamics
Computer simulation
Crack propagation
Deposits
Design optimization
Embedded discrete fracture model
Fluid flow
Fracture mechanics
Fracture propagation model
Heterogeneity
Hydraulic fracturing
Hydraulics
Less-developed natural fractures
Oil exploration
Oil field equipment
Oil fields
Oil shale
Physical simulation
Physical simulation experiment
Propagation
Reservoir performance
Sandstone
Shale gas
Shale oil
Stress propagation
Physical simulation experiment
Fracture propagation model
Shale oil
Less-developed natural fractures
Embedded discrete fracture model
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Summary:•Our integrated model helps to design fracturing treatment and optimize well performance.•The fracture propagation model considers the stress heterogeneity.•Fracture length is probably positively correlated with b-value.•Large brittleness index enhances the fracture geometry complexity. Giant Ordos basin, which locating in the northern China, consists of Palaeozoic lacustrine stacked sandstone and shale deposits with characteristics of low-permeability matrix rock and less-developed natural fractures (NFs). Recognizing the successful exploration of shale gas reservoirs in United States, Changqing oilfield uses advanced fracturing technology to create multiple straight hydraulic fractures (HFs) in shale oil zones with large differential horizontal stress. This paper firstly describes a hydraulic fracture propagation model (HFPM) that couples fracture deformation and fluid flow to simulate the growth of multiple HFs in the horizontal wellbore. We then integrated an embedded discrete fracture model (EDFM) and commercial reservoir simulator to analyze well performance based on the provided data from Changqing oilfield. We calibrated the fracture propagation model with reservoir performance data. Shale oil deposits in the Changqing oilfield have a relatively high brittleness index (BI) and large differential horizontal stress. This is the reason why reservoir with less-developed NFs system in the Ordos basin has less opportunity of generating complex fracture networks. Large-scale physical simulation experiments were conducted to validate the possibility of fracture networks generation. Our model considers the stress heterogeneity and offers the capability to address HF propagation in the presence of less-developed NFs and adjusts dimensions and spacing of NFs to achieve a history match with production data. This paper emphasizes the extensive application of an integrated model for lacustrine shale oil deposits. Considering features of Ordos basin, our model can provide a guideline for HF treatment design and optimization of well performance.
ISSN:0013-7944
1873-7315
DOI:10.1016/j.engfracmech.2019.106569