Numerical simulation of complex fracture growth during tight reservoir stimulation by hydraulic fracturing

Numerical simulation of complex fracture growth during tight reservoir stimulation by hydraulic fracturing

The success or failure of hydraulic fracturing technology is largely dependent on the design of fracture configurations and optimization of treatments compatible with the in-situ conditions in a given reservoir. The petroleum industry continues to face challenges with this technology in the field, s...

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Bibliographic Details
Published in:Journal of petroleum science & engineering Vol. 60; no. 2; pp. 86 - 104
Main Authors: Hossain, Md. Mofazzal, Rahman, M.K.
Format: Journal Article
Language:English
Published: Amsterdam Elsevier B.V 01-02-2008
Elsevier Science
Subjects:
Applied sciences
Coupled fluid and structural deformation
Crude oil, natural gas and petroleum products
Crude oil, natural gas, oil shales producing equipements and methods
Energy
Enhanced oil recovery methods
Exact sciences and technology
Fracture orientation
Fuels
Hydraulic fracture stimulation
In-situ stress
Natural and multiple fracture stimulation
Prospecting and production of crude oil, natural gas, oil shales and tar sands
Stress regime
Hydraulic fracture stimulation
Coupled fluid and structural deformation
Natural and multiple fracture stimulation
In-situ stress
Fracture orientation
Stress regime
Deformation
Hydraulics
In situ stress
Modeling
Hydraulic fracturing
Optimization
Petroleum
High pressure
Flow(fluid)
Numerical simulation
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Summary:The success or failure of hydraulic fracturing technology is largely dependent on the design of fracture configurations and optimization of treatments compatible with the in-situ conditions in a given reservoir. The petroleum industry continues to face challenges with this technology in the field, such as premature screen-outs, high treating pressures, complexities with multiple fractures propagation, complex fracture propagation from the deviated wellbore, etc. As these challenges persist better understanding of hydraulic fracture behavior for various reservoir conditions is still an important topic for research. Since the mechanism of hydraulic fracture growth involves the rock stress field and fluid flow field, the modeling work of fracture growth requires the treatment of coupled fluid flow and structural deformation phenomena. In this context, this paper briefly, summarizes an existing numerical tool for fracture growth analysis based on coupled fluid flow and structural deformation phenomena. Solid models have been developed to simulate different field conditions and then solved by using this numerical tool. The field conditions include different stress regimes, fracture geometry and fracture and well orientations. Results for different conditions have been presented and discussed to provide guide lines for better planning and design of hydraulic fracturing. The key finding is that if the well orientation and fracture configuration are not compatible with the in-situ stresses, complex fracture growth diminishes the likelihood of success and exhibits some of the above mentioned symptoms during treatments in the field.
ISSN:0920-4105
1873-4715
DOI:10.1016/j.petrol.2007.05.007