Abstract
We propose three idealized hydraulic fracture geometries (“fracture scenarios”) likely to occur in shale oil reservoirs characterized by high pore pressure and low differential in situ stresses. We integrate these geometries into a commercial reservoir simulator (CMG-IMEX) and examine their effect on reservoir fluids production. Our first, reference fracture scenario includes only vertical, planar hydraulic fractures. The second scenario has stimulated vertical natural fractures oriented perpendicularly to the vertical hydraulic fractures. The third fracture scenario has stimulated horizontal bedding planes intersecting the vertical hydraulic fractures. This last scenario may occur in mudrock plays characterized by high pore pressure and transitional strike-slip to reverse faulting stress regimes. We demonstrate that the vertical and planar fractures are an oversimplification of the hydraulic fracture geometry in anisotropic shale plays. They fail to represent the stimulated volume geometric complexity in the reservoir simulations and may confuse hydrocarbon production forecast. We also show that stimulating mechanically weak bedding planes harms hydrocarbon production, while stimulated natural fractures may enhance initial production. Our findings reveal that stimulated horizontal bedding planes might decrease the cumulative hydrocarbon production by as much as 20%, and the initial hydrocarbon production by about 50% compared with the reference scenario. We present unique reservoir simulations that enable practical assessment of the impact of varied hydraulic fracture configurations on hydrocarbon production and highlight the importance of constraining present-day in situ stress state and pore pressure conditions to obtain a realistic hydrocarbon production forecast.
Highlights
Development of the ultra-low permeability reservoirs, such as oil, condensate and dry gas mudrock (“shale”) plays, has provided additional hydrocarbon resources to meet the world’s growing demand for energy [1]
The unique reservoir simulations discussed here enable us to understand the impact of varied hydraulic fracture and stimulated natural fracture geometries and bedding planes on hydrocarbon production
Horizontal bedding planes, mechanically weak owing to little cohesion, may be stimulated in shale plays in transitional strike-slip to reverse faulting stress regimes, in which Shmin and the overburden (Sv) and Shmin are close in magnitudes and similar to the least principal stress (i.e., Shmin ∼Sv ∼S3 )
Summary
Development of the ultra-low permeability reservoirs, such as oil, condensate and dry gas mudrock (“shale”) plays, has provided additional hydrocarbon resources to meet the world’s growing demand for energy [1]. We investigate three idealized but viable stimulation geometries ( called “fracture scenarios”) that combine hydraulic and pre-existing natural fracture systems as well as mechanically weak horizontal bedding planes reported to exist in shale plays. We examine their effects on wellbore flow performance using a commercial reservoir simulator (CMG-IMEX). The unique reservoir simulations discussed here enable us to understand the impact of varied hydraulic fracture and stimulated natural fracture geometries and bedding planes on hydrocarbon production. Our work emphasizes the influence of constraining present-day in situ stress state (orientation and magnitudes) and pore pressure conditions on hydrocarbon production forecasting
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