Efficient History Matching of Thermally Induced Fractures Using Coupled Geomechanics and Reservoir Simulation

Almarri, Misfer J.

doi:10.3390/en13113001

Cited by 4 publications

(1 citation statement)

References 37 publications

(70 reference statements)

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“…These thermally induced fractures (TIFs) can cause non-uniform distribution of fluid flow in wellbores, reducing the sweep efficiency and initiating the early water breakthrough in the production wells nearby. Almarri [4] uses a 3D reservoir simulator coupled with 2D finite element TIF with geomechanical models to match an injector (NI6) in the N Field sector reservoir model. The author improves the reservoir and the geomechanical models by validating them via the observed TIF onset and propagation periods.…”

Section: Introductionmentioning

confidence: 99%

Mathematical Modeling of Fluid Flow and Heat Transfer in Petroleum Industries and Geothermal Applications 2020

Massoudi

2021

Energies

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In this Special Issue, all aspects of fluid flow and heat transfer in geothermal applications, including the ground heat exchanger, conduction, and convection in porous media, are considered. The emphasis here is on mathematical and computational aspects of fluid flow in conventional and unconventional reservoirs, geothermal engineering, fluid flow and heat transfer in drilling engineering, and enhanced oil recovery (hydraulic fracturing, steam-assisted gravity drainage (SAGD), CO2 injection, etc.) applications.

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Section: Introductionmentioning

confidence: 99%

Mathematical Modeling of Fluid Flow and Heat Transfer in Petroleum Industries and Geothermal Applications 2020

Massoudi

2021

Energies

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Blowout-Capping-Fracturing-Relief Well: A Full Cycle Workflow

Elnoamany,

Michael,

Gupta

et al. 2023

SPE Journal

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Summary Failed well-capping attempts following offshore-well blowouts undergoing worst case discharge (WCD) can lead to fluid-driven tensile failures (de facto hydraulic fracture initiations). Subsequent propagation of these fractures may lead to broaching of overburden-rock-formation layers and even the seafloor, providing pathways for reservoir hydrocarbons to escape into the seawater. After capping stack shut-in, the pressure buildup in the fluid column inside the wellbore exposes vulnerable locations to tensile (Mode I) failure. If this shut-in wellbore pressure exceeds the formation breakdown pressure (FBP) in any of the exposed-rock-formation layers, a fracture will initiate and will continue to propagate as long as sufficient energy is provided by the reservoir. Scenarios where the propagating fracture(s) broached the seafloor in the past led to severe environmental impacts, disturbing the local ecology. The quintessential example is Union Oil’s 1969 “A-21 Well” blowout in California’s Santa Barbara Channel, where subsequent well-capping attempts led to multiple broaching instances on the seafloor near the well with thousands of hydrocarbon gallons gushing into the seawater (observable from the sea surface as “oil boilups”). In this paper, numerical modeling is performed on a hypothetical case study using deepwater Gulf of Mexico parameters in order to evaluate the likelihood of a similar scenario by modeling a planar-fracture propagation longitudinally-to-the-wellbore, upon well capping. A workflow is developed that integrates post-blowout WCD flowrate and volume estimations, fracture initiation and propagation modeling following the capping stack shut-in, pertaining to a “cap-and-contain” strategy (including predictions in regard to seafloor broaching), along with relief-well intersection followed by kill-weight-mud injection. The casing-shoe depth is the presumed location of fracture initiation, assuming perfect integrity of all casedhole sections above it. Several sensitivity analyses are performed to investigate the impact of the casing-shoe depth, along with the stiffness of the overburden-rock-formation layer, and the post-blowout-discharge duration on the resultant fracture growth. Finally, the mud density and pump flowrate necessary to compensate the oil column to successfully kill the blown well are quantitatively assessed.

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Blowout - Capping - Fracturing - Relief Well, A Full Cycle Workflow

Elnoamany¹

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Efficient History Matching of Thermally Induced Fractures Using Coupled Geomechanics and Reservoir Simulation

Cited by 4 publications

References 37 publications

Mathematical Modeling of Fluid Flow and Heat Transfer in Petroleum Industries and Geothermal Applications 2020

Mathematical Modeling of Fluid Flow and Heat Transfer in Petroleum Industries and Geothermal Applications 2020

Blowout-Capping-Fracturing-Relief Well: A Full Cycle Workflow

Blowout - Capping - Fracturing - Relief Well, A Full Cycle Workflow

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