Upscaling of elastic properties for large scale geomechanical simulations

Chalon, Florent; Mainguy, M.; Longuemare, P.; Lemonnier, P.

doi:10.1002/nag.379

Cited by 7 publications

(2 citation statements)

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“…Generally geological materials contain inhomogeneous structures over a wide scale range from the scale of grains and pores to that of reservoirs; the scaling up of permeability and elastic modulus is commonly required in reservoir simulations and rock mechanics. Numerical simulations are widely conducted to obtain the scaled-up elastic stiffness tensors [40,41] and permeability [42]. The scaled-up parameters are expected to be equivalent to the elastic stiffness tensors that include the fine-scale contribution to coarsen the geomechanical mesh.…”

Section: Discussionmentioning

confidence: 99%

Fiber Optic Sensing for Geomechanical Monitoring: (2)- Distributed Strain Measurements at a Pumping Test and Geomechanical Modeling of Deformation of Reservoir Rocks

2019

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In this study distributed fiber optic sensing has been used to measure strain along a vertical well of a depth of 300 m during a pumping test. The observed strain data has been used in geomechanical simulation, in which a combined analytical and numerical approach was applied in providing scaled-up formation properties. The outcomes of the field test have demonstrated the practical use of distributed fiber optic strain sensing for monitoring reservoir formation responses at different regions of sandstone–mudstone alternations along a continuous trajectory. It also demonstrated that sensitive and scaled rock properties, including the equivalent permeability and pore compressibility, can be well constrained by the combined use of water head and distributed strain data. In comparison with the conventional methods, fiber optic strain monitoring enables a lower number of short-term tests to be designed to calibrate the parameters used to model the rock properties. The obtained parameters can be directly used in long-term geomechanical simulation of deformation of reservoir rocks due to fluid injection or production at the CO2 storage and oil and gas fields.

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Section: Discussionmentioning

confidence: 99%

Fiber Optic Sensing for Geomechanical Monitoring: (2)- Distributed Strain Measurements at a Pumping Test and Geomechanical Modeling of Deformation of Reservoir Rocks

2019

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“…To address this issue, one can resort to multi-scale modeling (e.g. Chalon et al 2004;Zhang and Fu 2010).…”

Section: Introductionmentioning

confidence: 99%

A True Poroelastic Up and Downscaling Scheme for Multi-scale Coupled Simulation

Ita

Malekzadeh²

2015

SPE Reservoir Simulation Symposium

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Multi-scale simulation allows an efficient use of computational resources when one to solve problems that have domains with very different spatial scales and can have significantly different discretizations. This is often the case in coupled reservoir flow-geomechanics simulations. Because of the fluid rock interaction, multi-scale simulation in this context requires a consistent upscaling of pore pressure and downscaling of pore volume change.In general, upscaling of the pore pressure will happen over a collection of cells where the change in pressure is not constant. This is to be expected due to diffusive propagation of pressure perturbations in the system. The differences in pressure perturbations will also be enhanced by heterogeneities in porosity or permeability. The impact of heterogeneity in flow properties is also exacerbated when considering variations in the mechanical properties. Clearly any type of upscaling scheme must consider the combination of pressure and mechanical properties at the fine scale to determine their effective properties at the coarse scale. The same is true if you want to downscale pore volume calculated at the coarse scale to the fine scale.Here a solution to this problem is presented which extends the Backus upscaling scheme using the pore pressure -apparent porosity thermodynamic conjugate. A solution is also presented for downscaling the pore volume change from the equivalent anisotropic medium at the coarse scale to the layered, fine scale medium. Validation of this method is given by consideration of a layered Mandel's problem. The behavior of numerical simulations is shown to be in good agreement with the analytical result using the proposed upscaling method.

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