Advantages of an Unstructured Unconventional Fractured Media Model Integrated Within a Multiphysics Computational Platform

Ricois, O.; Gratien, Jean-Marc; Bossie-Codreanu, D.; Khvoenkova, Nina; Delorme, Matthieu

doi:10.2523/iptc-18846-ms

Cited by 3 publications

(2 citation statements)

References 47 publications

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“…Due to the large grid blocks used by dual-continuum models, such phenomena cannot be simulated. However, this problem could be accurately solved using the MINC method (see Delorme et al, 2016;Farah et al, 2018;Ricois et al, 2016). Recently, Farah and Delorme (2020) proposed a Unified Fracture Network Model (UFNM) for unconventional reservoirs modeling.…”

Section: Introductionmentioning

confidence: 99%

The MINC proximity function for fractured reservoirs flow modeling with non-uniform block distribution

Farah

Ghadboun

2021

Oil Gas Sci. Technol. – Rev. IFP Energies nouvelles

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Reservoir simulation is a powerful technique to predict the amount of produced hydrocarbon. After a solid representation of the natural fracture geometry, an accurate simulation model and a physical reservoir model that account for different flow regimes should be developed. Many models based on dual-continuum approaches presented in the literature rely on the Pseudo-Steady-State (PSS) assumption to model the inter-porosity flow. Due to the low permeability in such reservoirs, the transient period could reach several years. Thus, the PSS assumption becomes unjustified. The numerical solution adopted by the Multiple INteracting Continua (MINC) method was able to simulate the transient effects previously overlooked by dual-continuum approaches. However, its accuracy drops with increasing fracture network complexity. A special treatment of the MINC method, i.e., the MINC Proximity Function (MINC–PF) was introduced to address the latter problem. And yet, the MINC–PF suffers a limitation that arises from the existence of several grid-blocks within a studied cell. In this work, this limitation is discussed and two possible solutions (transmissibility recalculation/adjusting the Proximity Function by accounting for nearby fractures) are put forward. Both proposed methods have demonstrated their applicability and effectiveness once compared to a reference solution.

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Section: Introductionmentioning

confidence: 99%

The MINC proximity function for fractured reservoirs flow modeling with non-uniform block distribution

Farah

Ghadboun

2021

Oil Gas Sci. Technol. – Rev. IFP Energies nouvelles

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“…Transfers in fractured porous media modeling is still a challenging issue having a broad variety of applications ranging from geothermal energy recovery (Aquilina et al, 1998), petroleum exploration and production (Bourbiaux, 2010), CO 2 geological storage to nuclear waste disposal (Grenier et al, 2005). Fracture networks may be studied using either continuous (Svensson, 2001;Karimi-Fard et al, 2006;Fourno et al, 2007) or Discrete Fracture Networks (DFN) models (Erhel et al, 2009;Hyman et al, 2014;Delorme et al, 2016;Ricois et al, 2016;Berrone et al, 2017). In practice, continuous models may be used when a representative elementary volume (REV) exists, that is small compared with other characteristic sizes of the problem (Long et al, 1982;Neuman, 1988).…”

Section: Introductionmentioning

confidence: 99%

FraC: A new conforming mesh method for discrete fracture networks

Fourno

Ngo

Nœtinger

et al. 2019

Journal of Computational Physics

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The Fracture Cut (FraC) approach to mesh three-dimensional (3D) Discrete Fracture Networks (DFN) is presented. The considered DFNs consist of a network of planar twodimensional (2D) fractures sharing intersections that can in turn intersect themselves, resulting in highly complex meshing issues. The key idea of FraC is to decompose each fracture into a set of connected closed contours, with the original intersection traces located at the boundaries of the contours. Thus, intersection segments can be more easily accounted for when building a conforming mesh. Three distinct strategies for intersection points management are also proposed to enhance the quality of resulting meshes. Steady-state singlephase flow simulations are performed to validate the conform meshes obtained using FraC.The results from flow simulations as well as from a mesh quality analysis on a benchmark case show that a flexible AoM strategy (Adding or Moving intersection points) appears to be the best choice to generate ready-to-run meshes for complex DFN. This approach also allows accounting for tiny features within the fracture networks while keeping a good mesh quality and respecting DFN connectivity. Finally, a scalability of the mesh generator is conducted to assess the performance of the approach.

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Unconventional Production Forecast Needs Integration of Field Hydraulic Stimulation Data Through Fracture Model Calibration and Optimized Numerical Scheme

Delorme

Bossie-Codreanu

Gharbia

et al. 2016

Day 3 Fri, June 03, 2016

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Objectives/Scope Hydraulic fracturing is today a standard when developing unconventional reservoir plays. This is studied through different models, based on a great deal of characterization data gathering and analysis. Unfortunately, numerical limitations impose drastic simplifications (number of fractures, some data being ignored…) leading to simple fracture geometries, lacking observed complexity. This limits any design optimization expectation. Our objective is to show that calibration data used for simpler models, along microseismic measurements, can lead to more realistic hydraulic fracturing geometries. Results can be linked to a reservoir platform, forecasting production. The presented computationally efficient method, within which sensitivity is performed, highlights key parameters governing the stimulation process. This study shows that the tool used is tailored for practical scenario design and evaluation. Methods, Procedures, Process The method used to generate realistic fracture geometries implies information at all scales (seismic, log, cores…) as well as numerical tools able to handle geomechanics and fluid flow, over a great number of fractures (as required by the characterization). Thus all data is input into one 3D Representative Deformable Discrete Fracture Network (DDFN), simulating the hydraulic stimulation. Characterization is based on geostatistical concepts applied to both natural and hydraulically induced fractures, driven by geological and geomechanical data. The process is simulated using a one phase hydrodynamic model within the DDFN (specific discretization) under far stress conditions. Fractures behavior is governed by geomechanical laws, reversible and non-reversible, with an approximate proppant model. Various scenarios are tested according to either geomechanical uncertain parameters, or characterization ones. Observed in-situ Bottom Hole Pressure (BHP) and microseismic characteristics (shape, frequency…) are then history-matched. Results, Observations, Conclusions For each simulated scenario, quality of the history match is shown and discussed, stressing the representativity of the data involved. The method has shown to be computationally efficient and robust enough to support hundred thousands of fractures while at the same time being able to simulate simpler cases. Also, within the studied framework, ties with already existing reservoir platform are shown. Advantages of such an approach are highlighted including current limitations of classical reservoir models. Novel/Additive Information This work undergone at different scales demonstrate the new possibilities of computational robust algorithms, within an approach considering both geological settings and geomechanical properties. The model offers the possibility to integrate several scales to an adaptive discretization scheme.

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Advantages of an Unstructured Unconventional Fractured Media Model Integrated Within a Multiphysics Computational Platform

Cited by 3 publications

References 47 publications

The MINC proximity function for fractured reservoirs flow modeling with non-uniform block distribution

The MINC proximity function for fractured reservoirs flow modeling with non-uniform block distribution

FraC: A new conforming mesh method for discrete fracture networks

Unconventional Production Forecast Needs Integration of Field Hydraulic Stimulation Data Through Fracture Model Calibration and Optimized Numerical Scheme

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