International Workshop on Computational Flow and Transport: Modeling, Simulations and Algorithms (CFT) Session 2

Time and Date: 14:30 - 16:10 on 6th June 2016

Room: Boardroom West

Chair: Shuyu Sun

292 A two-scale reduced model for Darcy flow in fractured porous media [abstract]
Abstract: In this paper, we develop a two-scale reduced model for simulating the Darcy flow in two-dimensional porous media with conductive fractures. We apply the approach motivated by the embedded fracture model (EFM) to simulate the flow on the coarse scale, and the effect of fractures on each coarse scale grid cell intersecting with fractures is represented by the discrete fracture model (DFM) on the fine scale. In the DFM used on the fine scale, the matrix-fracture system are resolved on unstructured grid which represents the fractures accurately, while in the EFM used on the coarse scale, the flux interaction between fractures and matrix are dealt with as a source term, and the matrix-fracture system can be resolved on structured grid. The Raviart-Thomas mixed finite element methods are used for the solution of the coupled flows in the matrix and the fractures on both fine and coarse scales. Numerical results are presented to demonstrate the efficiency of the proposed model for simulation of flow in fractured porous media.
Huangxin Chen, Shuyu Sun
352 Staggered/Collocated POD-ROM for Unsteady Navier-Stokes Flow [abstract]
Abstract: Reduced-order model by proper orthogonal decomposition of Navier-Stokes equation can be established in different manners. After careful screening under different sampling intervals and numbers of basis vectors, it has been found that the model can achieve high precision only when it is constructed on collocated grid with the samples still on the staggered grid. The model straight-forward established on the staggered grid may lose accuracy apparently. To precisely capture the dynamic behavior of flow field, the sampling interval should be small enough while the number of basis vectors should be moderate. These conclusions can be a valuable principle for future modeling of the dynamics of fluid flow.
Yi Wang, Tingyu Li
373 An Iterative Implicit Scheme for Nanoparticles Transport with Two-Phase Flow in Porous Media [abstract]
Abstract: In this paper, we introduce a mathematical model to describe the nanoparticles transport carried by a two-phase flow in a porous medium including gravity, capillary forces and Brownian diffusion. Nonlinear iterative IMPES scheme is used to solve the flow equation, and saturation and pressure are calculated at the current iteration step and then the transport equation is solved implicitly. Therefore, once the nanoparticles concentration is computed, the two equations of volume of the nanoparticles available on the pore surfaces and the volume of the nanoparticles entrapped in pore throats are solved implicitly. The porosity and the permeability variations are updated at each time step after each iteration loop. Numerical example for regular heterogenous permeability is considered. We monitor the changing of the fluid and solid properties due to adding the nanoparticles. Variation of water saturation, water pressure, nanoparticles concentration and porosity are presented graphically.
Mohamed El-Amin, Jisheng Kou, Amgad Salama, Shuyu Sun
374 Multi-Scale Coupling Between Monte Carlo Molecular Simulation and Darcy-Scale Flow in Porous Media [abstract]
Abstract: In this work, an efficient coupling between Monte Carlo (MC) molecular simulation and Darcy-scale flow in porous media is presented. The cell centered finite difference method with non-uniform rectangular mesh were used to discretize the simulation domain and solve the governing equations. To speed up the MC simulations, we implemented a recently developed scheme that quickly generates MC Markov chains out of pre-computed ones, based on the reweighting and reconstruction algorithm. This method astonishingly reduces the required computational times by MC simulations from hours to seconds. To demonstrate the strength of the proposed coupling in terms of computational time efficiency and numerical accuracy in fluid properties, various numerical experiments covering different compressible single-phase flow scenarios were conducted. The novelty in the introduced scheme is in allowing an efficient coupling of the molecular scale and the Darcy's one in reservoir simulators. This leads to an accurate description of thermodynamic behavior of the simulated reservoir fluids; consequently enhancing the confidence in the flow predictions in porous media.
Ahmed Saad, Ahmad Kadoura, Shuyu Sun
388 Modeling Pore-Scale Oil-Gas Systems Using Gradient Theory with Peng-Robinson Equation of State [abstract]
Abstract: This research addresses a sequential convex splitting method for numerical simulation of multicomponent two-phase fluids mixture in a single-pore at constant temperature, which is modeled by the gradient theory with Peng-Robinson equation of state. The gradient theory of thermodynamics and variational calculus are utilized to obtain a system of chemical equilibrium equations which are transformed into a transient system as a numerical strategy on which the numerical scheme is based. The proposed numerical algorithm avoids computing Hessian matrix arising from the second-order derivative of homogeneous contribution of free energy; it is also quite robust. This scheme is proved to be unconditionally component-wise energy stable. The Raviart-Thomas mixed finite element method is applied to spatial discretization.
Xiaolin Fan, Jisheng Kou, Zhonghua Qiao, Shuyu Sun