Developing a physical influence upwind scheme for pressure‐based cell‐centered finite volume methods

In this paper, we attempt to investigate the steady and laminar flow of incompressible Water based nanofluid between inclined plates and over an inclined plate. A uniform and external magnetic field is applied in order to control the nonfluid flow. Copper-Water based nanofluid can be also used for heat transfer enhancement. We can gain additional thermal energy in the fluid by increasing the volume fraction of copper nanoparticles in the base fluid and improving the thermophysical parameters for the single-phase model. The results also show that adjusting the Prandtl and Eckert numbers causes the velocity profile to change fast. According to our findings, fluid elements may be more intensively accelerated by raising the nano additive concentration and enhancing the thermo-physical characteristics of the fluid.

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“…Case B -PDES: To validate our results, the code developed by Vakilipour et al [30] has been used. In fig.…”

Section: Validationmentioning

confidence: 99%

The 2-D Cu-water nanofluid-flow and heat transfer over an inclined wall and between two inclined walls: The numerical solution of PDE and ODE

Azimi

Vakilipour

2022

THERM SCI

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“…Most recently, Vakilipour et al. [ 12 ] developed physical influence upwind interpolation schemes for linking pressure and velocity fields in incompressible flow solutions.…”

Section: Introductionmentioning

confidence: 99%

Accuracy of compact-stencil interpolation algorithms for unstructured mesh finite volume solver

Tasri

Susilawati

2021

Heliyon

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This study considers the accuracy of cell-to-face centre interpolation of convected quantities in unstructured finite volume meshes with cell-centred storage of variables. The accuracy of the interpolation algorithms were tested in isolation using ideal data to determine their numerical accuracy on both standard and artificially distorted meshes. It was found that the formally second- and third-order accurate interpolations based on one-dimensional interpolation along the line connecting the cells to the right and left of the face under consideration only have first-order accuracy in standard unstructured mesh, and less than first-order accuracy in distorted unstructured mesh. L1 interpolation errors in the distorted unstructured mesh are greater than in standard unstructured mesh. The order of accuracy and L1 errors can be improved by applying spatial corrections. The formally second-order accurate multi-dimensional interpolations tested in this study that are not based on one-dimensional interpolation along lines connecting the neighbour cells have first-order accuracy in both standard and distorted unstructured mesh. Linear interpolation between end vertices produces greatest L1 error in standard mesh; polynomial interpolation, linear interpolation between cell centres and standard QUICK produce the greatest L1 error in distorted mesh. Spatially correct QUICK, spatially correct linear interpolation between cell centres, Laplacian interpolation to face centres, and Taylor series expansion about an upstream cell produce the smallest L1 error in both standard and distorted mesh. Based on accuracy and the simplicity of implementation, Taylor series expansion about an upstream cell is the best choice for use in unstructured mesh.

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Newton linearization of the Navier–Stokes equations for flow computations using a fully coupled finite volume method

Mohammadi

Vakilipour

Ormiston

2021

Applied Mathematics and Computation

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Developing a physical influence upwind scheme for pressure‐based cell‐centered finite volume methods

Cited by 11 publications

References 52 publications

The 2-D Cu-water nanofluid-flow and heat transfer over an inclined wall and between two inclined walls: The numerical solution of PDE and ODE

The 2-D Cu-water nanofluid-flow and heat transfer over an inclined wall and between two inclined walls: The numerical solution of PDE and ODE

Accuracy of compact-stencil interpolation algorithms for unstructured mesh finite volume solver

Newton linearization of the Navier–Stokes equations for flow computations using a fully coupled finite volume method

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