Three-dimensional hybrid grid generation with application to high Reynolds number viscous flows

Athanasiadis, Aristotelis

29 June 2004

In this thesis, an approach is presented for the generation of grids suitable for the simulation of high Reynolds number viscous flows in complex three-dimensional geometries. The automatic and reliable generation of such grids is today on the biggest bottlenecks in the industrial CFD simulation environment.<p><p>In the proposed approach, unstructured tetrahedral grids are employed for the regions far from the viscous boundaries of the domain, while semi-structured layers of high aspect ratio prismatic and hexahedral elements are used to provide the necessary grid resolution inside the boundary layers and normal to the viscous walls. The definition of the domain model is based on the STEP ISO standard and the topological information contained in the model is used for applying the hierarchical grid generation parameters defined by the user. An efficient, high-quality and robust algorithm is presented for the generation of the unstructured simplicial (triangular of tetrahedral) part of the grid. The algorithm is based on the Delaunay triangulation and the internal grid points are created following a centroid or frontal approach. For the surface grid generation, a hybrid approach is also proposed similar to the volume.<p>Semi-structured grids are generated on the surface grid (both on the edges and faces of the domain) to improve the grid resolution around convex and concave ridges and corners, by aligning the grid elements in the directions of high solution gradients along the surface. A method is also developed for automatically setting the grid generation parameters related to the surface grid generation based on the curvature of the surface in order to obtain an accurate and smooth surface grid. Finally, a semi-structured prismatic/hexahedral grid generation algorithm is presented for the generation of the part of grid close to the viscous walls of the domain. The algorithm is further extended with improvements meant to increase the grid quality around concave and convex ridges of the domain, where the semi-structured grids are known to be inadequate.<p><p>The combined methodology is demonstrated on a variety of complex examples mainly from the automotive and aeronautical industry. / Doctorat en sciences appliquées / info:eu-repo/semantics/nonPublished

Electronique générale

Reynolds number

Viscous flow -- Simulation methods

Reynolds, Nombre de

computational fluid dynamics

grid generation

model definition

unstructured grids

Delaunay triangulation

hybrid grids

semi-structured grids

Electromagnetic Particle-in-Cell Algorithms on Unstructured Meshes for Kinetic Plasma Simulations

Na, Dong-Yeop, NA

January 2018

No description available.

Electrical Engineering

Electromagnetics

Plasma Physics

Contributions to the development of residual discretizations for hyperbolic conservation laws with application to shallow water flows

Ricchiuto, Mario

12 December 2011

In this work we review 12 years of developments in the field of residual based discretizations for hyperbolic problems and their application to the solution of the shallow water equations. Fundamental concepts related to the topic are recalled and he construction of second and higher order schemes for steady problems is presented. The generalization to time dependent problems by means of multi-step implicit time integration, space-time, and genuinely explicit techniques is thoroughly discussed. Finally, the issues of C-property, super consistency, and wetting/drying are analyzed in this framework showing the power of the residual based approach.

[SDE] Environmental Sciences

Numerical analysis

hyperbolic problems

unstructured grids

finite elements

residual based schemes

high order schemes

time dependent problems

free surface flow

shallow water equations

positivity preservation

source terms

C-property

super consistency

long wave run up simulations

tsunami simulations

An artificial compressibility analogy approach for compressible ideal MHD: application to space weather simulation

Yalim, Mehmet S.

05 December 2008

Ideal magnetohydrodynamics (MHD) simulations are known to have problems in satisfying the solenoidal constraint (i.e. the divergence of magnetic field should be equal to zero, $<p>ablacdotvec{B} = 0$). The simulations become unstable unless specific measures have been taken.<p><p>In this thesis, a solenoidal constraint satisfying technique that allows discrete satisfaction of the solenoidal constraint up to the machine accuracy is presented and validated with a variety of test cases. Due to its inspiration from Chorin's artificial compressibility method developed for incompressible CFD applications, the technique was named as \ / Doctorat en Sciences de l'ingénieur / info:eu-repo/semantics/nonPublished

Mécanique

Sciences de l'ingénieur

Magnetosphere

Magnétosphère

COOLFluiD

upwind

finite volume

unstructured grids

solution-adaptive mesh

implicit

parallel

unsteady

space weather

solar wind

Earth's magnetosphere

magnetic field splitting

reference speed

diffusion reduction coefficient

compressible ideal MHD

ACA

artificial compressibility

Construction and analysis of compact residual discretizations for conservation laws on unstructured meshes

Ricchiuto, Mario

21 June 2005

This thesis presents the construction, the analysis and the verication of compact residual discretizations for the solution of conservation laws on unstructured meshes. <p>The schemes considered belong to the class of residual distribution (RD) or fluctuation splitting (FS) schemes. <p>The methodology presented relies on three main elements: design of compact linear first-order stable schemes for linear hyperbolic PDEs, a positivity preserving procedure mapping stable first-order linear schemes onto nonlinear second-order schemes with non-oscillatory shock capturing capabilities, and a conservative formulation enabling to extend the schemes to nonlinear CLs. These three design steps, and the underlying theoretical tools, are discussed in depth. The nonlinear RD schemes resulting from this construction are tested on a large set of problems involving the solution of scalar models, and systems of CLs. This extensive verification fills the gaps left open, where no theoretical analysis is possible. <p>Numerical results are presented on the Euler equations of a perfect gas, on a two-phase flow model with highly nonlinear thermodynamics, and on the shallow-water equations. <p>On irregular grids, the schemes proposed yield quite accurate and stable solutions even on very difficult computations. Direct comparisone show that these results are more accurate than the ones given by FV and WENO schemes. Moreover, our schemes have a compact nearest-neighbor stencil. This encourages to further develop our approach, toward the design of very high-order schemes, which would represent a very appealing alternative, both in terms of accuracy and efficiency, to now classical FV and ENO/WENO discretizations. These schemes might also be very competitive with respect to very high-order DG schemes. / Doctorat en sciences appliquées / info:eu-repo/semantics/nonPublished

Sciences de l'ingénieur

Mécanique

Structural stability

Conservation laws (Physics)

Strains and stresses

Entropy

Constructions -- Stabilité

Lois de conservation (Physique)

Contraintes (Mécanique)

Entropie

unstructured grids

residual distribution

monotone shock-capturing

entropy stability

second-order accurate schemes

conservation laws

energy stability

homogeneous two-phase flow

shallow-water equations

conservative schemes

residual schemes

positive discretizations

Euler equations