A New Class Of Finite Element Variational Multiscale Turbulence Models For Incompressible Magnetohydrodynamics PDF Download

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A New Class of Finite Element Variational Multiscale Turbulence Models for Incompressible Magnetohydrodynamics

A New Class of Finite Element Variational Multiscale Turbulence Models for Incompressible Magnetohydrodynamics
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Total Pages: 21
Release: 2015
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ISBN:
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New large eddy simulation (LES) turbulence models for incompressible magnetohydrodynamics (MHD) derived from the variational multiscale (VMS) formulation for finite element simulations are introduced. The new models include the variational multiscale formulation, a residual-based eddy viscosity model, and a mixed model that combines both of these component models. Each model contains terms that are proportional to the residual of the incompressible MHD equations and is therefore numerically consistent. Moreover, each model is also dynamic, in that its effect vanishes when this residual is small. The new models are tested on the decaying MHD Taylor Green vortex at low and high Reynolds numbers. The evaluation of the models is based on comparisons with available data from direct numerical simulations (DNS) of the time evolution of energies as well as energy spectra at various discrete times. Thus a numerical study, on a sequence of meshes, is presented that demonstrates that the large eddy simulation approaches the DNS solution for these quantities with spatial mesh refinement.

Numerical Methods for Flows

Numerical Methods for Flows
Author: Harald van Brummelen
Publisher: Springer Nature
Total Pages: 358
Release: 2020-02-22
Genre: Mathematics
ISBN: 3030307050
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This book includes selected contributions on applied mathematics, numerical analysis, numerical simulation and scientific computing related to fluid mechanics problems, presented at the FEF-“Finite Element for Flows” conference, held in Rome in spring 2017. Written by leading international experts and covering state-of-the-art topics in numerical simulation for flows, it provides fascinating insights into and perspectives on current and future methodological and numerical developments in computational science. As such, the book is a valuable resource for researchers, as well as Masters and Ph.D students.

Numerical Analysis of a Variational Multiscale Method for Turbulence

Numerical Analysis of a Variational Multiscale Method for Turbulence
Author: Songül Kaya Merdan
Publisher: LAP Lambert Academic Publishing
Total Pages: 80
Release: 2011-10
Genre:
ISBN: 9783845432083
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Despite efforts of more than centuries, turbulence phenomena is categorized as an unsolved problem. Turbulence is part of everyday's life. The majority of flows of industrial and technological applications are turbulent; natural flows are invariably so. There are many important and interesting physical phenomena which are connected with turbulent flows. Turbulence is observed in natural and engineering applications such as in weather prediction, air pollution, water pollution, aerodynamics and heat exchangers. This work considers an accurate and reliable solutions of turbulent flows. It is concerned with one of the most promising approaches to the numerical simulation of turbulent flows, the subgrid eddy viscosity models. We analyze both continuous and discontinuous finite element approximation of the new subgrid eddy viscosity model. This approach has the advantage that the diffusivity is introduced only on the small scales of the flow. Numerical test shows the new stabilization technique is robust and efficient in solving Navier-Stokes equations for a wide range of Reynolds numbers.

Large Scale Finite Element Solvers for the Large Eddy Simulation of Incompressible Turbulent Flows

Large Scale Finite Element Solvers for the Large Eddy Simulation of Incompressible Turbulent Flows
Author: Oriol Colomés Gené
Publisher:
Total Pages: 261
Release: 2016
Genre:
ISBN:
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In this thesis we have developed a path towards large scale Finite Element simulations of turbulent incompressible flows. We have assessed the performance of residual-based variational multiscale (VMS) methods for the large eddy simulation (LES) of turbulent incompressible flows. We consider VMS models obtained by different subgrid scale approximations which include either static or dynamic subscales, linear or nonlinear multiscale splitting, and different choices of the subscale space. We show that VMS thought as an implicit LES model can be an alternative to the widely used physical-based models. This method is traditionally combined with equal-order velocity-pressure pairs, since it provides pressure stabilization. In this work, we also consider a different approach, based on inf-sup stable elements and convection-only stabilization. In order to do so, we define a symmetric projection stabilization of the convective term using an orthogonal subscale decomposition. The accuracy and efficiency of this method compared with residual-based algebraic subgrid scales and orthogonal subscales methods for equal-order interpolation is also assessed in this thesis. Furthermore, we propose Runge-Kutta time integration schemes for the incompressible Navier-Stokes equations with two salient properties. First, velocity and pressure computations are segregated at the time integration level, without the need to perform additional fractional step techniques that spoil high orders of accuracy. Second, the proposed methods keep the same order of accuracy for both velocities and pressures. Precisely, the symmetric projection stabilization approach is suitable for segregated Runge-Kutta time integration schemes. This combination, together with the use of block-preconditioning techniques, lead to elasticity-type and Laplacian-type problems that can be optimally preconditioned using the balancing domain decomposition by constraints preconditioners. The weak scalability of this formulation have been demonstrated in this document. Additionally, we also contemplate the weak imposition of the Dirichlet boundary conditions for wall-bounded turbulent flows. Four well known problems have been mainly considered for the numerical experiments: the decay of homogeneous isotropic turbulence, the Taylor-Green vortex problem, the turbulent flow in a channel and the turbulent flow around an airfoil.

The Role of Continuity in Residual-Based Variational Multiscale Modeling of Turbulence

The Role of Continuity in Residual-Based Variational Multiscale Modeling of Turbulence
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Total Pages: 19
Release: 2007
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This paper examines the role of continuity of the basis in the computation of turbulent flows. We compare standard finite elements and NURBS (non-uniform rational B-splines) discretizations that are employed in Isogeometric Analysis. We make use of quadratic discretizations that are C0-continuous across element boundaries in standard finite elements, and C1-continuous in the case of NURBS. The variational multiscale residual-based method is employed as a turbulence modeling technique. We find that C1-continuous discretizations outperform their C0-continuous counterparts on a per-degree-of- freedom basis. We also find that the effect of continuity is greater for higher Reynolds number flows.

Stabilized Finite Element Formulations for Solving Incompressible Magnetohydrodynamics

Stabilized Finite Element Formulations for Solving Incompressible Magnetohydrodynamics
Author: Ramon Planas Badenas
Publisher:
Total Pages: 180
Release: 2014
Genre:
ISBN:
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Magnetohydrodynamics (MHD) is the physics branch that studies electrically conducting fluids under external magnetic fields. This thesis deals with the numerical approximation using stabilized finite element methods of two different formulations to model incompressible MHD, namely the resistive and inductionless MHD problems. Further, the linear systems of equations resulting from the application of these discrete formulations to simulate real cases are typically ill-conditioned and can have as many as 10̂6-10̂9 degrees of freedom. An efficient and scalable solver strategy is mandatory in these cases. On one hand, a new stabilized finite element formulation for the approximation of the resistive magnetohydrodynamics equations has been proposed. The novelty of this formulation with respect to existing ones is that it always converges to the physical solution, even when it is singular, which has been proved through a detailed stability and convergence analysis of the formulation. Moreover, it is inferred from the convergence analysis that a particular type of meshes with a macro-element structure is needed, which can be easily obtained after a straight modification of any original mesh. Finally, different operator splitting schemes have been proposed for solving the transient incompressible resistive MHD system that are unconditionally stable. Two levels of splitting have been considered. On the first level, the segregation of the Lagrange multipliers, the fluid pressure and the magneric pseudo-pressure, from the vectorial fields computation is achieved. On the second level, the fluid velocity and induction fields are also decoupled. This way, the fully coupled indefinite multiphysics system is transformed into smaller uncoupled one-physics problems. On the other hand, a stabilized formulation to solve the inductionless magnetohydrodynamic problem using the finite element method is presented. The inductionless MHD problem models the flow of an electrically charged fluid under the influence of an external magnetic field where the magnetic field induced in the fluid by the currents is negligible with respect to the external one. This system of partial differential equations is strongly coupled and highly nonlinear for real cases of interest. Therefore, solving the multiphysics linear systems of equations resulting from the discretization of these equations with finite element methods is a very challenging task which requires efficient and scalable preconditioners. A new family of recursive block LU preconditioners has been designed to improve the convergence of iterative solvers for this problem. These preconditioners are obtained after splitting the fully coupled matrix into one-physics problems for every variable (velocity, pressure, current density and electric potential) that can be optimally solved, e.g. using preconditioned domain decomposition algorithms. Furthermore, these ideas have been extended for developing recursive block LU preconditioners for the thermally coupled inductionless MHD problem.

Computational Fluid-Structure Interaction

Computational Fluid-Structure Interaction
Author: Yuri Bazilevs
Publisher: John Wiley & Sons
Total Pages: 444
Release: 2013-01-25
Genre: Technology & Engineering
ISBN: 111848357X
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Computational Fluid-Structure Interaction: Methods and Applications takes the reader from the fundamentals of computational fluid and solid mechanics to the state-of-the-art in computational FSI methods, special FSI techniques, and solution of real-world problems. Leading experts in the field present the material using a unique approach that combines advanced methods, special techniques, and challenging applications. This book begins with the differential equations governing the fluid and solid mechanics, coupling conditions at the fluid–solid interface, and the basics of the finite element method. It continues with the ALE and space–time FSI methods, spatial discretization and time integration strategies for the coupled FSI equations, solution techniques for the fully-discretized coupled equations, and advanced FSI and space–time methods. It ends with special FSI techniques targeting cardiovascular FSI, parachute FSI, and wind-turbine aerodynamics and FSI. Key features: First book to address the state-of-the-art in computational FSI Combines the fundamentals of computational fluid and solid mechanics, the state-of-the-art in FSI methods, and special FSI techniques targeting challenging classes of real-world problems Covers modern computational mechanics techniques, including stabilized, variational multiscale, and space–time methods, isogeometric analysis, and advanced FSI coupling methods Is in full color, with diagrams illustrating the fundamental concepts and advanced methods and with insightful visualization illustrating the complexities of the problems that can be solved with the FSI methods covered in the book. Authors are award winning, leading global experts in computational FSI, who are known for solving some of the most challenging FSI problems Computational Fluid-Structure Interaction: Methods and Applications is a comprehensive reference for researchers and practicing engineers who would like to advance their existing knowledge on these subjects. It is also an ideal text for graduate and senior-level undergraduate courses in computational fluid mechanics and computational FSI.

Multiphysics Modeling With Finite Element Methods

Multiphysics Modeling With Finite Element Methods
Author: William B J Zimmerman
Publisher: World Scientific Publishing Company
Total Pages: 434
Release: 2006-10-25
Genre: Technology & Engineering
ISBN: 9813106735
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Finite element methods for approximating partial differential equations that arise in science and engineering analysis find widespread application. Numerical analysis tools make the solutions of coupled physics, mechanics, chemistry, and even biology accessible to the novice modeler. Nevertheless, modelers must be aware of the limitations and difficulties in developing numerical models that faithfully represent the system they are modeling.This textbook introduces the intellectual framework for modeling with Comsol Multiphysics, a package which has unique features in representing multiply linked domains with complex geometry, highly coupled and nonlinear equation systems, and arbitrarily complicated boundary, auxiliary, and initial conditions. But with this modeling power comes great opportunities and great perils.Progressively, in the first part of the book the novice modeler develops an understanding of how to build up complicated models piecemeal and test them modularly. The second part of the book introduces advanced analysis techniques. The final part of the book deals with case studies in a broad range of application areas including nonlinear pattern formation, thin film dynamics and heterogeneous catalysis, composite and effective media for heat, mass, conductivity, and dispersion, population balances, tomography, multiphase flow, electrokinetic, microfluidic networks, plasma dynamics, and corrosion chemistry.As a revision of Process Modeling and Simulation with Finite Element Methods, this book uses the very latest features of Comsol Multiphysics. There are new case studies on multiphase flow with phase change, plasma dynamics, electromagnetohydrodynamics, microfluidic mixing, and corrosion. In addition, major improvements to the level set method for multiphase flow to ensure phase conservation is introduced.