The European Computational Fluid Dynamics Conference and the European Conference on Numerical Methods in Engineering are major large scale events attracting the whole international community engaged in Computational Methods in Applied Sciences. The 146 papers, including many colour illustrations, in this two part volume cover topics such as: Numerical Methods: Finite difference, finite and boundary elements, volume methods; Spectral methods; Convergence acceleration methods: multigrid, pre-conditioning; Domain decomposition, zonal methods; Massively parallel and vector computing on new architectures; Mesh generation and adaptive grid refinement; Visualization techniques; Particle and microscopic simulation methods. Modelizations and Applications: Innovative algorithms for Euler and Navier-Stokes equations; Laminar and turbulent flows; Turbulence and transition modelization; Direct simulation of turbulence; Multiphase and reacting flows; Heat transfer and combustion; Free surface problems; Non-Newtonian fluids; Flow in porous media; Industrial applications for low to high speed internal and external flows.
The volumes will prove a useful and dynamic tool for those wishing to increase their knowledge of Computational Methods in Applied Sciences, as well as providing a guide to recent literature in this rapidly expanding area.
The European Computational Fluid Dynamics Conference and the European Conference on Numerical Methods in Engineering are major large scale events attracting the whole international community engaged in Computational Methods in Applied Sciences. The 146 papers, including many colour illustrations, in this two part volume cover topics such as: Numerical Methods: Finite difference, finite and boundary elements, volume methods; Spectral methods; Convergence acceleration methods: multigrid, pre-conditioning; Domain decomposition, zonal methods; Massively parallel and vector computing on new architectures; Mesh generation and adaptive grid refinement; Visualization techniques; Particle and microscopic simulation methods. Modelizations and Applications: Innovative algorithms for Euler and Navier-Stokes equations; Laminar and turbulent flows; Turbulence and transition modelization; Direct simulation of turbulence; Multiphase and reacting flows; Heat transfer and combustion; Free surface problems; Non-Newtonian fluids; Flow in porous media; Industrial applications for low to high speed internal and external flows.
The volumes will prove a useful and dynamic tool for those wishing to increase their knowledge of Computational Methods in Applied Sciences, as well as providing a guide to recent literature in this rapidly expanding area.
Sprache
Verlagsort
Verlagsgruppe
Elsevier Science & Technology
Zielgruppe
Für höhere Schule und Studium
Für Beruf und Forschung
Maße
ISBN-13
978-0-444-89793-0 (9780444897930)
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Schweitzer Klassifikation
Abbreviated.Volume 1. Sessions: I. Algorithm. Multidimensional upwind schemes for scalar advection on tetrahedral meshes (G. Bourgois et al.). A study on the acceleration of numerical simulations with qualitative reasoning and fuzzy logic (K. Yamaoka, M. Yamamoto). II. Transition and Turbulence. Numerical model for turbulent diffusion flames with applications (X.S. Bai, L. Fuchs). Application of algebraic-RNG eddy viscosity model to simulation of transitional boundary layer flow (A. Yakhot et al.). III. Hypersonic Reacting Flows. Are similarity parameters relevant to experimental simulations in high enthalpy nozzle flows? (R. Abgrall, A. Merlo). Comparative study of inviscid and viscous hypersonic flows over an STS (W. Schroder, F. Mergler).IV. Incompressible Flows. A numerical investigation of flow around a square-section cylinder mounted with a splitter plate (N. Arai, S. Saitoh). The discretization of the 2D incompressible Navier-Stokes equations on a co-located grid (P. Wilders, W. Couzy). V. Two-Phase Flow and Combustion. Numerical simulation of the 3D turbulent flow around the combustor dome of an aircraft engine (G. Brun et al.). Three-dimensional overlapping grids for internal combustion engine geometries (J.Y. Tu, L. Fuchs). Volume II. VI. Internal Flows. A robust inverse inviscid method for airfoil design (P. Chaviaropoulos et al.). Application of Roe's method for the simulation of viscous flow in turbomachinery (T. Siikonen, H. Pan). VII. Compressive Flows. An improved finite element method for the solution of the compressible Euler and Navier-Stokes equations (G.S. Baruzzi et al.). Transonic flow computations using a modified SIMPLE code based on a collocated grid arrangement (G. Zhou, L. Davidson). VIII. Compressive Flows II. Implicit upwind-Euler solution algorithms for unstructured-grid applications (J.T. Batina). An innovative algorithm to accurately solve the Euler equations for rotary wing flow (S. Wagner, E. Kramer). IX. Grid Generation and Adaption. Numerical resolution on a massively parallel computer of a test problem in meteorology using a domain decomposition algorithm (J.-D. Benamou, Y. Brenier). X. Boundary Layers. A method of separation of variables for laminar channel flow solution (F. Al-Bender, H. Van Brussel). XI. Environment. A comparison of differential systems for smooth oceanographic flows (G.L. Browning et al.). XII. Non-newtonian Flows. Finite element method for the approximation of viscoelastic fluid flow with a differential constitutive law (J. Baranger, D. Sandri).
