Editors:
- Covers development and application of high-order methods for high-fidelity CFD
- Offers extensive information on the use of high-order methods for LES and related aero-acoustics applications
- Highlights industrially-relevant findings
Part of the book series: Notes on Numerical Fluid Mechanics and Multidisciplinary Design (NNFM, volume 148)
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Table of contents (21 chapters)
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Front Matter
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Introduction - The TILDA project
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Front Matter
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Acceleration of High Order Methods for Unsteady Flows
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Front Matter
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Grid generation and HPC
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Front Matter
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Test Cases for Fundamental Unsteady Simulations
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Front Matter
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Test Cases for Industrial, Proof-of-Concept Unsteady Simulations
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Front Matter
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About this book
This book offers detailed insights into new methods for high-fidelity CFD, and their industrially relevant applications in aeronautics. It reports on the H2020 TILDA project, funded by the European Union in 2015-2018. The respective chapters demonstrate the potential of high-order methods for enabling more accurate predictions of non-linear, unsteady flows, ensuring enhanced reliability in CFD predictions.
The book highlights industrially relevant findings and representative test cases on the development of high-order methods for unsteady turbulence simulations on unstructured grids; on the development of the LES/DNS methodology by means of multilevel, adaptive, fractal and similar approaches for applications on unstructured grids; and on leveraging existent large-scale HPC networks to facilitate the industrial applications of LES/DNS in daily practice. Furthermore, the book discusses multidisciplinary applications of high-order methods in the area of aero-acoustics. All in all, it offers timely insights into the application and performance of high-order methods for CFD, and an extensive reference guide for researchers, graduate students, and industrial engineers whose work involves CFD and turbulence modeling.
Keywords
- High-order CFD methods
- Discontinuous Galerkin
- Flux Reconstruction
- Curved mesh generation
- LES applications
- High-performance computing in aeronautics
- Runge-Kutta methods
- Implicit time integration methods
- High Reynolds number flows
- Dual time stepping
- Multigrid multilevel preconditioners
- H2020 TILDA projects
Editors and Affiliations
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NUMECA S.A., Bruxelles, Belgium
Charles Hirsch
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Aerospace and Mechanical Engineering, University of Liège, Liège, Belgium
Koen Hillewaert
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Institut Aerodynamik Strömungstech, DLR, Braunschweig, Germany
Ralf Hartmann
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ONERA - The French Aerospace Lab, CHATILLON CEDEX, France
Vincent Couaillier
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CFD Team, CERFACS, Toulouse, France
Jean-Francois Boussuge
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DGT / DTIAE, Dassault Aviation, Saint Cloud, France
Frederic Chalot
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Aerodynamics Department, TsAGI, Zhukovsky, Russia
Sergey Bosniakov
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Aeronautics Consultants, Neubiberg, Germany
Werner Haase
Bibliographic Information
Book Title: TILDA: Towards Industrial LES/DNS in Aeronautics
Book Subtitle: Paving the Way for Future Accurate CFD - Results of the H2020 Research Project TILDA, Funded by the European Union, 2015 -2018
Editors: Charles Hirsch, Koen Hillewaert, Ralf Hartmann, Vincent Couaillier, Jean-Francois Boussuge, Frederic Chalot, Sergey Bosniakov, … Werner Haase
Series Title: Notes on Numerical Fluid Mechanics and Multidisciplinary Design
DOI: https://doi.org/10.1007/978-3-030-62048-6
Publisher: Springer Cham
eBook Packages: Engineering, Engineering (R0)
Copyright Information: Springer Nature Switzerland AG 2021
Hardcover ISBN: 978-3-030-62047-9Published: 29 June 2021
Softcover ISBN: 978-3-030-62050-9Published: 30 June 2022
eBook ISBN: 978-3-030-62048-6Published: 28 June 2021
Series ISSN: 1612-2909
Series E-ISSN: 1860-0824
Edition Number: 1
Number of Pages: IX, 550
Number of Illustrations: 71 b/w illustrations, 273 illustrations in colour
Topics: Engineering Fluid Dynamics, Aerospace Technology and Astronautics, Theoretical, Mathematical and Computational Physics, Classical and Continuum Physics, Acoustics