TILDA: Towards Industrial LES/DNS in Aeronautics Paving the Way for Future Accurate CFD - Results of the H2020 Research Project TILDA, Funded by the European Union, 2015 -2018 / [electronic resource] :
edited by Charles Hirsch, Koen Hillewaert, Ralf Hartmann, Vincent Couaillier, Jean-Francois Boussuge, Frederic Chalot, Sergey Bosniakov, Werner Haase.
- 1st ed. 2021.
- IX, 550 p. 344 illus., 273 illus. in color. online resource.
- Notes on Numerical Fluid Mechanics and Multidisciplinary Design, 148 1860-0824 ; .
- Notes on Numerical Fluid Mechanics and Multidisciplinary Design, 148 .
The TILDA Project - Objectives, Project and Activities -- Implicit methods -- Multi-level approach -- Space Adaptive Methods/Meshing -- Wall-modelled LES -- Quality Measures for Curvilinear Finite Elements -- Parallelisation to Several Tens-of-thousands of cores -- I/O post- and Co-processing for High-order Methods -- Implementation of High Order Discontinuous Galerkin Method and its Verification using Taylor-Green Vortex and Periodic Hills Test Cases -- Large Eddy Simulation of single stream jet using High-order methods -- Boeing Rudimentary Landing Gear Configurations -- Generic Falcon Business Jet in Landing Configuration -- Detached-Eddy Simulation of Dual Stream Nozzle Jet Using High Order Discontinuous Galerkin Method.
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. .
9783030620486
10.1007/978-3-030-62048-6 doi
Fluid mechanics.
Aerospace engineering.
Astronautics.
Mathematical physics.
Physics.
Acoustics.
Engineering Fluid Dynamics.
Aerospace Technology and Astronautics.
Theoretical, Mathematical and Computational Physics.
Classical and Continuum Physics.
Acoustics.
TA357-359
620.1064
The TILDA Project - Objectives, Project and Activities -- Implicit methods -- Multi-level approach -- Space Adaptive Methods/Meshing -- Wall-modelled LES -- Quality Measures for Curvilinear Finite Elements -- Parallelisation to Several Tens-of-thousands of cores -- I/O post- and Co-processing for High-order Methods -- Implementation of High Order Discontinuous Galerkin Method and its Verification using Taylor-Green Vortex and Periodic Hills Test Cases -- Large Eddy Simulation of single stream jet using High-order methods -- Boeing Rudimentary Landing Gear Configurations -- Generic Falcon Business Jet in Landing Configuration -- Detached-Eddy Simulation of Dual Stream Nozzle Jet Using High Order Discontinuous Galerkin Method.
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. .
9783030620486
10.1007/978-3-030-62048-6 doi
Fluid mechanics.
Aerospace engineering.
Astronautics.
Mathematical physics.
Physics.
Acoustics.
Engineering Fluid Dynamics.
Aerospace Technology and Astronautics.
Theoretical, Mathematical and Computational Physics.
Classical and Continuum Physics.
Acoustics.
TA357-359
620.1064