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Turbulence modeling for incompressible single phase flows in nuclear engineering

Published on Nov 03, 20161980 Views

The colloquium starts with a brief presentation of EDF R&D and its Fluid Mechanics, Energy and Environment Department. Then, after an overview of the main numerical tools utilized in different fields,

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Chapter list

Turbulence modeling for incompressible single phase flows in nuclear engineering00:00
Outlook00:45
Brief Introduction to EDF R&D01:41
EDF Group at a glance01:42
EDF R&D key figures03:09
EDF R&D strategic priorities04:29
Research Programs05:59
EDF R&D partners06:26
Paris-Saclay Campus07:10
Paris-Saclay – Closer cooperation with reasearch07:49
Brief Introduction to Code development at EDF R&D08:50
Code development at EDF R&D - 108:54
Code development at EDF R&D - 210:12
Brief Introduction to MFEE Department11:26
Fluid Mechanics, Energy and Environment Dept. 11:36
Overview of Thermal-Hydraulics activities12:44
Code_Saturne for nuclear engineering applications Presentation13:48
General Features - 113:52
General Features - 216:01
Mesh examples for complex geometries18:23
Verification & Validation (V&V) in Code_Saturne19:02
An example of Verification (with MMS), Anisotropic heterogeneous diffusion20:35
Code_Saturne Model Validation examples21:16
Examples of Single-Phase CFD Applications with Code_Saturne21:52
Code_Saturne for nuclear engineering applications Introduction to turbulence modeling ((U)RANS, LES) - 122:24
Code_Saturne for nuclear engineering applications Introduction to turbulence modeling ((U)RANS, LES) - 222:48
Turbulence modelling - 125:43
Turbulence modelling - 225:51
Turbulence modelling - 327:24
Wall modeled approaches: Wall functions29:17
Some observations - 129:20
Some observations - 230:57
Code_Saturne for nuclear engineering applications On the use of (U)RANS and LES in nuclear engineering applications33:34
Linear Eddy Viscosity Models (LEVMs) vs. Reynolds Stress Models (RSMs) - 133:37
Linear Eddy Viscosity Models (LEVMs) vs. Reynolds Stress Models (RSMs) - 234:37
Linear Eddy Viscosity Models (LEVMs) vs. Reynolds Stress Models (RSMs) - 336:12
Linear Eddy Viscosity Models (LEVMs) vs. Reynolds Stress Models (RSMs) - 437:52
Wall Resolved vs. Wall Modeled RANS - 139:16
Wall Resolved vs. Wall Modeled RANS - 240:49
Wall Resolved vs. Wall Modeled RANS - 341:02
Heat transfer with Eddy Viscosity Models - 141:21
Heat transfer with Eddy Viscosity Models - 242:05
Heat transfer with Eddy Viscosity Models - 342:59
Heat transfer with Eddy Viscosity Models - 443:20
DNS, Quasi-DNS and Wall Resolved LES44:22
Meshing requirements for Wall Resolved LES - 145:05
Meshing requirements for Wall Resolved LES - 245:52
A posteriori checks for Wall Resolved LES46:33
Wall modeling in LES? - 147:20
Wall modeling in LES? - 247:52
High Performance Computing - 148:29
High Performance Computing - 249:21
Open Questions?50:13