Turbulence Modelling 95 - Validating Smallest Near Wall Scale Estimation Techniques for Natural Conv

Turbulence Modelling 95 - Validating Smallest Near Wall Scale Estimation Techniques for Natural Conv

Channel:
Singapore Theo Ong Science and Engineering
Subscribers:
9,750
Published on ● Video Link: https://www.youtube.com/watch?v=ObJW0aUWmZk


Duration: 22:51
101 views
2

Petroleum Downstream Crash Course Playlist:
https://www.youtube.com/playlist?list=PLhPfNw4V4_YQ13CnhacUqEVk-tZlU4ISE

OpenFOAM for Windows 10 Beginner Playlist
https://www.youtube.com/playlist?list=PLhPfNw4V4_YRhBU4IqSaToQ8_X543YQsZ

OpenFOAM Intermediate Playlist
https://www.youtube.com/playlist?list=PLhPfNw4V4_YSpWX6mSOlwWEOKVa6i_iuE

OpenFOAM Heat Transfer Playlist
https://www.youtube.com/playlist?list=PLhPfNw4V4_YR2Qa3Q9-AzNSF2J9Dc4_qT

Radiation Heat Transfer Learning Journal:
https://www.youtube.com/watch?v=uUzh9kh-WTo&list=PLhPfNw4V4_YRUUVUydQp-n6U-7uu1kJof

Turbulence Modelling Playlist
https://www.youtube.com/watch?v=F_Rxv9uMM3g&list=PLhPfNw4V4_YSnbYkJIBQ1kRN06Mmxe2Be

Density and Viscosity Values for Air
https://www.engineeringtoolbox.com/air-density-specific-weight-d_600.html
https://www.engineeringtoolbox.com/air-absolute-kinematic-viscosity-d_601.html

Ampofo, F., & Karayiannis, T. G. (2003). Experimental benchmark data for turbulent natural convection in an air filled square cavity. International Journal of Heat and Mass Transfer, 46(19), 3551–3572. https://doi.org/https://doi.org/10.1016/S0017-9310(03)00147-9

Rayleigh Number

http://thermopedia.com/content/1076/

https://en.wikipedia.org/wiki/Rayleigh_number

Scheel, J. D., Emran, M. S., & Schumacher, J. (2013). Resolving the fine-scale structure in turbulent Rayleigh–Bénard convection. New Journal of Physics, 15(11), 113063.

Perry, R. H., & Green, D. W. (2015). Perry’s chemical engineers’ handbook. Mc Graw.

Komen, E., Shams, A., Camilo, L., & Koren, B. (2014). Quasi-DNS capabilities of OpenFOAM for different mesh types. Computers & Fluids, 96, 87–104.

https://doi.org/https://doi.org/10.1016/j.compfluid.2014.02.013

Ding, P., Wang, S., & Chen, K. (2020). Numerical study on turbulent mixed convection in a vertical plane channel using hybrid RANS/LES and LES models. Chinese Journal of Chemical Engineering, 28(1), 1–8.

https://doi.org/https://doi.org/10.1016/j.cjche.2019.04.007

Kasagi, N., & Nishimura, M. (1997). Direct numerical simulation of combined forced and natural turbulent convection in a vertical plane channel. International Journal of Heat and Fluid Flow, 18(1), 88–99.

Pope, S. B. (2001). Turbulent flows. IOP Publishing.

Tu, J., Yeoh, G. H., & Liu, C. (2018). Computational fluid dynamics: a practical approach. Butterworth-Heinemann.

Spalart, P. R., Deck, S., Shur, M. L., Squires, K. D., Strelets, M. K., & Travin, A. (2006). A new version of detached-eddy simulation, resistant to ambiguous grid densities. Theoretical and Computational Fluid Dynamics, 20(3), 181.

Grötzbach, G. 1983. Spatial resolution requirements for direct numerical simulation of Rayleigh-Bénard convection. J. Comput. Phys., 49: 241–264.



Other Videos By Theo Ong Science and Engineering


2020-06-24Linux Mint 3 - Conversion of Word to LaTeX part i
2020-06-22Linux Mint 2 - Word Editors (LibreOffice, MS word and LaTeX)
2020-06-19Linux Mint 1 - Introduction and Installation Links
2020-06-03Turbulence Modelling 102 - OpenFOAM Example Practical DNS and LES Mesh Sizing with 8GB Ram
2020-06-03Turbulence Modelling 101 OpenFOAM Example Case Discussion and lowering Re for DNS
2020-06-03Turbulence Modelling 100 - OpenFOAM Example fvSolutions and data Sampling across a line functionObj
2020-06-03Turbulence Modelling 99 - OpenFOAM Example fvSolutions and Brief Discussion on Solvers
2020-06-02Turbulence Modelling 98 - OpenFOAM Example Boundary Conditions fvSchemes fvSolutions
2020-06-02Turbulence Modelling 97- OpenFOAM mesh size timestep Co Number and BlockMesh (note RAM requirements)
2020-06-02Turbulence Modelling 96 - OpenFOAM Example Mixed Convection Getting DNS Scales
2020-05-22Turbulence Modelling 95 - Validating Smallest Near Wall Scale Estimation Techniques for Natural Conv
2020-05-21Turbulence Modelling 94 - Smallest Near Wall Scale Estimates for Natural Convection Example
2020-05-21Turbulence Modelling 93 - Comparing Kolmogorov Scales to Dimensionless Wall Units Example
2020-05-21Turbulence Modelling 92 - Batchelor and Kolmogorov smallest Scales in Natural Convection
2020-05-19Turbulence Modelling 91- DNS LES and RANS mesh sizing in Kolmogorov length scale and wall units
2020-05-19Turbulence Modelling 90 - Kolmogorov Scales in terms of Reynolds Number
2020-05-19Turbulence Modelling 89 - Meshing Guidelines and Kolmogorov Scales
2020-05-18Turbulence Modelling 88 - OpenFoam Jayatilleke Wallfunction and LES Natural Convection
2020-05-18Turbulence Modelling 87 - Mixed Convection Wall Behaviour and OpenFoam Equations for Heat Transfer
2020-05-17Turbulence Modelling 86 - IDDES Mixed Opposing and Aiding Convection and PL DDES
2020-05-17Turbulence Modelling 85 - LES Mixed Opposing and Aiding Convection DNS comparison and Friction Re No


Tags:
Engineering
Math
Science
Thermodynamics
Fluid Mechanics
Chemical
Nuclear
Chemical Potential
Fugacity
Enthalpy
Internal Energy
Entropy
First Law
Second law
Gibbs Free Energy
Hemholtz free energy
heat capacity
constant volume
constant pressure
tutorial
petroleum
oil
refinery
downstream
crude
jet
gasoline
gasoil
diesel
computational fluid dynamics
CFD
OpenFoam
Open
Foam
Fluid mechanics
heat transfer
turbulence
conduction
convection
radiation