Turbulence Modelling 80 - LES Convection Intro and LES Turbulent Prandtl Number Overview

Turbulence Modelling 80 - LES Convection Intro and LES Turbulent Prandtl Number Overview

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Petroleum Downstream Crash Course Playlist:
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https://www.youtube.com/watch?v=F_Rxv9uMM3g&list=PLhPfNw4V4_YSnbYkJIBQ1kRN06Mmxe2Be

LES Fire Simulation (natural convection)
Wang, Y., Chatterjee, P., & de Ris, J. L. (2011). Large eddy simulation of fire plumes. Proceedings of the Combustion Institute, 33(2), 2473-2480.

LES Simulation between Heated Surfaces (natural convection)

Lau, G. E., Yeoh, G. H., Timchenko, V., & Reizes, J. A. (2012). Large-eddy simulation of natural convection in an asymmetrically-heated vertical parallel-plate channel: Assessment of subgrid-scale models. Computers & fluids, 59, 101-116.

Peng, S. H., & Davidson, L. (2001). Large eddy simulation for turbulent buoyant flow in a confined cavity. International Journal of Heat and Fluid Flow, 22(3), 323-331.

Barhaghi, D. G., Davidson, L., & Karlsson, R. (2006). Large-eddy simulation of natural convection boundary layer on a vertical cylinder. International journal of heat and fluid flow, 27(5), 811-820.
Wang, W. P., & Pletcher, R. H. (1996). On the large eddy simulation of a turbulent channel flow with significant heat transfer. Physics of Fluids, 8(12), 3354-3366.

Natural Convection Wall Functions
Henkes, R. A. W. M., Van Der Vlugt, F. F., & Hoogendoorn, C. J. (1991). Natural-convection flow in a square cavity calculated with low-Reynolds-number turbulence models. International Journal of Heat and Mass Transfer, 34(2), 377-388.

Yuan, X., Moser, A., & Suter, P. (1993). Wall functions for numerical simulation of turbulent natural convection along vertical plates. International journal of heat and mass transfer, 36(18), 4477-4485.

Calculating Prt

Zaitsev, D. K., & Smirnov, E. M. (2019). Method of calculation of turbulent Prandtl number for the SST turbulence model, St. Petersburg Polytechnical State University Journal. Physics and Mathe-matics, 12(1), 35-44.

https://physmath.spbstu.ru/userfiles/files/articles/2019/1/3Zaytsev-Smirnov-eng.pdf

McEligot, D. M., & Taylor, M. F. (1996). The turbulent Prandtl number in the near-wall region for low-Prandtl-number gas mixtures. International Journal of Heat and Mass Transfer, 39(6), 1287-1295.

Kays, W. M. (May 1, 1994). "Turbulent Prandtl Number—Where Are We?." ASME. J. Heat Transfer. May 1994; 116(2): 284–295. https://doi.org/10.1115/1.2911398

Review Paper on Turbulent Pr
Kirillov, P. L. (2017). Heat exchange in turbulent flow. Part 1. Turbulent Prandtl number. Atomic Energy, 122(3), 156-171.

Bejan, A. (2013). Convection heat transfer. John wiley & sons.

Liquid Metal turbulent Pr model

Weigand, B., Ferguson, J. R., & Crawford, M. E. (1997). An extended Kays and Crawford turbulent Prandtl number model. International journal of heat and mass transfer, 40(17), 4191-4196.

LES subgrid models for turbulent Pr

Li, D. (2016). Revisiting the subgrid-scale Prandtl number for large-eddy simulation. Journal of Fluid Mechanics, 802.

Moin, P., Squires, K., Cabot, W., & Lee, S. (1991). A dynamic subgrid‐scale model for compressible turbulence and scalar transport. Physics of Fluids A: Fluid Dynamics, 3(11), 2746-2757.

Peng, S. H., & Davidson, L. (2002). On a subgrid-scale heat flux model for large eddy simulation of turbulent thermal flow. International Journal of Heat and Mass Transfer, 45(7), 1393-1405.

DES Models

Viswanathan, A. K., & Tafti, D. K. (2006). Detached eddy simulation of flow and heat transfer in fully developed rotating internal cooling channel with normal ribs. International journal of heat and fluid flow, 27(3), 351-370.

Turnow, J., & Kornev, N. EVALUATION OF FLOW STRUCTURES AND HEAT TRANSFER OVER DIMPLED SURFACES IN A NARROW CHANNEL FOR HIGH REYNOLDS AND PRANDTL NUMBER USING HYBRID RANS-LES METHODS.

WALE for Heat Transfer

Ben-Nasr, O., Hadjadj, A., Chaudhuri, A., & Shadloo, M. S. (2017). Assessment of subgrid-scale modeling for large-eddy simulation of a spatially-evolving compressible turbulent boundary layer. Computers & Fluids, 151, 144–158.

https://doi.org/https://doi.org/10.1016/j.compfluid.2016.07.004



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