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16.  L.Davidson. Computation of natural-convection flow in a square cavity, in ''Turbulent Natural Convection in Enclosures, Proc. Eurotherm Seminar'' ''No. 22'', R.A.W.M.Henkes and C.J.Hoogendoorn (Eds.), 45-53, 1993.
16.  L.Davidson. Computation of natural-convection flow in a square cavity, in ''Turbulent Natural Convection in Enclosures, Proc. Eurotherm Seminar'' ''No. 22'', R.A.W.M.Henkes and C.J.Hoogendoorn (Eds.), 45-53, 1993.


17.  I.Demirdžić, Ž.Lilek and M.Perić. Fluid flow and heat transfer test problems for non­orthogonal grids: benchmark solutions. ''Int. J. Numerical Methods in Fluids'', Vol. 15, 329­354, 1992.
17.  I.Demirdžić, Ž.Lilek and M.Perić. Fluid flow and heat transfer test problems for non­orthogonal grids: benchmark solutions. ''Int. J. Numerical Methods in Fluids'', Vol. 15, 329­354, 1992.


18.  G.De Vahl Davis. Natural convection of air in a square cavity: a benchmark numerical solution. ''Int. J. Numerical Methods in Fluids'', Vol. 3, 249­264, 1983.
18.  G.De Vahl Davis. Natural convection of air in a square cavity: a benchmark numerical solution. ''Int. J. Numerical Methods in Fluids'', Vol. 3, 249­264, 1983.


19.  H.Dol, K.Hanjalić and S.Kenjereš. A comparative assessment of the second-moment differential and algebraic models in turbulent natural convection. ''Int. J. Heat and Fluid Flow'', Vol. 18, 4-14, 1997.
19.  H.Dol, K.Hanjalić and S.Kenjereš. A comparative assessment of the second-moment differential and algebraic models in turbulent natural convection. ''Int. J. Heat and Fluid Flow'', Vol. 18, 4-14, 1997.


20.  ''H.Dol, K.Hanjalić, T.A.M.Versteegh.'' A DNS-based thermal second moment closure for buoyant convection at vertical walls. ''J. Fluid Mechanics'', Vol. 391, 211-247, 1999.
20.  ''H.Dol, K.Hanjalić, T.A.M.Versteegh.'' A DNS-based thermal second moment closure for buoyant convection at vertical walls. ''J. Fluid Mechanics'', Vol. 391, 211-247, 1999.
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32.  K.Hanjalić and S.Vasić. Computation of turbulent natural convection in rectangular enclosures with an algebraic flux model. ''Int. J. Heat and Mass Transfer'', Vol. 36, 3603-3624, 1993.
32.  K.Hanjalić and S.Vasić. Computation of turbulent natural convection in rectangular enclosures with an algebraic flux model. ''Int. J. Heat and Mass Transfer'', Vol. 36, 3603-3624, 1993.


33.  K.Hanjalić, S.Kenjereš and F.Durst. Natural convection in partitioned two-dimensional enclosures at higher Rayleigh numbers. ''Int. J. Heat and Mass Transfer'', Vol. 39, No. 7, 1407-1427, 1996.
33.  K.Hanjalić, S.Kenjereš and F.Durst. Natural convection in partitioned two-dimensional enclosures at higher Rayleigh numbers. ''Int. J. Heat and Mass Transfer'', Vol. 39, No. 7, 1407-1427, 1996.


34.  R.A.W.M.Henkes and C.J.Hoogendoorn. Comparison of turbulence models for the natural convection boundary layer along a heated vertical plate. ''Int. J. Heat and Mass Transfer'', Vol. 32, 157-169, 1989.
34.  R.A.W.M.Henkes and C.J.Hoogendoorn. Comparison of turbulence models for the natural convection boundary layer along a heated vertical plate. ''Int. J. Heat and Mass Transfer'', Vol. 32, 157-169, 1989.

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Natural convection in simple closed cavity

Underlying Flow Regime 4-10               © copyright ERCOFTAC 2004


References

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34. R.A.W.M.Henkes and C.J.Hoogendoorn. Comparison of turbulence models for the natural convection boundary layer along a heated vertical plate. Int. J. Heat and Mass Transfer, Vol. 32, 157-169, 1989.

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© copyright ERCOFTAC 2004



Contributors: Nicholas Waterson - Mott MacDonald Ltd


Front Page

Description

Test Case Studies

Evaluation

Best Practice Advice

References