Abstract
Vortex dynamics and heat transfer in a viscous incompressible fluid flow past shallow and deep trenches on a plane wall are studied methodically within the framework of the multiblock approach to solution of steady-state Reynolds equations closed by the Menter and Spalart-Allmaras turbulence models and the energy equation.
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REFERENCES
P. K. Chang, Separation of Flow [Russian translation], Vol. 2, Mir, Moscow (1973).
É. K. Kalinin, G. A. Dreitser, I. Z. Kopp, and A. S. Myakochin, Efficient Surfaces of Heat Transfer [in Russian], Énergoatomizdat, Moscow (1998).
Yu. F. Gortyshov and V. V. Olimpiev, Heat Exchangers with Enhanced Heat Transfer [in Russian], Izd. A. N. Tupolev KGTU, Kazan’ (1999).
V. V. Alekseev, I. A. Gachechiladze, G. I. Kiknadze, and V. G. Oleinikov, Tornado-like energy exchange in three-dimensional concave reliefs — structure of self-organizing flows, their visualization and mechanisms of flows past surfaces, in: Proc. 2nd Russ. Nat. Conf. on Heat Transfer. Vol. 6. Enhancement of Heat Transfer. Radiative and Combined Heat Transfer [in Russian], MÉI, Moscow (1998), pp. 33–42.
V. N. Afanas’ev, V. Yu. Veselkin, A. I. Leont’ev, A. P. Skibin, and Ya. P. Chudnovskii, Hydrodynamics and Heat Transfer in Flows Past Individual Dimples on an Initially Smooth Surface [in Russian], Preprint No. 2-91 of N. É. Bauman Moscow State Technical University, Pts. 1 and 2, Moscow (1991).
V. I. Terekhov, Separating flows. Mechanisms of formation and possibilities of control of heat transfer processes, in: Proc. XIII School-Seminar of Young Scientists and Specialists Headed by Academician A. I. Leont’ev “ Physical Principles of Experimental and Mathematical Modeling of Processes of Gas Dynamics and Heat and Mass Transfer in Power Plants” [in Russian], Vol. 1, MÉI, Moscow (2001), pp. 15–20.
I. A. Belov and S. A. Isaev, Modeling of Turbulent Flows. Manual [in Russian], BGTU, St. Petersburg (2001).
I. A. Belov and S. A. Isaev, Numerical study of separating flows of viscous fluid in recesses and in flows past bodies, in: Coll. of Papers of A. N. Krylov Sci.-Res. Soc. “Improvement of Flying Qualities” [in Russian], Issue 462 (1989), pp. 54–63.
I. A. Belov and S. A. Isaev, Numerical simulation of near-wall flows with organized circulation zones, Gazodinamika Teploobmen, Issue 10, 139–156 (1993).
N. A. Kudryavtsev, Hydrodynamics and heat transfer of a transverse flow past a trench, in: Ext. Abstr. of Papers presented at VIII All-Union School-Seminar Headed by Academician A. I. Leont’ev “Modern Problems of Gas Dynamics and Heat and Mass Transfer and Ways of Improving of the Efficiency of Power Plants” [in Russian], Pt. 1, MGTU, Moscow (1991), p. 35.
A. V. Ermishin and S. A. Isaev (Eds.), Control of Flows Past Bodies with Vortex Cells as Applied to Flying Vehicles of Integral Arrangement [in Russian], MGU, Moscow (2003).
S. A. Isaev, Development of multiblock computation technologies for solving problems of vortex aeromechanics and thermal physics, in: Proc. XIV School-Seminar of Young Scientists and Specialists Headed by Academician A. I. Leont’ev “Problems of Gas Dynamics and Heat and Mass Transfer in Power Plants” [in Russian], Vol. 1, MÉI, Moscow (2003), pp. 13–16.
F. R. Menter, Two-equation eddy-viscosity turbulence models for engineering application, AIAA J., 32, No. 8, 1598–1605 (1994).
P. Spalart and S. Allmaras, A One-Equation Turbulence Model for Aerodynamic Flows, Tech. Rep. AIAA, No. 92-0439 (1992).
S. A. Isaev, S. V. Guvernyuk, M. A. Zubin, and Yu. S. Prigorodov, Numerical and physical modeling of a low-velocity air flow in a channel with a circular vortex cell, Inzh.-Fiz. Zh., 73, No. 2, 346–353 (2000).
S. A. Isaev, P. A. Baranov, S. V. Guvernyuk, and M. A. Zubin, Numerical and physical modeling of a turbulent flow in a diverging channel with a vortex cell, Inzh.-Fiz. Zh., 75, No. 2, 3–8 (2002).
S. A. Isaev, A. I. Leont’ev, P. A. Baranov, and I. A. Pyshnyi, Numerical analysis of the influence of the depth of a spherical lune on a plane wall on turbulent heat transfer, Inzh.-Fiz. Zh., 76, No. 1, 52–59 (2003).
S. A. Isaev and A. I. Leont’ev, Numerical modeling of vortical enhancement of heat transfer in a turbulent flow past a spherical lune on the wall of a narrow channel, Izv. Ross. Akad. Nauk, Teplofiz. Vys. Temp., 41, No.5, 755–770 (2003).
R. W. Benodekar, A. J. H. Goddard, A. D. Gosman, and R. I. Issa, Numerical prediction of turbulent flow over surface-mounted ribs, AIAA J., 23, No. 3, 359–366 (1985).
F. R. Menter, M. Kuntz, and R. Langtry, Ten years of industrial experience with the SST turbulence model, in: Proc. Int. Conf. “Turbulence: Heat and Mass Transfer 4,” Begell House, Inc. (2003).
S. A. Isaev, N. A. Kudryavtsev, D. A. Lysenko, and A. E. Usachov, A retrospective analysis of semi-empirical differential models of turbulence for calculation of separating flows, in: Proc. 3rd Int. School-Seminar “Models and Methods of Aerodynamics” [in Russian], MTsNMO, Moscow (2003), pp. 54–55.
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Translated from Inzhenerno- Fizicheskii Zhurnal, Vol. 77, No. 6, pp. 18–22, November–December, 2004.
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Isaev, S.A., Baranov, P.A., Kudryavtsev, N.A. et al. Analysis of vortex heat transfer in a transverse flow past a trench on a plane using multiblock computation technologies and different semi-empirical models of turbulence. J Eng Phys Thermophys 77, 1236–1246 (2004). https://doi.org/10.1007/s10891-005-0020-y
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DOI: https://doi.org/10.1007/s10891-005-0020-y