Article information
2019 , Volume 24, ¹ 3, p.88-105
Pivovarov Y.V.
Computation of motion of viscous fluid partially filling a rotating cavity at large Reynolds numbers
The goal of the research is to simulate a hydrodynamic flow of semiconductor material melt during its purification from impurity by using the method of zone melting in a horizontal cylindrical rotating container. The container is not fully filled with melt, there is a free surface. The flow is considered to be plane-parallel and stationary. It is supposed that the flow domain with unperturbed free boundary is a semicircle. The melt is separated from a container wall by a thin layer of finely dispersed lubricant. Therefore, when stating a problem, the Navier slip condition is set on the boundary with a wall. The problem formulation in variables of vortex – stream function is performed. To solve it, the following methods are used, namely, relaxation method for time, the method of an approximate factorization for solution of an evolutionary equation for vortex, V.G. Zverev’s method is used to solve the problems for stream function, this method allows precise satisfying a boundary condition which connects a vortex on boundary and nearboundary values of stream function at each time step using finite-difference method and method of computation on the sequence of meshes, beginning with the mesh of dimension 32×8 and ending with the mesh of dimension 2048×512. The research results in constructed patterns of streamlines and vortex isolines along with the form of perturbed free boundary at various values of Reynolds number. The range of Reynolds number is from zero to three thousand that corresponds to the experimental data. Conclusions. 1. The problem on motion of viscous fluid filling half the cylindrical rotating cavityis solved. 2. A great number of mesh points made it possible to minimize the influence ofscheme viscosity and to obtain trustworthy results at large Reynolds numbers. 3. It is shown that the flow domain is divided into a vortex boundary layer, transitionzone and the zone of constant vortex.
[full text] [link to elibrary.ru]
Keywords: conformal mapping, incompressible fluid, the Navier - Stokes equations, slip condition, vortex, stream function
doi: 10.25743/ICT.2019.24.3.007
Author(s): Pivovarov Yurii Vladimirovich Position: Research Scientist Address: 630090, Russia, Novosibirsk
Phone Office: (3832) 33 30 46
References: [1] Zhdan, S.A. The problem of movement of viscous fluid in a rotating circle in the field of gravity. Vestnik Moskovskogo Universiteta. Seriya 1. Matematika. Mekhanika. 1987; (1):86-89. (In Russ.)
[2] Greenspan, H.P. On a rotational flow disturbed by gravity. Journal of Fluid Mechanics. 1976; 74(2):335–352.
[3] Gans, R.F., Yalisove, S.M. Observations and Measurments of Flow in Partially-Filled Horizontally Rotating Cylinder. TRANSACTIONS ASME. Ser. 1. Journal of Fluids Engineering. 1982; 104(3):363–366.
[4] Balmer, R.T., Wang, T.G. An experimental study of internal hidrocyts. TRANSACTIONS ASME. Ser 1. Journal of Fluids Engineering. 1976; 98(4):688–694.
[5] Badratinova, L.G. O dvizhenii zhidkogo sloya po vnutrenney poverkhnosti gorizontal'nogo vrashchayushchegosya tsilindra. Sbornik nauchnykh trudov: Dinamika sploshnoy sredy [On motion of fluid layer over an internal surface of horizontal rotating cylinder]. Novosibirsk: AN SSSR. Sib. otd-nie. In-t gidrodinamiki. 1993; (106):179-184. (In Russ.) [6] Shrager, G.R., Kozloborodov, A.N., Yakutenok, V.A. Modelirovanie gidrodinamicheskikh protsessov v tekhnologii pererabotki polimernykh materialov [Simulation of hydrodynamic processes in technology of refinement of polymeric materials]. Tomsk: Izdatel'stvo Tomskogo universiteta; 1999: 230. (In Russ.)
[7] Voevodin, A.F., Ostapenko, V.V., Pivovarov, Yu.V., Shurgin, S.M. Problemy vychislitel'noy matematiki [Problems of computational mathematics]. Novosibirsk: Izdatel’stvo SO RAN; 1995: 154. (In Russ.)
[8] Pivovarov, Yu.V. Modelirovanie konvektsii rasplava poluprovodnikovogo materiala pri zonnoy plavke [Convection modelling of a semiconductor material melting zone]. Dis. ... kand. fiz.-mat. nauk. Novosibirsk: Institut Gidrodinamiki; 2006: 135. (In Russ.)
[9] Navier, C.-L.-M.-H. Mémoire sur les lois de l’équilibre et du mouvement des corps solides élastiques (1821). Mém. Acad. Sci. Inst. France. 1827; 7(2):375–393.
[10] Astarita G., Marrucci G. Principles of non-Newtonian fluid mechanics. McGraw – Hill; 1974: 296.
[11] Pukhnachev, V.V., Solonnikov, V.A. On the problem of dynamic contact angle. Journal of Applied Mathematics and Mechanics. 1982; 46(6):771–779.
[12] Baiocchi, C., Pukhnachev, V.V. Problems with one-side limitations for Navier-Stokes equations and the dynamic contact-angle problem Journal of Applied Mechanics and Technical Physics. 1990; 31(2):185–197.
[13] Bogoryad, I.B. Dinamika vyazkoy zhidkosti so svobodnoy poverkhnost'yu [Dynamics of viscous fluid with a free boundary]. 1980: 102. (In Russ.) [14] Beirao da Veiga, Í. Regularity for Stokes and generalized Stokes systems under nonhomogeneous slip-type boundary conditions. Advances in Differential Equations. 2004; 9(9-10):1079–1114.
[15] Fugita, H. Non-stationary Stokes flows under leak boundary conditions of friction type. Journal of Computational Mathematics. 2001; (19):1-8.
[16] Itoh, S. The initial value problem for the Navier-Stokes equations with general slip boundary conditions in Holder spaces. Journal of Mathematical Fluid Mechanics. 2003; (5):275-301.
[17] Pivovarov, Yu.V. Calculating the approach of two spherical droplets located in a Bingham fluid. Journal of Applied Mechanics and Technical Physics. 2014; 55(5):750 -763.
[18] Pivovarov, Yu.V. Monotonicity conditions of factored difference scheme for an evolutionary equation with two space variables. Computational Technologies. 2001; 6(4):81 - 91. (In Russ.)
[19] Pivovarov, Yu.V. Calculation of a flow of liquid with variable viscosity in a domain with curvilinear boundary. Computational Technologies. 2005; 10(3):87 - 107. (In Russ.)
[20] Zverev, V.G. An iterative algorithm for the solution of difference elliptical equations. Computational Technologies. 1999; 4(1):55 - 65. (In Russ.)
Bibliography link: Pivovarov Y.V. Computation of motion of viscous fluid partially filling a rotating cavity at large Reynolds numbers // Computational technologies. 2019. V. 24. ¹ 3. P. 88-105
|