Abstract
We study three-dimensional potential gas flow in a nozzle. The matrix of the system of linear equations obtained in approximating the equation for the velocity potential by symmetric differences has a strongly sparse form. This property is used for an approximate expansion of it as a product of triangular matrices. To guarantee stability in the supersonic region of flow additional terms of artificial viscosity type are introduced into the equation for the velocity potential. We study gas flows in axisymmetric and three-dimensional nozzles: elliptic, superelliptic, and nozzles with nonsymmetric subsonic part. Comparison of the results with the data of other authors has shown the high effectiveness of such an approach.
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Literature Cited
M. Ya. Ivanov and V. V. Koretskii, “Computation of flows in two-dimensional and three-dimensional nozzles using the method of approximate factorization,”Zh. Vychisl. Mat., Mat. Fiz.,25, No. 9, 1365–1381 (1985).
V. A. Veretentsev, V. A. Mechenova, and G. S. Roslyakov, “Numerical study of gas flows in channels and nozzles using the equations for the potential,” in:Nonstationary Gas Flows with Shock Waves [in Russian], Leningrad (1990), pp. 317–328.
V. A. Veretentsev and G. S. Roslyakov, “Application of the method of factorization to the computation of a potential gas flow in the transonic region of a nozzle,” in:Direct and Inverse Problems of Mathematical Physics [in Russian], Moscow University Press (1991), pp. 229–241.
V. A. Veretentsev and G. S. Roslyakov, “Computation of nonpotential transonic gas flows in nozzles using the solution of the equations for the current function and a generalized potential,” in:Mathematical Models and Optimization of Computational Algorithms [in Russian], Moscow University Press (1993), pp. 232–239.
H. L. Stone, “Iterative solution of implicit approximation of multidimensional partial differential equations,”SIAM J. Num. Anal.,5, 530–558 (1968).
V. A. Mechenova and G. S. Roslyakov, “Flow past a flattened body in the subsonic region of a nozzle,” in:Mathematical Models and Optimization of Computational Algorithms [in Russian], Moscow University Press (1993), pp. 224–231
M. Zedan and G. E. Schneider, “A three-dimensional modified strongly implicit procedure for heat conduction,”AIAA J.,21, No. 2, 295–303 (1983).
Terry L. Holst, “Fast, conservative algorithm for solving the transonic full-potential equation,”AIAA J.,18, No. 12, 1431–1439 (1980).
U. G. Pirumov and G. S. Roslyakov,Gas Dynamics of Nozzles [in Russian], Nauka, Moscow (1990).
P. Lavalle, “The nonstationary method of computing transonic flows in nozzles,” in:Numerical Methods in Fluid Mechanics [Russian translation], Mir, Moscow (1973), pp. 9–17.
V. A. Mechenova and G. S. Roslyakov, “Application of completely implicit methods for solving a direct problem of the theory of a nozzle,” in:Numerical Methods in Mathematical Physics [in Russian], Moscow University Press (1996), pp. 39–51.
V. V. Koretskii and D. A. Lyubimov, “The modified approximate factorization method for computing potential three-dimensional flows in channels,”Zh. Vychisl. Mat. Mat. Fiz.,30, No. 10, 1553–1570 (1990).
V. M. Dvoretskii, “On the study of three-dimensional mixed flows in nozzles with nonsymmetric entrance,”Izv. Akad. Nauk SSSR, MZhG, No. 2, 167–169 (1975).
M. Ya. Ivanov and O. A. Ryl'ko, “Computation of transonic flow in three-dimensional nozzles,”Zh. Vychisl. Mat. Mat. Fiz.,12, No. 5, 1280–1291 (1972).
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Translated fromMetody Matematicheskogo Modelirovaniya, 1998, pp. 76–86.
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Roslyakov, G.S., Fedorenko, V.V. The study of three-dimensional gas flow in a nozzle using the completely implicit method. Comput Math Model 9, 296–303 (1998). https://doi.org/10.1007/BF02409863
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DOI: https://doi.org/10.1007/BF02409863