Main Catalog Mathematics and Mechanics Mechanics of Liquid, Gas and Plasma

High-Order Numerical Scheme for Vortex Layer Intensity Computation in Two-Dimensional Aerohydrodynamics Problems Solved by Vortex Element Method

Authors: Kuzmina K.S., Marchevsky I.K.	Published: 06.12.2016
Published in issue: #6(69)/2016
DOI: 10.18698/1812-3368-2016-6-93-109
Category: Mathematics and Mechanics \| Chapter: Mechanics of Liquid, Gas and Plasma
Keywords: vortex method, vortex layer, high order scheme, least squares method, curvature, piecewise-polynomial approximation

The study deals with the numerical simulation of two-dimensional viscous incompressible flow around airfoils by using vortex element method. The numerical scheme and the corresponding algorithm for this method usually presuppose the replacement of the airfoil with the polygon which consists of panels, and the unknown vortex layer intensity is assumed to be piecewise-constant on the panels. The accuracy of this scheme varies from O(h²) to O(h³) for different airfoils (h is the panels’ length). In the present research we developed a new high-order numerical scheme. The new approach assumes the vortex layer intensity to be not piecewise-constant, but piecewise-linear or piecewise-quadratic on each panel. It is also important that the solution is not assumed to be continuous along the airfoil; it is most needed for correct simulation of the flow around airfoil with the angular points and sharp edges. Moreover, we take into account the fact that the airfoil’s boundary is curvilinear: each part of the airfoil’s boundary is approximated by a cubic spline instead of a straight panel. In order to obtain linear algebraic equations, we used the least squares method instead of collocation-type conditions in separate control points or on average on the panels. We applied higher order of accuracy Gaussian quadrature formulas for approximate integrals calculation. The results of the research show that the developed scheme has higher accuracy order than the previously known schemes. For some particular model problems (flow around circular, elliptical and Zhukovsky airfoils) this approach allows us to obtain solution with accuracy O(h⁵).

References

[1] Lifanov I.K., Belotserkovsky S.M. Methods of discrete vortices. CRC, 1992.

[2] Cottet G.-H., Koumoutsakos P. Vortex methods: theory and practice. Cambridge University Press, 2000.

[3] Dynnikova G.Ya. Vortex motion in two-dimensional viscous fluid flows. Fluid Dynamics, 2003, vol. 38, no. 5, pp. 670-678.

[4] Kalugin V.T., Mordvintcev G.G., Popov V.M. Modelirovanie protsessov obtekaniya i upravleniya aerodinamicheskimi kharakteristikami letatel’nykh apparatov [Modeling of the flow and the aerodynamic characteristics control for aircrafts]. Moscow, MGTU im. N.E. Baumana Publ., 2011. 527 p.

[5] Andronov P.R., Guvernyuk S.V., Dynnikova G.Ya. Vikhrevye metody rascheta nestatsionarnykh gidrodimamicheskikh nagruzok [Vortex methods for unsteady hydrodynamic loads]. Moscow, MGU im. M.V. Lomonosova Publ., 2006.

[6] Ogami Y., Akamatsu T. Viscous flow simulation using the discrete vortex model - the diffusion velocity method. Comput. and Fluids, 1991, vol. 19, no. 3/4, pp. 433-441.

[7] Kuzmina K.S., Marchevsky I.K. On numerical schemes in 2D vortex element method for flow simulation around moving and deformable airfoils. Proc. of Summer School-Conference "Advanced Problems in Mechanics 2014". St. Petersburg, 2014. pp. 335-344. Available at: http://www.ipme.ru/ipme/conf/APM2014/2014-PDF/2014-335.pdf

[8] Kuzmina K.S., Marchevsky I.K., Moreva V.S. On the accuracy of numerical schemes for flow simulation around airfoils with angle point. Nauka i obrazovanie. MGTU im. N.E. Baumana [Science & Education of the Bauman MSTU. Electronic Journal], 2015, no. 2, pp. 234-249. DOI: 10.7463/0215.0756954 Available at: http://technomag.neicon.ru/en/doc/756954.html

[9] Kempka S.N., Glass M.W., Peery J.S., Strickland J.H. Accuracy considerations for implementing velocity boundary conditions in vorticity formulations. SANDIA REPORT SAND96-0583 UC-700, 1996.

[10] Moreva V.S. Matematicheskoe modelirovanie obtekaniya profiley s ispol’zovaniem novykh raschetnykh skhem metoda vikhrevykh elementov. Diss. kand. fiz.-mat. nauk [Mathematical modeling of flow of profiles using the new calculation schemes of vortex element method. Cand. phys.-math. sci. diss.]. Moscow, 2013.

[11] Marchevsky I.K., Moreva V.S. Vortex element method for 2D flow simulation with tangent velocity components on airfoil surface. ECCOMAS 2012. V European Congress on Computational Methods in Applied Sciences and Engineering, e-Book Full Papers, 2012, pp. 5952-5965.

[12] Vaz G., Falcao de Campos J.A.C., Eca L. A numerical study on low and higher-order potential based BEM for 2D inviscid flows. Computational Mechanics, 2003, vol. 32, iss. 4-6, pp. 327-335.

[13] Makarova M.E. Calculation of flow past airfoils of simplest topology using the modified vortex-element method. Jelektr. nauchno-tekh. izd. "Inzhenernyy zhurnal: nauka i innovacii" [El. Sc.-Tech. Publ. "Eng. J.: Science and Innovation"], 2012, iss. 4. DOI: 10.18698/2308-6033-2012-4-166 Available at: http://engjournal.ru/eng/catalog/mathmodel/hidden/166.html

[14] Abramowitz M., Stegun I.A. Handbook of mathematical functions with formulas, graphs, and mathematical tables. N.Y., Dover, 1965.

[15] Lavrent’ev M.A., Shabat B.V. Metody teorii funktsiy kompleksnogo peremennogo [Methods of the theory of functions of a complex variable]. Moscow, Nauka Publ., 1965. 716 p.