Meshless local radial basis function collocation method for convective‐diffusive solid‐liquid phase change problems

International Journal of Numerical Methods for Heat and Fluid Flow - Tập 16 Số 5 - Trang 617-640 - 2006
Robert Vertnik1, Božidar Šarler1
1(Laboratory for Multiphase Processes, Nova Gorica Polytechnic, Nova Gorica, Slovenia)

Tóm tắt

PurposeThe purpose of this paper is to develop a new local radial basis function collocation method (LRBFCM) for one‐domain solving of the non‐linear convection‐diffusion equation, as it appears in mixture continuum formulation of the energy transport in solid‐liquid phase change systems.Design/methodology/approachThe method is structured on multiquadrics radial basis functions. The collocation is made locally over a set of overlapping domains of influence and the time stepping is performed in an explicit way. Only small systems of linear equations with the dimension of the number of nodes in the domain of influence have to be solved for each node. The method does not require polygonisation (meshing). The solution is found only on a set of nodes.FindingsThe computational effort grows roughly linearly with the number of the nodes. Results are compared with the existing steady analytical solutions for one‐dimensional convective‐diffusive problem with and without phase change. Regular and randomly displaced node arrangements have been employed. The solution is compared with the results of the classical finite volume method. Excellent agreement with analytical solution and reference numerical method has been found.Practical implicationsA realistic two‐dimensional non‐linear industrial test associated with direct‐chill, continuously cast aluminium alloy slab is presented.Originality/valueA new meshless method is presented which is simple, efficient, accurate, and applicable in industrial convective‐diffusive solid‐liquid phase‐change problems with non‐linear material properties.

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Tài liệu tham khảo

Altenpohl, D.G. (1998), Aluminum: Technology, Applications, and Environment: A Profile of a Modern Metal, Aluminium Association & TMS, Warrendale.

Atluri, S.N. (2004), The Meshless Method for Domain and BIE Discretisations, Tech Science Press, Forsyth, GA.

Atluri, S.N. and Shen, S. (2002), The Meshless Method, Tech Science Press, Forsyth, GA.

Bennon, W.D. and Incropera, F.P. (1987), “A continuum model for momentum, heat and species transport in binary solid‐liquid phase change systems – I. Formulation”, International Journal of Heat and Mass Transfer, Vol. 30, pp. 2161‐70.

Brandes, E.A. and Brook, G.B. (1992), Smithells Metals Reference Book, 7th ed., Butterworth‐Heinemenn, Oxford.

Buhmann, M.D. (2003), Radial Basis Function: Theory and Implementations, Cambridge University Press, Cambridge.

Chen, W. (2002), “New RBF collocation schemes and kernel RBFs with applications”, Lecture Notes in Computational Science and Engineering, Vol. 26, pp. 75‐86.

Dalhuijsen, A.J. and Segal, A. (1986), “Comparison of finite element techniques for solidification problems”, International Journal for Numerical Methods in Engineering, Vol. 29, pp. 1807‐29.

Fasshauer, G.E. (1997), “Solving partial differential equations by collocation with radial basis functions”, in Mehaute, A.L., Rabut, C. and Schumaker, L.L. (Eds), Surface Fitting and Multiresolution Methods, Vanderbilt University Press, Nashville, TN, pp. 131‐8.

Fic, A., Nowak, A.J. and Białecki, R. (2000), “Heat transfer analysis of the continuous casting process by the front tracking BEM”, Engineering Analysis with Boundary Elements, Vol. 24, pp. 215‐23.

Kansa, E.J. (1990), “Multiquadrics – a scattered data approximation scheme with applications to computational fluid dynamics‐II. Solutions to parabolic, hyperbolic and elliptic partial differential equations”, Computers and Mathematics with Application, Vol. 19, pp. 147‐61.

Kovačević, I., Poredoš, A. and Šarler, B. (2003), “Solving the Stefan problem by the RBFCM”, Numerical Heat Transfer, Part B: Fundamentals, Vol. 44, pp. 575‐99.

Lee, C.K., Liu, X. and Fan, S.C. (2003), “Local muliquadric approximation for solving boundary value problems”, Computational Mechanics, Vol. 30, pp. 395‐409.

Liu, G.R. (2003), Mesh Free Methods, CRC Press, Boca Raton, FL.

Mai‐Duy, N. and Tran‐Cong, T. (2001), “Numerical solution of differential equations using multiquadrics radial basis function networks”, International Journal for Numerical Methods in Engineering, Vol. 23, pp. 1807‐29.

Mai‐Duy, N. and Tran‐Cong, T. (2002), “Mesh‐free radial basis function network methods with domain decomposition for approximation of functions and numerical solution of Poisson's equations”, Engineering Analysis with Boundary Elements, Vol. 26, pp. 133‐56.

Mai‐Duy, N. and Tran‐Cong, T. (2003), “Indirect RBFN method with thin plate splines for numerical solution of differential equations”, Computer Modeling in Engineering & Sciences, Vol. 4, pp. 85‐102.

Nayroles, B., Touzot, G. and Villon, P. (1991), “The diffuse approximation”, C.R. Acad. Sci. Paris, Vol. 313‐II, pp. 293‐6.

Özisik, M.N. (1994), Finite Difference Methods in Heat Transfer, CRC Press, Boca Raton, FL.

Pardo, E. and Weckman, D.C. (1986), “A fixed grid finite element technique for modelling phase change in steady‐state conduction‐advection problems”, International Journal for Numerical Methods in Engineering, Vol. 23, pp. 1807‐29.

Perko, J. (2005), “Modelling of transport phenomena by the diffuse approximate method”, doctoral dissertation, School of Applied Sciences, Nova Gorica Polytechnic, Nova Gorica.

Power, H. and Barraco, W.A. (2002), “Comparison analysis between unsymmetric and symmetric RBFCMs for the numerical solution of PDE's”, Computers and Mathematics with Applications, Vol. 43, pp. 551‐83.

Sadat, H. and Prax, C. (1996), “Application of the diffuse approximation for solving fluid flow and heat transfer problems”, International Journal of Heat and Mass Transfer, Vol. 39, pp. 214‐8.

Šarler, B. (2004), “Meshless methods”, in Nowak, A.J. (Ed.), Advanced Numerical Methods in Heat Transfer, Chapter 9, Silesian Technical University Press, Gliwice, pp. 225‐47.

Šarler, B. (2005), “A radial basis function collocation approach in computational fluid dynamics”, Computer Modeling in Engineering & Sciences, Vol. 7, pp. 185‐93.

Šarler, B. and Kuhn, G. (1998), “Dual reciprocity boundary element method for convective‐diffusive solid‐liquid phase change problems, Part 2. Numerical examples”, Engineering Analysis with Boundary Elements, Vol. 21, pp. 65‐79.

Šarler, B. and Mencinger, J. (1999), “Solution of temperature field in DC cast aluminium alloy billet by the dual reciprocity boundary element method”, International Journal of Numerical Methods in Heat & Fluid Flow, Vol. 9, pp. 267‐97.

Šarler, B., Perko, J. and Chen, C.S. (2004), “Radial basis function collocation method solution of natural convection in porous media”, International Journal of Numerical Methods for Heat & Fluid Flow, Vol. 14, pp. 187‐212.

Šarler, B. and Vertnik, R. (2005), “Meshfree explicit radial basis function collocation method for diffusion problems”, Computers and Mathematics with Applications(in press)..

Šarler, B., Vertnik, R. and Perko, J. (2005), “Application of diffuse approximate method in convective‐diffusive solidification problems”, Computers, Materials, Continua, Vol. 2, pp. 77‐83.

Shu, C., Ding, H. and Yeo, K.S. (2003), “Local radial basis function‐based differential quadrature method and its application to solve two‐dimensional incompressible Navier‐Stokes equations”, Computer Methods in Applied Mechanics and Engineering, Vol. 192, pp. 941‐54.

Tolstykh, A.I. and Shirobokov, D.A. (2005), “Using radial basis functions in a ‘finite difference mode’”, Computer Modeling in Engineering & Sciences, Vol. 7, pp. 207‐22.

Versteeg, H.K. and Malalasekera, W. (1995), An Introduction to Computational Fluid Dynamics: The Finite Volume Method, Longman Scientific & Technical, Harlow.

Vertnik, R., Perko, J. and Šarler, B. (2004), “Solution of temperature field in DC cast aluminium alloy billet by the diffuse approximate method”, Materials and Technology, Vol. 38, pp. 257‐61.

Voller, V.R., Swaminathan, S. and Thomas, B.G. (1990), “Fixed‐grid techniques for phase‐change problems – a review”, International Journal of Numerical Methods in Engineering, Vol. 30, pp. 875‐98.

Wang, J.G. and Liu, G.R. (2002), “On the optimal shape parameter of radal basis functions used for 2‐D mesheless method”, Computer Methods in Applied Mechanics and Engineering, Vol. 26, pp. 2611‐30.

Wrobel, L.C. (2001), The Boundary Element Method –Volume 1: Applications in Thermofluids and Acoustics, Willey, New York, NY.

Zhang, X., Song, K.Z., Lu, M.W. and Liu, X. (2000), “Meshless methods based on collocation with radial basis functions”, Computational Mechanics, Vol. 26, pp. 333‐43.

Zienkiewicz, O.C. and Taylor, R.L. (2000), The Finite Element Method, Volume 1: The Basis, Vol. 1, Butterworth‐Heinemann, Oxford.

Šarler, B., Kovačević, I. and Chen, C.S. (2004), “A mesh‐free solution of temperature in direct‐chill cast slabs and billets”, in Mammoli, A.A. and Brebbia, C.A. (Eds), Moving Boundaries VII, WIT Press, Southampton, pp. 271‐80.

Tolstykh, A.I. and Shirobokov, D.A. (2003), “On using radial basis functions in a ‘finite difference mode’ with applications to elasticity problems”, Computational Mechanics, Vol. 33, pp. 68‐79.

Venneker, B.C.H. and Katgerman, L. (2002), “Modelling issues in macrosegregation predictions in direct‐chill casting”, Journal of Light Metals, Vol. 2, pp. 149‐59.

Zerroukat, M., Power, H. and Chen, C.S. (1998), “A numerical method for heat transfer problems using collocation and radial basis functions”, International Journal for Numerical Methods in Engineering, Vol. 42, pp. 1263‐78.

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International Journal of Numerical Methods for Heat and Fluid Flow

Tập 16 Số 5

617-640

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