The Method of Fundamental Solutions for Steady-State Heat Conduction in Nonlinear Materials

被引:0
作者
Karageorghis, A. [1 ]
Lesnic, D. [2 ]
机构
[1] Univ Cyprus, Dept Math & Stat, CY-1678 Nicosia, Cyprus
[2] Univ Leeds, Dept Appl Math, Leeds LS2 9JT, W Yorkshire, England
来源
COMMUNICATIONS IN COMPUTATIONAL PHYSICS | 2008年 / 4卷 / 04期
关键词
Nonlinear heat conduction; radiation; method of fundamental solutions;
D O I
暂无
中图分类号
O4 [物理学];
学科分类号
0702 ;
摘要
The steady-state heat conduction in heat conductors with temperature dependent thermal conductivity and mixed boundary conditions involving radiation is investigated using the method of fundamental solutions. Various computational issues related to the method are addressed and numerical results are presented and discussed for problems in two and three dimensions.
引用
收藏
页码:911 / 928
页数:18
相关论文
共 50 条
[41]   Double side approach method to obtain solutions for transient nonlinear heat conduction using genetic algorithms [J].
Chen, CK ;
Hung, CI ;
Lee, ZY .
APPLIED MATHEMATICS AND COMPUTATION, 2002, 133 (2-3) :431-444
[42]   The Method of Fundamental Solutions for Two- and Three-Dimensional Transient Heat Conduction Problems Involving Point and Curved Line Heat Sources [J].
Mehrdad Mohammadi .
Iranian Journal of Science and Technology, Transactions of Mechanical Engineering, 2021, 45 :993-1005
[43]   The Method of Fundamental Solutions for Two- and Three-Dimensional Transient Heat Conduction Problems Involving Point and Curved Line Heat Sources [J].
Mohammadi, Mehrdad .
IRANIAN JOURNAL OF SCIENCE AND TECHNOLOGY-TRANSACTIONS OF MECHANICAL ENGINEERING, 2021, 45 (04) :993-1005
[44]   Dynamic Adaptation Method in Gasdynamic Simulations with Nonlinear Heat Conduction [J].
Breslavskii, P. V. ;
Mazhukin, V. I. .
COMPUTATIONAL MATHEMATICS AND MATHEMATICAL PHYSICS, 2008, 48 (11) :2102-2115
[45]   Dynamic adaptation method in gasdynamic simulations with nonlinear heat conduction [J].
P. V. Breslavskii ;
V. I. Mazhukin .
Computational Mathematics and Mathematical Physics, 2008, 48 :2102-2115
[46]   Estimation of the heat transfer coefficient by means of the method of fundamental solutions [J].
Valle, Marcus F. ;
Colaco, Marcelo J. ;
Neto, Francesco S. .
INVERSE PROBLEMS IN SCIENCE AND ENGINEERING, 2008, 16 (06) :777-795
[47]   Fracture analysis of functionally graded materials by the method of fundamental solutions [J].
Wen, J. C. ;
Sladek, J. ;
Sladek, V. ;
Aliabadi, M. H. ;
Wen, P. H. .
THEORETICAL AND APPLIED FRACTURE MECHANICS, 2023, 123
[48]   Simulation of nonlinear non-steady-state conduction: expansion on the branch modes. [J].
Neveu, A ;
El-Khoury, K ;
Flament, B .
INTERNATIONAL JOURNAL OF THERMAL SCIENCES, 1999, 38 (04) :289-304
[49]   Bifurcation indicator for geometrically nonlinear elasticity using the Method of Fundamental Solutions [J].
Askour, Omar ;
Tri, Abdeljalil ;
Braikat, Bouazza ;
Zahrouni, Hamid ;
Potier-Ferry, Michel .
COMPTES RENDUS MECANIQUE, 2019, 347 (02) :91-100
[50]   Steady-state heat flux measurements in radiative and mixed radiative-convective environments [J].
Lam, Cecilia S. ;
Weckman, Elizabeth J. .
FIRE AND MATERIALS, 2009, 33 (07) :303-321
12345