Amirkabir University of Technology Amirkabir Journal of Mechanical Engineering 2008-6032 46 1 2014 10 23 Exponential basis functions in solution of time –dependent heat equation in axially layered materials Exponential basis functions in solution of time –dependent heat equation in axially layered materials 37 46 340 10.22060/mej.2014.340 FA Bashir Movahedian Bijan Boroomand Journal Article 2012 05 29 In this paper we present a novel method based on using Exponential Basis Functions (EBFs) to solve heat conduction problem in axially layered materials. In the first step, we have considered each layer of material as a separate element. Then the solution in each element was approximated by a summation of EBFs satisfying the differential equation of transient heat conduction problem. The unknown coefficients of the series solution were related to initial condition and Dirichlet side conditions of each layer employing a discrete transformation technique. Finally, the general solution of material was completed by satisfying the continuity conditions between adjacent layers in a manner similar to conventional finite element method. In this hybrid method, a collocation scheme was used for satisfying the time dependent boundary conditions as well as the initial conditions. The capability of the presented technique was investigated in the solution of some benchmark problems. In this paper we present a novel method based on using Exponential Basis Functions (EBFs) to solve heat conduction problem in axially layered materials. In the first step, we have considered each layer of material as a separate element. Then the solution in each element was approximated by a summation of EBFs satisfying the differential equation of transient heat conduction problem. The unknown coefficients of the series solution were related to initial condition and Dirichlet side conditions of each layer employing a discrete transformation technique. Finally, the general solution of material was completed by satisfying the continuity conditions between adjacent layers in a manner similar to conventional finite element method. In this hybrid method, a collocation scheme was used for satisfying the time dependent boundary conditions as well as the initial conditions. The capability of the presented technique was investigated in the solution of some benchmark problems. Transient Heat Conduction Layered Materials Meshless Method Exponential Basis Functions Discrete Transformation https://mej.aut.ac.ir/article_340_40008b9a5380fcacce3976bf7c08af5b.pdf