A truly meshless method formulation for analysis of nonFourier heat conduction in solids

The non-Fourier effect in heat conduction is important in strong thermal environments and thermal shock problems. Generally, commercial FE codes are not available for analysis of nonFourier heat conduction. In this study, a meshless formulation is presented for the analysis of the nonFourier heat conduction in the materials. The formulation is based on the symmetric local weak form of the secondorder nonFourier heat conduction equation in terms of the temperature. Using the local weak form of heat transfer equations in the subdomains, the governing equation of the nonFourier heat conduction is discretized in the space domain to the second order ordinary differential equations for the time. The discretized equations are integrated into the time domain with an appropriate finite difference method. The fictitious numerical oscillations are completely suppressed from the front of temperature waves in the presented method. An analytical series solution is developed for the nonFourier heat transfer in one-dimensional heat transfer for special boundary conditions and the accuracy of presented numerical meshless method is validated by comparison of the results of the numerical meshless solution and the series solution. The numerical results are presented for non-Fourier heat conduction for various Vernotte numbers and boundary conditions and the results are compared with the results of the classical Fourier heat conduction.