Litcius/Paper detail

A new meshless “fragile points method” and a local variational iteration method for general transient heat conduction in anisotropic nonhomogeneous media. Part II: Validation and discussion

Yue Guan, Rade Grujičić, Xuechuan Wang, Leiting Dong, Satya N. Atluri

2020Numerical Heat Transfer Part B Fundamentals22 citationsDOI

Abstract

In the first part of this two-paper series, a new computational approach is presented for analyzing transient heat conduction problems in anisotropic nonhomogeneous media. The approach consists of a truly meshless Fragile Points Method (FPM) being utilized for spatial discretization, and a Local Variational Iteration (LVI) scheme for time discretization. In the present article, extensive numerical results are provided as validations, followed by a discussion on the recommended computational parameters. The FPM + LVIM approach shows its capability in solving 2 D and 3 D transient heat transfer problems in complex geometries with mixed boundary conditions, including preexisting cracks. Both functionally graded materials and composite materials are considered. It is shown that, with appropriate computational parameters, the FPM + LVIM approach is not only accurate, but also efficient, and has reliable stability under relatively large time intervals.

Topics & Concepts

DiscretizationTransient (computer programming)Thermal conductionAnisotropyBoundary (topology)MathematicsApplied mathematicsRegularized meshless methodBoundary value problemMathematical optimizationSingular boundary methodMathematical analysisComputer scienceFinite element methodBoundary element methodPhysicsThermodynamicsQuantum mechanicsOperating systemNumerical methods in engineeringAdvanced Numerical Methods in Computational MathematicsModel Reduction and Neural Networks