On using mesh-based and mesh-free methods in problems defined by Eringen’s non-local integral model: issues and remedies

• Published in: Meccanica (Milan) Vol. 54; no. 11-12; pp. 1801 - 1822
• Main Authors: Abdollahi, Reza, Boroomand, Bijan
• Format: Journal Article
• Language: English
• Published: Dordrecht Springer Netherlands 01.09.2019; Springer Nature B.V
• Subjects: Automotive Engineering; Boundary layers; Civil Engineering; Classical Mechanics; Computer networks; Cost effectiveness; Crack propagation; Finite element method; Galerkin method; Gateways (computers); Integrals; Mathematical models; Mechanical Engineering; Meshless methods; Methods; Physics; Physics and Astronomy; Singularities; Finite element method; Crack modeling; Element free Galerkin method; Non-local elasticity; Finite point method; Eringen’s integral; Boundary layer
• ISSN: 0025-6455; 1572-9648
• DOI: 10.1007/s11012-019-01048-6

With the recent success of nonlocal theories in modeling of engineering problems involving small intrinsic length scales, such as modeling of crack propagation, this paper addresses issues pertaining to cost-ineffectiveness of Eringen’s integral model. The cost effectiveness of the computation may be considered as a twofold issue; one pertaining to the non-local model and another pertaining to the numerical tool. First of all, we shall show that during the solution of problems with Eringen’s non-local integral model, there is no need to consider the integral model for the whole computational domain. In fact, the problems may be solved by just using the integral model close to the boundaries, i.e. a boundary layer effect, or around the points with singularities. In this paper we propose a partitioning strategy to remarkably reduce the computational cost. This may be considered as a gateway for solving some types of two-scale problems, e.g. those with macro/micro and nano scales, in which the small scale effects are localized just at parts of the domain. To demonstrate the efficiency of the numerical tools, we examine the performance of the finite element method (FEM), the element free Galerkin method (EFG) and the finite point method (FPM). This paves the way for using mesh-free methods in the solution of problems with non-local integral models. Examples with smooth and non-smooth solutions are considered for examining the efficiency of the methods. It will be shown that, by considering the boundary layer effect, the FEM and FPM will be efficient enough for being used in problems defined by Eringen’s non-local integral model.