Topology optimization of variable thickness Reissner-Mindlin plate using multiple in-plate bi-directional functionally graded materials

TL;DR

This paper develops a multi-material topology optimization method for in-plane bi-directional functionally graded Reissner-Mindlin plates with variable thickness, using an alternating active-phase algorithm and advanced finite element techniques.

Contribution

It introduces a novel multi-phase topology optimization framework for IBFG plates considering local material properties and shear effects, with detailed mathematical formulation and numerical validation.

Findings

Effective interaction of IBFG materials demonstrated

Method successfully minimizes compliance in optimized plates

Numerical examples verify accuracy and efficiency

Abstract

This paper firstly presents an implementation of multi-material topology optimization (MTO) for in-plane bi-directional functionally graded (IBFG) non-uniform thickness Reissner-Mindlin plates. The mathematical formulation of the MTO is associated with a first shear deformation theory (FSDT) to solve the minimization of compliance as the objective function. From a multi-phase TO problem with multi-volume fraction constraints, the problem is transferred into many binary phases TO sub-problems with only one volume fraction constraint using an alternating active-phase algorithm in conjunction with the block Gauss-Seidel method. In the study's scope, IBFG materials following effective local bulk and shear modulus are considered to show a more accurate interaction of materials. Besides, the numerical technique of the well-established mixed interpolation of tensorial components 4-node elements (MITC4) is utilized to overcome the shear locking problem occurring to thin plate models. The study formulates in great detailed mathematical expressions for IBFG plates MTO. Several numerical examples of IBFG plates are presented to verify the efficiency and reliability of the current methodology.