Modular-topology optimization of structures and mechanisms with free material design and clustering

TL;DR

This paper presents a bi-level strategy combining free material design, clustering, and topology optimization to create modular structures and mechanisms, enabling sustainable, customizable, and reusable designs for Industry 4.0 applications.

Contribution

It introduces a novel deterministic clustering algorithm and a modular mapping approach for topology optimization of modular structures and mechanisms.

Findings

Successfully optimized compliance of modular structures.

Designed non-periodic compliant modular mechanisms.

Developed reusable modules for inverters and grippers.

Abstract

Topology optimization of modular structures and mechanisms enables balancing the performance of automatically-generated individualized designs, as required by Industry 4.0, with enhanced sustainability by means of component reuse. For optimal modular design, two key questions must be answered: (i) what should the topology of individual modules be like and (ii) how should modules be arranged at the product scale? We address these challenges by proposing a bi-level sequential strategy that combines free material design, clustering techniques, and topology optimization. First, using free material optimization enhanced with post-processing for checkerboard suppression, we determine the distribution of elasticity tensors at the product scale. To extract the sought-after modular arrangement, we partition the obtained elasticity tensors with a novel deterministic clustering algorithm and interpret its outputs within Wang tiling formalism. Finally, we design interiors of individual modules by solving a single-scale topology optimization problem with the design space reduced by modular mapping, conveniently starting from an initial guess provided by free material optimization. We illustrate these developments with three benchmarks first, covering compliance minimization of modular structures, and, for the first time, the design of non-periodic compliant modular mechanisms. Furthermore, we design a set of modules reusable in an inverter and in gripper mechanisms, which ultimately pave the way towards the rational design of modular architectured (meta)materials.