Optimal Structures for Failure Resistance Under Impact

TL;DR

This paper develops a gradient-based topology optimization framework for designing impact-resistant structures with tailored geometries and multi-material compositions, demonstrating improved blast and impact performance.

Contribution

It introduces a novel variational model with gradient phase-field damage and an efficient transient dynamic simulation method for optimizing impact-resistant structures.

Findings

Optimized 2D structures show enhanced blast resistance.

Trade-offs between strength and toughness are characterized.

Multi-material designs improve impact performance.

Abstract

The complex physics and numerous failure modes of structural impact creates challenges when designing for impact resistance. While simple geometries of layered material are conventional, advances in 3D printing and additive manufacturing techniques have now made tailored geometries or integrated multi-material structures achievable. Here, we apply gradient-based topology optimization to the design of such structures. We start by constructing a variational model of an elastic-plastic material enriched with gradient phase-field damage, and present a novel method to efficiently compute its transient dynamic time evolution. We consider a finite element discretization with explicit updates for the displacements. The damage field is solved through an augmented Lagrangian formulation, splitting the operator coupling between the nonlinearity and non-locality. Sensitivities over this trajectory are computed through the adjoint method, resulting in an adjoint problem which we solve in a similar manner to the forward dynamics. We demonstrate this formulation by studying the optimal design of 2D solid-void structures undergoing blast loading. Then, we explore the trade-offs between strength and toughness in the design of a spall-resistant structure composed of two materials of differing properties undergoing dynamic impact.