Modelling Fatigue Behaviours and Lifetimes of Novel GLARE Laminates under Random Loading Spectrum

TL;DR

This study combines experimental and numerical methods to analyze fatigue behaviors and lifetimes of novel GLARE laminates under random loading, revealing load-dependent failure mechanisms and validating a new mixed damage model.

Contribution

A new mixed algorithm based on fatigue damage concepts for three-phase materials to model fatigue damage and life of GLARE laminates under random loading spectrum.

Findings

Numerical predictions align well with experimental results.

Failure mechanisms depend on load levels and fiber or metal layer strength.

Fatigue life is influenced by the reference load level of the spectrum.

Abstract

This paper aims to experimentally and numerically probe fatigue behaviours and lifetimes of novel GLARE (glass laminate aluminium reinforced epoxy) laminates under random loading spectrum. A mixed algorithm based on fatigue damage concepts of three-phase materials was proposed for modelling progressive fatigue damage mechanisms and fatigue life of fibre metal laminates (FML) under random loading spectrum. To validate the proposed modelling algorithm, fatigue tests were conducted on the GLARE 2/1 and GLARE 3/2 laminates subjected to random loading spectrum, and fatigue mechanisms were discussed by using scanning electron microscope (SEM) analysis. It is shown that predominant fatigue failure of the GLARE laminate depends on the reference load level of random loading spectrum. Specifically, dominant fatigue failure of the GLARE laminate is dependent on fatigue strength of fibre layer at a high reference load level, but metal layer at a low reference load level. Numerical predictions agree well with experimental results, demonstrating that the proposed mixed modelling algorithm can effectively simulate fatigue behaviours and lives of the GLARE laminate under random loading spectrum.