Experimental and numerical investigation on fatigue damage in micro-lattice materials by Digital Volume Correlation and μCT-based finite element models

This work addresses the fatigue behaviour of two strut-based topologies of micro-lattice materials, focusing in particular on the damage evolution throughout the fatigue life. An experimental campaign is performed on micro-lattice specimens tested in fatigue with different stress ratio (R = 0, R = -1 and R = 10). A methodological approach for metal foams is adopted to analyse the experimental tests and to characterize the fatigue damage evolution. To validate this approach the Digital Volume Correlation technique is applied on two in-situ experimental fatigue tests conducted inside a Micro-Computed Tomography scanner. An analysis based on a finite element model of the as-manufactured geometry and the application of a suitable multiaxial fatigue criterion to evaluate the local stress field shows good results in predicting the fatigue failure location.

Automated summary

This study investigates the fatigue behavior of two strut-based topologies of micro-lattice materials, with a specific focus on the damage evolution during fatigue life. Experimental tests are conducted on micro-lattice specimens under different stress ratios, and a methodological approach for metal foams is adopted to analyze the test results and characterize the fatigue damage evolution. The results show that the finite element model based on the manufactured geometry and the use of a suitable multiaxial fatigue criterion are effective in predicting the location of fatigue failure.