Publication: Crack morphology in lattice-core specimens made of biopolymer via fused deposition modelling
Loading...
Identifiers
Publication date
2022
Defense date
Advisors
Tutors
Journal Title
Journal ISSN
Volume Title
Publisher
Elsevier
Impact
Export
Abstract
During the last decades, it has been shown how additive manufacturing is becoming a cost-efficient alternative to produce customized parts or prototyping with traditional manufacturing processes. However, the integrity assessment of 3D printing technology parts is still challenging due to the huge number of parameters involved during the process along with the lack of industry standards. Therefore, further investigations are required to optimize the in-service behaviour of additive manufacturing parts. The objective of this work is to analyse the failure of components made from additive manufacturing under three-point bending tests in terms of crack morphology and strength. Specimens were made by a biopolymer (polylactic acid, PLA) via fused deposition modelling with different infill core densities. Next, three-point bending tests were carried out at a low strain rate under monotonic loading. In addition, three-dimensional digital image correlation was applied during tests in order to track the exterior full-field displacement and strain and output crack trajectories. The results are analysed in terms of fracture morphology and flexural strength of the post-mortem specimens, and they show the high impact of process parameters in the mechanical behaviour and failure of components made from additive manufacturing.
Description
Proceedings of: The 7th International Conference on Crack Paths (CP 2021), 21-24 September 2021, virtual format.
Keywords
Additive manufacturing, Biopolymer, Fracture
Bibliographic citation
Álvarez-Blanco, M., Arias-Blanco, A., Infante-García, D., Marco, M., & Giner, E. (21-24 September 2021). Crack morphology in lattice-core specimens made of biopolymer via fused deposition modelling [proceedings]. The 7th International Conference on Crack Paths (CP 2021), virtual format. Published in Procedia Structural Integrity, 39, 2022, 379-386.