Showing papers by "Simonetta Boria published in 2023"
27 Jun 2023-Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science
TL;DR: In this paper , the behavior of flax/epoxy and hemp-epoxy laminates subjected to tensile, four-point bending, and Low-Velocity Impact (LVI) tests was analyzed from an experimental and numerical point of view.
Abstract: Nowadays, in the global composites industry, an increasing number of companies are studying high-quality innovative and green solutions, in order to achieve the environmental sustainability goals. In this context, the use of a natural fiber reinforced polymer in the design of structural components needs to be validated through experimental mechanical tests. This study provides an overview of the behaviors of flax/epoxy and hemp/epoxy laminates subjected to tensile, four-point bending, and Low-Velocity Impact (LVI) tests, both from an experimental and numerical point of view. For each type of test, finite element models were simulated using the explicit code LS-DYNA in order to characterize the materials, reproduce the load-displacement plots, and analyze the damage evolution of the laminates. Two different types of mesh modeling were investigated for the models: shell and solid elements. In both cases, a proper contact modeling between layers was carried out to account for delamination phenomena of the material. The results obtained show an agreement between the experimental response and the simulated one, highlighting the possibility of designing and manufacturing structural components in composite material reinforced with natural fibers.
TL;DR: In this paper , an optimization procedure for predicting the behavior of flax/epoxy composite laminates under low-velocity impact, using the LS-DYNA solver for numerical simulation, is presented.
TL;DR: In this paper , the effects of temperature variation on the impact behavior of natural fiber laminates from an experimental, analytical, and numerical point of view were investigated, and two different analytical models available in literature for synthetic materials were combined and validated to reproduce the full loading-unloading trend of natural fibre composites.