Article ID | Journal | Published Year | Pages | File Type |
---|---|---|---|---|
5021115 | Composites Part B: Engineering | 2017 | 35 Pages |
Abstract
This article deals with the development of a finite element model for the prediction of low velocity impact damage within unidirectional composite laminates. This model is based on analysis of the impact damage observed experimentally. The modelling scale is that of the bundle of fibers of the unidirectional ply. These bundles are represented with 1D rod elements. The matrix is modeled with 2D damageable shell elements. The laminate is the built using cohesive elements. The strategy is validated by a comparison with low velocity drop weight impact tests. Several experimental parameters are varied: the materials (T700/M21 and HTA7/913), the thickness (1.44mm and 2.4mm), the stacking sequence and the impact velocity (2m.sâ1 and 3m.sâ1). The calculated load-displacement curves and the damage extent correlate well with experimental results.
Related Topics
Physical Sciences and Engineering
Engineering
Engineering (General)
Authors
Bassam Mahmoud, Marcos Colungo Torrecilla, Pablo Navarro, Steven Marguet, Issam Tawk, Jean-Francois Ferrero,