Abstract EN:

Numerical simulations of the composite forming processes are essential in the design phase of composite structures. Fabric Forming simulations have many objectives: these determine the feasibility of forming or conditions of this feasibility and help determine the position of fibres after forming. This is important for the identification of mechanical characteristics of composites in service and to calculate the permeability after dry reinforcement draping for correct analysis of injection moulding process. This particular study has been accomplished with three main stages: the development of a stress computation algorithm for numerical analysis of fibrous materials; the experimental forming analysis of textile fabrics with an in-house development of double dome benchmark forming device; and finite element forming simulations using the benchmark model. Continuous approach has been used to predict the mechanical characteristics of woven composite fabrics during forming which considers the fibrous materials as a continuum on average at macroscopic scale. An algorithm based on a hypoelastic behaviour has been proposed for composite reinforcement forming simulations. It has been shown that using hypoelastic law with an objective derivative based on warp and weft fibre rotation tensors can successfully trace the correct behaviour of fibrous materials in deformation. The algorithm has been validated through a number of elementary tests with theoretical results. The de-facto standard in-plane shear tests of picture-frame and bias-extension have also been validated numerically. Double dome fabric forming tests have been carried out experimentally. 3D optical strain measurements were performed exploiting digital image correlation system of Vic-3D in order to measure the shear angles of the deformed fabrics. The forming simulations performed with the proposed numerical approach show a good agreement with the experimental results obtained with double dome device.