Abstract
3D composite materials are characterized by complex internal yarn architectures, leading to complex deformation and failure development mechanisms. Net-shaped preforms, which are originally periodic in nature, lose their periodicity when the fabric is draped, deformed on a tool, and consolidated to create geometrically complex composite components. As a result, the internal yarn architecture, which dominates the mechanical behaviour, becomes dependent on the structural geometry. Hence, predicting the mechanical behaviour of 3D composites requires an accurate representation of the yarn architecture within structural scale models. When applied to 3D composites, conventional finite element modelling techniques are limited to either homogenised properties at the structural scale, or the unit cell scale for a more detailed material property definition. Consequently, these models fail to capture the complex phenomena occurring across multiple length scales and their effects on a 3D composite’s mechanical response. Here a multi-scale modelling approach based on a 3D spatial Voronoi tessellation is proposed. The model creates an intermediate length scale suitable for homogenisation to deal with the non-periodic nature of the final material. Information is passed between the different length scales to allow for the effect of the structural geometry to be taken into account on the smaller scales. The stiffness and surface strain predictions from the proposed model have been found to be in good agreement with experimental results.The proposed modelling framework has been used to gain important insight into the behaviour of this category of materials. It has been observed that the strain and stress distributions are strongly dependent on the internal yarn architecture and consequently on the final component geometry. Even for simple coupon tests, the internal architecture and geometric effects dominate the mechanical response. Consequently, the behaviour of 3D woven composites should be considered to be a structure specific response rather than generic homogenised material properties.
Highlights
The increased use of high performance composite materials in a variety of applications requires the adoption of new technologies to improve the performance and reduce the cost of these materials
The drive for better mechanical performance as well as manufacturing efficiency has led to the introduction of composite materials with through-thickness reinforcement produced in a near netshape pre-form
The strain and stress distributions found using this modelling approach show a strong relation between the internal yarn architecture and the mechanical response of 3D woven composites
Summary
The increased use of high performance composite materials in a variety of applications requires the adoption of new technologies to improve the performance and reduce the cost of these materials. For 3D woven materials a dedicated multi-scale approach that takes into consideration the complexities associated yarn architecture and its interaction at both the meso and macro scales is needed. On the meso-scale, the woven composite structure is described in terms of yarn and matrix materials.
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