A numerical material model for intra-laminar failure prediction of biaxial non-crimp fabric composites is presented. The model combines the elasto-plastic continuum damage constitutive model proposed by Ladevèze with the intra-laminar matrix failure model of Puck, and improves the shear damage representation using an exponential damage function. The work focuses on numerical model development for damage and failure prediction and validation for both unsheared and sheared fabric composites which will result from draping of the fabric preform over a double curved geometry in order to manufacture complex shaped parts. An extensive test program has been conducted using flat composite coupons with differing degrees of fabric pre-shear in order to establish a database of material stiffness, strength, and in-plane matrix shear damage evolution prior to failure. This database is used to identify parameters for the proposed ‘Ladevèze-Puck’ damage and failure model. Final validation has been made by implementing the model in an explicit Finite Element code and performing a series of experimental and simulation analyses on transversely loaded circular composite discs having differing degrees of fabric pre-shear. The model has been shown to successfully capture intra-ply failure modes in the principle fibre directions for tension and compression, intra-ply shear and also the interaction of these modes.
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