Quasi-static and high-rate in-plane shear tests on aramid and carbon fiber woven composites featuring a nanoparticle-enriched high-density polyethylene matrix

Nanoparticles are known to enable the modification of the properties of the material they are integrated into. In the context of ballistic protection, previous works have demonstrated that graphene and Montmorillonite (MMT) particles included in high-density polyethylene (HD-PE) and used as a matrix enable an increase in the ballistic performance, of consolidated woven aramid fabrics. Furthermore, the ballistic performance has been reported to be influenced by the in-plane shear properties of the impacted materials. In this context, quasi-static and high-rate in-plane shear tests have been conducted on two types of reinforcements, aramid, and carbon woven fabrics, consolidated by a high-density polyethylene matrix enriched by graphene, MMT and a mix of graphene and MMT nanoparticles. The conducted investigations provide for the first time in the literature the results of high-rate in-plane shear tests on aramid woven reinforcement consolidated with nanoparticle-enriched and not enriched high-density polyethylene composites. Despite the use of the same reinforcement and enriched matrix material as in previous works of literature, no significant differences in terms of in-plane shear behavior have been observed for any of the different types of nanoparticles integrated into the matrix. Nevertheless, the obtained results demonstrate a clear strain rate sensitivity of the tested materials.Highlights Aramid and carbon fabrics were consolidated with nanoparticle-enriched HD-PE Quasi-static and high-rate in-plane shear tests were conducted No influence of the nanoparticles could be identified A clear strain-rate sensitivity could be identified for both composites Overview of the manufacturing and quasi-static as well as high-rate in-plane shear testing campaign of the aramid and carbon fiber woven composites featuring a nanoparticle-enriched high-density polyethylene matrix. The test results demonstrate no clear influence of the nanoparticules but a strong strain rate sensitivity of the materials. image