High-Performance Transparent Laminates Based on Highly Oriented Polyethylene Films

Advanced composite materials reinforced with high-performance fibers like carbon, glass, aramid, or ultra-high-molecular-weight polyethylene are widely used as lightweight materials in the fields of automotive, aerospace, sports, and protection. However, nearly always these composites are opaque and/or absorb light, which greatly limits their application in areas where high optical transparency is desired such as impact-resistant windows and visors. In this work, composite laminates that combine high optical clarity with high mechanical properties are reported for the first time using highly oriented high-density polyethylene (HDPE) films as the reinforcing phase. A high optical transparency with a far-field light transmittance of around 85% was achieved for four-layer HDPE-reinforced laminates sandwiched between glass or polycarbonate (PC) sheets with either unidirectional (UD) or bidirectional (BD) orientations. In combination with outer layers of glass or PC, the fabricated transparent composite laminates show high tensile strength and also high penetration energy absorption, outperforming existing transparent materials like glass, laminated glass, or PC. These transparent composites combine both high mechanical performance and high optical clarity, providing great potential for future applications in structural glazing, automotive glazing, safety shields, visors, and displays for portable electronics

Proposal for a smart pressurised ring test to study thick composite produced by filament winding

This work was supported by OSEO agency. The authors would like to thank Air Liquide and EADS Composites Aquitaine for their technical support in the H2E project.Improvements in the characterisation of materials used in pipes, tubes or vessels rely on the development of tests on cylindrical samples in order to be consistent with the real manufacturing process. Existing devices are unable to reach the pressure limits required to test high pressure hydrogen storage tanks. We therefore propose an original test device based on a conical fitting system. First, the operational principle and the pressure measurement technique are presented. Next, the choice of apparatus design parameters according to test requirements is discussed. In addition, the device’s capabilities are illustrated on a 39 mm thick CFRP ring test including Digital Image Correlation measurements