With fuel economy and lightweight design becoming ever more significant due to the current materials, resources and environmental crisis, the manufacture of polymer composites for automotive industry use has experienced a steady growth in the last years and is expected to keep growing in the coming years. This means that there is a vast range of different polymer composites available in the market, with their unique properties, manufacturing processes and materials imbedded in them, each with their own set of impacts on the environment throughout their whole life cycle. The end-of-life treatment of a composite determines a substantial fraction of its footprint on the planet, and advanced treatments, namely pyrolysis can be used to obtain high value added compounds such as hydrogen and other light fuels. This study aims to address and quantify the impacts associated with the manufacturing and end of life treatments of an experimental glass fibre mat reinforced thermoplastic composite and compare them with the impacts caused by materials currently used in the automotive industry. Life Cycle assessment methodology will be used to compare the environmental impacts of this new material with traditional glass fibre composites, natural fibre reinforced composites and other materials with similar mechanical properties.
Abstract
With fuel economy and lightweight design becoming ever more significant due to the current materials, resources and environmental crisis, the manufacture of polymer composites for [...]
The recent trend to replace Body-in-White components with carbon fibre laminates, known as “Body in Black”, has been taking hold in new vehicle designs. This is how various hybrids with a thermoplastic matrix are born, such as CAPET, which has titanium with carbon fibres in PEEK, CAPAAL, which has aluminium with carbon fibres and glass in PA 6, CATPUAL based on CAPAAL, with thermoplastic polyurethane matrix and aluminium sheets. This project includes the study and design of hybrid laminates that can replace a monolithic steel sheet. Analytical models based on the classical laminate theory and models based on the rule of mixtures were used to predict the mechanical behaviour of the material. The structural behaviour of a semi-product was analysed using finite element simulations. The results show that it is possible to obtain a weight reduction between 13% and 22% when using a hybrid laminate, but it is required to increase the thickness of the lamina up to 3 times compared to the metal. Subsequently, studies were carried out to measure the wetness of the surface and the adhesion resistance of a carbon fibre prepreg with PA6 matrix on aluminium. A life cycle analysis (LCA) of hybrid laminates designed to observe the environmental impact on energy consumption and carbon footprint was carried out.
Abstract
The recent trend to replace Body-in-White components with carbon fibre laminates, known as “Body in Black”, has been taking hold in new vehicle designs. This is how various hybrids with a thermoplastic [...]