Buildings account for around 40% of total energy use and 36% of CO2 emissions in Europe . According to the recast Directive on the energy performance of buildings (EPBD) all new buildings after 2020 should reach nearly zero energy levels, meaning that they should demonstrate very low energy needs mainly covered by renewable energy sources. EU 2030 targets aim at least 40% cuts in greenhouse gas emissions (from 1990 levels), at least 32% share for renewable energy, at least 32.5% improvement in energy efficiency , and 80% reduction of greenhouse gas (GHG) emissions by 2050 . Therefore, an urgent need is present for a deep market transformation by deploying efficient materials and technologies in the construction sector to support the real implementation of nearly zero-energy/emission and plus-energy buildings with high indoor environment quality across Europe. As energy consumption of buildings depend strongly on the climate and the local weather conditions, additional aspects arise (such as environmental, technical, user experience, functional and design aspects) on the selection of the appropriate material and technical components installation for a successful implementation of nZEBs. Further, this selection of materials and design for climate should be based on a circular economy perspective considering environmental, economic and social effects along value chains. Better utilisation of products and resources via reuse-repair-recycling is essential in achieving a transformation from a linear to a circular economy model. Many of the current materials and technical systems still have varying degree of difficulty in accomplishing a circular perspective. Material and technical system development in a ZEB framework should focus on building thermal performance improvement, high quality of indoor environment according to occupants’ comfort and health needs, while reducing the emission intensity in terms of production, maintenance, assembling and operation.

Current technological demands are increasingly stretching the properties of advanced materials to expand their applications to more severe or extreme conditions, whilst simultaneously seeking cost-effective production processes and final products. The aim of this project is to demonstrate the influence of different surface enhancing and modification techniques on CF-based materials for high value and high performance applications. These materials are a route to further exploiting advanced materials, using enabling technologies for additional functionalities, without compromising structural integrity. Carbon fibre (CF) based materials have particular advantages due to their lightweight, good mechanical, electrical and thermal properties. Current generation CFs have extensively been used in a multitude of applications, taking advantage of their valuable properties to provide solutions in complex problems of materials science and technology, however the limits of the current capability has now being reached. MODCOMP aims to develop novel fibre-based materials for technical, high value, high performance products for non-clothing applications at realistic cost, with improved safety and functionality. Demonstrators will be designed to fulfil scalability towards industrial needs . End users from a wide range of industrial sectors (transport, construction, leisure and electronics) will adapt the knowledge gained from the project and test the innovative high added value demonstrators. An in-depth and broad analysis of material development, coupled with related modelling studies, recycling and safety will be conducted in parallel for two types of materials (concepts): • CF-based structures with increased functionality (enhanced mechanical, electrical, thermal properties). • CNF-based structures for flexible electronics applications. Dedicated multiscale modelling, standardisation and production of reference materials are also considered

BIO4SELF aims at fully biobased self-reinforced polymer composites (SRPC). To produce the SRPCs two polylactic acid (PLA) grades are required: a low melting temperature (Tm) one to form the matrix and an ultra high stiffness and high Tm one to form the reinforcing fibres. To reach unprecedented stiffness in the reinforcing PLA fibres, we will combine PLA with bio-LCP (liquid crystalline polymer) for nanofibril formation. Further, we will increase the temperature resistance of PLA and improve its durability. This way, BIO4SELF will exploit recent progress in PLA fibre technology. We will add inherent self-functionalization via photocatalytic fibres (self-cleaning properties), tailored microcapsules (self-healing properties) and deformation detecting fibres (self-sensing). Prototype composite parts for luggage, automotive and home appliances will be demonstrators to illustrate the much broader range of industrial applications, e.g. furniture, construction and sports goods. Our developments will enable to use biobased composites for high end applications, thus contributing to using sustainable and renewable raw materials. Being able to produce, process and sell these novel SRPCs and related composite intermediates will be a clear competitive advantage. First estimates predict a market of at least 35 kton/year, corresponding to ca. 165 M€, within 5 years. Using the PLA SRPCs, BIO4SELF will demonstrate the first fully biobased suitcase, which partner SAMSONITE intends to commercialise to renew its top selling high end line (currently based on self-reinforced polypropylene). BIO4SELF is a well balanced mix of end-users (large enterprises to maximise impact), technology providers (mainly R&D driven SMEs), R&D actors (RTDs and universities) and innovation support (specialised SMEs). It covers the required expertise, infrastructure, and industrial know-how to realise the innovation potential of the novel high performance biobased SRPCs, both during and beyond the project.

The main goal of DECOAT is to enable circular use of textiles and plastic parts with (multilayer) ‘coatings’, which are typically not recyclable yet. These ‘coatings’ comprise functional and performance coatings and paints as well as adhesion layers. Therefore, novel triggerable smart polymer material systems and the corresponding recycling processes will be developed. The triggerable solutions will be based on smart additives (like microcapsules or microwave triggered additives) for the ‘coating’ formulations that will be activated by a specific trigger (heat, humidity, microwave, chemical). A continuous recycling pilot plant will demonstrate the novel DECOAT principle that allows upgrading existing mechanical recycling by adding tools for sorting by and activation of the trigger. The optimal use of the Creasolv® process for recycling of coated parts will be assessed. The focus is on recycling of the bulk material, but re-use of the coatings materials themselves will also be tackled. Using these recycling processes, circular use of demo cases for outdoor gear, household electronics and automotive parts will be validated. The novel triggerable DECOAT technologies will create new markets for additives, coatings, paints and adhesives fulfilling the recycling need. The concepts will support designers and product developers for making ‘recyclable-by-design’ products. This will create direct business opportunities for the DECOAT partners and serve as examples for promoting DECOAT solutions to the wider stakeholder community. The targeted products (parts) are coated plastic from cars, electrical and electronic equipment and coated textiles which produce annually almost 3.5 million tons waste. DECOAT will lead to a decrease in landfilling of ca. 75% and a reduction in the carbon footprint by at least 30% for these products. By enabling their recycling, DECOAT is expected to generate on medium term a novel market of over 150 million in Europe (or ca 500 jobs).