The main objective of the SOLRESS project is to propose an integrated biorefinery system to replace the chemical origin of some of the most widely used solvents in the industry, such as ethyl acetate, ethyl lactate and butyl acetate with a bio-based origin from second generation sugars from post-consumer coffee grounds and lignocellulosic feedstocks. The aim is to reinforce the integration of bio-based research and innovation throughout industrial bio-based systems. Moreover, in the valorisation process of these feedstocks, not only the cellulose fraction will be valorised, but also the hemicellulose fraction to obtain 2 of the most notorious green solvents of today, 2-MeTHF and GVL, from an additional line dedicated to the processing of furfural. The challenges will lie in improving downstream purification (DSP) processes and the techniques employed to achieve a technology that is efficient and cost-competitive with current chemical production systems for solvents. At the end of the project, all solvents will be validated in at least 3 of the most relevant applications (productive processes, formulations and recycling technologies) & at least 3 of the sectors with the greatest use of solvents (paints & coatings, cosmetics & materials processing) with the aim of evaluating its performance in comparison with its fossil-based counterparts, but also as a replacement for other dangerous and toxic solvents, such as NMP, CCL4, THF or toluene. Thus, the ambition of the SOLRESS project is triple: To replace the use of fossil, non-renewable raw materials with specific bio-based feedstocks in the production of some of the most widely used solvents. Offer SSbD alternatives to controversial solvents in terms of danger & toxicity (including the ones under the SVHC & SoCs categories). To improve the competitiveness of these processes by incorporating new methods & technologies that increase efficiency & sustainability, demonstrating their scalability & industrial applicability.

The project NoVOC addresses the Topic Environmentally sustainable processing techniques applied to large scale electrode and cell component manufacturing for Li ion batteries. The activities of NoVOC are tailored to the challenges addressed by the call topic: 1. Lower carbon footprint cell manufacturing in Europe. 2. New sustainable electrode and cell manufacturing techniques with low energy consumption, and no Volatile Organic Compounds (VOCs) emissions. 3. Electrode coating production techniques eliminate organic solvents reduce the capital costs associated to the solvent recovery system. 4. Dry manufacturing techniques with next generation materials. 5. Industrializing closed loops and process design to return low-value chemicals from manufacturing processes to high-value products In NoVOC we aim to design and demonstrate two competitive cell manufacturing technologies aqueous and dry cell manufacturing technologies for automotive batteries intended for production in Europe. The innovations proposed in NoVOC centre on improvements of cell manufacturing process by integrating two novel electrode manufacturing processes into the currently available cell assembly process and demonstrate manufacturability of automotive cells in two formats (pouch and cylindrical) with no toxic organic solvent at the fraction of the cell manufacturing cost that is currently available today. Next generation cell manufacturing processes developed in Europe for electric vehicles batteries

Building sector is responsible for 40% of energy consumption and 36% of CO2 emissions in the EU. As nZEB becomes the new standard, the role of building materials and smart envelope systems is becoming more and more important. Exploit4InnoMat OITB will make available a high-end Open Innovation Testbed network for building envelopes including roofs and facades, enabling the replication of prototypes in different buildings taking into consideration the trade-offs between the three sustainability pillars, the life cycle stages as well as their impacts. End-User Market Needs for low-cost, flexible, on demand material-based solutions, which will be assessed through an extensive partnership knowledge on materials characterization and modelling, monitoring and process control, environmental and assessment, regulatory and standardization, social acceptance and innovation management, realizing for nZEB solutions. In order to achieve this target a wide range of expertise has been brought to the OITB covering fields such as Open Innovation Testbeds for nano enabled cement, non cement premixes and ceramics, advanced coatings and glazing solutions loaded with aerogel, fibers, PCMs and other nanomaterials providing multifunctional properties; pilot lines for nanodispersion, 3D printing and roboting spraying; as well as a network of four real scale living laboratories for nZEB technologies evaluation, will facilitate a realization tool for developing close to market technological solutions. Additionally, a semi-automated tool combining BIM analysis, fast track modelling and simulation will make enable a digital tool for utilizing building blocks (structural, solar thermal and BIPV) in order to create a harmonized and aesthetically pleasing urban environment.