Terrestrial demands on space missions are increasing rapidly in terms of complexity, technology and velocity. Next to navigation (GPS, GALILEO), science (investigation of space and the universe) and exploration (ISS, Mars), two types of space missions are very important for Europe: Earth Observation (EO, for the sustainability of nature and mankind) and Telecommunication (TC, for business and global connectivity). Each mission requires partly unique technologies, which are produced by only very few global suppliers. If these technologies are not available from within Europe, there is a danger that non-dependent missions may not be performed, created and tailored with a consequent loss of sovereignty in political decisions and a loss of market shares. One of these so-called “Critical Technologies” is the “Large Deployable Reflector (LDR)”. Packed in stowed configurations, these reflectors can be accommodated on satellites, which then still comply with the limited launcher fairing volumes. By enlarging the size of the reflector it is possible to offer higher sensitivity and resolution, e.g. for radar missions (EO & science) and implement stronger communication links for e.g. higher data throughput (TC). Within the upcoming eight years the demand for such reflectors will increase worldwide, whereas the Consortium targets a certain market share with its “Large European Antenna (LEA)”. The proposed H2020 project would now enable the combination of the technologies previously developed by the consortium members and the joining of further European entities to fill the remaining gaps and form one strong and complete European team. Through obtaining an EC-grant for LEA, each building block will be upgraded with innovation, adapted to a scenario and qualified to meet one common target, namely: 1st European PFM (including reflector and arm) reaching TRL 8 to be ready for integration by the end of 2020 and for flight in 2021.

To date, the battery market is dominated by lithium-ion (Li-ion) chemistries, as the energy density has more than doubled and their costs have dropped by a factor of at least 10. However, conventional Li-ion batteries (LIB) are reaching their performance limits in terms of energy density and facing safety issues, is required the development and production of new battery generations, such as Solid-State Batteries (SSBs), to create a new industry value chain in Europe towards their commercialization. Consequently, high-energy-density EU-made SSBs will ensure the supply of, among others, the automotive sector. To do so, the development and deployment of new manufacturing technologies, enabling the large-scale production of SSBs, is crucial. Indeed, among the overarching themes to develop and produce sustainable batteries in the future, the BATTERY 2030+ roadmap4 considers manufacturability as a cross-cutting key area. Innovative and scalable manufacturing techniques to produce SSBs will accelerate cost reduction, energy savings, and enhanced safety. ADVAGEN will develop a new lithium metal (LiM) battery cell technology based on a safe, reliable, and high performing hybrid solid-state electrolyte (LLZO-LPS based), gaining a competitive advantage over the worldwide (mainly Asian) competition. This will sustainably strengthen the EU as a technological and manufacturing leader in batteries as specified in the ERTRAC electrification roadmap and SET-Plan Action Point-7. ADVAGEN consortium contains key EU actors in the battery sector, from industrial materials producers (SCHT, CPT, ABEE), battery manufacturer (ABEE) to R&D centers (IKE, CEA, IREC, TUB, CICe, POLITO, INEGI, UL, FEV) and the automotive industry (TME), covering the complete knowledge and value chain. By developing high-performance, affordable and safe batteries, ADVAGEN aims to re-establish European competitiveness in battery cell production.

The Airframe ITD aims at re-thinking and developing the technologies as building blocks and the “solution space” on the level of the entire or holistic aircraft: pushing aerodynamics across new frontiers, combining and integrating new materials and structural techniques – and integrating innovative new controls and propulsion architectures with the airframe; and optimizing this against the challenges of weight, cost, life-cycle impact and durability.

One of the main challenges of EU battery sector to achieve the net-zero emissions objectives for 2050 consists of keeping the added value of EoL batteries, enabling their 2nd life, and improving recycling and recovery of critical materials. REINFORCE aims at designing, developing and deploying a novel sustainable, and highly efficient circular value chain serving as a reference for automated, safe and cost-efficient logistics and processing of EoL batteries from EV and stationary applications for repurposing and recycling. REINFORCE will demonstrate all technological solutions and processes in a real environment at TRL6, and the viability of the new circular value chain and business model innovations for EoL battery repurposing. This will be achieved by: (i) an optimisation of collection and reversed logistics focussed on efficient diagnostics for early battery status cut-off decision-making and safe and smart transportation solutions; (ii) safe and improved battery diagnostics and speed-up discharge and energy recovery systems adapted to the current batteries stream; (iii) adaptable and safe dismantling and sorting of EoL batteries and components based on robotics, Machine Learning and Industry 4.0, including fully automated pack-to-module disassembly and advanced module-to-cell-to-electrode disassembly; (iv) an innovative traceability system along the battery value chain based on a battery passport for the 2nd and 3rd life battery user; (v) the definition of standardisation guidelines in line with current and upcoming regulations; all revolving around (vi) robust sustainable circular business models demonstrating the application of REINFORCE proposition in a circular economy strategy and implement actions towards full market maturity. For this, REINFORCE is bringing together a wide experienced consortium led by INE, involving a team of leading industrial technology developers and providers, R&D centres and academic institutions, and end-users, at European level.

Batteries have been identified as an important technology to guide the clean-energy transition. Its presence in the automotive and energy storage industry is well-established and forecasts show its incoming market uptake. However, the current BMS of FLBs lack interoperability features, resulting in a time-consuming, expensive, and non-standardized reconfiguration process for SLB adaptation. These drawbacks complicate FLB repurposing for SLB applications, like ESS. The BIG LEAP project focuses on developing solutions for the SLBs BMS and its reconfiguration process. Technology breakthroughs will be made in its BMS, as a new three-layer architecture will be designed to ensure interoperability, safety, and reliability. It will be complemented with an adaptable ESS design to ensure BMS integration and expand the SLB's potential applications. Additionally, the BIG LEAP project intends to optimize the battery reconfiguration process by making it cost-effective, faster, and standardized. The methodology for the development of these innovations includes the collection of EV, maritime E-Vessel, and ESS batteries that will be dismantled and the data collected will serve as the basis for the BMS architecture development. It will contain adaptable SoX algorithms for accurate battery measurement, a DT for real-time monitoring, and a standardization roadmap. The new BMS will be integrated into the batteries, alongside the ESS and will be tested in three demo sites. Two physical demos will be in Paris and Prague, and a virtual demo will be in Morocco. They aim to validate the novel BMS and ESS, proving their optimization and interoperability. The BIG LEAP innovation includes a multidisciplinary consortium, a strong business case, and an Environmental Impact assessment. All with the intention of accelerating its market uptake with a cost-effective solution, positively impacting the European economy through the battery value chain and tracing its sustainable benefits.