ENLIGHTEN aims at developing, integrating and testing a next generation post 800V electric vehicle powertrain with an indicative voltage level of 1200V. It targets a higher performing, cost optimized and more sustainable drivetrain layout that is also backwards compatible to the existing charging infrastructure with 1000V or 500V respectively. Determining exactly how high the new voltage level should be, to enable expected advantages in a systemic and systematic way is also part of the project. A new voltage level affects the entire sphere of electric mobility, both horizontally (vehicle, charging infrastructure, users, manufacturers) and vertically (OEM, tier1, tier2, single component supplier), hence a deliberate decision is required. To accomplish this an advanced electrical system architecture is presented by the ENLIGHTEN consortium in this proposal on whose basis a specific electric vehicle drivetrain will finally be developed and demonstrated in a C-segment vehicle. The at TRL5 delivered powertrain will consist of a dual voltage battery system and an integrated motor-inverter E-drive system, complemented by an intermediate DCDC converter, an AC and DC capable onboard charger and a power distribution. All power electronic devices will exploit low loss, ultra-fast switching gallium nitride (GaN) semiconductors for highest efficiency and to minimize cooling demand and component size. The dual voltage battery can be switched dynamically from one battery voltage into the other while driving. Through these and other measures, the ENLIGHTEN system delivers significant advances over the 2024 State of the Art. The ENLIGHTEN consortium includes 2 automotive companies, 1 Tier1 supplier and 2 SMEs. Their expertise is leveraged by the partnership with 2 research institutions and 4 academia/universities, constituting an ideal setup for strengthening the competitiveness of the European automotive industry.

In the long haul transport sector, the reduction of real driving emissions and fuel consumption is the main societal challenge. The LONGRUN project will contribute to lower the impacts by developing different engines, drivelines and demonstrator vehicles with 10% energy saving (TtW) and related CO2, 30% lower emission exhaust (NOx, CO and others), and 50% Peak Thermal Efficiency. A second achievement will be the multiscale simulation framework to support the design and development of efficient powertrains, including hybrids for both trucks and coaches. With the proposed initiatives a leading position in hybrid powertrain technology and Internal Combustion Engine operating on renewable fuels in Europe will be guaranteed. A single solution is not enough to achieve these targets. The LONGRUN project brings together leading OEMs of trucks and coaches and their suppliers and research partners, to develop a set of innovations and applications, and to publish major roadmaps for technology and fuels in time for the revision of the CO2 emission standards for heavy duty vehicles in 2022 to support decision making with most recent and validated results and to make recommendations for future policies. The OEMs will develop 8 demonstrators (3 engines, 1 hybrid drivelines, 2 coaches and 3 trucks); within them technical sub-systems and components will be demonstrated, including electro-hybrid drives, optimised ICEs and aftertreatment systems for alternative and renewable fuels, electric motors, smart auxiliaries, on-board energy recuperation and storage devices and power electronics. This includes concepts for connected and digitalised fleet management, predictive maintenance and operation in relation to electrification where appropriate to maximise the emissions reduction potential. The 30 partners will accelerate the transition from fossil-based fuels to alternative and renewable fuels and to a strong reduction of fossil-based CO2 and air pollutant emissions in Europe

HYLENA-Hop On will investigate and mature (TRL2 to TRL3) an electrical power distribution solution supporting the development of an innovative, highly efficient, hydrogen powered electrical aircraft propulsion concept being developed in HYLENA. This concept is based on the integration of Solid Oxide Fuel Cells (SOFC) with turbomachinery in order to use both the electric and thermal energy for improved propulsive efficiency. HYLENA-Hop On sets out to overcome both the known and unknown technical challenges associated with electrical power distribution, protection and coordination, as well as the integration of the electrical motor and Motor Control Unit by focusing on the following key aspects: • Power Distribution Unit (PDU) concept including latest technologies. • Electric Motor and Motor Control Unit design studies and possible development directions targeting improved efficiency of the novel HYLENA hybrid propulsion architecture. • Innovative resilient and coordinated power management strategies. • Reliability assessment framework for electrical power distribution systems applicable to hybrid aircraft propulsion architectures including SOFC. This complementary work will accelerate the availability of an electrical power distribution solution bringing HYLENA one step closer to ground demonstration phase and thereby supporting HYLENA’s path towards climate neutral aviation. EATON’s participation in the HYLENA project will not only introduce a new dimension of expertise complementing HYLENA’s objectives, but will also reinforce the project’s outreach. It will enhance EATON’s visibility and knowledge on EU funded collaborations. Moreover, it will create the opportunity to break up existing silos, to enhance the development of new networks and to increase the permeability for talents between Czech and European organisations which are well established in the European funding landscape, thereby strengthening a pan-European innovation ecosystem.

The project HYPERRIDE (HYbrid Provision of Energy based on Reliabilty and Resiliancy via Integration of Dc Equipment) contributes to the field implementation of DC and hybrid ACDC grids. Starting with the definition of most relevant fields of application for DC grids (local microgrids, grid enforcement to overcome congestions, coupling of AC grid sections, etc.), the enabling technologies will be specified in detail on different levels. Starting from the system perspective, guidelines for grid planning and operation are developed. To optimize invest for the use case dependent use of assets available sizing tools are adapted for the field of DC grids.DC circuit breakers are key technologies for grid protection needed to overcome the main concerns related to these infrastructures. Therefore, HYPERRIDE will raise the TRL of the most promising approaches currently available with a main focus on MVDC breakers. To enable grid automation DC sensors are developed further to provide field ready devices to create data for optimal grid automation. Automation algorithms will be created, validated in a test platform and transferred towards demonstration. This also involves concepts and solutions for cyber security and fault detection. In case of grid faults necessary solutions are developed to prevent cascading effects. For fault prevention databases are created to trigger preventive measures. With demonstrations in three countries (Aachen/Germany, Lausanne/Switzerland, Terni/Italy) the project will showcase relevant and above-mentioned enabling technologies within a wide range of use cases. Benefits of the solutions will be evaluated, especially the integration potential of renewables with respect to conventional AC grids. Finally, business models are created for the products, services and applications in HYPERRIDE.Consequently, HYPERRIDE will actively identify and provide solutions to overcome barriers for a successful roll-out of new infrastructure concepts throughout Europe.

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.