The SOLAR-MOVE project aims to contribute to the massive adoption of electric vehicles (EVs) minimizing their impact in the power grid by proposing solutions for different Vehicles Integrated Photovoltaic (VIPV) ecosystems: i) VIPV in cities, ii) VIPV in residential and service buildings, iii) VIPV in passenger transportation and iv) VIPV in highways. The SOLAR-MOVE will follow three main targets: i) increase the range of the VIPV in 5 to 10 km/day compared to normal EVs; ii) reduce the dependency on the grid (energy provided by the grid) from 20 to 50 %, depending on the eco-system; and iii) create solutions with positive Net Present Value. To achieve these goals the consortium - comprised by 34 partners across 16 countries - will develop innovative VIPV solutions, including tools to be integrated in VIPV; VIPV prototypes (Heavy-duty vehicles with PV in the trailer, garbage trucks, passenger buses, last-mile delivery and motorhome); VIPV Use Optimisation solutions to maximise the range of the VIPVs; and ePIPV (charging stations with PVs) for diverse applications (in highways, opportunity charging for eBus, ePIPVs at municipality level, public ePIPV in commercial areas and private ePIPVs). The solutions will be demonstrated in six pilots across Denmark (VIPV:heavy Duty vehiles, ePIPV parking lot for trucks in highways), Greece (VIPV: Garbage Truck, ePIPV: Management of ePIPV at municipality level), Turkey (VIPV: Passenger Bus, ePIPV: Management of ePIPV Opportunity charging), Portugal (VIPV: Last mile delivery, ePIPV: Management of public ePIPV), Albania (ePIPV; Management of private ePIPV) and Slovenia (VIPV:Motorhome). The findings will contribute to the elaboration of policy recomendations to support the adoption of VIPV and ePIPV, guidelines for municipalities to simplify the procurement process for VIPS and ePIPVs solutions and regulatory frameworks and incentives to facilitate the mass deployment of these technologies.

The ongoing energy system digitization is making available an enormous amount of data, paving the way for data sharing-enabled cross-value chain services, which may contribute to system-level increased efficiency and hence facilitate the energy transition. However data sharing in the energy sector is lagging behind, mainly due to lack of trust, privacy breaches risk and business models immaturity. In that respect ENERSHARE will a) deliver a Reference Architecture for a European Energy Data Space, which hybridizes SGAM with IDSA and GAIA-X architectures, by bringing data value chain perspective into the energy one b) evolve interoperability, trust, data value and governance building blocks to TRL 6-7 IDSA-compliant ones, adapt them to energy sector, and deploy: 1) across-energy and cross-sector data enhancement technology enablers and standardizable interfaces and open APIs by leveraging on open Standards (e.g. ETSI Context Broker) and ontologies (e.g. SAREF 2) trust-related connectors, to ensure privacy, confidentiality, cybersecurity-preserving trust, sovereignty and full control of data 3) Blockchain/Smart contract-enriched marketplace for data versus energy assets/services coordination, sharing, exchange, and beyond financial compensation 4) cross-value chain value-added services and Digital Twins, by leveraging on privacy-preserving federated learning c) integrate and deploy them within a Reference Implementation of a European Energy Data Space, which will be demonstrated along 7 pilots and 11 intra-electricity, intra-energy and beyond energy use cases d) co-design SSH-based consumer-centric business models for energy data sharing enabling data beyond-financial value creation and spreading along value chain d) prepare the ground for the European Energy Data Space setup, through alignment with EU-level relevant initiatives (GAIA-X, IDSA, BDVA, ETIP SNET, BRIDGE), contributing to Data Space standardization and boosting a level playing field for data sharing.

CRETE VALLEY aims to create a Renewable Energy Valley 'Living Lab' (REV-Lab) in Crete. It is envisioned as a decentralised renewable energy system that combines leading-edge ICT technologies, interoperable and open digital solutions (including data sovereignty), social innovation processes, and sound business models that are easy to adopt. CRETE VALLEY will demonstrate a digitalised, distributed, renewable, low carbon landscape that is affordable for all and fully covers the local energy needs on an annual basis, utilizing multiple renewable energy carriers and leveraging energy storage technologies. The REV-Lab will integrate four Community Energy Labs (CELs) located in distinct sites across CRETE VALLEY, conceived as Innovation Hubs. An integrated social, technological & business approach will be deployed, providing: A Social Science Framework for REV-Labs & CELs, innovative multi-level governance models & social-driven mechanisms for involving citizens in the co-design, implementation and exploitation of RES; AI-based market segmentation algorithms, MCDA methods and consensus analysis for REV configuration; Interactive tools for REV planning (REV Readiness Assessment & computation, Augmented Reality applications, decision support tool); Energy Data Space compliant digital backbone for consumer and REV-level data-driven ‘activation’; P2P DLT/Blockchain digital marketplace for tokenised energy and non-energy assets valuation and reciprocal compensation; Data-driven operational analysis, advanced AI/ML tools and flexibility modelling services for optimal operation & resilience of the local energy grid; System-of-system Dig. Twin for multiple carrier grid management & operation; Data-driven services and apps for energy efficiency and activation performance management towards energy autonomy; Enabling RES technologies to increase the power production; REV Business Sandbox and blueprints for REV-Lab setup, upscaling and replication (including 4 Follower Communities).

The ambition of the STREAM project (STREAM) is the creation of an innovative and robust flexibility ecosystem (“STREAM Ecosystem”) on the low voltage (LV) grid side of existing power markets connecting data, technologies, stakeholders and markets, thus facilitating the flexibility provision. A variety of benefits for both technical- and non-technical aspects of energy services supporting power market and power grid operations will be created. STREAM will empower data from flexible devices and support creation of other citizen services through a User-centric Approach to improve their acceptance. The exploitation of both types of services will benefit from new business models, built upon local LV flexibility markets and novel barter-like mechanism, developed in STREAM. Presently, such services and business models don’t exist in either established- or developing power markets. The STREAM ecosystem covers their implementation, includes various stakeholder groups on all levels of power markets, from small-scale end-users, energy communities, ESCOs, service providers, to market- and system operators. To achieve the goals, STREAM consortium comprises relevant actors to capture the entire flexibility value chain within STREAM ecosystem from end users, energy communities to service providers, flexibility services providers, market operators, DSOs, and TSO, complemented by technology and research partners. The latter will supply knowledge in a form of STREAM tools that will enable the realization of STREAM ecosystem. They will be adapted, deployed, calibrated, and demonstrated in the 4 STREAM pilots that serve as a basis for benchmarking of STREAM ideas. They cover geographical, economic, size and type diversity of the consumers. While complementary, the pilots focus on a specific part of STREAM Ecosystem. The pilot partners have all the essential roles and authority to carry out the specified activities.

Internet of Things (IoT) is one of the next big concepts to support societal changes and economic growth, being one of the fastest growing ICT segments. A specific challenge is to leverage existing technology strengths to develop solutions that sustain the European industry and values. To address this, IoT-NGIN introduces novel research and innovation concepts, to establish itself as the “IoT Engine” that will fuel the Next Generation of IoT as a part of the European Next Generation Internet. First, IoT-NGIN uncovers a patterns based meta-architecture that encompasses evolving, legacy, and future IoT architectures. Second, it optimizes IoT/M2M and 5G/MCM communications, including using secure-by-design micro-services to extend the edge cloud paradigm. Thirdly, it enables user and self-aware, autonomous IoT systems through privacy-preserving federated ML and ambient intelligence, with AR support for humans. Finally, IoT-NGIN researches towards distributed IoT cybersecurity and privacy, for example, using Self-Sovereign Identities and interconnected DLTs to implement Meta-Level Digital Twins. IoT-NGIN will be validated via more than 30 types of heterogeneous IoT devices, ranging from tiny resource constrained IoT sensors to intelligent, autonomous buses, drones and robots, deployed in one of the most prestigious IoT/5G lab (OneLab) and five Living Labs: the “Twin Cities” Living Lab in Helsinki/Tallinn, a fully customizable Smart Agri Living Lab in Greece, the BOSCH and the ABB employee-friendly Industry 4.0 facilities in Barcelona and Helsinki, and a hybrid field-lab facility focused on Smart Energy, interconnecting Terni City and EDD Eurolab in Aachen. Beyond partners exploitation plans, to maximize impact and sustainability, IoT-NGIN will push all results via alliances, clusters, SDOs and DIHs, including FIWARE, BDVA, and AIOTI, offer developed software as open source, and organize open Open Calls to engage FGPA/ASIC/fabless and IoT application developers.