The EU is transitioning to The EU is transitioning to a secure, sustainable and competitive energy system as laid out in the EC’s Energy Union strategy. The growing penetration of renewable energy sources in the EU energy market, go hand in hand with a high-competitiveness of the most consolidated technologies: Wind Energy and Solar Photovoltaics. The non-dispatchable renewable generation requires a higher flexibility in the energy system, where the weight of much more decentralised installations grow day-to-day. In fact, the flourishing of a wide portfolio of renewable energy installations is allowing the deployment of large to small scale industrial electricity grids, and in an increased share of electricity produced in private households. The NAIMA project will demonstrate that the new generation of high-competitive and safety Na-Ion cells developed and tested during the project, is one of the most robust and cost-effective alternatives to unseat the current and future Li-based technologies, nowadays controlled by Asian industry. The EU cannot jeopardize the future of its stronger industry to a technology already in the hands of non-European countries. Just the availability of the raw materials of Li-ion cells is almost a “miracle”. Under this scenario, the most robust non-Lithium alternative is the technology based on Sodium-ion (Na-ion). This disruptive technology is already supported by a solid European Battery value chain (industry partners of the consortium) through their solid commitment of substantial investments in the manufacturing of all components of a battery, preserving the ownership and industry strength around European countries. Within the framework of the project, 3 SIB prototypes will be tested in 3 multi-scale Business Scenarios to provide solid evidences about the competitiveness of the technology in 3 real ESS environments (renewable generation, industry and private household) through the application of an assessment and monitoring protocol.

DC grids attractiveness has been increased in the last years due to the high proliferation of renewable energy sources together with the increase in DC loads (electronics, LED lighting, electric vehicles, energy storage…). The main drivers behind this paradigm shift are related to the improved efficiency, flexibility, security and reliability DC grids may provide, thus increasing the sustainability of the energy distribution system. However, there is a need for demonstration of DC technologies and grid topologies so that these solutions are able to evolve from a promising solution for the future smart grids to a commercially available technological option. Under this context, TIGON aims to achieve a smooth deployment and integration of intelligent DC-based grid architectures within the current energy system while providing ancillary services to the main network. To do so, TIGON proposes a four-level approach aiming at improving 1) Reliability, 2) Resilience 3) Performance, and 4) Cost Efficiency of hybrid grids through the development of an innovative portfolio of power electronic solutions and software systems and tools focused on the efficient monitoring, control and management of DC grids. These solutions will be demonstrated in two main Demo-Sites located in France and Spain, while additional use cases in the residential and urban railway sectors will act as niche markets for analysing and further solidifying the replication of TIGON developments after the project’s end. TIGON has involved for this purpose a multidisciplinary team of 15 partners from 8 different European Member States with a well-balanced consortium integrated by 7 non-profit entities and 7 companies. This partnership provides the required expertise from fields such as power electronics, cybersecurity, standardisation, etc. to design the solutions proposed within TIGON as well as the industrial capabilities required for the manufacturing, integration and validation of the whole TIGON concept.

The FORESIGHT project aims to develop a federated cyber-range solution to enhance the preparedness of cyber-security professionals at all levels and advance their skills towards preventing, detecting, reacting and mitigating sophisticated cyber-attacks. This is achieved by delivering an ecosystem of networked realistic training and simulation platforms that collaboratively bring unique cyber-security aspects from the aviation, smart grid and naval domains. The proposed platform will extend the capabilities of existing cyber-ranges and will allow the creation of complex cross-domain/hybrid scenarios to be built jointly with the IoT domain. Emphasis is given on the design and implementation of realistic and dynamic scenarios that are based on identified and forecasted trends of cyber-attacks and vulnerabilities extracted from cyber-threat intelligence gathered from the dark web; this will enable cyber-security professionals to rapidly adapt to an evolving threat landscape. The development of advanced risk analysis and econometric models will prove to be valuable in estimating the impact of cyber-risks, selecting the most appropriate and affordable security measures, and minimising the cost and time to recover from cyber-attacks. Innovative training curricula, guiding cyber-security professionals to implement and combine security measures using new technologies and established learning methodologies, will be created and employed for training needs; they will be linked to professional certification programs and be supported by learning platforms. Aside from the development of skills, the project aims at a holistic approach to cyber-threat management with the ultimate goal of cultivating a strong security culture. As such, the project puts considerable emphasis on research and development (i.e. research on cyber-threats, development of novel ideas, etc) as the key to increasing training dynamics and awareness methods for exceeding the rate of evolution of cyber-attackers

FLEXITRANSTORE project shall develop a next generation of Flexible Energy Grid (FEG), which provides the technical basis to support the valorisation of flexibility services, enhancing the existing European Internal Energy Market (IEM). This FEG addresses the capability of a power system to maintain continuous service in the face of rapid and large swings in supply or demand, whatever the cause. Thus, a wholesale market infrastructure and new business models within this integrated FEG should be upgraded to network players, incentivize new ones to join, while demonstrating new business perspectives for cross border resources management and energy trading. The strategic objectives of FLEXITRANSTORE are: to enhance and accelerate the integration of renewables into European energy systems and to increase cross border electricity flows across Europe. Flexibility is one of the keys to meeting these strategic objectives. A range of state-of-the-art ICT technologies / control improvements will be exploited to enhance the flexibility of this novel energy grid while increasing the utility of the existing infrastructure by integrating storage and demand response management. From a market perspective, state-of-the-art ICT technologies / control improvements will be applied to develop an enhanced market model on an integrated platform, for flexibility services and to support cross border auctioning and trading of energy. The FEG components and the digital market infrastructure will be deployed in 8 Demonstrations which will take place in 6 countries (Greece, Bulgaria, Cyprus, Slovenia, Belgium, Spain), focusing on illustrating specific functions and serving real needs and existing challenges.

The smart energy ecosystem constitutes the next technological leap of the conventional electrical grid, providing multiple benefits such as increased reliability, better service quality and efficient utilization of the existing infrastructures. However, despite the fact that it brings beneficial environmental, economic and social changes, it also generates significant security and privacy challenges, as it includes a combination of heterogeneous, co-existing smart and legacy technologies. Based on this reality, the SDN-microSENSE project intends to provide a set of secure, privacy-enabled and resilient to cyberattacks tools, thus ensuring the normal operation of EPES as well as the integrity and the confidentiality of communications. In particular, adopting an SDN-based technology, SDN-microSENSE will develop a three-layer security architecture, by deploying and implementing risk assessment processes, self-healing capabilities, large-scale distributed detection and prevention mechanisms, as well as an overlay privacy protection framework. Firstly, the risk assessment framework will identify the risk level of each component of EPES, identifying the possible threats and vulnerabilities. Accordingly, in the context of self-healing, islanding schemes and energy management processes will be deployed, isolating the critical parts of the network in the case of emergency. Furthermore, collaborative intrusion detection tools will be capable of detecting and preventing possible threats and anomalies timely. Finally, the overlay privacy protection framework will focus on the privacy issues, including homomorphic encryption and anonymity processes