The use of fossil fuels and the emission of greenhouse gases (GHG) into the atmosphere must be minimised as fast as possible to reach a climate-neutral society by 2050. A vital prerequisite of the de-carbonisation is the rapid growth of renewables. In 2050 more than 60 % of electrical power is expected to come from wind and solar, both significantly more remote located than traditional thermal power generation. To achieve this, efficient grid-integration of renewables across Europe and globally requires the development of high-power transmission systems and components, and more specifically Medium Voltage DC (MVDC) and High Voltage DC (HVDC) switchgear. In existing grids MVAC and HVAC switchgear is filled with the insulation gas SF6, the world's most potent GHG with a global warming potential (GWP) of 24 300. SF6-emissions due to leakages during gas handling or defective sealings / compartments represents a significant part of the grid owners' total GHG emissions. MISSION project will develop and demonstrate three SF6-free products as key-levers for climate neutral power transmission based on the requirements defined by TSOs, filling critical gaps in future hybrid ACDC grids: 1. SF6-free HVAC circuit breaker will be developed and type tested by Siemens Energy and installed and demonstrated by Statnett in Norway and RTE in France reaching TRL 8, 2. SF6-free HVDC GIS will be developed and type tested by Siemens Energy in Germany reaching TRL 8, 3. MVDC circuit breaker will be developed and tested in relevant environment by G&W reaching TRL 6. In addition, MISSION will determine technical properties of different SF6-alternatives for application in AC and DC switchgear for high and medium voltage operation. MISSION will contribute to enable emission-free energy transmission and switchgear technology transition for a resilient and sustainable future electric grid.

The aim of the RESIST project is to enhance the resilience of large scale interconnected critical infrastructures, thanks to the combination of the Skydweller, a versatile ultra-persistent sustainable platform fitted with high end performing sensors and the Copernicus satellite imagery (optical and radar imagery (Synthetic-aperture radar, SAR)). This solution will support critical infrastructures operators and crisis managers across EU territories before, during, and after disasters. The project will involve key European Civil Protection Authorities, Critical Infrastructure Operators, technology providers, universities and security foundations to build the most relevant and effective solution. RESIST will provide (i) a multi-missions capacity, (ii) the ability to perform a persistent or an aleatory monitoring of critical infrastructures, (iii) relevant data to actualize emergency plans and strengthen critical infrastructures security, (iv) a reaction and coordination capacity, in case of the occurrence of a disaster, (v) support climate adaptation strategies and plans in place at different levels across Europe and neighbour countries (whenever applicable). The resilience enhancement of large scale interconnected critical infrastructures will be approached through three particular use cases dealing with transmission lines monitoring in Spain, electricity production and distribution infrastructure monitoring in Portugal and surveillance of a strategic hydrocarbons site in Cyprus (simulated use case).

Renewable power is one of the main drives to achieve carbon reduction and net-zero, and to meet the ambitious climate goals. In particular, offshore wind power in Europe has been developing at a rapid pace in recent years. Multi-Giga watts offshore wind farms with larger wind turbine power ratings, floating wind turbines installed in deeper water areas, and higher ratio of renewables integrated to existing power grids, are fundamentally changing power system operations and bringing new challenges and technical demands. This industry-doctorate consortium, ADOreD, will recruit and train 15 Researchers by collaborating with 19 academic and industrial organisations. It aims to tackle the academic and technical challenges in the areas of transmission of offshore wind power to the AC grid by using power electronics-based AC/DC technologies. In doing so, it will equip the Researchers, through their PhD studies, with essential knowledge and skills to face fast energy transition in their future careers. The project covers 3 key research aspects: offshore wind (including wind turbines, wind power collection, and wind farm design and control); DC technologies (including AC/DC converters, HVDC control and DC network operation and protection); and AC grid (including stability and control of AC grids dominated with converters under various control modes. The ADOreD consortium has excellent coverage of academic universities and industry organisations including manufacturers, energy utilities, system operators, consultancy and technology innovation centres. All the research questions in the project reflect industry needs; academic novelty and innovation will be reflected in the methodologies and solutions; and the research results will be disseminated directly to the industry partners’ products, grid operation and services. The outcomes of the project are both technologies and a talent pool to accelerate the deployment and grid integration of large-scale offshore wind power.

The ongoing transformation of the European energy sector is crucial to reduce CO2 emissions and increase security of supply and independence from energy imports. A pillar of this transformation is increased power generation from renewable resources, especially wind power and photovoltaics, but also electrification of the heating and mobility sector. These generators and consumers of electrical energy are increasingly connected to the power grid via power electronic converters. Furthermore, DC lines and subnetworks are built to reduce power conversion losses and achieve cost-efficient network strengthening. Due to these trends, power systems are increasingly hybrid AC/DC systems, and their dynamic is highly influenced by power electronic devices. Maintaining system stability and situation awareness in such hybrid systems is a challenge for system operators on distribution and transmission level and creates a need for SCADA systems that are adaptable and help operators to tackle the challenges posed by the rapid transformation of the grids. InterSCADA is committed to developing and providing an open-source, vendor-independent SCADA system for operators. This will enable them to quickly adapt to sudden system perturbations, implement new monitoring and control functions, and maintain situational awareness. The InterSCADA platform will implement a set of relevant functions as microservices, creating a modular SCADA system for system operators. The InterSCADA solutions will be deployed and tested in demonstration sites in four different countries, involving both distribution and transmission system operators. Furthermore, InterSCADA will provide recommendations to grid codes and standards for hybrid AC/DC systems, aiming to facilitate the transformation of the power grid while ensuring the maintenance of stability and reliability.