Developing low-cost energy storage systems is a central pillar for a secure, affordable and environmentally friendly energy supply based on renewable energies. A hybrid energy storage system (HESS) can be capable of providing multiple system services (e.g. frequency regulation or renewable balancing) at low cost and without the use of critical resources. Within HyFlow, an optimized HESS is designed consisting of a high-power vanadium redox flow battery (HP-VRFB), a supercapacitor (SC), advanced converter topologies and a highly flexible control system that allows adaptation to a variety of system environments. The system design enables modular long-term energy storage through HP-VRFB, while the SC as a power component ensures high load demands to be handled. The flexible Energy Management System (EMS) will be designed to perform high level of control and adaptability using computational analysis and hardware development. Within HyFlow, this innovative HESS is developed and validated on demonstrator-scale (5 kW scale) including sustainability analysis. The scope is to base the HP-VRFB on recycled vanadium and thereby reduce the environmental impact as well as the costs of the HESS. The consortium will build upon lab-scale and industrial application-scale experimental data to derive models and algorithms for the EMS development and the optimization of existing VRFB and SC components. An industry-scale demonstrator (300 kW scale) provides the possibility to test even the fastest grid-services like virtual inertia. Outputs of the project support the whole value-chain and life cycle of HESS by developing new materials and components and adding them together with an innovative EMS. The development of the above described HESS especially through the flexible EMS allows a plethora usage potentials to be assessed. This will lead to the grid integration of the HESS where the full potential of the flexibility can thoroughly be qualified and optimized for market requirements.

This proposal is an application to the EU programme “Horizon 2020” and its topic “Large scale energy storage” (LCE-09-2015). The presented project “STORE&GO” will demonstrate three “innovative Power to Gas storage concepts” at locations in Germany, Switzerland and Italy in order to overcome technical, economic, social and legal barriers. The demonstration will pave the way for an integration of PtG storage into flexible energy supply and distribution systems with a high share of renewable energy. Using methanation processes as bridging technologies, it will demonstrate and investigate in which way these innovative PtG concepts will be able to solve the main problems of renewable energies: fluctuating production of renewable energies; consideration of renewables as suboptimal power grid infrastructure; expensive; missing storage solutions for renewable power at the local, national and European level. At the same time PtG concepts will contribute in maintaining natural gas or SNG with an existing huge European infrastructure and an already advantageous and continuously improving environmental footprint as an important primary/secondary energy carrier, which is nowadays in doubt due to geo-political reasons/conflicts. So, STORE&GO will show that new PtG concepts can bridge the gaps associated with renewable energies and security of energy supply. STORE&GO will rise the acceptance in the public for renewable energy technologies in the demonstration of bridging technologies at three “living” best practice locations in Europe.

BAMBOO aims at developing new technologies addressing energy and resource efficiency challenges in 4 intensive industries (steel, petrochemical, minerals and pulp and paper). BAMBOO will scale up promising technologies to be adapted, tested and validated under real production conditions focus on three main innovation pillars: waste heat recovery, electrical flexibility and waste streams valorisation. These technologies include industrial heat pumps, Organic Rankine Cycles, combustion monitoring and control devices, improved burners and hybrid processes using energy from different carriers (waste heat, steam and electricity) for upgrading solid biofuels. These activities will be supported by quantitative Life Cycle Assessments. In order to maximize their application and impact to plant level, flexibility measures will be implemented in each demo case towards energy neutrality and joined in a horizontal decision support system for flexibility management. This tool will analyse, digest and interchange information from both, the process parameters and the energy market, including the BAMBOO solutions. As a result, the operation of the plants will be improved in terms of energy and raw materials consumption, and will lay the foundation of new approaches in the energy market. BAMBOO will empower intensive industries to take better decisions to become more competitive in the use of natural resources in a broader context, in the spirit of facilitating the use of larger variability and quantity of RES. BAMBOO consortium comprises strong industrial participation; 6 large companies as final users and 3 SMEs as technology providers, working with experienced RTOs and supporting entities. The private investment associated to BAMBOO is over 7M€ along the execution of the project. Lastly, the transferability potential of BAMBOO is extremely relevant as targeted process and plant improvements offer very high potential applications in other intensive industries.

MultiFutures systematically broadens the scope for policy action towards sustainable societies by assessing and developing transition scenarios based on alternative economic paradigms. This involves extending established transition scenarios (e.g. the EC's 'Long term strategic vision' scenarios or the IEA’s net zero scenarios) to include alternative economic paradigms that are based on a wide spectrum of sound economic and social theories and have demonstrated potential to address global challenges. These paradigms introduce new policy options and instruments, which we aim to critically assess regarding their relevance, effectiveness, and potential trade-offs. The project will proceed through four main steps. First, we use state-of-the-art AI language tools and qualitative methods to map alternative paradigms and develop a paradigm taxonomy. Second, desired futures are extended into quantified transition scenarios using a set of 'beyond GDP' indicators to assess the potential for achieving a climate-neutral, just, and resilient society. Thirdly, stakeholder engagement through anticipatory systems mapping and social simulations will be used to co-create alternative futures and develop concrete policies that balance trade-offs, mitigate negative impacts, and enable dissemination and implementation. In addition, a large-scale survey of >18,000 citizens in Europe provides insights into public perception and acceptance of alternative paradigms and transition policies. Fourth, state-of-the-art modelling will be integrated to assess the economic, environmental, technological and social impacts of alternative paradigms and policies from a well-being perspective, including their environmental and social justice implications. Ultimately, MultiFutures provides policymakers with a comprehensive understanding of alternative paradigms and a broader range of policy options to accelerate progress towards a climate-neutral, just, and resilient society.