The distributed generation is growing hugely due to kingly decisions at national levels. These distribution means in particular those based on renewable sources produce their energy without coordination with the consumption. This production was marginal in the last decade and not neglictible nowadays. The distributed generation reaches 30% in some countries (Netherlands), even more than 50% in some particular cases. Some American studies plan an upper penetration rate in the middle of this century, other studies in Europe plan from their side a 100 % renewable energy based grid (EREC RE-thinking on 2050). The grid operation integrating a high rate of renewable energies (almost non-controllable sources, difficult to predict, which could have negative impacts and dysfunctions) requires to develop an intelligent network (Smart Grid) which will be characterized by a specific algorithmic and physical architectures; the energy management will play a key role as well. It is the objective of PARADISE project. PARADISE is a long term anticipating approach regarding the grid as it will be seen with high rate of renewable, intelligent loads, Plug-in Hybrid Electric Vehicles (PHEV) . The storage can take the shape of embedded batteries inside the PHEV’s or distributed stationary ones. By emphasizing the system approach, PARADISE will allow a global overview of a new architecture and a distributed management approach.

UNITED-GRID aspires to be the arrow-head within “Integrated cyber-physical solutions for intelligent distribution grid with distributed energy resources” and addresses the challenges in the “competitive low-carbon energy", relevant to next generation of active distribution grids. UNITED-GRID will develop a tool-box with technologies enabling at least 80% renewable-based energy production on an annual basis, with an increased reliability performance of 50%, while decreasing grid losses by 10%. The developed technologies include e.g. solutions for real-time system awareness and control, short term generation and load forecasting, setting-less protection schemes and new business models. The tool-box will be integrated into a professional system ensuring interoperability and smooth integration with existing EMS/DMS on the market. To enhance future impacts, at least 2/3 of novel solutions which have been positively validated will have an agreed and financed development processes for the next TRL level beyond the project. The project team has been selected carefully and has proven R&I, demonstration and deployment capabilities as well as established regulatory and policy channels. The team includes experienced research organisations (SP, TU/e, CEA, and Chalmers), 3 DSOs, a DMS provider and expert SME partners to ensure the exploitation of the developed solutions. To further enhance the deployment towards a low carbon energy society, the project will together with at least 20 market actors define pathways to navigate in the rapidly changing energy environment. Furthermore, at least 25% of the test-pilots will sign a letter of commitment to execute parts of the developed pathways. The real-life demonstrators, covering more than 80% of European market conditions, are provided by the project partners in-kind to an estimated value of €4.1M. With the requested EC contribution of €4M, the project encloses €8M, matching the UNITED-GRID projects ambitions and objectives.

Utilities are facing political pressure to reduce the energy end use by their customers and GHG emissions. Consumers, on the other hand, are empowered by the proliferation of IT interfaces and multiplication of channels. Their expectations for everything-anytime-anywhere interaction are redefining the nature of (energy) services. The advent of smart building technologies for energy efficiency reveal a mega-trend on the evolution of consumer choices and highlight the need for addressing their requirements for user-friendly, meaningful and actionable communication. Faced with these realities, business as usual is no longer an option for energy utilities. They must seek new sources of revenues by introducing bundled building energy management service packages including energy efficiency, smart controls and automation. The UtilitEE project will provide a customer-oriented Behavioural Change Framework (Energy-as-a-Service delivery approach via an open ICT ecosystem integrated into the building with off-the-shelf sensors). It focuses on discovering, quantifying and revealing energy-hungry activities and conveys meaningful feedback to engage users into a continuous process of learning and improvement. UtilitEE will leverage well-known behavioural models/ theories and standardized operational rating/ certification methods. It will also incorporate human-centric intelligent control features that use occupant comfort profiles and supportively control HVAC and lights so as to minimize energy waste, while always keeping occupants comfortable and preserving a healthy indoor environment. The framework will be validated in real-life conditions by a large population of residential and commercial consumers and aims to reduce energy use by ~30%. Validation activities will also explore future business models and go-to-market strategies for utilities. A holistic roadmap and business plan for the exploitation and replication of project results will be delivered.

The future electricity generation mix evolution, EU projects 97% generation from variable RES by 2050, will render current solutions for grid balancing and stability insufficient. Intermittent generation will require extensive electricity demand flexibility - beyond conventional solutions - to alleviate the unpredictable grid stresses in high VRES times. This flexibility cannot only come from electricity end-uses, the volatility and variability of RES generation is too high. Energy system decarbonisation will necessitate the use of novel conversion and storage in alternative energy carriers and their networks to achieve the avoidance of RES generation curtailment. The PLANET aim is to design and develop a holistic Decision Support System for grid operational planning and management in order to explore, identify, evaluate and quantitatively assess optimal strategies to deploy, integrate and operate conversion/storage systems on the distribution grid of several energy carriers within boundary constraints of real deployments outlined in the future energy system scenarios. Such tools are crucial for policy makers and network operators who need support in decision making process. The simulation of the integration between electricity, gas and heat networks models, together with conversion/storage technologies models for power-to-gas, power-to-heat and virtual thermal energy storage, will help to understand and quantify how these conversions can affect network stability, reliability and responsiveness as well as to optimize these metrics across networks. The PLANET tools will be demonstrated and validated using information from the actual premises and customers of two distribution network operators in Italy and France. They manage electricity, natural gas and district heating networks, hence they provide a solid testbed corresponding to real-world solution deployments to evaluate the actual benefits of PLANET solutions.

Buildings constitute a vast, yet currently untapped, source of energy demand flexibility that can provide invaluable services to the energy system. This flexibility currently remains unattainable due to the lack of a technological framework that can connect the multitude of buildings and building systems with the energy system in a cost-effective manner as well as the reluctance of energy consumers to enroll in demand response programs. DRIMPAC offers a comprehensive solution to empower consumer to become active participants in the energy markets. It comprises three main pillars: a) A legacy and Standards-compliant interoperability framework to interconnect building energy loads/appliances and expose their demand flexibility as price-responsive demand to the grid or for market actors to aggregate and bid in ancillary service markets. b) A human-centric, intelligent building energy management system that will lift the burden of demand response from the consumers shoulders and reduce reluctance and fear of participation in DR programs. It will infer user comfort preferences and dynamically control building loads to minimize energy cost and use for the building occupant leveraging dynamic prices, while always preserving comfortable and healthy indoor conditions. c) Innovative business models and service offering for energy retailers in order to facilitate their transformation from commodity suppliers to digital energy service suppliers and kick-start the deployment of the DRIMPAC solution in the market. The DRIMPAC technological framework and business models will be validated by four retailers supplying three energy carriers – electricity, natural gas and district heating – in four different national markets across the EU - France, Cyprus, Germany and Spain. Pilot demonstrations will take place in a range of building types, including residential, office, educational and others, in order to validate the DRIMPAC benefits across most building typologies.