RINNO envisions to deliver a framework solution that will help drastically accelerating the rate of deep renovation in EU building stock reaching an ambitious annual renovation rate of 3.5%. Its ultimate goal is to develop, validate and demonstrate an operational interface with augmented intelligence and an occupant-centered approach that will streamline and facilitate the whole lifecycle of building renovation (planning-design, retrofitting, monitoring). This concept has at its foundation, a set of cost-attractive, environmentally friendly, multi-functional and easily applicable building-related innovations, grouped into: a) plug-n-play, modular building envelope solutions and b) RES, hybrid and storage solutions. RINNO couples the above with innovative retrofitting processes, methods and tools, characterized by low tenants’ disruption. These comprise: efficient (off/on-site) construction strategies, on-the-job AR facilitating environment and multi-stakeholder collaboration, which are expected to shrink the time and cost required for deep renovation, while improving buildings’ performance; all with a short payback period of <4 years on average. The above will be supported businesswise with novel business models aligned with the circular economy principles, enriched with investment de-risking tools and advanced crowd-equity/crowd-lending schemes. RINNO is expected to impact the EU inefficient building stock by a) reaching an ambitious annual renovation rate of 3.5%; b) primary energy savings of 165 GWh/year; c) a reduction of electricity cost by at least 30%; d) a total cost / time reduction in comparison with typical renovation by more than 30% and 40% respectively, and e) an estimated reduction of 40,400 tons CO2-eq/year. RINNO optimized renovation roadmap will be demonstrated at 4 large scale (3,386m2) pilot use cases after being pre-piloted, covering different EU climatic zones and markets of diverse maturity in the renovation sector.

Agro2Circular (A2C) project is focused on the implementation of the first territorial systemic solution for the upcycling of most relevant residues in the agrifood sector (fruits& vegetables and plastic multilayers) into high added value products, powered by a digital tool and constructed upon a systemic approach with high replicable/scalable potential. Through this solution, A2C will face important industrial, economic & social challenges in the agrifood sector: 1) The fruits & vegetables (F&V) are the group of major contribution to food waste along the food supply chain rising up to > 40% of waste, and are as excellent source of natural bioactives. However, these F&V wastes are not exploited. A2C will valorise them by green routes to obtain these bioactives for the production of nutraceuticals, functional foods, and cosmetics. 3) Multilayer plastic films are widely used as industrial packaging for the protection of food and agriculture for crops due to their unique barrier properties. However, there is a lack of sorting and recycling technologies for an economic and environmentally sustainable valorisation of these multilayer structures. A2C will develop the first recycling value chain for post-industrial multilayer films based on a synergistic approach combining innovative sorting, physical delamination, enzymatic depolymerisation, decontamination & mechanical recycling. 3) There is a lack of digitalisation in the agrifood sector. A2C will implement a Data Integration System (DIS) as a digital tool for ensuring traceability and as Predictive Decision Tool in the agrifood sector. A2C will be a demonstrated in the Regi?n de Murcia (Spain) and replicable systemic solution throughout Europe for the territorial deployment of the circular economy.

VPP4Islands aims to facilitate the integration of renewable systems, accelerate the transition towards smart and green energy and help Islands to exploit energy efficiency potential and innovative storage approaches, foster the active participation of citizens and become self-sufficient in energy, while reducing costs, GHG emissions and reliance on heavy fuel oil to generate power, and creating new intelligent business, growth and local skilled jobs. To reach these goals, VPP4Islands project proposes disruptive solutions based on digital twin concept, Virtual energy storage systems (VESS) and Distributed Ledger technology (DLT) to revolutionize the existing VPP and build smart energy communities. Based on aggregation and smart management of distributed energy resources (DERs), VPP4Islands increases the flexibility and profitability of energy systems while providing novel services. VPP4Island will also enhance the Demand Response Capability of consumers by understating their behaviors and promoting self-consumption. In order to validate and evaluate the proposed solutions, two use cases in real-life with diverse assets in two leading islands are planned. The control and optimization of different systems will be extended to consider not only electrical, but also multi-energy vectors. Moreover, the qualified VPP4Islands solutions will be replicated in 3 follower islands, in order to generate and initiate smart sustainable energy plans. Also, VPP4Islands will generate durable social and environmental values for the benefit of consumers/prosumers. Finally, VPP4Islands project consortium is composed of 1 large company, 1 DSO, 7 SMEs, 3 universities, 2 RTOs, 3 islands municipalities, and 2 non-profits organisation.

P2P-SmartTest project investigates and demonstrates a smarter electricity distribution system integrated with advanced ICT, regional markets and innovative business models. It will employ Peer-to-Peer (P2P) approaches to ensure the integration of demand side flexibility and the optimum operation of DER and other resources within the network while maintaining second-to-second power balance and the quality and security of the supply. The proposed project will built upon extensive experience of the consortium on Information and Communications Technologies (ICT), especially ICT for the Energy Sector, Smart Grids including Distributed Energy Resources (DER) integration, MicroGrids, CELLs, Virtual Power Plants etc., power system economics, electricity markets and business models. The project comprises of 7 work packages (WP), of which 5 are technical WPs. Apart from project management (WP1) and dissemination and exploitation (WP7) the P2P-SmartTest project defines and demonstrates the suitable business models (WP2) for peer-to-peer based distributed smart energy grids, quantify the value from significantly increased system interaction and integration, and assess the required development in ICT and power networks in conjunction with commercial and regulatory frameworks to enable P2P trading realising its full potential. WP3 shall develop and demonstrate the distributed wireless ICT solutions capable of offloading the required traffic of different applications of energy trading, network optimization, AMR data and real-time network control to name a few. In WP4 the optimization mechanisms of energy flows in P2P context shall be defined, as well as market design solutions. To properly operate distributed network, WP5 shall integrate the necessary network operation functions for resilient distribution system operation. The results of WPs 2-5 will be integrated to demonstration and validation environment in WP 6 to provide real-life results of distributed energy system designs.

In the framework of the achievement of the EU Climate and Energy packages for the decarbonisation of the energy sectors, the integration of variable renewable energy sources will put at stake the stability and provision security of the electricity system: there is a growing need for flexibility provision to ensure a reliable and stable electric system. MAGNITUDE addresses the challenge to rise flexibility in electricity systems, by increasing the synergies between electricity, heating/cooling and gas networks and associated systems. MAGNITUDE will bring technical solutions, market design and business models, to be integrated on ongoing policy discussions. MAGNITUDE will define technological and operational means for maximising flexibility provision to the electricity network. It will identify the regulatory framework to bring such flexibility service to the energy markets and will provide enhanced market designs and related business mechanisms. MAGNITUDE is built upon 7 real life case studies of multi energy systems, located in different European countries, under different regulatory and geopolitical environments and with different technological development levels. It will: 1. Simulate the multi energy systems in the case studies and optimise their operation strategies maximising the provision of specific flexibility services 2. From existing regulations, propose improved market designs, and integrate them in a market simulation platform for evaluating its performance among the case study countries 3. Quantify the benefit of pooling flexibilities from decentralized multi energy systems for energy markets through an aggregation platform. MAGNITUDE results will define policy strategies and recommendations in a pan-European perspective. Achievements will be spread among stakeholders to raise awareness and foster higher collaboration among the electricity, heating and gas sectors to achieve the common goal of a less carbon intensive, yet reliable energy system.