The Auto-DAN project aims to enable homes and small businesses across the EU to optimize their energy consumption and provide an assessment of the live energy performance of a building which takes into account the quality of appliances/systems installed, user operational habits and the smart readiness of a building.The solution is rooted in augmented intelligence which will focus on the assistive role automation will have in buildings, emphasizing the fact that cognitive technology is designed to enhance human intelligence rather than replace it and that the occupant is a proactive component of the building. Augmented Intelligence enhances a self-optimisation solution as it is a mix of automated controls with user interaction which will maximise the savings of a building in operation. To enable this step-change, the Auto-DAN project will deliver a trebled-structured project framework that evaluates the actual energy performance of EU buildings and provide building users with the awareness to proactively optimize their energy use. The following, lists the subdivisions of the solution: • Smart Hardware Infrastructure - Adaptable hardware strategy that can be applied to all building types and features to ensure maximum replicabilbilty of the Auto-DAN solution across the EU building stock. • Inter-operable Software Architecture - The data analysis platform iSCAN will be used as a foundation for self-optimizing and self-assessing EU buildings stock complemented by 2 analytical features that provides optimisation actions. Those features are a 1. Digital Occupancy Model and a 2. Digital Twin. • Self-Energy Assessment Framework - Generates an automated, dynamic and continuous energy performance assessmentd erived from the monitoring of the energy consumption at building level, dis-aggregated monitoring at an appliance/system level and incorporates existing EU energy regulations (e.g. EPBD, ECO Design, SRI, and Energy Labeling).

TwinERGY will introduce a first-of-a-kind Digital Twin framework that will incorporate the required intelligence for optimizing demand response at the local level without compromising the well-being of consumers and their daily schedules and operations. The main idea behind the conception of the TwinERGY project lies on the interest of the project partners to exploit the new business opportunities that project implementation delivers and increase the relevance of the DR optimization tools and strategies in the new generation of energy management systems. By coupling mature practice for citizen engagement with service innovation through the lenses of public value, TwinERGY will ensure that a wide range of interests and especially of consumers/prosumers will be represented and supported in the energy marketplace. In this context, TwinERGY will develop, configure and integrate an innovative suite of tools, services and applications for consumers, enabling increase of awareness and knowledge about consumption patterns, energy behaviours, generation/ demand forecasts and increase of local intelligence via properly established Digital Twin-based Consumer-Centric Energy Management and Control Decision Support mechanisms that locally optimize demand response. Key use cases will be trialed across 4 pilot regions making use of cutting-edge methods and tools. Special focus is given on standardization and policy & market reform as key enablers for the successful commercialization of the TwinERGY results. Additional attention is given in establishing knowledge transfer and exchange synergies with similar projects listed under the BRIDGE Initiative, while explicit focus will be given on the establishment of close collaboration with the projects funded under the LC-SC3-ES-5-2018 topic, to further reinforce and catalyze collaborative advancements in research, innovation, regulatory and market issues around Demand Response, RES Integration and Consumer Engagement.

Heat Pump and solar appliances are the most social accepted residential Renewable Energy based energy systems. SunHorizon will demonstrate up to TRL 7 innovative and reliable Heat Pump solutions (thermal compression, adsorption, reversible) that acting properly coupled and managed with advanced solar panels (PV, Hybrid, thermal) can provide heating and cooling to residential and tertiary building with lower emissions, energy bills and fossil fuel dependency. A Cloud based functional monitoring platform will be realised in the project to be the “performance data mine” for the development of Data Driven/KPI oriented optimized algorithms and tools to predict maintenance, optimize the management towards maximisation of solar exploitation and give to the manufacturer inputs for new installation design, via an innovative “robust design under uncertainty approach” which aims to overcome classical H&C equipment oversizing due to safety factors . This monitoring platform will also drive smart end user interfaces that will be applied at building level to collect thermal comfort data towards a new end-user driven H&C control system. SunHorizon tools will be applicable not only to proposed solar coupled HPs, but to all H&C appliances towards a global increasing efficiency of EU H&C stock and its decarbonisation. 5 low emission H&C Technology packages (TPs) will be tested coupling HP and solar installation. SunHorizon aims to be a breakthrough demonstration to market project involving 21 partners and 8 demosites all around EU focusing its activities on “reducing system costs and improving performance as well as optimising existing technologies for H&C applications”. SunHorizon will be focused on three main research pillars interacting each other towards project objectives achievement, demonstration and replication: i) OPTIMIZED DESIGN, ENGINEERING AND MANUFACTURING OF SUNHORIZON TECHNOLOGIES ii) SMART FUNCTIONAL MONITORING FOR H&C,iii) KPI DRIVEN MANAGEMENT AND DEMONSTRATION.

ENSNARE’s main objective is to boost the implementation of renovation packages through (1) the digitalisation of the entire process by means of a digital platform and (2) the development of an industrialised envelope mesh enabling fast assembly and interconnection of passive and multifunctional building components. The methodology and tools provided will facilitate the necessary market uptake of novel and highly efficient solutions for nZEB, accelerating the current retrofitting rate and supporting the transformation of the European building stock into a highly efficient and technologically advanced built environment. Within a comprehensive systemic approach, the project will target the development of modular adaptable components to be integrated within the system (rather than marketed as standalone products that increase the cost and complexity of the system), including an active window for ventilation and heat recovery, solar harvesting devices (thermal collectors, PV and hybrid panels with advanced technologies such as roll-bonding), heat pumps and energy batteries for load shifting. The digital platform will comprise a set of digital tools supporting and accelerating all stages for a more efficient renovation process: automated data acquisition, LCA/LCC analysis and decision support, digital BIM model building and computer-assisted manufacturing (CAM), and a smart building management system (sBMS) for optimised operation and maintenance. All these tools are linked to a digital model, which increases in complexity and interaction potentialities as the project develops. At completion, the model becomes a Digital Twin of the renovated building allowing real-time monitorization, simulation and optimised operation of all building components. The ENSNARE solution will be validated through three pilot renovation projects covering Nordic, Continental and Mediterranean climates, and three virtual demonstration buildings aimed at upscaling the development of the solution.

If BIM is key to address the construction sector growing technical complexity, to overcome construction processes fragmentation and communication problems between stakeholders, to reduce on-site time and improve quality and affordability, its uptake for the renovation of the EU existing building stock is yet to come and already late. To face this BIM4REN starts from 3 workflows adapted to the construction sector segmentation (90% of companies are SMEs) presenting particular technical and organisational requirements and has adapted the project and consortium to provide adequate and innovative processes, methodologies, software and hardware tools & BIM developments for each one of them, backboned by state of the art BIM technologies like worldwide used BIM Server (open-source) and BIM Bots by TNO among many others. BIM4REN gathers together top European RTOs active in the Built Environment domain (Nobatek, CSTB, Tecnalia, TNO, Fraunhofer ISE) alongside key industrial actors (EDF, CMB Carpi & ATI Project (leading BIM implementers in the EU market) with 2 Universities (RWTH & Vilnius Gedimas) and up to 11 SMEs: R&D performing (R2M, Ekodenge), SME contractors (Kursaal) and technology providers (IES, EnerBIM, WiseBIM, VRM, AEC3, etc.) with the European Builders Confederation, the Green Building Council Italy and a large French Social Housing Organisation (Logirep) representing the whole residential renovation value chain. B4R digital ecosystem will be accessible via a web based One Stop Access Platform, where depending on each user profile and needs, orientation, best practice examples from a dedicated database and links to the different tools and services (from Top-grade to Entry-level) will be provided on differentiated access schemes underpinned by different business models. Inspired by the Open Innovation 2.0 paradigm the project will setup a demonstration campaign with “pilots as Living Labs” integrating all stakeholders in 3 cities (Paris, San Sebastian and Venice).