The European Commission’s policy framework (i.e., Clean Energy Package, FiT 55) seeks to decarbonise the energy system, encouraging the electrification of heat and transport, as well as the connection of more clean but intermittent generation. Electricity markets and smart grid digitalization should proceed very fast to enable the fulfillment of these targets, incentivizing energy consumers and maximizing the use of assets from different energy consumption sectors (i.e., electricity, water, heating, cooling, mobility) in order to fully exploit the flexibility services. ENFLATE project will build upon existing solutions on data drivel energy services and non-energy services, and replicate them in different geographies, climate and consumer needs. It will propose applicable consumer-centered flexibility platforms and test them in Bulgaria, Greece, Spain, Sweden and Switzerland engaging local consumers, TSOs, DSOs, market operators, regulatory authorities, service providers, manufacturers, academia. It will provide smart grid innovative technologies, peer-to-peer market platforms for consumers, smart building and local community cross vector flexibility services, integration of consumer centered flexibility with pan European spot markets. Efficient business models will be developed and tested, combing energy services with health and mobility services. The developed ENFLATE project will be interoperable with existing data platforms in Horizon 2020, like ONENET, CoordiNET, SmartNet and INTERRFACE, leveraging the benefits of data exchange and adaptive middleware architectures. ENFLATE will evaluate the impact of the proposed multi-vector flexibility services to local, regional and pan European level.

The COLLECTiEF consortium will enhance, implement, test and evaluate an interoperable and scaleable energy management system based on Collective intelligence (CI) that allows easy and seamless integration of legacy equipment into a collaborative network within and between existing buildings and urban energy systems with reduced installation cost, data transfer and computational power while increasing data security, energy flexibility and climate resilience. This is done through developing software and hardware packages to install and smart up buildings and their legacy equipment on large scale, meanwhile to maintain simple and robust communication with the energy grid. The proposal includes the following objectives: (1)Enhancement and adaptation of algorithms for creating a CI-based energy flexible network (2)Realization of CI-based cost-effective system components with easy deployment and maintenance (3)Demonstration and testing of a CI-based energy network in the real environment (4)Testing and implementing a scalable and customizable occupant-centric fusion sensor network for accurate and non-invasive environmental monitoring (5)Designing and implementing a smart, user-centric and user friendly digital platform for interacting with users and controlling technical building systems (6)New business model for energy services including a clear model for commercialization of COLLECTiEF system. This will be achieved by building on technologies developed in previous EU-funded projects and by expertise from the scientific and commercial partners of this proposal, involving a number of highly innovative SMEs. The consortium forms a full value chain with academic partners, component manufacturers, building owners and - associated through LoIs - energy providers. The provided scalable solutions will integrate seamlessly with existing legacy equipment, and will facilitate demand-side management of multiple buildings, enhancing energy flexibility and resilience in urban areas.

The technical and economic viability of today’s district heating (DH) networks are undermined by transitions to highly efficient building stocks and ineffective business models which fail to benefit all stakeholders. TEMPO tackles this by 1) innovations to create low temperature (LT) networks for increased network efficiency and integration options for renewable and residual heat sources; and 2) new business models to boost network competitiveness and attractiveness for stakeholder investment. In TEMPO, six innovations related to networks, digitisation thereof and building optimisation undergo final development (TRL7-8). The innovations are combined into 3 solution packages suitable for 3 different application areas: new LT DH networks in urban areas, new LT DH networks in rural areas, and existing (HT) networks. The benefits of these solution packages to reduce network temperatures will be demonstrated in 3 selected representative demos. The Vattenfall demo is a new urban LT network whereby solution package 1 will be demonstrated to reduce temperatures and therefore to enable integration of a geothermal energy source and cooling. The Enerpipe demo is a new rural LT network whereby solution package 2 will be demonstrated to reduce temperatures and so can open up the possibility to integrate a renewable energy source at a later stage. The existing network of A2A currently operates at a very high supply temperature. By integrating solution package 3, with particular emphasis on end consumer engagement, reduction in network temperatures will be similarly demonstrated. A comparable monitoring approach will ensure optimal network performance (reliability and durability) assessment and to foster maximal replication options in other areas. Each solution package will be coupled to an innovative business model, which can leverage cost savings due to improved energy efficiency to offset the investment costs. Stakeholder engagement and consumer empowerment will be high pr

The annual space heating and cooling energy consumption in Europe is almost 3,500TWh. In 2012, in EU28 the electricity consumption ratio was around the 20% of the total energy consumption, from which 30% was consumed in the residential and 30% in the services sectors. From these proportions, air conditioning represents 17% of the total electricity consumption in the EU27 residential buildings. In the EU tertiary sector the electric space and water heating system represent 19.22%, the ventilation 12.47%, the commercial refrigeration 8.57% and the air conditioning 2.86% of the buildings electricity consumption. Heating, ventilation and air conditioning system’s electricity consumption of a building can represent between the 30% and 40% of the total energy consumption. The inertia of these power to heat solutions constitute an enormous potential for electric flexibility usable for absorbing the excess of renewable generation and avoiding curtailment while managing local power congestion, voltage stability in the grid and avoiding reversal power flows, as well as minimizing RES production imbalance. That is, DER with thermal inertia can provide services to RES owners, grid operators, aggregators and actors on the power market, while saving energy in the buildings. In fact, flexibility harnessing using heat to power solutions enables to deploy large-scale renewable throughout Europe successfully. The Flexible Heat and Power (FHP) project will develop a Power-to-Heat (and Cooling) solution package that manages this complexity through an easily accessible interface aimed at buildings and power grid actors. A practical prototype will be developed and deployed in two different demonstration scenarios in The Netherlands and Sweden representing diverse parts of the European power grid. FHP has the potential to provide total thermal flexibility with the aim of increasing the share of renewables by 22% over the total electric consumption from current technical limits (40%).