MEZeroE is an EU distributed open innovation ecosystem for: (i) developing nZEB Enabler Envelope technology solutions ; (ii) transferring knowledge; (iii) matching testing needs with existing facilities; (iv) providing monitoring in living labs and; (v) standardizing cutting-edge solutions coming from SMEs and larger industries, to foster inclusive change in the building sector, being accessible via a single-entry point to all users. MEZeroE allows the development of ground-based solutions focused on carbon neutrality and healthy indoor environment, validated with advanced assessment methods and services, recognized protocols and long-term vision to embrace industry 4.0 trends, rapid decision making and customer-centric requirements. MEZeroE accompanies enterprises in adopting the open innovation approach comprising discovery (phase 1), empowering (phase 2), and exploiting (phase 3). MEZeroE will be accessed via a single-entry point web-based multi-side virtual marketplace, including 9 Pilot Measurement & Verification Lines (PM&VL) and 3 Open Innovation Services (OIS) covering training, business model development, systematic IP and knowledge management. MEzeroE will fast-track prototypes to the market as fully characterized products. MEZeroE virtual marketplace provides structured knowledge to different stakeholders with a pragmatic and well-grounded mid to long-term ambition of developing and consolidating a trusted expertise network, to be active and self-sustaining well beyond the project timeline. Based on synergies among partners, existing channels and a dedicated marketing strategy MEZeroE will exploit 3 revenue lines to ensure a 4x leverage factor vs. EU contribution. These revenue streams include: (I) memberships (benefit of web-based platform manager); (ii) consultancy for innovation and IPR protection (benefit of OIS developers) and (iii) incremental revenues of industrial partners (benefit of users) thanks to product transferred to market.

In the past 25 years, many integrated photovoltaics (IPV) products have been introduced and demonstrated. Mostly BIPV products, but more recently also IIPV and VIPV products. However, large scale deployment and massive market adoption of these technologies and products have not yet taken place. We are at the brink of a huge scale-up and capacity build-up of PV in Europe, that will have a large effect on our living environment. Therefore, it is now urgent and essential that IPV products become widely available and affordable. This is important (1) to generate solar electricity where the demand is (in the built environment) and (2) to enable multifunctional use of area and space in the built environment. Several parties in the MC2.0 consortium have more than 20 years of experience in IPV development and as such have been involved in many earlier projects and studies. We believe that the number one barrier for large scale market uptake of IPV is the high cost. Other - secondary but also important barriers are immature sector cooperation and certification issues. The overarching ambition of the MC2.0 project is to demonstrate a cost breakthrough for IPV by means of an advanced manufacturing approach, referred to as mass customization. In coherence with this approach, we will contribute to solving the other identified barriers. To realize this ambition, the MC2.0 consortium brings together experts and companies on materials for PV laminates (including PV cells), on manufacturing of PV laminates, on manufacturing of IPV products and on market and application of IPV products.

INCREASE aims to contribute to a wider uptake of IPV by delivering innovations at module and system level, as well as for the design & operation phase. New encapsulants and coatings will be developed contributing to improved aesthetics, reduced glare, lower environmental footprint, improved behavior during fire, and improved antifoiling and antisoiling behavior. At system level, innovations focus on integrated facade and roof concepts, as well as noise barriers. Practical guidelines will further be delivered for bespoke infrastructure integrated projects, validated with a variety of complementary infrastructure integrated PV projects. Elaborate testing is foreseen at module and system level in line with relevant construction related and electrical standards. Optimal case-specific selection of IPV size and characteristics will be supported by a multi-objective optimisation software that takes into account the shape and use of the building or infrastructure, its surroundings, and its energy flexibility potential and steer the asset operation as well as suggest specific user behaviour to maximise the self-consumption. To increase market acceptance, a strong layer of user feedback and co-creation underpins the overall R&D activities, and contributes to delivering 10 complementary building and infrastructure demonstrations on 9 locations in 6 European countries. Cross-sector interactions, policy exchanges, investor dialogues, and country-specific business case assessments will further direct the exploitation towards large scale market uptake.

Traditional silo approaches, where stakeholders manage their own data, could be replaced by digital and smart buildings, merging heterogeneous data sources, and placing the stakeholders as the core of these buildings. DigiBUILD will catalyse this much-needed transformation by making use of high-quality data and next generation digital building services, supporting the deployment of EU-wide Framework for a Digital Building Logbook. An inclusive environment for multi-stakeholder knowledge exchange (based on European Bauhaus initiative) will be applied to co-design end-user-oriented services. DigiBUILD will provide an open, interoperable and cloud-based toolbox to transform current ‘silo’ buildings into digital, interoperable and smarter ones, based on consistent and reliable data, supporting better-informed decision-making for performance monitoring & assessment, planning of building infrastructure, policy making and de-risking investments. It will be built on top of existing platforms and common EU initiatives, towards an Energy Efficient Building Data Space, based on standard cloud-data platform frameworks (FIWARE) and Data Space initiatives (GAIA-X and IDSA). On top of this advanced data governance framework, we will create AI-based data analytics and Digital Building Twins based on high-quality data, aiming to facilitate transparency, trust, informed decision-making and information sharing within the built environment and construction sector, which will be deployed across 10 real-world conditions (TRL 8). DigiBUILD will contribute to the uptake of digital technologies in the building sector to better align the EU Member States’ long-term renovation strategies with the EPBD requirements on decarbonisation, and on a path towards a climate-neutral building stock by 2050.

European rural areas will boost when their natural resources constitute the basis of innovative and sustainable value chains with a high positive economic impact. In this sense, forests constitute an asset that provide not only ecosystems and biodiversity, but also a valuable and sustainable raw material, “wood”. Wood is consumed by various sectors, including one of the most “raw materials” demanding sector, the construction. The BASAJAUN project is a puzzle composed of 1st and 2nd transformation companies, research organizations, associations and public bodies that are focused on maximizing the forest value through its use in wood construction. Its main goal is to optimize the wood forest resources to enable the construction of a medium sized building (16 dwellings with 4 floors) with the lowest possible forest hectares – that will depends on the tree species and the forest local peculiarities (climate, surface, ..). The whole process will be optimised to maximize the consumption of wood products from the forest (solid wood, fibers, veneers, bark, sawdust, etc.). For this purpose, a) innovative wood-based construction materials (thermal insulation, composites, varnishes, SIPs) and systems (structure, facades, floors, walls, roof and fixings) will be developed and upscaled, b) two full -scale demo buildings (Finland and France) that use those products will be constructed, c) digitalization of the whole construction value chain (from forest to building) will be done and d) the rural development impact will be studied at regional level. The environmental impact of the products of these value chains will be assessed as well. Besides, to assure a sustainable impact of the project a novel thematic platform to integrate the stakeholders of the wood region with urban areas will be developed. Besides, BASAJAUN leverages the previous results of successful projects where the innovative materials and systems were designed at laboratory and semi-industrial scale.