6. A circular transition for construction

Cross-cutting policies

The following cross-cutting policies relevant to the circular economy in the construction sector have been identified at the EU level:

• The circular economy is one of the focus areas of the European Green Deal and its New Circular Economy Action Plan (European Commission, 2020[87]), which foresees a Strategy for a Sustainable Built Environment (currently under development) (European Parliament, 2021[88]). Specific EU plans and policies cover various parts of the construction value chain in the buildings sector.

• At the design phase, the current EU circular economy approach for the construction sector is to enhance circular design, focusing on durability and adaptability, as well as waste reduction and high-quality waste management.

• Under the EU Recovery and Resilience Facility (European Commission, 2021[89]), loans and grants have been made available to support reforms and investments undertaken by Member States to mitigate the economic and social impacts of the COVID-19 pandemic while contributing to Europe’s sustainable development. Flagship areas for investments and reforms include energy efficiency through renovation in buildings or re-/upskilling the local labour force.

• The first European Climate Law (European Commission, 2021[90]) proposes a legally binding target of net zero GHG emissions by 2050. This is supposed to be achieved by cutting emissions, investing in green technologies and protecting the natural environment. As emphasised in the European Green Deal, the circular economy has an essential role to play in reaching carbon neutrality, given that a significant share of GHG emissions in the construction sector is attributed to materials management activities (IRP, 2020[5]).

Policies targeting specific life cycle stages

The following policies are relevant for individual life cycle stages of construction at the EU level.

National Waste Management Plan 2021-2027 (NWMP 2021-2027)

The strategic objectives for CDW laid out in the National Waste Management Plan of 2021-2027 include:

• Increasing the rate of preparation for reuse and recycling.

• Promoting selective demolition and on-site recovery.

• Reducing the amount of landfilled waste.

• Increasing the number of drop-off locations for citizens.

• Improving control, monitoring and quality control.

The plan includes a proposal for two indicators to measure progress towards the objectives: the rate of preparation for reuse and recycling of CDW (with a target set to 70%), and the percentage of CDW landfilled (without a set quantitative target). To support a more sustainable management of CDW, the plan proposes a set of concrete measures, including:

• Strengthening the selective sorting of materials, removal of hazardous materials and safe handling.

• Establishing a selective sorting system for wood, minerals, metal, glass, plastics and gypsum.

• Encouraging efficient sorting on site and in inert processing plants.

• Promoting investment in on-site recovery.

• Establishing regional recovery centres.

• Setting up monitoring and control systems (such as a camera system, bridge scales, an online monitoring system, the designation of accredited laboratories).

• Establishing waste collection yards.

• Promoting the use of secondary raw materials, and the revision of technical road standards.

• Enforcing strict legal penalties for the illegal dumping of CDW.

• Introducing legislation on the end-of-waste status.

• Increasing the use of demolition waste for energy purposes.

National Waste Prevention Programme

The National Waste Prevention Programme has been drafted as part of the National Waste Management Plan 2021-2027. The CDW-related strategic objectives include:

• Avoiding the demolition of buildings by possibly repurposing buildings.

• Reducing primary raw materials use in production, construction, maintenance, conservation and in the demolition of construction products and structures.

• Increasing the life cycle of construction products.

• Dramatically reducing the amount of CDW going to landfill.

To achieve these objectives, the programme recommends a number of specific actions:

• Promoting alternative uses for obsolete buildings and structures.

• Setting up a coordination body to bring together the actors of the construction sector to find synergies and prompt common actions.

• Separate dismantling.

• Restructuring the building materials certification system.

• Establishing a waste transfer system.

• Establishing a mandatory minimum percentage of construction waste to green construction procurement in order to increase the reuse and recovery potential of CDW.

• Establishing sectoral legislation on CDW.

Source: Ministry for Innovation and Technology (2021[21]).

Secondary raw materials policy of the Czech Republic

The secondary raw materials policy was developed in collaboration with experts from both academia and industry, and approved by the Czech government in 2014 (Ministry of Industry and Trade of the Czech Republic, 2016[92]). It is the first document establishing a national strategic framework for the use of secondary raw materials, defining 5 strategic objectives and 16 measures, with specific tasks developed in a separate action plan. The strategy identifies 10 commodities and sources of secondary raw materials, including CDW, that are of particular value for the country’s production and export. The list of priority materials remains open to updates as business needs and the economy change. The overall objective of the national strategy is to promote self-sufficiency in raw materials by increasing the use of secondary raw materials.

Strategy for raw materials management in the Southern region of Denmark

The Region of Southern Denmark (Syddanmark) is preparing a new raw materials strategy, which will provide an opportunity to rethink raw materials management in line with the UN Sustainable Development Goals. The consultancy firm Metabolic has helped prepare inputs into this strategy, providing a conceptual framework for the sustainable management of raw materials in the region (Metabolic, 2020[93]). It has also analysed the current supply and consumption trends in the region, examined materials and activities in the value chain with the largest environmental impacts, and identified measures to successfully manage raw materials sustainably.

Austrian quality standards for recycled building materials

Published in 2015 and revised in 2016, the Austrian Recycling Building Materials Ordinance has as its main objectives the standardisation of recycling materials from CDW and their improved marketability. The ordinance sets out the procedures for construction and demolition, including conducting an audit of the on-site conditions prior to demolition. The audit should cover the presence of reusable components and pollutants or contaminants. The evaluation also has to follow the Austrian standard ÖNORM B 3151, which provides the specific dismantling procedure and the required documentation (European Commission, 2022[94]). The ordinance also establishes quality standards for the different recycling materials, defining the permitted input materials and the areas of application (the highest quality being classified as ‘U-A’ materials, which are no longer regarded as waste but as ready-to-use products). One major contribution of the ordinance in promoting a circular construction sector is the establishment of legal certainty and improved confidence in the quality of recycled building materials (Austrian Construction Materials Recycling Association, 2017[95]).

Moreover, the Austrian Construction Materials Recycling Association (BRV), an association of recycling companies formed in 1990 and member of the European Quality Association for Recycling (EQAR), offers recycling enterprises that join the Austrian Recycled Construction Materials Quality Insurance Association (ÖGSV) a quality label for recycled construction materials. The quality label, recognised as a quality assurance scheme under national law, is conferred on the basis of regular external and internal controls, which certify the meeting of quality standards according to guidelines by the ÖGSV. The BRV thus links public and private stakeholders, advising on the use of recycled construction materials and on adhering to national waste legislation (Austrian Construction Materials Recycling Association, 2017[95]).

Quality scheme for recycling CDW in the Netherlands

The recycling of CDW in the Netherlands started in the 1980s with the development of a national waste plan, implemented through landfill bans and recycling targets. The country’s recycling industry was assigned the task to develop a quality assurance scheme for recycled materials, which started with the relatively simple crushing of inert CDW into aggregates. The quality of recycled aggregates, which improved over the years due to advances in production processes and quality controls, is assured through certification schemes covering mandatory requirements from the Soil Quality Decree. Asphalt and wood recycling have also become widespread, although a main alternative outlet for waste wood remains biomass for energy recovery. The recycling of other materials, such as flat glass and PVC windows, has proven more difficult as these constitute smaller fractions of CDW (Fédération Internationale du Recyclage, n.d.[96]).

Quality standards for recycled wood in France

Waste wood in France is classified into three categories: Class A (clean products, with no additives), Class C (heavily admixed products, containing hazardous substances, such as heavy metals), and Class B (anything between Class A and C, i.e. lightly admixed products). Different end uses eventually determine the regulations and quality standards that apply to recycled wood (Besserer et al., 2021[97]), such as the 2003 Order on the “Serviceability of wood-based panels intended for construction” (RECORD, 2019[98]). The basic waste law in France, inscribed under the Environment Code (Ordinance No. 2000-914), aligns French classification codes for waste wood with European ones and sets a landfill ban on waste wood, unless it cannot be reused or recycled (Economic Commission for Europe and Food and Agriculture Organization, 2021[99]).

European Standards for Waste from Electrical and Electronic Equipment (WEEE)

Following the requirement of the WEEE Directive and its article 8(5), the European Commission requested European Standardization Organisations (ESOs) to develop European standards for the collection, logistics and treatment of WEEE, including its recovery, recycling and preparation for reuse. The process of formulating standards is transparent and consensus based. The European Standards (ENs) are reviewed every 5 years, and the Technical Specifications (TS) are reviewed every 3 years. These standards reflect the state-of-the-art technologies and market needs, and can be used to support legislation. They have a harmonizing effect and can remove trade barriers and enhance economic growth (CENELEC, 2017[100]).

The objectives of the standards are to:

• Assist treatment operators in fulfilling the requirements of the WEEE Directive without placing unnecessary administrative burdens on operators of any size, including SMEs.

• Give additional guidance to operators.

• Cover the treatment of waste from all products within the extended scope of the WEEE Directive.

• Cover the collection and logistics of WEEE to allow for proper treatment.

  Source: Adapted from OECD (2022[101]) and from sources reported in the box.

Aggregates levy on sand, gravel and rock in the United Kingdom

In 2002, the United Kingdom introduced an aggregates levy on rock, sand and gravel used as bulk fill in construction. Charged on quarry operators and other organisations that commercially exploit aggregates, this environmental tax is intended to:

• Reduce the environmental costs associated with quarrying operations (such as noise, dust, visual intrusion, loss of amenity and damage to biodiversity).

• Reduce the demand for aggregates and encourage the use of alternative materials (such as secondary aggregate materials exempt from the levy, or recycled aggregate materials).

The levy was introduced at a rate of EUR 2.35 (or GBP 1.60) per tonne (constituting around 20% of the average materials price per tonne). The basis for the tax was informed by a contingent valuation study that estimated the total annual external costs of aggregates extraction to be EUR 558 million. A proportion of the revenue raised has been used to correct market failures, namely, training lorry drivers to transport aggregates more efficiently and less disruptively.

In addition to the levy, the United Kingdom has also implemented two associated policy measures (contrary to some EU Member States, which tend to implement the tax in isolation):

• Revenues raised from the aggregates levy are redistributed to business through a 0.1% cut in the employer’s National Insurance contributions. With this measure, the UK Government intends to shift taxation from the “good” to the “bad” (Seely, 2011[102]).

• A 10% share of the revenues raised from the aggregates levy are redistributed through an Aggregates Levy Sustainability Fund (ALSF). This fund provides a source of funding to R&D projects that are designed to deliver local environmental benefits to areas subject to the environmental costs of aggregates extraction. The first objective of the fund is to reduce the demand of primary aggregates by promoting a greater use of recycled and secondary aggregates (Seely, 2011[102]; EEA, 2008[103]).

The introduction of the levy has contributed to an increase in the use of secondary aggregates. In 2020, the total UK sales amounted to 29%, which is the highest share of secondary aggregates in Europe (Highways, 2020[104]).

Lessons learned from Sweden

An interesting feature of Sweden’s gravel tax has been the decision to incrementally increase the gravel tax over time. This appears to have been effective in sending a price signal to producers and consumers, reinforcing the need to shift away from natural gravel use. The Ministry of Environment predicted that companies would view the tax as an instrument that was likely to increase over time and so they changed their investment decisions. Such a “signal effect” would have strongly influenced companies to adapt their production plans. The gradual tax increases have also helped to facilitate an incremental restructuring across the aggregate industry.

Another lesson learnt from Sweden is the way in which competition issues were considered before the gravel tax was introduced. Although the tax intended to maintain natural gravel deposits in the southern part of Sweden (where natural gravel is scarce), it inadvertently imposed costs in northern Sweden (where natural gravel is abundant). This may have given the impression that the decision to introduce the gravel tax was not a cost-effective option for the North and had in fact distorted the market. A solution may have been to compensate the communities in the North that were most affected by using some of the revenue raised by the gravel tax for equity and social purposes. Instead, all the revenue from the tax was incorporated into the central budget and used to finance general government spending programmes.

Charges on minerals extraction in the Czech Republic

Instead of a tax, levy or duty, 11 other EU Member States, including the Czech Republic, increased charges on mining and extraction. In the early 1990s the Czech Republic introduced charges that were applied to the volume and area of extracted minerals. This system was originally designed to focus predominantly on strategic raw materials, such as coal, metals and high-quality mineral ores. In 2002 the scope of the charges was extended to include aggregate materials. The area charge is equivalent to EUR 3.6-36 (or CZK 100-1 000) per km² per year in accordance with local conditions and the impact to the environment, which is negligible compared to the total costs of a mining company. The beneficiaries of this charge are municipalities on whose territories the mining activities take place (EEA, 2008[103]).

Source: Adapted from OECD (2022[101]) and from the sources reported in the box.

EU Circular Economy Principles for Buildings Design

The EU’s Circular Economy Principles for Buildings Design, developed within the framework of the Construction 2020 initiative and its multi-stakeholder Thematic Group 3 on “Sustainable use of natural resources”, focuses on a set of sustainable design principles with the aim of reducing CDW generation and facilitating the reuse and recycling of construction materials. The guidelines target various groups, including building users, facility managers and owners, design teams, contractors and builders, investors, and government or local authorities, among others. General principles for circular buildings design are presented in addition to principles relevant for specific target groups (European Commission, 2020[35]).

Ellen MacArthur Foundation Circular Buildings Toolkit

Launched jointly by Arup and the Ellen MacArthur Foundation, the toolkit is intended to help designers and planners mainstream the circular economy principles into the design and operation of buildings. The main objective of the toolkit is to translate the principles of the circular economy into concrete strategies and actions for construction projects. Alongside circular building guidelines, the platform showcases exemplary case studies of projects where circular economy principles have already been successfully applied. The toolkit, which is regularly updated with new resources, is free to use and has open access (ARUP and Ellen MacArthur Foundation, n.d.[105]).

Building As Material Banks (BAMB)

The BAMB project, funded under EU Horizon 2020, represented an initiative to promote circular design in buildings through the use of instruments, such as materials passports and reversible building design. The project, which started in 2015 and lasted for three and a half years, brought together 15 partners from 7 European countries in a collaborative effort. Outputs included the development of tools, such as best practices and guidelines, which received inputs from lessons learned during pilot projects (BAMB, n.d.[106]).

New York City’s Zero Waste Design Guidelines

New York City’s Zero Waste Design Guidelines are an example of the application of circular economy principles in construction at the local level. These guidelines are the result of collaboration of architects, planners, developers, city officials and other stakeholders working towards the city’s ambitious goal of sending zero waste to landfill by 2030. Improving the design of the built environment plays a critical role in achieving such a target, with the guidelines meant as a resource to help building designers, operators and planners reduce waste and improve the circularity of material flows (Zero Waste Design, n.d.[107]).

A “master” urban plan in Vienna

Aspern Seestadt is one of Europe's largest urban development projects, offering workplaces and housing to more than 20 000 people as well as spaces for education, culture, shopping and leisure in Vienna’s 22nd municipal district. Its design was conceived from an underlying “master plan” that is flexible and robust enough to respond to change. Seestadt was designed as a city of short distances, giving priority to pedestrians and cyclists, while a well-developed network of public transport and innovative mobility options ensure city-wide connectivity. At the centre of the urban project is the 50 000 m² lake and surrounding park, while a circular boulevard interlinks the various city quarters. The plan for Seestadt was developed with the intention of serving as a basis for a future-proof smart city, detailed yet flexible in its planning. The Vienna City Council has approved the plan to serve as an urban development concept and the basis for all subsequent planning measures (Die Seestadt Wiens, n.d.[108]).

Copenhagen’s Nordhavn

Copenhagen’s new district of Nordhavn, a former industrial shipyard, is setting the benchmark for sustainable urban planning. Urban development in the area has been ongoing for a decade and is planned to end in 2050, providing housing and workspaces for about 80 000 people. Current development plans have put the municipality on track to receive the German Sustainable Building Council’s platinum award certification. The area is being designed as a “five-minute city”, meaning it will be possible to reach any destination or public transport within a five minute walk from any given point in the district. Everything from energy-efficient heating pumps, electric transportation and energy storage systems have been engineered by local companies, utility providers and government entities within the “smart city’s energy lab”. A city-wide energy data system collects real-time information on clean energy production, weather, energy costs and consumption levels at any given moment, allowing authorities to efficiently manage district-wide energy usage. Residents of the Harbour Park residential development regularly give up control of their personal heat supply systems, while a supermarket has technology in place to capture surplus heat from cooling systems and transfer it to a district heating network (Mary Holland, 2021[109]).

EU’s GPP criteria

The European Commission developed model GPP criteria for certain applications or groups of products (European Commission, 2008[110]). The Office Building Design, Construction and Management criteria cover the following aspects and measures, among others:

• Include selection criteria for project managers, architects and engineers with experience in sustainable building design, and for contractors in implementing improved designs and specifications.

• When specifying materials, include criteria to reduce their associated environmental impacts and resource use.

• Give preference to designs that incorporate high efficiency or renewable energy systems.

• Install physical and electronic systems to support the ongoing minimisation of energy use, water use and waste by facility managers and occupiers.

• Within the contract, give contractors responsibility to train the users of the building on sustainable energy use and, where they have ongoing responsibilities, for monitoring and managing energy performance for several years after construction.

GPP in the Netherlands

The Department of Public Works of the Ministry of Infrastructure and the Environment [Rijkswaterstaat, RWS] developed a methodology for infrastructure projects whereby the functional specification of the tender, together with the quality input from the client, ensure an innovative and high-quality solution. The bidder is also asked to respond to specific quality criteria. The RWS uses the “most economically advantageous tender” (MEAT) methodology, including specific sustainability criteria (OECD, 2016[111]).

The RWS decided to focus on two criteria when assessing the sustainability attributes of offers, work processes and associated products: CO₂ emissions and environmental impact. Two instruments were therefore developed: the CO₂ performance ladder (for CO₂ emissions) and “DuboCalc” (for environmental impact). The CO₂ performance ladder is a certification system with which a bidder can show the measures in place to limit CO₂ emissions within the company and its projects, as well as elsewhere in the supply chain. DuboCalc is a life cycle assessment (LCA) based tool that calculates the sustainability value of a specific design based on the materials to be used. Bidders use DuboCalc to compare different design options for their submissions. The DuboCalc score of the preferred design is submitted with the tender price.

Source: Adapted from OECD (2022[101]) and from the sources reported in the box.

Schools as shared use facilities in Western Australia

In Western Australia, public buildings, such as schools, are regarded as an opportunity for local communities to access a range of high-quality services, resources and facilities outside of school hours, providing a greater return on a public investment. Several individual arrangements between schools, local governments and communities already exist. However, a guide has been prepared by the Department of Sport and Recreation in collaboration with the Department of Education to provide a standardised approach to developing shared use facilities. The guide is intended for stakeholders considering the shared use of community and school facilities, and informs on their planning, development and management. Besides the several benefits to both schools and local communities, shared use facilities provide advantages in terms of minimising the duplication of resources by maximising public access (Government of Western Australia, n.d.[112])

Social purpose mixed-use development in Toronto

The Infrastructure Institute of the University of Toronto’s School of Cities partnered with the real estate agency that manages the City of Toronto’s real estate portfolio to promote the mixed-use model, blending residential, commercial and other uses, for the creation of more affordable housing. Examples of mixed-use include the co-location of schools, libraries, recreation centres and childcare into community hubs, or affordable housing built on top of fire stations and paramedic centres. The institute also launched a series of free training models, and will provide an accelerator programme for organisations undertaking social purpose real estate projects (University of Toronto, 2022[113]).

Green Deals for innovation in circular activities in the Netherlands

Green Deals in the Netherlands offer a best practice example of collaboration between government, private companies and other stakeholders in addressing cross-cutting issues. Such deals consist of mutual agreements defining specific initiatives, actions and quantitative targets for all involved stakeholders. The government then commits to the removal of regulatory obstacles to support sustainable projects. Several of these deals included projects related to innovation and the circular economy, but mostly involve recycling (Green Deal, n.d.[117]).

Public-private digital discussion platform for a circular construction sector in the Netherlands

Rijkswaterstaat, in collaboration with the National Real Estate company and the National Standardisation body, sought to achieve a consensus on the concept of a “circular building sector” through the establishment of a public-private discussion platform. Discussions with several stakeholders covered issues such as how to measure circularity, with which type of tools, and the information required. As a result, guidelines were drawn up from the discussions, including the “Core method for measuring circularity in the construction sector” or “Passports for the construction sector”. More recently, the focus of discussion has shifted to information and data exchange (PLATFORM CB’23, 2020[118]; DigiDealGO, 2020[119]).

Source: Adapted from OECD (2022[101]) and from sources reported in the box.

Circular Economy Training Programme

With the support of nine Slovenian ministries, EIT Climate-KIC has developed a Circularity Thinking course for stakeholders and practitioners of the Slovenia Deep Demonstration project (Climate-KIC, 2022[120]). Based on research and a feasibility study, the programme aims to implement change by developing an understanding of how circular economy tools and approaches can be used in developing strategies, policies and plans. It is specifically designed for individuals working in municipalities and governments, as well as business associations working at the national level, to understand how to support the transition to a circular society. It considers the complexities of systems and how the perspectives of different stakeholders need to be taken into account.

Holland Circular Hotspot

Holland Circular Hotspot is a private-public platform composed of the HCH foundation, (local) government authorities, knowledge institutes and companies (Holland Circular Hotspot, n.d.[121]). It serves as a network where key stakeholders collaborate and exchange knowledge with the aim of stimulating entrepreneurship in the field of circular economy. The founding of HCH emerged from one of the actions of the Dutch government programme “Nederland Circulair 2050”.

The activities of Holland Circular Hotspot are to:

• Offer insights in and access to the network of Dutch circularity pioneers.

• Develop and exchange knowledge on international market opportunities for a circular economy.

• Create circular opportunities internationally by matching offer and demand.

• Support companies and organizations that want to contribute to the internationalization of a circular economy.

• Stimulate cooperation between the private sector, knowledge institutions, governments and other relevant parties.

• Provide international visibility of Dutch CE innovations/best practices.

• Facilitate access to Dutch and international (financing) instruments and programmes.

MSc programme Circular Design in the Built Environment – TU Eindhoven, Netherlands

This programme, at one of the main technical universities in the Netherlands, is designed to provide students with theoretical knowledge and practical (real world) assignments, who want to understand energy, waste and material flows, and the associated emissions that come with building in the construction sector (Eindhoven University of Technology, n.d.[122]). Mainstreaming the circular economy curricula into courses on traditional urban planning, architecture and design helps to prepare the next generation of decision makers, designers and home-owners to follow ecological principles when thinking and building the homes and facilities of the future.

France’s National Buildings Database

The National Buildings Database [Base de données nationale des bâtiments] in France is an open-data project cross-sourcing geospatial information from about 20 different datasets in the public domain, representing a unified identity map of more than 21.4 million buildings on French (metropolitan) territory (DATA.GOUV.FR, 2022[123]). The data relate to the morphology of buildings, the type of uses, embedded materials and technical equipment, energy consumption and performance, as well as administrative and economic data. This unified database allows users to navigate information on the national built environment, bypassing the limitations of individual datasets. Relevant applications include the fields of energy transition (such as the Bat-ID project on monitoring buildings’ energy renovation), circular economy, social housing, infrastructure networks, and others. Since April 2022, publicly available data can be downloaded directly from the government’s website.

Data-driven CDW management in the Netherlands

Rijkswaterstaat, part of the Dutch Ministry of Infrastructure and Water Management, is responsible for the design, construction, management and maintenance of the main infrastructure in the Netherlands. The maintenance of over 6 000 assets, including bridges, sluices, viaducts and aqueducts, and over 3 000 kilometres of national road infrastructure, would not be possible without access to detailed information. Notably, information on assets’ performance, their materials and components, as well as the repair and maintenance undertaken over their lifetime, is crucial for the potential future reuse of embedded materials. Compared to previous years, in which this informational aspect was largely overlooked, Rijkswaterstaat is now explicitly seeking to become a data-driven organisation (Rijkswaterstaat, 2019[124]).

Some of Rijkswaterstaat’s data-driven initiatives include discussions on digitalising the construction sector, for example, through the piloting of Dutch start-ups, such as Excess Materials Exchange, which aims to develop a cross-sectoral “dating site for secondary materials” based on blockchain technology (Excess Materials Exchange, 2019[125]), and Madaster, an online materials library, aiming to become the central register of construction materials use and to facilitate their reuse (Madaster Foundation, 2020[126]).

Source: Adapted from OECD (2022[101]) and from the sources reported in the box.

Bulgaria’s digital transformation strategy

Adopted in July 2020, the Digital Transformation of Bulgaria strategy for 2020-2030 outlines the vision, goals and general policy framework for the digitalisation of the country’s key public and economic sectors. The strategy takes into account the UN 2030 Agenda for Sustainable Development and the role of digital tools to achieve the SDGs, as well as the EU guidelines and commitments to achieve the digital transition. In line with the European Green Deal, the strategy envisions specific measures targeted at the digitalisation of the construction sector, which should ensure the application of circular economy principles. More specifically, the digitalisation of the construction sector is intended to cover the entire life cycle of buildings using digital databases, 3D models and electronic passports for the improved design and management of construction, repair, renovation and demolition works (Bulgarian Government, 2020[127]).

Estonia’s digital construction cluster

In 2015, the e-difice Digital Construction Cluster was launched to bring together private and public stakeholders to initiate the digital transformation of the Estonian construction sector. In 2019, this was superseded by the Estonian Digital Construction Cluster, the main purpose of which is to develop an innovative digital construction environment that encompasses the entire construction life cycle and value chain (European Commission, 2020[128]).

Source: Adapted from OECD (2022[101]) and from the sources reported in the box.

Circular Economy Business Support Service in Scotland

Scotland’s Circular Economy Business Support Service is a one-to-one service supported by the European Regional Development Fund, providing consultancy to SMEs across all sectors. The service is intended to help companies discover more circular ways of doing business, including adopting principles of sharing resources, modular design, reuse and repair, remanufacturing and reprocessing. Once the service is completed, businesses may be eligible for funding for prototyping, lab testing or field testing activities via the Circular Economy Development Grant. The Circular Economy Investment Fund is available for projects nearing commercialisation (Zero Waste Scotland, 2020[129]).

Circular Business Challenge in the Netherlands

Another exemplary support programme for SMEs is the Circular Business Challenge (previously Circular Economy Challenge) provided by Rabobank since 2014. This is a regional initiative to help entrepreneurs develop circular-inspired businesses in the Netherlands. Companies and entrepreneurs are offered practical workshops and other forms of support, including financial support, to develop innovative business models. Over 50 companies have participated in the challenge, acting as a source of inspiration and serving as role models for circular entrepreneurship in the country (Rabobank, n.d.[130]).

European Framework for Sustainable Buildings

Developed specifically for SMEs in the construction and demolition sector by the European Commission, Level(s) is a voluntary reporting framework to help professionals working in the built environment to assess and monitor the sustainability performance of buildings. From developers and investors to architects, engineers, contractors and building occupants, this open-source tool helps complement existing assessments and certification schemes to encourage more consistency and a common language between projects and countries. Project partners are Green Building Councils throughout Europe (European Commission, n.d.[131]).