Construction and demolition waste

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The construction and demolition sectors are under increasing pressure to improve performance, reduce waste and increase recycling and reuse in a drive towards a more circular economy. Reducing waste is a priority for the European Union and the UK Government and there are many regulations, measures and targets to reduce waste within the construction industry. For example, the government’s Resources and Waste Strategy (2018)[1] aims ‘to eliminate avoidable waste of all kinds by 2050’ in England, this includes waste from the construction sector; both buildings and infrastructure.

Steel construction products and systems are inherently low waste through all stages of the building life cycle; production, construction and in particular at the end-of-life of buildings. This article explains some of the measures introduced to reduce construction, demolition and excavation (CD&E) waste and sets out steel’s credentials as a low waste, circular construction material.

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A skip of mixed construction waste; a common sight on many construction sites

[top]Background

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Waste Arisings from construction, demolition and excavation sectors (2008‐2016)

The construction sector is the largest user of materials in the UK and produces the biggest waste stream in terms of tonnage. In 2016, the total waste in England was estimated to be 189 million tonnes, with construction, demolition and excavation contributing 120 million tonnes to this total (61%). Of this an estimated 60 million tonnes (54%) was construction and demolition waste, 51 million tonnes (46%) excavation waste and the remaining 9 million tonnes (8%), was dredging spoil.

The figure (right) shows estimates of the breakdown of CD&E waste in the UK between 2008 and 2016; the latest available dataset. It should be noted that that establishing definitive data on national waste arisings is difficult and also data collection and assessment methodologies evolve over time. This may explain the apparent increase in CD&E arisings between 2008 and 2016.

UK Government statistics show that 91% of non-hazardous construction and demolition waste is recovered for some form of recycling. However, much of this is heavy, voluminous materials such as concrete, brick and asphalt, which is recovered but generally downcycled for use as aggregates. This does still leave nearly 5 million tonnes sent to landfill each year. For excavation waste it is estimated that 47% was recovered, equivalent to 23 million tonnes, with the remaining 26 million tonnes disposed of.

The figure (below) shows the breakdown of key demolition waste products from a typical non-domestic building based on a pre-demolition audit of a school building carried out by BRE.

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Breakdown of key demolition waste products by weight - BRE pre-demolition audit on a school building


Research commissioned by WRAP suggests that 10 – 30% of the construction materials that end up as waste on site have never actually been used and that the true cost of construction waste can be up to 15 times more than the waste disposal (skip hire) costs when labour and material costs are taken into account. The construction industry therefore is increasingly coming under pressure to improve resource efficiency and reduce waste.

The revised Waste Framework Directive (2008/98/EC)[2] came into force on 12 December 2008. Article 40 requires EU member states to bring into force the laws, regulations and administrative provisions necessary to comply with this Directive.

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Evolution of the UK waste management hierarchy

Such provisions have needed to take account of the five-step waste management hierarchy shown (right).

The Waste Framework Directive)[2] requires the UK to design and implement waste prevention programmes and sets the target to reuse and recycle 70% of construction and demolition waste by 2020.

The figure (below) shows the recovery rate for C&D waste in EU member states in 2011. As shown, most Member states are already (even in 2011, which is the latest EU data available) exceeding this 70% target. More challenging targets are therefore required to encourage moving up the waste hierarchy and doing better than simply crushing and downcycling the majority of EU C&D waste.

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UK Waste hierarchy


The government’s Resources and Waste Strategy (2018)[1] aims ‘to eliminate avoidable waste of all kinds by 2050’ in England. This includes waste from the construction sector (both buildings and infrastructure). As part of this strategy, work is underway, led by the Green Construction Board, to define ‘zero avoidable construction waste’ and to develop a routemap setting out how and when this can be achieved.

[top]Avoidable construction and demolition waste

Avoidable waste is interpreted as materials, products or components that can be prevented from becoming waste and this is the primary objective of ‘zero avoidable waste in construction’ in line with the waste hierarchy. Examples of this include designing out waste for new buildings by designing for deconstruction and disassembly, efficient manufacturing processes, extending the life of buildings, disassembly for reuse and reducing surplus materials.

If waste cannot be prevented then the secondary objective is for waste to be kept at its highest level by following the waste hierarchy, which in descending order of preference, is preparing for reuse (for example repair or remanufacture), closed-loop recycling (where waste is used as a feedstock in the same process) and open-loop recycling (where waste is used as a feedstock for a different purpose). If waste is managed in this way, then it is ‘avoidable’ as it has a further use and is not being disposed of to landfill or as energy recovery.

[top]Unavoidable construction and demolition waste

However, some of the waste produced by the building and infrastructure sector may be unavoidable. Some waste is considered unsuitable for further use, for example materials that are now considered hazardous such as asbestos, asbestos contaminated materials, or material treated with persistent organic pollutants. All other waste is avoidable waste, in that it can either be prevented, reused or recycled.

The concept of the waste hierarchy has been embedded within the working interpretation of zero avoidable waste in construction, in line with the government’s Resources and Waste Strategy and the legislation following the EU Waste Framework Directive. The government is preparing the national Waste Prevention Programme which will include the construction sector as one of the key sectors.

Other relevant Government strategies include:

[top]Resources and Waste Strategy

The Resources and Waste Strategy[1] published in 2018 applies to England and sets out how the government will preserve material resources by minimising waste, promoting resource efficiency and moving towards a circular economy in England. It is in line with the 25 Year Environment Plan, in which the government pledged to leave the environment in a better condition for the next generation. The Strategy includes high level ambitions of eliminating avoidable plastic waste over the lifetime of the 25 Year Plan (2042), doubling resource productivity, and eliminating avoidable waste of all kinds by 2050.

[top]Waste Prevention Programme

The Waste Prevention Programme (WPP) is a requirement of the revised EU Waste Framework Directive (2008/98/EC)[2] and was last produced for England by Defra in 2013. The aim of the programme is to ‘improve the environment and protect human health by supporting a resource efficient economy, reducing the quantity and impact of waste produced whilst promoting sustainable economic growth’. The programme includes several measures such as standards for reuse, leasing models, repair of products, a waste prevention loan fund and a set of metrics though none are specifically targeted at the construction sector. A new programme is expected in 2020 with the construction sector likely to feature as a priority sector.

[top]Industrial Strategy

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Industrial Strategy[3]

The Industrial Strategy[4], published in 2017, is a White Paper which sets out four grand challenges for the UK and the wider economy including artificial intelligence and data revolution, clean growth, the future of mobility and the needs of an ageing society and intends to support innovation to help deliver a new industrial revolution to address these challenges. The Strategy includes a number of commitments including financial support to progress these challenges such as Industrial Strategy Challenge Fund programmes. The construction sector is identified as a priority business sector and a Construction Sector Deal is part of the Strategy.

[top]Industrial Strategy: Construction Sector Deal

The Construction Sector Deal[3] sets out an ambitious partnership between the industry and the government that aims to transform the sector’s productivity through innovative technologies and a more highly skilled workforce. The Sector Deal builds on Construction 2025[5], published by the government and the Construction Leadership Council (CLC) in 2013, and provides the framework for a sector that delivers:

  • a 33% reduction in the cost of construction and the whole life cost8 of assets
  • a 50% reduction in the time taken from inception to completion of new build
  • a 50% reduction in greenhouse gas emissions in the built environment –supporting the Industrial Strategy’s Clean Growth Grand Challenge
  • a 50% reduction in the trade gap between total exports and total imports of construction products and materials


These goals will be met by focusing on three areas: digital techniques, offsite manufacturing and whole life asset performance. The government and the sector are investing in the Industrial Strategy Challenge Fund (ISCF) Transforming Construction programme, as well as supporting training and infrastructure projects.

[top]Regulations and other drivers

To help to achieve the UK’s waste reduction targets, a number of measures have been introduced to reduce and manage waste through all stages of the design, construction and at the end-of-life of buildings. These apply to designers and construction and demolition contractors.

[top]Duty of Care Regulations

Construction companies have a legal ‘duty of care’[6] with respect to any waste that they generate on site. This duty applies to anyone who produces, imports, transports, stores, treats or disposes of controlled waste from business or industry. Commercial, industrial and household wastes (including hazardous/special wastes) are classified as ‘controlled waste’. The duty of care also applies to anyone who acts as a waste broker. Companies must ensure that:

  • Their waste is stored, handled, recycled or disposed of safely and legally
  • Their waste is stored, handled, recycled or disposed of only by businesses which hold the correct, current licence to do the work
  • They record all transfers of waste between their and another business, using a waste transfer note (WTN) signed by both businesses
  • They keep all WTNs for at least two years
  • They record any transfer of hazardous/special waste between their business and another business, using a consignment note signed by both businesses
  • They keep all consignment notes for at least three years.


If the company is a sub-contractor and the main contractor arranges for the recovery or disposal of waste that they produce, the sub-contractor is still responsible for those wastes under the duty of care.

This duty of care has no time limit. It extends until the waste has either been finally disposed of or fully recovered.

If companies produce or deal with waste that has certain hazardous properties, they will also have to comply with the hazardous/special waste regulations.

[top]Hazardous/Special Waste Regulations

Waste that has hazardous properties which may make it harmful to human health or the environment is known as hazardous waste[7] in England, Wales and Northern Ireland and special waste in Scotland.

The definition of hazardous/special waste is relatively wide and covers objects that contain hazardous substances such as televisions and fluorescent light tubes. As a result, many companies are likely to produce some form of waste that is hazardous and need to deal with it accordingly.

The European Waste Catalogue[8] (EWC) contains a list of all types of waste and each waste type is given a six-digit code. Hazardous waste is identified in the EWC with an asterisk (*):

  • Some wastes, called 'absolute entries', are always classed as hazardous, for example inorganic wood preservatives, waste paint or varnish remover and wastes from asbestos processing
  • Other wastes, called 'mirror entries', are classed as hazardous if they are present in amounts above certain threshold concentrations, for example some wastes containing arsenic or mercury.


The environmental regulator, this is the Environment Agency in England and Natural Resources Wales in Wales, tracks the movement of hazardous waste through the consignment note system. This ensures that waste is managed responsibly from where it is produced until it reaches an authorised recovery or disposal facility. Companies must ensure that all hazardous waste is stored and transported with the correct packaging and labelling.

Hazardous waste can only be disposed of at a landfill site that is authorised to accept it. Some landfill sites that are classified as non-hazardous may be able to take certain stable non-reactive hazardous wastes if they have the appropriate facilities. A landfill site authorised to accept hazardous waste may not be able to take all types of hazardous waste.

Hazardous waste must be treated, before it can be sent to landfill, to meet the limits set by a landfill site's waste acceptance criteria (WAC). Treatment means physical, thermal, chemical or biological processes, including sorting, that change the characteristics of the waste in order to:

  • Reduce its volume
  • Reduce its hazardous nature
  • Make it safe to handle
  • Make it easier to recover.


For further information on current legislation with respect to construction waste see the Environment Agency guidance.

[top]Landfill Tax and Aggregates Levy

Introduced in 1996, the Landfill Tax remains the primary fiscal incentive to encourage waste producers and the waste management industry to switch to more sustainable alternatives for disposing of material. The tax has risen steadily since 1996, in line with inflation and, from April 2020, the standard rate is £94.15 per tonne. A lower rate of £3 per tonne applies to inactive (or inert) waste.

Reflecting the large volume of aggregates consumed by the construction industry (over 200 Mt pa), the Aggregates Levy was introduced in 2002 to reduce demand for primary aggregates and to encourage the use of recycled and secondary aggregates. The levy is payable by all businesses that exploit aggregate in the UK and is currently £2.00 per tonne of primary aggregates. The tax is payable on sand, gravel or rock that has either been quarried, dredged or imported.

[top]Site Waste Management Plans Regulations (SWMP)

Effective construction site waste management is a key tool for improving efficiency and reducing waste. Introduced in April 2008, the SWMP Regulations[9] made it compulsory to develop and implement SWMPs on construction projects costing more than £300k. Defra guidance[10] advised that a SWMP should:

  • Identify the different types of waste that will be produced by the project, and note any changes in the design and the materials specification that seek to minimise this waste
  • Consider how to re-use, recycle or recover the different wastes produced by the project
  • Require the construction company to demonstrate that it is complying with the duty of care regime
  • Record the quantities of waste produced.


The Regulations also required a more detailed analysis to be conducted on projects costing more than £500k.

Although the Site Waste Management Plans Regulations Act 2008 was repealed on the 1st December 2013 as part of Government’s Red Tape Challenge, SWMPs continue to be used on many construction sites and by responsible contractors.

[top]BREEAM

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BREEAM New Construction 2018 (UK)[11]

BREEAM is BRE’s Environmental Assessment Method for buildings. Under BREEAM, credits are awarded under a number of environmental categories, one of which is waste, and the buildings rated according to its total score.

Under BREEAM New Construction 2018 (UK)[11] the following waste issues are assessed:

  • Wst 01 Construction waste management (7 credits)
    Improving resource efficiency through developing a pre-demolition audit and a Resource Management Plan, maximising the recovery of material during demolition and diverting non-hazardous waste from landfill.
  • Wst 02 Use of recycled and sustainably sourced aggregates (1 credit)
    Encouraging the use of recycled or secondary aggregate or aggregate types with lower environmental impact to reduce waste and optimise material efficiency.
  • Wst 03 Operational waste (1 credit)
    Encouraging the diversion of operational waste form landfill through the provision of space and facilities allowing the segregation and storage of recyclable waste.
  • Wst 04 Speculative finishes, Offices only (1 credit)
    Specification of floor and ceiling finishes only where agreed with the occupant or, for tenanted areas where the future occupant is unknown, installation in a show area only, to reduce wastage.
  • Wst 05 Adaptation to climate change (1 credit)
    Encouraging consideration and implementation of measures to mitigate the impact of more extreme weather conditions arising from climate change over the lifespan of the building.
  • Wst 06 Design for disassembly and adaptability (2 credits)
    Encouraging consideration and implementation of measures design options related to functional adaptability and disassembly, which can accommodate future changes to the use of the building and its systems over its lifespan.


BREEAM does not specifically address any issues in connection with demolition waste reduction or management although credit Wst 02 does encourage the use of recycled and secondary aggregates.

The most highly weighted waste issue under BREEAM is Construction waste management (Wst 01) under which credits are awarded according to the benchmarks shown in the table.

Non-hazardous construction waste (excluding demolition and excavation waste) benchmarks
BREEAM credits Amount of waste generated per 100m2 (gross internal floor area)
Volume (m3) Weight (tonnes)
One credit ≤13.3 ≤11.1
Two credits ≤7.5 ≤6.5
Three credits ≤3.4 ≤3.2
Exemplary level ≤1.6 ≤1.9

The only minimum construction waste requirements under BREEAM are that one Wst 03 credit is required to obtain an ‘Excellent’ rating, and both one Wst 01 and one Wst 03 credit are required to obtain an ‘Outstanding’ rating.

Where there are existing buildings on the site being developed, it is a requirement under Wst 01 that a pre-demolition audit be undertaken.

A further credit is available under Wst 01 where it can be demonstrated that a significant proportion of non-hazardous C&D waste generated by the project, has been diverted from landfill.

Wst 01 requirements for diversion from landfill
BREEAM credits Type of waste Volume (%) Tonnage (%)
One credit Non-demolition 70 80
Demolition 80 90
Excavation N/A N/A
Exemplary level Non-demolition 85 90
Demolition 85 95
Excavation 95 95

Further information on the assessment of waste under BREEAM is available in the Waste section of the BREEAM New Construction Technical Manual[11].

[top]ICE demolition protocol

The ICE Demolition Protocol[12] provides an overarching framework which enables the waste hierarchy to inform approaches for managing buildings and structures at the end of their lives. First launched in 2003, the Demolition Protocol has been adopted and implemented across a range of public and private sector projects and is included in Supplementary Planning Guidance in a number of Local Authorities.

The Protocol describes the overarching implementation approaches for Materials Resource Efficiency (MRE) associated with demolition and construction activities, with a decision-making framework which emphasises the need to reuse, then recycle, with landfill as a last resort. It provides a number of overarching methodologies which include:

  • Providing a Deconstruction/Demolition Recovery Index (DRI) – this is the percentage of building elements, products or materials to be reused or recycled
  • Estimating bulk quantities through a pre-demolition audit, summarised in a Demolition Bill of Quantities (D-BOQ)
  • Providing a new build recovery index (NBRI) – describing the percentage of building elements, products or materials recovered for use in the new build
  • Demonstrating compliance with Site Waste Management Plan requirements
  • Describing how carbon benefits, through avoided haulage movements, can be realised and estimated easily
  • Providing data for in-house and local authority monitoring of annual construction and demolition waste arisings.


[top]EU Construction and Demolition Waste Management Protocol

Launched in 2018, this Protocol[13] fits within the EU Construction 2020 strategy[14], as well as the Communication on Resource Efficiency Opportunities in the Building Sector[15]. It is also part of the more recent Circular Economy Package that the European Commission has adopted. Its overall aim is to increase confidence in the C&D waste management process and the trust in the quality of C&D recycled materials. This will be achieved by:

a) Improved waste identification, source separation and collection; b) Improved waste logistics; c) Improved waste processing; d) Quality management; e) Appropriate policy and framework conditions.

The Protocol includes good practices from across the EU that can be sources of inspiration for both policy makers and practitioners. It also includes an overview of definitions and a checklist for practitioners.

[top]Pre-demolition audits

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Elements of a pre-demolition audit (EU guidelines for waste audits)

Any demolition, renovation or construction project needs to be well planned and managed in order to reduce environmental and health impacts while providing important cost benefits.

To give guidance on pre-demolition audits, the European Commission published guidelines for waste audits in 2018. The Guidelines provide information about best practices for the assessment of construction and demolition waste (CDW) streams prior to demolition, deconstruction or renovation of building or infrastructure. The aim of the document is to facilitate and maximize recovery of materials and components for beneficial reuse and recycling without compromising the safety measures and practices outlined in the EU Construction & Demolition Waste Management Protocol. The Guideline supports the targets of the Circular Economy Package presented by the European Commission in 2015. In this Circular Economy Package, CDW is identified as a key issue and the preliminary assessment is an essential part of construction and demolition waste management.

Pre-demolition or pre-deconstruction audits involve an assessment of a building before it is to be demolished (or prior to a major refurbishment) to understand the types and quantities of materials that will be produced and make recommendations on how these materials can be managed. They also look at what targets can be set. A site visit is usually undertaken along with the analysis of any drawings. Assessment of the viable recovery routes for materials are given including reuse (and the potential reuse value), recycling on and offsite (and the associated cost savings), energy recovery and landfill.

The audit should also consider any relevant legislation such as the requirements for Environmental Permits if waste is to be utilised onsite or any waste that may be hazardous and as such needs to be managed in accordance with hazardous waste legislation. Environmental savings can also be determined.

The elements of a pre-demolition audit are shown (right).

For the case of structural steelwork, recommendations for the pre-deconstruction assessment of existing structures is provided in SCI’s Protocol for structural steel reuse (SCI P427).

[top]C&D waste management tools

The BRE has developed a suite of SMARTWaste tools and associated consultancy services, to measure, manage and reduce construction and demolition waste. SmartWaste Waste Management enables clients to measure, report on and manage waste generated on their construction sites, whether these waste materials are retained, reused on site, or sent for recycling and processing

[top]Waste in steel construction

Steel construction products are inherently low waste products through all phases of the design, production, construction and deconstruction process. Designers and specifiers can be confident that, by choosing steel construction products and systems, material resources are optimised, waste is minimised and recycling is maximised.

[top]Steel production

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Scrap being loaded into the steel furnace

By-products from iron and steel making, including sludges, slags and dust, are beneficially used by the construction industry in a range of products including roadstone, lightweight aggregate and as a substitute for Portland cement.

Slag is the voluminous by-product accounting for approximately 90% by mass. Global average recovery and recycling rates for blast furnace slag and steel-making slag are 100% and 80% respectively; leading to an overall material efficiency rate of 97.6% worldwide.

British Steel and Tata Steel, the major steel producers in the UK, recycle or reuse over 90% of their process residues.

Approximately 2 million tonnes of blast furnace slag is produced in the UK annually. Of this around 75% is quenched and this is then processed to produce ground granulated blast furnace slag (GGBS), which is used by the concrete industry as a cement replacement material. The remainder is air-cooled and is used as an aggregate. The split between the two uses is dictated by production choices, economics and demand.

[top]Manufacture

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Swarfe produced by drilling holes in structural steel members

During component manufacture, computer controlled, fully or semi-automated production lines ensure that wastage of steel is minimised. The typical wastage rate for fabricating structural steel products is just 4% and any off-cuts, trimmings, swarfe, etc. from the production process are 100% recycled into new steel. For steel cladding and decking products, wastage rates are typically 1.5 – 2% and around 1.8% for secondary structural products such as rails, purlins, studs, etc.

[top]Construction

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Transporting structural steel efficiently and with minimum packaging

Steel products are delivered to the construction site pre-engineered to the correct dimensions; consequently there is no site waste. Furthermore the quality of factory produced steel construction products and the dimensional stability of the material itself, means that there are few defects and hence little site waste. Steel products are delivered to site with minimal packaging. Packaging comprises mainly timber pallets and bearers and plastic or metal strapping. Timber packaging is generally reused by the haulage company making site deliveries and the strapping is either recycled or reused.

[top]Deconstruction

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A steel frame being reused and extended at a distribution warehouse in Leeds

When a building is deconstructed, the ease with which steel construction products can be reclaimed, coupled with the economic value of scrap steel, means that virtually all steel is recovered and either reused or recycled. Currently 96% of steel from deconstructed buildings in the UK is recovered.

[top]Designing out waste

To date the focus of C&D waste reduction has been mainly on site waste management practice. Arguably however, the best opportunities for improving materials resource efficiency in construction projects occur during the design stage. Implementing these opportunities can provide significant reductions in cost, waste and carbon emissions.

There are five key principles that design teams can use during the design process to reduce waste. These principles are based on extensive consultation, research and work carried out by WRAP[16] directly with design teams . They are summarised below together with questions the design team should address to design out waste.

[top]Design for reuse and recovery

Design for reuse of material components and/or entire buildings has considerable potential to reduce the environmental burdens from construction. Much of this is common sense as, with reuse, the effective life of the materials is extended and thus annualised burdens are spread over a greater number of years. Reuse, in the waste hierarchy is generally preferable to recycling, where additional processes are involved, some of which will have their own environmental burdens.

Key questions for the design team include:

  • On previously developed sites, can materials from demolition of the building be reused in the design?
  • Can reclaimed products or components be reused?
  • When materials are reused, can they be reused at their highest value?
  • Can any excavation materials be reused?
  • Can cut and fill balance be achieved? How can it be optimised to avoid removal of spoil from site?


In addition to considering reuse of previously developed sites, designers are encouraged to think about how their new buildings can be designed in ways that they can be dismantled more easily for reuse and recovery in the future.

[top]Design for off-site construction

The benefits of off-site factory production in the construction industry are well documented and include the potential to considerably reduce waste especially when factory manufactured elements and components are used extensively. Its application also has the potential to significantly change operations on site, reducing the amount of trades and site activities and changing the construction process into one of a rapid assembly of parts that can yield many benefits including:

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Rapid construction using steel modules
  • Reduced construction related transport movements;
  • Improved health and safety on site through avoidance of accidents;
  • Improved workmanship quality and reducing on site errors and re-work, which themselves cause considerable on site waste, delay and disruption; and
  • Reduced construction timescales and improved programmes.


Off-site construction is one of a group of approaches to more efficient construction sometimes called Modern Methods of Construction (MMC) that also include prefabrication and improved supply chain management. Technologies used for off site manufacture and prefabrication include light gauge steel framing systems and modular and volumetric forms of construction which offer great potential for improvements to the efficiency and effectiveness of UK construction. To assess the suitability of off-site construction, design teams should consider the following questions:

  • Can the design or any part of the design be manufactured off site?
  • Can site activities become a process of assembly rather than construction?


Experience shows that the choice of off-site construction can have a significant influence on initial design considerations and therefore should be considered during the early project stages. Key considerations with respect to the choice of off-site construction include:

  • Space planning, especially structural and planning grids
  • Structural design/system selected
  • Project buildability
  • Procurement routes
  • Consideration of how aesthetics are affected by off-site construction.


[top]Design for materials optimisation

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Resource efficient, long-span cellular beam construction

Good practice in this context means adopting a design approach that focuses on materials resource efficiency so that less material is used in the design, i.e. lean design, and/or less waste is produced in the construction process, without compromising the design concept.

Three main areas offer significant potential for waste reduction

  • Minimisation of excavation
  • Simplification and standardisation of materials and component choices
  • Dimensional coordination.


In order to assess the best project opportunities for material optimisation, the following key questions need to be answered by the design team:

  • Can the design, form and layout be simplified without compromising the design concept?
  • Can the design be coordinated to avoid/minimise excess cutting and jointing of materials that generate waste?
  • Is the building designed to standard material dimensions?
  • Can the range of materials required be standardised to encourage reuse of offcuts?
  • Is there repetition & coordination of the design, to reduce the number of variables and allow for operational refinement, e.g. reusing formwork?


BS 8895; Designing for material efficiency in building projects gives recommendations for the process by which both design and project teams can seek to maximize material efficiency through design. It outlines what material efficiency in design involves and how the process is implemented through the Strategic Definition and Preparation and Brief stages of the RIBA Plan of Work.

BS 8895 is in four parts:

  • Part 1[17]: Code of practice for Strategic Definition and Preparation and Brief was published in 2013. It covers Stages 0 (Strategic Definition) and 1 (Preparation and Brief) of the RIBA Plan of Work.
  • Part 2[18] is a code of practice for designing for material efficiency, which is a key part to achieve higher levels of resource efficiency in a building project. It gives recommendations for the processes, information exchanges and responsibilities for design teams to incorporate into projects at the ‘Concept Design’ and ‘Developed Design’ stages of a building project.
  • Part 3[19] was published in 2019 and provides a code of practice for technical design which builds on parts 1 and 2 by setting out the process for integrating material efficiency into Stage 4 of the RIBA Plan of Work
  • Part 4: Code of practice for operation, refurbishment and end of life (yet to be published) will aid end users (owners, operators, facilities managers) by providing information that will help them make informed decisions regarding resource efficiency during operation, retrofit and end of life (reclamation).

[top]Design for waste efficient procurement

Designers have considerable influence on the construction process itself, both through specification as well as setting contractual targets, prior to the formal appointment of a contractor/constructor. Designers need to consider how work sequences affect the generation of construction waste and work with the contractor and other specialist subcontractors to understand and minimise these. Once work sequences that cause site waste are identified and understood, they can often be ‘designed out’.

Key questions for the design team include:

  • Has research been carried out to identify where on site waste arises?
  • Can construction methods that reduce waste be devised through liaison with the contractor and specialist subcontractors?
  • Have specialist contractors been consulted on how to reduce waste in the supply chain?
  • Have the project specifications been reviewed to select elements/components/materials and construction processes that reduce waste?


[top]Design for deconstruction and flexibility

Designers need to consider how materials can be recovered effectively during the life of the building when maintenance and refurbishment is undertaken or when the building comes to the end of its life.

There are a number of barriers to large scale reuse of materials and components in the construction industry. Perhaps the greatest difficulty in applying design for deconstruction and flexibility however, is the time frame involved, which is very often longer than the financial and professional involvement of the client and design team. As buildings are sold and re-sold over time, any connection between the original client and designer and the ultimate beneficiary of design for deconstruction and flexibility can become very remote.

Nevertheless, designing for future generations is embedded in the concept of long-term sustainable development and the circular economy. Not to design with design for deconstruction and flexibility in mind limits the future potential of design for reuse.

To assess the best project opportunities for reducing waste at deconstruction stage, the following key questions need to be addressed:

  • Is the design adaptable for a variety of purposes during its life span?
  • Can building elements and components be maintained, upgraded or replaced without creating waste?
  • Does the design incorporate reusable/recyclable components and materials?
  • Are the building elements/components/materials easily disassembled?
  • Can a Building Information Modelling (BIM) system or building handbook be used to record which and how elements/components/materials have been designed for disassembly?


A range of alternative construction methods are likely to be suitable for design for deconstruction and flexibility. Generally, those methods that facilitate easy disassembly at the end of the design/service life to improve the potential for reuse and/ or recyclability should be selected in preference to the more contiguous structural systems. Reuse should invariably be chosen as a preferred end of life scenario rather than recycling. There is an added waste reduction benefit in the choice of such structural systems as they are likely to be fabricated using off-site construction and assembled on site.

Steel-framed buildings are inherently reusable and flexible.

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Long span steel beams providing flexible, column-free space, Vulcan House, Sheffield


As part of its programme to ‘design out waste’ WRAP produced a series of sheets of alternative design details which use less materials or result in less waste being created than ‘standard’ details used in construction. One of these design sheets[20] described the benefits of cellular steel beams. The table highlights the potential benefits of this form of construction identified by WRAP.

Resource efficiency benefits of cellular beams
Materials/waste 25 – 50% reduction in steel weight in web (flanges unaffected).
Up to 15% reduction in M&E materials by passing straight through the web openings.
Less material required for supporting elements (columns, foundations etc).
Cost Average savings of £38/metre for castellated steel beams.
Reduced savings for cellular beams due to more complex manufacture.
Light weight can result in lower transportation costs.
Further cost savings for supporting structure.
Time Long spans and light weight allow omission of some supporting structure leading to quicker construction.
Light weight also allows fewer deliveries and good manoeuvrability on site.
Carbon Potential steel embodied carbon savings of 41kg CO2e/metre compared to solid I-beams.
Other structural elements can also be lighter, reducing embodied carbon further.
Recycling Steel is 100% recyclable.
Manufacturing waste is recycled.
Constructability Light weight allows easy assembly.
Bolted sections are easy to assemble and disassemble.
M&E services can pass through the beams.
Replicability Bespoke for individual projects – laser precision cutting ensures efficient manufacturing process.
Particularly suitable for long spans such as stadia, car parks and bridges

[top]References

  1. 1.0 1.1 1.2 Our waste, our resources: a strategy for England, Department for Environment, Food & Rural Affairs. December 2018
  2. 2.0 2.1 2.2 Directive 2008/98/EC Of the European Parliament and of the Council of 19 November 2008 on waste and repealing certain Directives
  3. 3.0 3.1 Industrial Strategy, Construction Sector Deal, BEIS, 2018, HMSO
  4. Industrial Strategy, Building a Britain fit for the future, BEIS, November 2017, HMSO
  5. Construction 2025: industrial strategy for construction - government and industry in partnership, BIS, July 2013, HMSO
  6. The Environmental Protection (Duty of Care) (England) (Amendment) Regulations 2003, Statutory Instrument 2003 No. 63
  7. The Hazardous Waste (England and Wales) Regulations 2005, Statutory Instrument 2005 No. 89
  8. European Waste Catalogue. List of wastes pursuant to Article 1(a) of Directive 75/442/EEC on waste and Article 1(4) of Directive 91/689/EEC on hazardous waste
  9. The Site Waste Management Plans Regulations 2008, Statutory Instrument 2008 No. 314
  10. Non-statutory guidance for Site Waste Management Plans. defra, 2008
  11. 11.0 11.1 11.2 BREEAM UK New Construction, Non-domestic buildings (United Kingdom), Technical Manual, SD5078: 2018 1.0. BRE Global Ltd.
  12. Demolition Protocol; The Institution of Civil Engineers, 2008
  13. [EU Construction and Demolition Waste Protocol and Guidelines, September 2018, European Commission]
  14. Strategy for the sustainable competitiveness of the construction sector and its enterprises, 2012, European Commission
  15. Resource Efficiency Opportunities in the Building Sector, July 2014, European Commission
  16. Designing out Waste: a design team guide for buildings, WRAP
  17. BS 8895-1:2013, Designing for material efficiency in building projects. Code of practice for Strategic Definition and Preparation and Brief, BSI
  18. BS 8895-2:2015, Designing for material efficiency in building projects. Code of Practice for concept and developed design, BSI
  19. BS 8895-3:2019, Designing for material efficiency in building projects. Code of practice for technical design, BSI
  20. Designing out Waste: design detail sheet - Castellated and cellular beams, WRAP

[top]Resources

[top]Further reading

  • Design for deconstruction. Principles of design to facilitate reuse and recycling CIRIA Report C607, 2004.

[top]See also

[top]External links

[top]CPD