Urban mining. Scoping resources for circular construction

2021

The large volume of in-and out-flow of raw materials to construction projects has a huge potential to be optimised for resource efficiency and waste reduction. With the recent awareness of the importance of the circular economy, construction actors are aligning their practices to be more circular and sustainable. The concept of material banks is born out of this awareness in order to document the lifecycle information of materials and facilitate re-using them. The introduction of new cycles before individual materials reach their final lifecycle stages results in reduced negative environmental impacts. This paper presents a workflow by positioning different digital technologies to automate the procedures for reuse assessment: from the deconstructed building to M/C bank to new construction projects. This automation supports a practical material and component reuse, while it provides the necessary infrastructure to digitise and digitalise the post-deconstruction materials to be visualised, selected and used by future designers in Building Information Modelling (BIM)-based design and management environments. To this aim, the coupling of BIM, reality capturing technologies, additive manufacturing techniques, IoT and RFID sensors is also anticipated.

Journal of Engineering in Industrial Research, 2025

Circular economy, as a new approach to economic development, seeks to reduce pollution and manage resources more efficiently. The purpose of this article is estimate of Circular Economy Principles in Architectural Design, Construction and Real Estate. Circular economy is an economic system in which products, materials and resources are continuously recycled, resulting in no or minimal waste. It is based on three fundamental principles: design to eliminate waste and pollution; keep materials and products in the cycle of use; and restore natural systems. The world population is expected to reach 9 billion by 2050, with 55% of them living in cities. This population growth will put more pressure on natural resources and demand new infrastructure, services and housing. Currently, cities account for approximately two-thirds of global energy demand and are responsible for 80% of greenhouse gas emissions as well as 50% of global waste, with estimates indicating that urban waste levels will double by 2050. The construction industry’s approach to the life cycle of materials and buildings is evolving. For a long time, this cycle has followed the simple formula of “plan, design, build and finally demolish”, but over time, new concepts such as recycling, dismantling, reuse and circular demolition have emerged in the industry and form part of the gradual transformation towards a circular economy in construction. This approach not only extends the lifecycle of building components, but also fosters a symbiotic relationship between the built environment and the natural world. Circular design emphasizes several key principles: designing for longevity, adaptability, and disassembling components; using sustainable materials; and ensuring that products can be easily repaired, reused, or recycled at the end of their life cycle. The transformation in the construction industry’s approach is bringing the stages of use of buildings and their life cycle closer to reality.

2016

The recycling of different forms of architectural buildings within the settlement areas and buildings that appear to be waste (Berger, 2006; Koolhaas, 2006) are produced unintentionally (Clement, 2008; Bauman, 2005) by the transformations of the city (Lynch, 1992; Price, 2003). The presence of numerous abandoned or being abandoned buildings and urban equipment structures- architecture and engineering products- is not occasional, but a structural factor of the form of urbanism that characterizes the contemporary city. This research aims to take action on the effects of this dynamic, partly physiologically, for the internal migration of residences or other facilities and, for buildings and building materials, there is currently no programming life cycle, or recycling and design of these wastes (McDonough, Braungart, 2002). The aim of the research will be the recycling of these areas, and architectural objects, considering them as parts of new building structures, new architectures for...

Proceedings of The Institution of Civil Engineers-engineering Sustainability, 2004

2017

In recent years there has been growing interest in urban mining from various environmental and economic perspectives. Materials hidden in buildings are attractive alternatives to raw ones, while building activities are responsible for a large share of waste. The paper is a summary of findings from an analysis of possibilities for urban mining in Amsterdam, focusing on prospecting for metals in residential buildings. Both global literature and interviews with Dutch demolition experts suggest that performance in metal recovery from buildings is as high as it can get. However, estimation of metal content in buildings and of waste processing rates is far from reliable, accurate and precise enough to support such claims or identify possibilities for further improvement, especially in relation to processes of urban and real-estate redevelopment and rejuvenation. To improve understanding and embedding of urban mining in these processes, we propose (a) a BIM-based information infrastructure...

IOP Conference Series: Earth and Environmental Science

Buildings and construction have been identified as having one of the greatest potential for value creation and capture from the application of circular economy principles. To achieve this requires a fundamental transformation in the recovery, remanufacture and re-use of end of service life structural products such as steel, bricks, concrete which make up the largest proportion of materials. At the same time these products must be re-used in new buildings and infrastructure designed for subsequent deconstruction and disassembly. REBUILD is a 3 year way UK research project to address this challenge. Initial findings on quantifying the material intensity of buildings (stock and flow assessment) are presented based on one of our case study cities. Results from new techniques to separate and reclaim bricks from cement mortar shows technical feasibility and ability to retain structural performance. Details on the next stage of scaling this work and techniques for separating and reclaiming steel and concrete are briefly described. Subsequent stage of life cycle assessment, value stream mapping and creating products for new forms of circular building and construction systems are also described. The paper concludes that whilst there are considerable challenges in reclaiming structural products that redesigned circular building and construction system could transform the value of end of service life buildings and the offers new opportunities for circular innovation and the circulation of materials and products at their highest value for the longest period.

AGATHÓN - International Journal of Architecture, Art and Design, 2021

Although the circular economy has occupied a crucial place in the development agendas of industrialized countries in recent years, the construction sector still seems far from a mature understanding of the cultural dimensions related to the notion of circularity since, until now, its focus has been mainly on improving technological solutions. However, the circular economy opens up new operational frontiers beyond the scale of the construction detail. It embraces more complex social and cultural fields that ultimately question the changing relationship between man and inhabited space. The article assumes this perspective and examines the possible implications of circular logics’ spatial organizations at larger scales that have a great impact on settlement forms, proposing a critical comparison between two case studies characterized by two built fabrics with different densities. The first one is the regeneration of the Ilot de l’Arc de Triomphe district (high density and compactness), and the second one is the transformation of Contrada Bricconi (low density and rarefaction). The two design experiences ensure a second life to inhabited artifacts and soils.

At a time when planning research is under pressure to better respond to sustainable development, revision on the urban planning models and available planning tools and methodologies has been claimed. This paper reveals a methodological approach towards planning that takes in account the analysis of the urban material dynamics as the principal indicator for the guarantee of the sustainability condition. It does this by exposing the existing relationship between the urban material dynamics and sustainability as the ...

The growing concern about climate change and the recognition of the planet’s limits led society to look for alternatives that promote the balance between the natural and the built environment. The circular economy emerges as an alternative to the linear economic model, inspired by natural metabolisms, by circulating resources in continuous loops, where their intrinsic value is maintained and improved. This research proposes a closed-loop strategy in the built environment by studying innovative constructive solutions that aim to find use, value, and inspiration in what is considered waste. A literature review is conducted on the circular design strategies, re-use and recycle typologies, and waste transformation processes. Then, the development of a methodology for qualitative evaluation and selection of re-used and upcycled construction materials from post-consumer waste and by-products is presented and then applied to thirty-five cases of constructive solutions from plastic, wood, p...

The Routledge Handbook of Catalysts for a Sustainable Circular Economy, 2023

Construction is one of the most significant sectors consuming virgin materials and producing waste and greenhouse gases. The circular economy has been proposed as a solution to the industry's environmental problems. However, the transition has proved difficult and biased towards recycling rather than waste prevention and reuse. It is not known how the industry could adopt reuse-based solutions, even if reuse could reduce the environmental burdens more so than recycling. This chapter provides insights into how the construction sector could become more circular and low-carbon by reusing building components. It stems from developing the ReCreate project (Horizon 2020), which investigates the deconstruction and reuse of prefabricated concrete elements not originally designed for disassembly. The analytical approach used here is Frank Geels's multi-level perspective for technology transitions. This chapter is a theoretical contribution that identifies and explains a wide spectrum of diverse catalysts necessary for the reuse transition, ranging from technological development (in deconstruction, remanufacturing, design, and digitalisation) to societal and economic developments (in behaviour and acceptance, work skills, safety, regulation, business models, and value chains). It also discusses catalysts' roles and timeframes in the nexus of a sociotechnical regime (business-as-usual construction) and niche innovation (reuse), which is attempting a breakthrough. A conceptual framework is provided for facilitating a reuse transition in the construction sector.