Estimating the recoverable value of in-situ building materials

Estimating the recoverable value of in-situ building materials

•Factors impacting the value of in-situ materials have been studied.•A decision support tool based on an optimization model is developed for in-situ building material value estimation.•Impact of key factors on value of-situ materials have been analyzed using the developed tool.•Building component re...

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Bibliographic Details
Published in:Sustainable cities and society Vol. 91; p. 104455
Main Authors: Mollaei, Aida, Bachmann, Chris, Haas, Carl
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-04-2023
Subjects:
Building information models
Circular economy
Construction
Deconstruction
Demolition
Disassembly
End-of-life
Materials
Optimization
Recovery
Reuse
End-of-life
Deconstruction
Construction
Circular economy
Building information models
Materials
Reuse
Demolition
Recovery
Optimization
Disassembly
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Summary:•Factors impacting the value of in-situ materials have been studied.•A decision support tool based on an optimization model is developed for in-situ building material value estimation.•Impact of key factors on value of-situ materials have been analyzed using the developed tool.•Building component recovery through the optimization of EoL options can have high return on investments. Construction, renovation and demolition of buildings in our cities is driving substantial material consumption and waste streams. They can be reduced by recovering in-situ materials from buildings with controlled demolition, disassembly, and deconstruction of components and materials. To do this, a decision support tool that can be used to estimate current recoverable environmental and market values from the owner's perspective of in-situ construction materials in a specific facility must be developed. Here, a linear programming optimization methodology is used that considers cost, value, duration, environmental impacts, and building component precedence in demolition and deconstruction activities. It helps choose the optimal combination of reuse, recycling and disposal options for those materials. The resulting decision support tool is functionally demonstrated on an institutional building to find the building components’ optimal end-of-life alternatives to maximize the recovered value from the in-situ materials. Sensitivity analyses add further validation. Thus, this research supports the transition to a more circular economy in cities by making it easier to realize the full value of in-situ materials for planning, asset management, and demolition project bids. [Display omitted]
ISSN:2210-6707
2210-6715
DOI:10.1016/j.scs.2023.104455