The impact of lifespan assumptions in LCA: Comparing the replacement of building parts versus building layers—A housing case study

IF 6.6 2区 工程技术 Q1 CONSTRUCTION & BUILDING TECHNOLOGY Energy and Buildings Pub Date : 2024-11-15 DOI:10.1016/j.enbuild.2024.115050
Annette Davis , Alberto Quintana-Gallardo , Núria Martí Audí , Ignacio Guillén Guillamón
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Abstract

The circular economy transition of the built environment is of high priority in the EU, a challenge even more pressing in the housing sector. Conceptualising buildings as ensembles of standardised and prefabricated products, which can be separated into both defined building parts or layers is an accepted circular design approach facilitating future replacement and reuse. Life Cycle Assessment (LCA) is a tool for achieving circularity by informing design choices based on predefined lifespans. However, there is conflicting top-down guidance about whether to assume individual lifespans for constituent components or to group these into building layers when carrying out whole building LCAs. This study reviews the latest guidance on building layers and parts according to the European Level(s) framework, ISO 20887 standard for Design for Disassembly and Adaptability, and the Shearing Layers concept. An energy efficient housing case study was used to compare organisation of the Life Cycle Inventory into separate lifespans for components and layers aligned to Shearing Layers, with lifespans defined by Level(s) Indicator 2.1. The study focussed on Module B4 replacements over a 100-year period. The findings reveal that assuming the replacement of building components as opposed to layers results in greater carbon emissions. In both cases, emissions were approximately double the amount of upfront carbon to produce the initial building. These findings demonstrate the importance of lifespan assumptions in LCA, which should be further developed. The study provides an LCA template for practitioners to organise the building inventory and apply lifespan assumptions, improving rationale behind design decisions.

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生命周期评估中寿命假设的影响:比较建筑部件和建筑层的更换--住房案例研究
建筑环境的循环经济转型是欧盟的当务之急,这一挑战在住房领域更为紧迫。将建筑概念化为标准化预制产品的组合体,并将其拆分为确定的建筑部件或建筑层,是一种公认的循环设计方法,有利于未来的更换和再利用。生命周期评估(LCA)是实现循环的一种工具,它根据预先确定的生命周期为设计选择提供信息。然而,关于在进行整栋建筑生命周期评估时,是假设组成部件的单独寿命,还是将这些部件归类为建筑层,自上而下的指导意见存在冲突。本研究根据欧洲标准(Level(s))框架、ISO 20887《可拆卸性和适应性设计》标准以及 "剪切层 "概念,回顾了有关建筑层和部件的最新指导。通过一项节能住宅案例研究,比较了按照 "剪切层 "和 "Level(s)指标 2.1 "所定义的生命周期,将生命周期清单中的组件和层组织成不同的生命周期。研究重点是模块 B4 在 100 年内的更换情况。研究结果表明,假设更换建筑构件而非层,会导致更多的碳排放。在这两种情况下,排放量约为生产初始建筑的前期碳排放量的两倍。这些发现表明了生命周期分析假设的重要性,应进一步加以发展。该研究为从业人员提供了一个生命周期评估模板,用于组织建筑清单和应用生命周期假设,从而改善设计决策的合理性。
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来源期刊
Energy and Buildings
Energy and Buildings 工程技术-工程:土木
CiteScore
12.70
自引率
11.90%
发文量
863
审稿时长
38 days
期刊介绍: An international journal devoted to investigations of energy use and efficiency in buildings Energy and Buildings is an international journal publishing articles with explicit links to energy use in buildings. The aim is to present new research results, and new proven practice aimed at reducing the energy needs of a building and improving indoor environment quality.
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