Environmental impact assessment of Swiss residential archetypes: a comparison of construction and mobility scenarios

Judith Drouilles; Sergi Aguacil; Endrit Hoxha; Thomas Jusselme; Sophie Lufkin; Emmanuel Rey

doi:10.1007/s12053-019-09811-0

Environmental impact assessment of Swiss residential archetypes: a comparison of construction and mobility scenarios

Judith Drouilles, Sergi Aguacil, Endrit Hoxha^*, Thomas Jusselme, Sophie Lufkin, Emmanuel Rey

^*Corresponding author for this work

Research output: Contribution to journal › Journal article › Research › peer-review

16 Citations (Scopus)

Abstract

Environmental performance assessment of the built environment tends to focus mostly on operational final energy consumption of buildings located within a specific context. Such a limited scope prevents broader usability of findings in practice. In Switzerland, the ‘2000-W society’ vision provides a theoretical framework towards energy transition. Intermediate targets for 2050 relate to an extensive assessment incorporating environmental impacts of construction materials and use of a building, and of induced mobility of its occupants. Accordingly, it becomes crucial to gather information about the current building stock performance and its transition potential. The paper aims at contributing to the sustainability transition debate by providing a comparative assessment of retrofitted and new residential buildings representative of the Swiss building stock. A direct output could constitute in establishing a reliable reference dataset to support practitioners’ or lawmakers’ future decisions. The novelty of the study relies on two aspects: (1) on adopting an interdisciplinary approach to propose an overview of the current status and transition potential of the built environment, and (2) on building a methodology able to extrapolate results for large-scale studies of neighbourhoods or larger built areas. Based on the definition of four building archetypes, this study assesses four scenarios decomposed into four to six variants. The scenarios consist in varying the building energy-performance, while the variants implement different locations—among urban, peripheral and rural areas—and different passive or active strategies. Results are expressed in terms of non-renewable primary energy consumption and global warming potential. They highlight in particular the performances of renovation projects that can decrease the impacts of current building stock by 75 to 85%, the effect of high-energy performance on embodied impacts, the high-level of performance of multi-family houses with 37% lower impacts compared to those of single-family houses and the significant impact of mobility (around 50%).

Original language	English
Journal	Energy Efficiency
Volume	12
Issue number	6
Pages (from-to)	1661-1689
Number of pages	29
ISSN	1570-646X
DOIs	https://doi.org/10.1007/s12053-019-09811-0
Publication status	Published - 15 Aug 2019

Bibliographical note

Funding Information:
This article presents the results of the LOW CARBON HOUSING research project, supported by the Smart living Lab, a research and development centre for the built environment of the future whose ambition is to bridge the gap between research and industry. This study was also conducted in the framework of the LIVING PERIPHERIES research project, supported by the Swiss National Science Foundation (SNSF) (Project n°100013_152586/1), and the ACTIVE INTERFACES interdisciplinary research project, part of the National Research Programme "Energy Turnaround" (NRP 70) of the SNSF. Further information on the National Research Programme can be found at www.nrp70.ch. The authors also acknowledge the participation of Angela Clua Longas from the Laboratory of architecture and sustainable technologies (LAST) of the Ecole Polytechnique Fédérale de Lausanne (EPFL) for providing information and data about the new multi-family house archetype.

Funding Information:
This article presents the results of the LOW CARBON HOUSING research project, supported by the Smart living Lab, a research and development centre for the built environment of the future whose ambition is to bridge the gap between research and industry. This study was also conducted in the framework of the LIVING PERIPHERIES research project, supported by the Swiss National Science Foundation (SNSF) (Project n?100013_152586/1), and the ACTIVE INTERFACES interdisciplinary research project, part of the National Research Programme "Energy Turnaround" (NRP 70) of the SNSF. Further information on the National Research Programme can be found at www.nrp70.ch. The authors also acknowledge the participation of Angela Clua Longas from the Laboratory of architecture and sustainable technologies (LAST) of the Ecole Polytechnique F?d?rale de Lausanne (EPFL) for providing information and data about the new multi-family house archetype.

Publisher Copyright:
© 2019, Springer Nature B.V.

Keywords

Daily mobility
Embodied impacts
Life-cycle assessment
Non-renewable primary energy
Operational impacts
Residential building archetypes

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title = "Environmental impact assessment of Swiss residential archetypes: a comparison of construction and mobility scenarios",

abstract = "Environmental performance assessment of the built environment tends to focus mostly on operational final energy consumption of buildings located within a specific context. Such a limited scope prevents broader usability of findings in practice. In Switzerland, the {\textquoteleft}2000-W society{\textquoteright} vision provides a theoretical framework towards energy transition. Intermediate targets for 2050 relate to an extensive assessment incorporating environmental impacts of construction materials and use of a building, and of induced mobility of its occupants. Accordingly, it becomes crucial to gather information about the current building stock performance and its transition potential. The paper aims at contributing to the sustainability transition debate by providing a comparative assessment of retrofitted and new residential buildings representative of the Swiss building stock. A direct output could constitute in establishing a reliable reference dataset to support practitioners{\textquoteright} or lawmakers{\textquoteright} future decisions. The novelty of the study relies on two aspects: (1) on adopting an interdisciplinary approach to propose an overview of the current status and transition potential of the built environment, and (2) on building a methodology able to extrapolate results for large-scale studies of neighbourhoods or larger built areas. Based on the definition of four building archetypes, this study assesses four scenarios decomposed into four to six variants. The scenarios consist in varying the building energy-performance, while the variants implement different locations—among urban, peripheral and rural areas—and different passive or active strategies. Results are expressed in terms of non-renewable primary energy consumption and global warming potential. They highlight in particular the performances of renovation projects that can decrease the impacts of current building stock by 75 to 85%, the effect of high-energy performance on embodied impacts, the high-level of performance of multi-family houses with 37% lower impacts compared to those of single-family houses and the significant impact of mobility (around 50%).",

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note = "Funding Information: This article presents the results of the LOW CARBON HOUSING research project, supported by the Smart living Lab, a research and development centre for the built environment of the future whose ambition is to bridge the gap between research and industry. This study was also conducted in the framework of the LIVING PERIPHERIES research project, supported by the Swiss National Science Foundation (SNSF) (Project n°100013_152586/1), and the ACTIVE INTERFACES interdisciplinary research project, part of the National Research Programme {"}Energy Turnaround{"} (NRP 70) of the SNSF. Further information on the National Research Programme can be found at www.nrp70.ch. The authors also acknowledge the participation of Angela Clua Longas from the Laboratory of architecture and sustainable technologies (LAST) of the Ecole Polytechnique F{\'e}d{\'e}rale de Lausanne (EPFL) for providing information and data about the new multi-family house archetype. Funding Information: This article presents the results of the LOW CARBON HOUSING research project, supported by the Smart living Lab, a research and development centre for the built environment of the future whose ambition is to bridge the gap between research and industry. This study was also conducted in the framework of the LIVING PERIPHERIES research project, supported by the Swiss National Science Foundation (SNSF) (Project n?100013_152586/1), and the ACTIVE INTERFACES interdisciplinary research project, part of the National Research Programme {"}Energy Turnaround{"} (NRP 70) of the SNSF. Further information on the National Research Programme can be found at www.nrp70.ch. The authors also acknowledge the participation of Angela Clua Longas from the Laboratory of architecture and sustainable technologies (LAST) of the Ecole Polytechnique F?d?rale de Lausanne (EPFL) for providing information and data about the new multi-family house archetype. Publisher Copyright: {\textcopyright} 2019, Springer Nature B.V.",

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Environmental impact assessment of Swiss residential archetypes: a comparison of construction and mobility scenarios

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Keywords

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