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A platform for research: civil engineering, architecture and urbanism
An analytical method for evaluating and visualizing embodied carbon emissions of buildings
https://orcid.org/0000-0002-0592-5956
https://orcid.org/0000-0001-6908-2284
Abstract Greenhouse gas emissions associated with buildings constitute a large part of global emissions, where building materials and associated processes make up a significant fraction. These emissions are complicated to evaluate with current methodologies due to, amongst others, the lack of a link between the material inventory data and the aggregated results. This paper presents a method for evaluating and visualizing embodied emission (EE) data of building material production and transport, including replacements, from building life cycle assessments (LCAs). The method introduces a set of metrics that simultaneously serve as a breakdown of the EE results and as an aggregation of the building's inventory data. Furthermore, future emission reductions due to technological improvements are modeled and captured in technological factors for material production and material transport. The material inventory is divided into building subparts for high-resolution analysis of the EE. The metrics and technological factors are calculated separately for each subpart, which can then be evaluated in relation to the rest of the building and be compared to results from other buildings. Two methods for evaluating and visualizing the results are presented to illustrate the method's usefulness in the design process. A case study is used to demonstrate the methods. Key driving factors of EE are identified together with effective mitigation strategies. The inclusion of technological improvements shows a significant reduction in EE (−11.5%), reducing the importance of replacements. Furthermore, the method lays the foundation for further applications throughout the project phases by combining case-specific data with statistical data.
Graphical abstract Display Omitted
Highlights Evaluating production, transport, and replacement emissions of building materials. Metrics for each building subpart are enabling detailed interpretation of emissions. Effect of technological improvements on future replacement emissions is modeled. Future emissions due to replacements are less important than near-future emissions. Method enables use of previous LCA studies for statistical reference values.
An analytical method for evaluating and visualizing embodied carbon emissions of buildings
https://orcid.org/0000-0002-0592-5956
https://orcid.org/0000-0001-6908-2284
Abstract Greenhouse gas emissions associated with buildings constitute a large part of global emissions, where building materials and associated processes make up a significant fraction. These emissions are complicated to evaluate with current methodologies due to, amongst others, the lack of a link between the material inventory data and the aggregated results. This paper presents a method for evaluating and visualizing embodied emission (EE) data of building material production and transport, including replacements, from building life cycle assessments (LCAs). The method introduces a set of metrics that simultaneously serve as a breakdown of the EE results and as an aggregation of the building's inventory data. Furthermore, future emission reductions due to technological improvements are modeled and captured in technological factors for material production and material transport. The material inventory is divided into building subparts for high-resolution analysis of the EE. The metrics and technological factors are calculated separately for each subpart, which can then be evaluated in relation to the rest of the building and be compared to results from other buildings. Two methods for evaluating and visualizing the results are presented to illustrate the method's usefulness in the design process. A case study is used to demonstrate the methods. Key driving factors of EE are identified together with effective mitigation strategies. The inclusion of technological improvements shows a significant reduction in EE (−11.5%), reducing the importance of replacements. Furthermore, the method lays the foundation for further applications throughout the project phases by combining case-specific data with statistical data.
Graphical abstract Display Omitted
Highlights Evaluating production, transport, and replacement emissions of building materials. Metrics for each building subpart are enabling detailed interpretation of emissions. Effect of technological improvements on future replacement emissions is modeled. Future emissions due to replacements are less important than near-future emissions. Method enables use of previous LCA studies for statistical reference values.
An analytical method for evaluating and visualizing embodied carbon emissions of buildings
https://orcid.org/0000-0002-0592-5956
https://orcid.org/0000-0001-6908-2284
Abstract Greenhouse gas emissions associated with buildings constitute a large part of global emissions, where building materials and associated processes make up a significant fraction. These emissions are complicated to evaluate with current methodologies due to, amongst others, the lack of a link between the material inventory data and the aggregated results. This paper presents a method for evaluating and visualizing embodied emission (EE) data of building material production and transport, including replacements, from building life cycle assessments (LCAs). The method introduces a set of metrics that simultaneously serve as a breakdown of the EE results and as an aggregation of the building's inventory data. Furthermore, future emission reductions due to technological improvements are modeled and captured in technological factors for material production and material transport. The material inventory is divided into building subparts for high-resolution analysis of the EE. The metrics and technological factors are calculated separately for each subpart, which can then be evaluated in relation to the rest of the building and be compared to results from other buildings. Two methods for evaluating and visualizing the results are presented to illustrate the method's usefulness in the design process. A case study is used to demonstrate the methods. Key driving factors of EE are identified together with effective mitigation strategies. The inclusion of technological improvements shows a significant reduction in EE (−11.5%), reducing the importance of replacements. Furthermore, the method lays the foundation for further applications throughout the project phases by combining case-specific data with statistical data.
Graphical abstract Display Omitted
Highlights Evaluating production, transport, and replacement emissions of building materials. Metrics for each building subpart are enabling detailed interpretation of emissions. Effect of technological improvements on future replacement emissions is modeled. Future emissions due to replacements are less important than near-future emissions. Method enables use of previous LCA studies for statistical reference values.
An analytical method for evaluating and visualizing embodied carbon emissions of buildings
Resch, Eirik (author) / Lausselet, Carine (author) / Brattebø, Helge (author) / Andresen, Inger (author)
Building and Environment ; 168
2019-10-12
Article (Journal)
Electronic Resource
English
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