Loading…

Building Information Modelling (BIM) aided waste minimisation framework

Building design can have a major impact on sustainability through material efficiency and construction waste minimisation (CWM). The construction industry consumes over 420 million tonnes of material resources every year and generates 120 million tonnes of waste containing approximately 13 million t...

Full description

Saved in:
Bibliographic Details
Main Author: Zhen Liu
Format: Default Thesis
Published: 2014
Subjects:
Online Access:https://hdl.handle.net/2134/14971
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1818173365303640064
author Zhen Liu
author_facet Zhen Liu
author_sort Zhen Liu (74646)
collection Figshare
description Building design can have a major impact on sustainability through material efficiency and construction waste minimisation (CWM). The construction industry consumes over 420 million tonnes of material resources every year and generates 120 million tonnes of waste containing approximately 13 million tonnes of unused materials. The current and on-going field of CWM research is focused on separate project stages with an overwhelming endeavour to manage on-site waste. Although design stages are vital to achieve progress towards CWM, currently, there are insufficient tools for CWM. In recent years, Building Information Modelling (BIM) has been adopted to improve sustainable building design, such as energy efficiency and carbon reduction. Very little has been achieved in this field of research to evaluate the use of BIM to aid CWM during design. However, recent literature emphasises a need to carry out further research in this context. This research aims to investigate the use of BIM as a platform to help with CWM during design stages by developing and validating a BIM-aided CWM (BaW) Framework. A mixed research method, known as triangulation, was adopted as the research design method. Research data was collected through a set of data collection methods, i.e. selfadministered postal questionnaire (N=100 distributed, n=50 completed), and semistructured follow-up interviews (n=11) with architects from the top 100 UK architectural companies. Descriptive statistics and constant comparative methods were used for data analysis. The BaW Framework was developed based on the findings of literature review, questionnaire survey and interviews. The BaW Framework validation process included a validation questionnaire (N=6) and validation interviews (N=6) with architects. Key research findings revealed that: BIM has the potential to aid CWM during design; Concept and Design Development stages have major potential in helping waste reduction through BIM; BIM-enhanced practices (i.e. clash detection, detailing, visualisation and simulation, and improved communication and collaboration) have impacts on waste reduction; BIM has the most potential to address waste causes (e.g. ineffective coordination and communication, and design changes); and the BaW Framework has the potential to enable improvements towards waste minimisation throughout all design stages. Participating architects recommended that the adoption of the BaW Framework could enrich both CWM and BIM practices, and most importantly, would enhance waste reduction performance in design. The content should be suitable for project stakeholders, architects in particular, when dealing with construction waste and BIM during design.
format Default
Thesis
id rr-article-9456188
institution Loughborough University
publishDate 2014
record_format Figshare
spelling rr-article-94561882014-01-01T00:00:00Z Building Information Modelling (BIM) aided waste minimisation framework Zhen Liu (74646) Other built environment and design not elsewhere classified Construction waste minimisation Construction waste causes during design Building Information Modelling (BIM) Building design Sustainable building design Sustainability Built Environment and Design not elsewhere classified Building design can have a major impact on sustainability through material efficiency and construction waste minimisation (CWM). The construction industry consumes over 420 million tonnes of material resources every year and generates 120 million tonnes of waste containing approximately 13 million tonnes of unused materials. The current and on-going field of CWM research is focused on separate project stages with an overwhelming endeavour to manage on-site waste. Although design stages are vital to achieve progress towards CWM, currently, there are insufficient tools for CWM. In recent years, Building Information Modelling (BIM) has been adopted to improve sustainable building design, such as energy efficiency and carbon reduction. Very little has been achieved in this field of research to evaluate the use of BIM to aid CWM during design. However, recent literature emphasises a need to carry out further research in this context. This research aims to investigate the use of BIM as a platform to help with CWM during design stages by developing and validating a BIM-aided CWM (BaW) Framework. A mixed research method, known as triangulation, was adopted as the research design method. Research data was collected through a set of data collection methods, i.e. selfadministered postal questionnaire (N=100 distributed, n=50 completed), and semistructured follow-up interviews (n=11) with architects from the top 100 UK architectural companies. Descriptive statistics and constant comparative methods were used for data analysis. The BaW Framework was developed based on the findings of literature review, questionnaire survey and interviews. The BaW Framework validation process included a validation questionnaire (N=6) and validation interviews (N=6) with architects. Key research findings revealed that: BIM has the potential to aid CWM during design; Concept and Design Development stages have major potential in helping waste reduction through BIM; BIM-enhanced practices (i.e. clash detection, detailing, visualisation and simulation, and improved communication and collaboration) have impacts on waste reduction; BIM has the most potential to address waste causes (e.g. ineffective coordination and communication, and design changes); and the BaW Framework has the potential to enable improvements towards waste minimisation throughout all design stages. Participating architects recommended that the adoption of the BaW Framework could enrich both CWM and BIM practices, and most importantly, would enhance waste reduction performance in design. The content should be suitable for project stakeholders, architects in particular, when dealing with construction waste and BIM during design. 2014-01-01T00:00:00Z Text Thesis 2134/14971 https://figshare.com/articles/thesis/Building_Information_Modelling_BIM_aided_waste_minimisation_framework/9456188 CC BY-NC-ND 4.0
spellingShingle Other built environment and design not elsewhere classified
Construction waste minimisation
Construction waste causes during design
Building Information Modelling (BIM)
Building design
Sustainable building design
Sustainability
Built Environment and Design not elsewhere classified
Zhen Liu
Building Information Modelling (BIM) aided waste minimisation framework
title Building Information Modelling (BIM) aided waste minimisation framework
title_full Building Information Modelling (BIM) aided waste minimisation framework
title_fullStr Building Information Modelling (BIM) aided waste minimisation framework
title_full_unstemmed Building Information Modelling (BIM) aided waste minimisation framework
title_short Building Information Modelling (BIM) aided waste minimisation framework
title_sort building information modelling (bim) aided waste minimisation framework
topic Other built environment and design not elsewhere classified
Construction waste minimisation
Construction waste causes during design
Building Information Modelling (BIM)
Building design
Sustainable building design
Sustainability
Built Environment and Design not elsewhere classified
url https://hdl.handle.net/2134/14971