Integrating building information modelling with sustainability to design building projects at the conceptual stage

Ahmad Jrade; Farzad Jalaei

doi:10.1007/s12273-013-0120-0

Building Simulation 2013, 6(4): 429-444 https://doi.org/10.1007/s12273-013-0120-0

Research Article | Issue | Published: 02 April 2013

Integrating building information modelling with sustainability to design building projects at the conceptual stage

Show Author's Information Hide Author's Information Ahmad Jrade(

), Farzad Jalaei

Department of Civil Engineering, University of Ottawa, 161 Louis Pasteur Pv., Ottawa, Ontario K1N 6N5, Canada

Keywords:

sustainability, green buildings, BIM, LCA, EI, LEED certification system and construction cost estimating

Cite this article:

Jrade A, Jalaei F. Integrating building information modelling with sustainability to design building projects at the conceptual stage. Building Simulation, 2013, 6(4): 429-444. https://doi.org/10.1007/s12273-013-0120-0

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Abstract

Lately the construction industry has become more interested in designing and constructing environmentally friendly buildings (e.g. sustainable buildings) that can provide both high performance and monetary savings. In general, sustainability integrates the following three related components: (1) environmental, (2) economic, (3) social well-being. Incorporating these components at the conceptual stage is achieved by using sustainable design, through which designers must identify associated materials and systems based on any selected certification (rating) system. The use of building information modelling (BIM) concepts helps engineers design digital models that allow owners to visualize the building before the physical implementation takes place. To apply BIM concepts, designers use tools to create 3D models of buildings where the design materials and systems are selected from the built-in database of these tools. Designers will not be able to quantify the environmental impacts of these materials to support the decisions needed to design sustainable buildings due to the following reasons: (1) a lack of information about the sustainable materials that are stored in the database, (2) a lack of interoperability between the design and analysis tools that enable full life cycle assessments (LCAs) of buildings. This paper presents a methodology that integrates BIM and LCA tools with a database for designing sustainable building projects. The methodology describes the development and implementation of a model that incorporates a database in which information about sustainable materials is stored and linked to a BIM (3D) module along with an LCA module and a certification and cost module. The goal of this model is to simplify the process of creating sustainable designs and to evaluate the environmental impacts (EI) of newly designed buildings at the conceptual stage of their life. An actual building project is presented in order to illustrate the usefulness and capabilities of the developed model.

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Integrating building information modelling with sustainability to design building projects at the conceptual stage

Show Author's information Hide Author's Information Ahmad Jrade(

), Farzad Jalaei

Department of Civil Engineering, University of Ottawa, 161 Louis Pasteur Pv., Ottawa, Ontario K1N 6N5, Canada

Abstract

Keywords: sustainability, green buildings, BIM, LCA, EI, LEED certification system and construction cost estimating

References(31)

Autodesk (2005). Building information modeling for sustainable design. Available: http://www.federalnewsradio.com/pdfs/Building Information Modeling for SustainableDesign-white%20paper.pdf. Accessed 14 Dec. 2012.

Autodesk (2008). Improving building industry results through integrated project delivery and building information modeling. Available: http://images.autodesk.com/adsk/files/bim_and_ipd_whitepaper.pdf. Accessed 14 Dec. 2012

S Azhar, J Brown, A Sattineni (2010). A case study of building performance analyses using building information modeling. In: Proceedings of the 27th International Symposium on Automation and Robotics in Construction (ISARC-27), Bratislava, Slovakia.

DOI

A Azhar, J Brown (2009). BIM for sustainability analyses. International Journal of Construction Education and Research, 5: 276-292.

DOI Google Scholar

R Baldwin, A Yates, N Howard, S Rao (1998). Building Research Establishment Environmental Assessment Method for offices (BREEAM). Watford, UK.

T Biswas, T-H Wang, R Krishnamurti (2008). Integrated sustainable building rating systems with building information modeling. In: Proceedings of the 13th International Conference on Computer Aided Architectural Design Research in Asia, Chiang Mai, Thailand, pp. 193-200.

CaGBC (Canada Green Building Council) (2011). What is LEED? Available: http://www.cagbc.org/AM/Template.cfm?Section=LEED. Accessed 27 Jun. 2012.

CASBEE (2008). Comprehensive Assessment System for Building Environmental Efficiency. Available: http://www.ibec.or.jp/CASBEE/english/index.htm. Accessed 6 Jun. 2012.

RJ Cole, D Rousseau, GT Theaker (1993). Building environmental performance assessment criteria (BEPAC) Foundation. Vancouver, Canada

C Eastman, P Teicholz, R Sacks, K Liston (2008). BIM Handbook: A Guide to Building Information Modeling for Owner, Managers, Designers, Engineers, and Contractors. New York: John Wiley & Sons.

DOI

M Fischer, T Hartmann, E Rank, F Neuberg, M Schreyer, K Liston, J Kunz (2004). Combining different project modeling approaches for effective support of multi-disciplinary engineering tasks. In: Proceedings of International Conference on Information Technology in Design and Construction, Langkawi, Malaysia, pp. 167-182.

GKC Ding (2008). Sustainable construction: The role of environmental assessment tools. Journal of Environmental Management, 86: 451-464.

DOI Google Scholar

GBCA (Green Building Council of Australia) (2008). Available: http://www.gbca.org.au/. Accessed 06 Jun. 2012.

GSA (General Services Administration) (2007). Building Information Modeling Guide Series 01, Overview. Available: http://www.gsa.gov/graphics/pbs/GSA_BIM_Guide_v0_60_Series01_Overview_05_14_07.pdf. Accessed 5 Dec. 2012.

JB Guinée, R Heijungs, G Huppes, A Zamagni, P Masoni, R Buonamci, T Ekvall, T Rydberg (2011). Life cycle assessment: Past, present, and future. Journal of Environmental Science and Technology, 45: 90-96.

DOI Google Scholar

T Häkkinen, A Kiviniemi (2008). Sustainable building and BIM. In: Proceedings of World Sustainable Building Conference (SB08), Melbourne, Australia.

B Hardin (2009). BIM and Construction Management. Indianapolis, USA: John Wiley & Sons.

JL Hoff (2008). Life cycle assessment and the LEED green building rating systems. In: Proceedings of the RCI 23rd International Convention, Phoenix, USA.

MM Khasreen, PFG Banfill, GF Menzies (2009). Life-cycle assessment and the environmental impact of buildings: A review. Sustainability, 1: 674-701

DOI Google Scholar

E Kriegel, B Nies (2008). Green BIM. Indianapolis, USA: John Wiley & Sons.

E Loh, D Nashwan, J Dean (2007). Integration of 3D tool with environmental impact assessment (3D EIA). In: Proceedings of International Conference of Arab Society for Computer Aided Architectural Design (ASCAAD 2007), Alexandria, Egypt.

B McFarlane (2008). How a major design firm adapted to a paradigm shift. Healthcare Design, Available: http://www.healthcaredesignmagazine.com/article/how-major-design-firm-adapted-paradigm-shift?page=3. Accessed 5 Dec. 2012.

McGraw Hill Construction (2009). Smart Market Report: The business value of BIM: Getting Building information modeling to the bottom line. Available: http://www.tpm.com/images/stories/documents/autodesk/Final_2009_BIM_SmartMarket_Report.pdf. Accessed 20 Sept. 2011.

N Wang, KM Fowler, RS Sullivan (2012). Green building certification system review. US Department of Energy, PNNL-20966.

RM Pulselli, E Simoncini, FM Pulselli, S Bastianoni (2007). Emergy analysis of building manufacturing, maintenance and use: Em-building indices to evaluate housing sustainability. Energy and Buildings, 39: 620-628.

DOI Google Scholar

R Ries, A Mahdavi (2001). Integrated computational life-cycle assessment of buildings. Journal of Computing in Civil Engineering, 15: 59-66.

DOI Google Scholar

J Steel, R Drogemuller, B Toth (2010). Model interoperability in building information modeling. Software and System Modeling, 11: 99-109.

DOI Google Scholar

DB Thomson, RG Miner (2006). BIM: Contractual risks are changing with technology. Consulting-Specifying Engineer, 40: 54-66.

Google Scholar

USGBC (US Green Building Council (2011). Introduction to LEED. Available: http://www.usgbc.org/DisplayPage.aspx?CMSPageID=1988. Accessed 26 Sept. 2011.

WBDG (2012). Whole Building Design Guide: Evaluating and Selecting Green Products. Available: http://www.wbdg.org/resources/greenproducts.php. Accessed 8 Jun. 2012.

WGBC (World Green Building Council) (2008) Available: http://www.worldgbc.org/. Accessed 28 May 2011.

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Publication history

Received: 13 August 2012

Revised: 31 January 2013

Accepted: 19 February 2013

Published: 02 April 2013

Issue date: December 2013

Integrating building information modelling with sustainability to design building projects at the conceptual stage

Integrating building information modelling with sustainability to design building projects at the conceptual stage

Abstract

References(31)

Publication history

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