An Integrated Model of Lean Construction and Off-Site Construction for Industrialization Architecture: Review and Future Directions
الموضوعات :
Nastaran Esmaeili
1
(Ph.D. Candidate, Department of Architecture, Mashhad Branch, Islamic Azad University, Mashhad, Iran.)
Mohsen Vafamehr
2
(Professor, Department of Architecture, Faculty of Mashhad Branch, Islamic Azad University Mashhad, Iran.)
Hassan Rezaei
3
(Assistant Professor, Department of Architecture, faculty member of Mashhad Branch, Islamic Azad University, Mashhad, Iran.)
Ali Khaki
4
(Department of Architecture, Ahvaz Branch, Islamic Azad University, Ahvaz, Iran.)
الکلمات المفتاحية: industrialization architecture, Off-Site Construction, Future Construction, technological development, Lean Construction,
ملخص المقالة :
The construction industry is one of the most energy-consuming and Contamination industries. Lean construction (L.C.) is an advanced manufacturing approach that could potentially bring novel developments in the construction industry and seeks to elevate the value of the building, diminishing waste. Off-site construction (OSC) techniques have numerous advantages. Recent research studies have outlined the advantages of bringing together L.C. and OSC. This research aims to identify the elements of blending L.C. and OSC for the Industrialization architecture framework. The core ideas that are integrated into the framework are addressed and discussed. This research employed a 3-step bibliometric review of industrialization research within the construction and manufacturing sectors. A comprehensive systematic literature review technique to review the literature on L.C. and OSC for industrialization architecture identified factors of integrated L.C. and OSC for industrialization architecture and arrived at a conceptual model by recognizing these components. To refine AEC performance toward industrialization construction, The increased efficiency of the enhanced production system is taking a more prominent place. The introduction of automation and robotic systems into the construction process, pre-fabrication technique, construction 4.0 and use of information communication technology and digital technology (BIM, RFID,...), use of DFMA technique (design for manufacture and assembly) and sustainability ability for the elimination of construction waste are factors for integrating L.C. and OSC for industrialization architecture. This document provides a reference for future construction direction to achieve industrialization construction.
Abanda, F.H, Tah, J.H.M., Cheung, F.K.T. (2017) . BIM in off-site manufacturing for buildings. Journal of Building Engineering, 14, 89–102.
Ajayi, S. O., Oyedele, L. O., Akinade, O. O., Bilal, M., Owolabi, H. A., Alaka, H. A., & Kadiri, K. O. (2016). Reducing waste to landfill: A need for cultural change in the UK construction industry. Journal of Building Engineering, 5, 185-193.
Andersson, N., Lessing, J. (2017). The Interface between industrialized and project-based construction. Creative Construction Conference 2017, CCC 2017, 19-22 June 2017, Primosten, Croatia.
Aslam, M ., Smith, G., Gao, Z . (2022). Framework for selection of lean construction tools based on lean objectives and functionalities. International Journal of Construction Management, 22(3), 1-12.
Babalola, O., Ibem, E.O., & Ezema, I.C. (2019). Implementation of lean practices in the construction industry: a systematic review. Building and Environment, 148, 34-43.
Bag, S., Gupta, S., & Kumar, S. (2021). Industry 4.0 adoption and 10R advance manufacturing capabilities for sustainable development. International journal of production economics, 231, 107844.
Bajjou, M. S., Chafi, A., & En-Nadi, A. (2017). The potential effectiveness of lean construction tools in promoting safety on construction sites. International Journal of Engineering Research in Africa, 33, 179-193.
Bekdik, B., Hall, D., & Aslesen, S. (2016). Off-Site prefabrication: what does it require from the trade contractor. Int Group Lean Constr, 43, 43-52.
Benachio, G. L. F., Freitas, M. D. C. D., & Tavares, S. F. (2021). Interactions between lean construction principles and circular economy practices for the construction industry. Journal of construction engineering and management, 147(7), 04021068.
Bernstein, H. M., Jones, S. A. (2013). Lean construction: Leveraging collaboration and advanced practices to increase project efficiency. Intelligence, McGraw Hill Construction, Bedford, MA.
Blismas, N., Pasquire, C., & Gibb, A. (2006). Benefit evaluation for off‐site production in construction. Construction management and Economics, 24(2), 121-130.
Bogue, R. (2012). Design for manufacture and assembly: background, capabilities, and applications. Assembly Automation, 32(2), 112-118.
Boothroyd, G., Dewhurst, P., & Knight, W. (2002). Product Design for Manufacture and Assembly. 2nd ed, CRC Press Taylor & Francis, Boca Raton,U.S. Raton,U.S.
Boothroyd, G., Dewhurst, P., Knight, W.(2004). Product Design for Manufacture and Assembly, second ed. Marcel Dekker, New York.
Burgess, J.C ., Buckett, N.R., Page, I.C. (2013). Pre-fabrication Impacts in the New Zealand Construction Industry. (SR279), BRANZ, Judgeford, New Zealand, Retrieved from: https://www.branz.co.nz/pubs/research-reports/sr279
Chauhan, K., Peltokorpi, A., Seppänenand, O., Berghede, K . (2018). Combining takt planning with pre-fabrication for industrialization. Construction. IGLC - Proceedings of the 26th Annual Conference of the International Group for Lean Construction, 2, . 848–857.
Chippagiri, R., Deepak, S., Bras, Ana., & Ralegaonkar, R. (2022). Technological and Sustainable Perception on the Advancements of Pre-fabrication in Construction Industry, Energies, 15(20), 7548.
Construction Industry Council (CIC). (2019). What is CIC? Retrieved from: https://bit.ly/2vBWLVI
Davila Delgado, J.M., Oyedele, L., Ajayi, A., Akanbi, L., Akinade, O., Bilal, M.,& Owolabi, H. (2019). Robotics and automated systems in construction: understanding industry-specific challenges for adoption, Journal of Building Engineering, 26, 100868.
Denyer, D. & Tranfield, D. (2009). Producing a Systematic Review. In: Buchanan, P. D. & Bryman, P. A. (eds.) The Sage Handbook of Organizational Research Methods. London: Sage Publications.
Elnaas, H., Gidado, K., & Philip, A. P. (2014). Factors and drivers effecting the decision of using off-site manufacturing (OSM) systems in house building industry. Journal of Engineering, Project, and Production Management, 4(1), 51-58.
Gao, S., Low, S. P., & Nair, K. (2018). Design for manufacturing and assembly (DfMA): a preliminary study of factors influencing its adoption in Singapore. Architectural engineering and design management, 14(6), 440-456.
Garcia de Soto, B., Skibniewski, M. J. (2020). Future of robotics and automation in construction. Chapter 15. In: Sawhney, A., Riley, M., & Irizarry, J. (eds.), Construction 4.0: An Innovation Platform for the Built Environment, 1st Edn. Routledge, London.
Gerber, D.J., Pantazis, E., & Wang, A. (2017). A multi-agent approach for performance-based architecture: design exploring geometry, user, and environmental agencies in façades. Automation in Construction, 76, 45-58.
Goh, M., Goh, Y. M. (2019). Lean production theory-based simulation of modular construction processes. 27th Annual Conference of the International Group for Lean Construction, IGLC 2019, 711-722.
Green, S., May, S. (2005). Lean construction: arenas of enactment, models of diffusion, and the meaning 'leanness. Build. Res. Inf., 33(6), 498-511.
Grilo, A., & Jardim-Goncalves, R. (2010). Value proposition on interoperability of BIM and collaborative working environments. Automation in construction, 19(5), 522-530.
Gusmao Brissi, S., Wong Chong, O., Debs, L., & Zhang, J. (2022). A review on the interactions of robotic systems and lean principles in offsite construction. Engineering, Construction and Architectural Management, 29(1), 383-406.
Jayawardana, J., Kulatunga, A. K., Jayasinghe, J. A. S. C., Sandanayake, M., & Zhang, G. (2023). Environmental Sustainability of Off-Site Construction in Developed and Developing Regions: A Systematic Review. Journal of Architectural Engineering, 29(2), 04023008.
Jensen, P., Olofsson, T., Sandberg, M., & Malmgren, L. (2008). Reducing complexity of customized prefabricated buildings through modularization and IT support. In International Conference on Informations Technology in Construction: 15/07/2008-17/07/2008 (pp. 429-437). Universidad de Talca.
Jin, R., Gao, S., Cheshmehzangi, A., & Aboagye-Nimo, E. (2018). A holistic review of off-site construction literature published between 2008 and 2018. Journal of cleaner production, 202, 1202-1219.
Johnsson, H. (2011). The Building System as a Strategic Asset in Industrialised Construction. 6th Nordic Conference on Construction Economics and Organisation.
Jørgensen, F., Matthiesen, R., Nielsen, J., & Johansen, J. (2007). Lean maturity, lean sustainability. In Advances in Production Management Systems: International IFIP TC 5, WG 5.7 Conference on Advances in Production Management Systems (APMS 2007), September 17–19, Linköping, Sweden (pp. 371-378). Springer US.
Kolberg, D., Zuhlke, D. (2015). Lean automation enabled by industry 4.0 technologies. IFAC Papers Online, 48(3), 1870-1875.
Kolo, S. J., Rahimian, F. P., & Goulding, J. S. (2014). Offsite manufacturing construction: a big opportunity for housing delivery in Nigeria. Procedia Engineering, 85, 319-327.
Koskela, L. (1992). Application of the new production philosophy to construction. (Vol. 72). CIFE Technical Rep. Stanford, CA: Stanford University.
Langston, C., & Zhang, W. (2021). DfMA: Towards an integrated strategy for a more productive and sustainable construction industry in Australia. Sustainability, 13(16), 9219.
Lekan, A., Clinton, A., Isaac Fayomi, O., & James, O. (2020). Lean Thinking and Industrial 4.0 Approach to Achieving Construction 4.0 for Industrialization and Technological Development. Buildings, 10(12), 221.
Lekan, A ., Clinton, A ., Stella, E ., Moses, E., & Biodun, O.(2022). Construction 4.0 Application: Industry 4.0, Internet of Things, and Lean Construction Tools' Application in Quality Management System of Residential Building Projects. Buildings, 12(10), 1557.
Li, X., Shen, G. Q., Wu, P., Fan, H., Wu, H., & Teng, Y. (2018). RBL-PHP: Simulation of lean construction and information technologies for prefabrication housing production. Journal of Management in Engineering, 34(2), 04017053.
Linner, T., Bock, T. (2012). Evolution of large-scale industrialization and service innovation in the Japanese pre-fabrication industry. Construction Innovation, 12(2), 156-178.
Lu, W., & Yuan, H. (2013). Investigating waste reduction potential in the upstream processes of offshore prefabrication construction. Renewable and Sustainable Energy Reviews, 28, 804-811.
Luo, J. (2022). Construction-Oriented Architectural Design in Off-Site Construction Towards Lean Construction and Management. Advances in Transdisciplinary Engineering, 31, 696–703.
Lu, W., Tan, T., Xu, J., Wang, J., Chen, K., Gao, S., & Xue, F. (2021). Design for manufacture and assembly (DfMA) in construction: The old and the new. Architectural Engineering and Design Management, 17(1-2), 77-91.
Mahamadu, A. M., Mahdjoubi, L., & Booth, C. A. (2017). Critical BIM qualification criteria for construction pre-qualification and selection. Architectural Engineering and Design Management, 13(5), 326-343.
Malik, N., Ahmad, R., Chen, Y., Altaf, M. S., & Al-Hussein, M. (2019). Minimizing joist cutting waste through dynamic waste allocation in panelized floor manufacturing. International journal of construction management, 21(10), 1011-1023.
Marte Gómez, J ., I. Daniel , Emmanuel ., Fang,Y., Oloke, D., & Gyoh ,L . (2021). implementation of Bim and lean construction in off-site housing construction: evidence from the U.K., 29th Annual Conference of the International Group for Lean Construction (IGLC29).
Ma, S., Li, Z., Li, L., Yuan, M., & Yin, X. (2023). Exploring the effect of stakeholder relationship quality on technological innovation in off-site construction: the mediating role of the knowledge sharing. Journal of Civil Engineering and Management, 29(1), 77-92.
Meng, Q., Zhang, Y., Li, Z., Shi, W., Wang, J., Sun, Y., Xu, L.,&Wang, X. (2020). A review of integrated applications of BIM and related technologies in whole building life cycle. Engineering Construction and Architectural Management, 27(8), 1647-1677.
McKinsey Global Institute. (2017). Reinventing Construction: A Route to Higher Productivity. McKinsey and Company, New York, NY.
Nanyam, V. N., Sawhney, A., & Gupta, P. A. (2017). Evaluating offsite technologies for affordable housing. Procedia Engineering, 196, 135-143.
National Research Council. (2009). Advancing the Competitiveness and Efficiency of the U.S. Construction Industry. Washington: DC: The National Academic Press.
Nawari, N. O. (2012). BIM standard in off-site construction. Journal of Architectural Engineering, 18(2), 107-113.
Nof, S.Y. (Ed.), (2009), Springer Handbook of Automation, Springer Handbooks, Springer, Berlin, Heidelberg. West Lafayette IN 47907, USA.
O'Brien, M., Wakefield, R.,& Beliveau, Y. (2000). Industrializing the residential construction site. Center for Housing Research, Virginia Polytechnic Insititute and State University Blacksburg, Virginia.
Oesterreich, T. D., & Teuteberg, F. (2016). Understanding the implications of digitisation and automation in the context of Industry 4.0: A triangulation approach and elements of a research agenda for the construction industry. Computers in industry, 83, 121-139.
Ogunbiyi, O., Goulding, J. S., & Oladapo, A. (2014). An empirical study of the impact of lean construction techniques on sustainable construction in the U.K. Construction Innovation, 14(1), 88–107.
O'Hegarty, R., & Kinnane, O. (2020). Review of precast concrete sandwich panels and their innovations. Construction and building materials, 233, 117145.
Pan, W., Gibb, A. G., & Dainty, A. R. (2012). Strategies for integrating the use of off-site production technologies in house building. Journal of construction engineering and management, 138(11), 1331-1340.
Pan, W., & Goodier, C. (2012). House-building business models and off-site construction take-up. Journal of architectural engineering, 18(2), 84-93.
Pascall, T.(2019). Innovation and Industry 4.0. Disruption. Retrieved 19 April. from: https://disruptionhub com/innovation-industry-4-0
Popovic, D., & Winroth, M. (2016). Industrial timber house building-levels of automation. In 33rd International Symposium on Automation and Robotics in Construction, Auburn, AL, USA.
Prasad, S., Sharma, S.K. (2014). Lean and Manufacturing: Concept and its Implementation in Operation Management. International Journal of Advanced Mechanical Engineering. 2014, 4, 2250–3234.
Qi , B., Razkenari ,M., Costin, A., Kibert, Charles,. Fu, M . (2021). A systematic review of emerging technologies in industrialized construction. Journal of Building Engineering, 39, 102265.
Rastogi, S. (2017). Construction 4.0, The 4th Generation Revolution. Indian Lean Construction Conference—ILCC 2017:C288; Kessington Press Ltd.: New York, NY, USA.
Saidi, K ., Bock, T.,& Georgoulas, C. (2016). Robotics in construction. in Siciliano, B. and Khatib,O. (Eds), Springer Handbook of Robotics, 1493-151.
Saieg, P., Sotelino, E. D., Nascimento, D., & Caiado, R. G. G. (2018). Interactions of building information modeling, lean and sustainability on the architectural, engineering and construction industry: a systematic review. Journal of cleaner production, 174, 788-806.
Santana-Sosa, A., & Riola-Parada, F. (2018). A theoretical approach towards ressource efficiency in multi-story timber buildings through BIM and lean. In WCTE 2018-World Conference on Timber Engineering.
Sawhney, A., Riley, M.,& Irizarry, J. (Eds). (2020). Construction 4.0: An Innovation Platform for the Built Environment, Routledge.
Tafazzoli, M., Mousavi, E., & Kermanshachi, S. (2020). Opportunities and challenges of green-lean: An integrated system for sustainable construction. Sustainability, 12(11), 4460.
Tam, V. W., Tam, C. M., Zeng, S. X., & Ng, W. C. (2007). Towards adoption of pre-fabrication in construction. Building and Environment, 42(10), 3642-3654.
Tan, T., Lu,w., Tan,G ., Xue, F ., Chen.,K ., Xu,J ., Wang, J ., & Gao, sh .(2020). Construction-Oriented Design for Manufacture and Assembly (DfMA)Guidelines. Journal of Construction Engineering and Management, 146(8), 04020085.
Tezel, A., Taggart, M., Koskela, L., Tzortzopoulos, P., Hanahoe, J., & Kelly, M. (2020). Lean construction and BIM in small and medium-sized enterprises (SMEs) in construction: a systematic literature review. Canadian Journal of Civil Engineering, 47(2), 186-201.
Treasury, H.M. (2017). Autumn Budget: London, UK, ISBN 978-1-5286-0119. Retrieved from: https://assets.publishing.service.gov.uk
UK parliament, (2018). Off-site manufacture for construction: Building for change" 2nd Report of Session 2017-19 - Published 19 July 2018 - HL Paper 169.
Von Heyl, J ., Teizer, J. (2017). Lean Production Controlling and Tracking Using Digital Methods, LC3 2017 Volume II – Proceedings of the 25th Annual Conference of the International Group for Lean Construction (IGLC).
Von Heyl, J., & Demir, S. (2019). Digitizing Lean Construction With Building Information Modelling. In Proc. 27th Conf. Int. Gr. Lean Constr., 843-852.
Wuni, I. Y., Shen, G. Q., & Mahmud, A. T. (2019). Critical risk factors in the application of modular integrated construction: a systematic review. International Journal of Construction Management, 22(2), 133-147.
Wuni, I., Qiping Shen,G., Darko, A. (2022). Best practices for implementing industrialized construction projects: lessons from nine case studies. Construction Innovation, 22(4), 915–938.
Yuan, Z., Sun, C., & Wang, Y. (2018). Design for manufacture and assembly-oriented parametric design of pre-fabricated buildings. Automation in Construction, 88, 13–22.
Zhang, X., Skitmore, M., & Peng, Y. (2014). Exploring the Challenges to Industrialized Residential Building in China. Habitat Int, 41, 176–84.
