To read this content please select one of the options below:

Improved biogeography-based optimization algorithm for lean production scheduling of prefabricated components

Juan Du (SILC Business School, Shanghai University, Shanghai, China) (Faculty of Engineering and IT, University of Technology Sydney, Sydney, Australia) (Shanghai Engineering Research Center of Urban Infrastructure Renewal, Shanghai, China)
Yan Xue (SILC Business School, Shanghai University, Shanghai, China)
Vijayan Sugumaran (Oakland University, Rochester, Michigan, USA)
Min Hu (SILC Business School, Shanghai University, Shanghai, China) (Shanghai Engineering Research Center of Urban Infrastructure Renewal, Shanghai, China)
Peng Dong (SILC Business School, Shanghai University, Shanghai, China)

Engineering, Construction and Architectural Management

ISSN: 0969-9988

Article publication date: 3 February 2022

Issue publication date: 8 May 2023

840

Abstract

Purpose

For prefabricated building construction, improper handling of the production scheduling for prefabricated components is one of the main reasons that affect project performance, which causes overspending, schedule overdue and quality issues. Prior research on prefabricated components production schedule has shown that optimizing the flow shop scheduling problem (FSSP) is the basis for solving this issue. However, some key resources and the behavior of the participants in the context of actual prefabricated components production are not considered comprehensively.

Design/methodology/approach

This paper characterizes the production scheduling of the prefabricated components problem into a permutation flow shop scheduling problem (PFSSP) with multi-optimization objectives, and limitation on mold and buffers size. The lean construction principles of value-based management (VBM) and just-in-time (JIT) are incorporated into the production process of precast components. Furthermore, this paper applies biogeography-based optimization (BBO) to the production scheduling problem of prefabricated components combined with some improvement measures.

Findings

This paper focuses on two specific scenarios: production planning and production rescheduling. In the production planning stage, based on the production factor, this study establishes a multi-constrained and multi-objective prefabricated component production scheduling mathematical model and uses the improved BBO for prefabricated component production scheduling. In the production rescheduling stage, the proposed model allows real-time production plan adjustments based on uncertain events. An actual case has been used to verify the effectiveness of the proposed model and the improved BBO.

Research limitations/implications

With respect to limitations, only linear weighted transformations are used for objective optimization. In regards to research implications, this paper considers the production of prefabricated components in an environment where all parties in the supply chain of prefabricated components participate to solve the production scheduling problem. In addition, this paper creatively applies the improved BBO to the production scheduling problem of prefabricated components. Compared to other algorithms, the results show that the improved BBO show optimized result.

Practical implications

The proposed approach helps prefabricated component manufacturers consider complex requirements which could be used to formulate a more scientific and reasonable production plan. The proposed plan could ensure the construction project schedule and balance the reasonable requirements of all parties. In addition, improving the ability of prefabricated component production enterprises to deal with uncertain events. According to actual production conditions (such as the occupation of mold resources and storage resources of completed components), prefabricated component manufacturers could adjust production plans to reduce the cost and improve the efficiency of the whole prefabricated construction project.

Originality/value

The value of this article is to provide details of the procedures and resource constraints from the perspective of the precast components supply chain, which is closer to the actual production process of prefabricated components. In addition, developing the production scheduling for lean production will be in line with the concept of sustainable development. The proposed lean production scheduling could establish relationships between prefabricated component factory manufacturers, transportation companies, on-site contractors and production workers to reduce the adverse effects of emergencies on the prefabricated component production process, and promote the smooth and efficient operation of construction projects.

Keywords

Acknowledgements

This work is supported by The Chinese Ministry of Education of Humanities and Social Science project under Grand No. 17YJC630021.

Data Availability Statement: Data generated or analyzed during the study are available from the corresponding author by request.

Citation

Du, J., Xue, Y., Sugumaran, V., Hu, M. and Dong, P. (2023), "Improved biogeography-based optimization algorithm for lean production scheduling of prefabricated components", Engineering, Construction and Architectural Management, Vol. 30 No. 4, pp. 1601-1635. https://doi.org/10.1108/ECAM-04-2021-0311

Publisher

:

Emerald Publishing Limited

Copyright © 2022, Emerald Publishing Limited

Related articles