Optimal Selection of Industrial Building Systems using Analytic Hierarchy Process: A Case Study in Schools of Kerman Province
Subject Areas :Amirabbas Abouei Mehrizi 1 , Hamzeh Dehghani 2
1 - Department of Industrial Engineering, Higher Education Complex of Bam, Bam, Iran
2 - Department of Civil Engineering, Higher Education Complex of Bam, Bam, Iran
Keywords: Industrial building systems, Analytic hierarchy process, Cost criterion, Time criterion, Execution criterion, Quality and technical capability criterion.,
Abstract :
Objective: The aim of this research is to select the optimal industrial building systems in the schools of Kerman province using the hierarchical analysis. necessity: Industrialization of buildings as systematic method to improve the quality and speed of construction has been considered by construction policymakers. in recent years, industrialization is policies the School Renovation, Development and Equipping Organization. Methodology: Four main criteria and twenty sub-criteria were identified to evaluate industrial systems suitable for schools. According to the eleventh national building regulations, lightweight steel frame (LSF), prefabricated concrete buildings, reinforced concrete structural wall system with permanent insulation mold and three-dimensional prefabricated panel system have been used for evaluation. In this research, the hierarchical analysis process approach has been used in order to rank the effective factors in the optimal selection of industrial building systems in the schools of Kerman province. Findings: the data analysis was done using the hierarchical method. The results show that LSF with a score of 0.303 is the most suitable option. the score of prefabricated concrete building system, three-dimensional style prefabricated panel system and reinforced concrete structural wall system with permanent insulation mold were obtained as 0.266, 0.22 and 0.21 respectively. Conclusion: Four main criteria have been used in this research. The results obtained from the data analysis show that the criterion of practicability is the most important criterion with a relative weight of 0.427. according to quality and technical ability, cost and time with relative weights of 0.401, 0.106 and 0.067 were placed in next priorities.
اولیا، جلیل؛ تقدیری، علیرضا؛ قنبرزاده، سارا. (1389). سازگاری ساختاری سیستم های صنعتی ساختمان سازی، معماری و شهرسازی ایران (JIAU). 1 (1). doi: 10.30475/isau.2010.61920
حقیقی، حسین؛ حسینعلی پور، مجتبی. (1389). راهبرد صنعتیسازی ساختمان در چشمانداز بیست ساله کشور (مطالعه موردی امکانسنجی استفاده از LSF در تهران). فصلنامه علمی راهبرد، 18 (4).
دفتر مقررات ملی ساختمان. (1400). مبحث یازدهم مقررات ملی ساختمان (طرح واجرای صنعتی ساختمان ها)
رضاییان، علیرضا؛ حسینی، سیدامیرحسین. (1394). انتخاب سیستم ساختمانی بهینه با استفاده از روش های تصمیم گیری چند معیاره با تاکید بر سه روش AHP, SAW,TOPSIS . مهندسی سازه و ساخت، 2 (2)، 16-27.
قیصری، سمیه؛ رخشانی مهر، مهراله؛ ورناصری، داریوش و همکاران. (1399). صنعتي سازي مدارس. نشر كلام ماندگار.
مركز تحقيقات ساختمان و مسكن. (1387). سيستم قالب هاي عايق ماندگار
مركز تحقيقات ساختمان و مسكن. (1388). فناوري هاي نوين ساختماني. ویرایش پنجم
مركز تحقيقات ساختمان و مسكن. (1390). سيستم قاب سبك فولادي
مركز تحقيقات ساختمان و مسكن. (1396). سيستم صفحات ساندويچي با بتن پاششي (3D)
Chen, Y., Okudan, G. E., & Riley, D. R. (2010). Decision support for construction method selection in concrete buildings: Prefabrication adoption and optimization. Automation in Construction, 19(6), 665-675. doi: https://doi.org/10.1016/j.autcon.2010.02.011
Dehghani, H., Amiri Moghadam, M., & Mahdavi, S. H. (2021). OPTIMIZED FLOORING SYSTEMS SELECTION BY ANALYTIC HIERARCHY PROCESS. [Research]. Iran University of Science & Technology, 11(3), 397-409.
Dehghani, H., & Fadaee, M. J. (2013). Calibration of resistance factors for torsional reinfrced concrete beams strengthened with FRP composites. Asian Journal of Civil Engineering, 14, 503-516.
Dehghani, H., Hormozi, A., & Nikpour, M. (2022). Systematic risks assessment of precast concrete canal in irrigation projects using DEMATEL method. International Journal of System Assurance Engineering and Management, 13(1), 123-130.
Ebrahimi, M., Hedayat, A. A., & Fakhrabadi, H. (2018). Selecting optimized concrete structure by Analytic Hierarchy Process (AHP). Computers and Concrete, 22, 327-336. doi: 10.12989/cac.2018.22.3.327
Fiorino, L., Della Corte, G., & Landolfo, R. (2007). Experimental tests on typical screw connections for cold-formed steel housing. Engineering Structures, 29(8), 1761-1773. doi: https://doi.org/10.1016/j.engstruct.2006.09.006
Jaillon, L., & Poon, C. S. (2014). Life cycle design and prefabrication in buildings: A review and case studies in Hong Kong. Automation in Construction, 39, 195-202. doi: https://doi.org/10.1016/j.autcon.2013.09.006
Lawson, R., Ogden, R., Pedreschi, R., Grubb, P., & Ola, S. P. (2005). Developments in pre-fabricated systems in light steel and modular construction. Transport, 35(15), 15.
Qi, B., Razkenari, M., Costin, A., Kibert, C., & Fu, M. (2021). A systematic review of emerging technologies in industrialized construction. Journal of Building Engineering, 39, 102265. doi: https://doi.org/10.1016/j.jobe.2021.102265
Saad, S., Alaloul, W. S., Ammad, S., Altaf, M., & Qureshi, A. H. (2022). Identification of critical success factors for the adoption of Industrialized Building System (IBS) in Malaysian construction industry. Ain Shams Engineering Journal, 13(2), 101547. doi: https://doi.org/10.1016/j.asej.2021.06.031
Saaty, T. L. (1986). Axiomatic foundation of the analytic hierarchy process. Management Science, 32, 841-855.
Zaid Hatem, M. A., Alhamza Flaih, Ammar Oda. (2021). Barriers to the adoption of industrialized building system in Iraqi construction industry. Zanco Journal of Pure and Applied Sciences, 33(3), 30-42.
Zhang, X., Skitmore, M., & Peng, Y. (2014). Exploring the challenges to industrialized residential building in China. Habitat International, 41, 176–184. doi: 10.1016/j.habitatint.2013.08.005