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Evaluation of the Seismic Collapse Capacity of Steel Moment-Resisting Frames Designed using Elastic Design (ED) and Performance-Based Plastic Design (PBPD) Methodologies

Kourosh Mehdizadeh*, Abbasali Sadeghi**, Amirreza Sadeghi***, Mohammad Hossein Razmkhah****

* Department of Civil Engineering, Islamic Azad University, Garmsar Branch, Garmsar, Iran.

** Department of Civil Engineering, Islamic Azad University, Mashhad Branch, Mashhad, Iran.

*** Department of Civil Engineering, University of Birjand, Birjand, Iran.

**** Department of Civil Engineering, Semnan University, Semnan, Iran.

Periodicity:January - March'2025
DOI : https://doi.org/10.26634/jce.15.1.21742

Abstract

In the past, calculating and spreading seismic base shear forces along the height of buildings mainly used the elastic design (ED) method found in different structural codes. This approach often resulted in designs that were neither optimal nor cost-effective, potentially leading to severe damage to buildings during seismic events. To address these shortcomings, the Performance-Based Plastic Design (PBPD) method has emerged in recent years, emphasizing the plastic behavior of structures. This study focuses on assessing the seismic collapse capacity of Steel Moment Resisting Frames (SMRFs) designed using both the ED and PBPD methods. Two SMRFs, comprising five and ten stories with intermediate ductility, were analyzed using OpenSees software and subjected to seven pairs of far-fault earthquake records. Subsequently, incremental dynamic analysis (IDA) was conducted until structural failure occurred, allowing for the extraction of fragility curves to evaluate the seismic collapse capacities of the frames. The results show that the PBPD method improves how well we can manage the ways structures bend and change shape under stress. Furthermore, the probability of failure for frames designed with the PBPD method is deemed acceptable. Notably, the research reveals that the seismic collapse capacities of frames designed with PBPD are significantly superior to those designed with ED, with a 25% and 31% increase in collapse capacity for the five-story and ten-story frames, respectively, at a statistical level of 50%. This result underscores the reliability and precision of the PBPD method in comparison to the ED approach.

Keywords

Steel moment resisting frame (SMRF), Performance-based plastic design (PBPD), Elastic design (ED), Incremental dynamic analysis (IDA), Fragility curve.

How to Cite this Article?

Mehdizadeh, K., Sadeghi, A., Sadeghi, A., and Razmkhah, M. H. (2025). Evaluation of the Seismic Collapse Capacity of Steel Moment-Resisting Frames Designed using Elastic Design (ED) and Performance-Based Plastic Design (PBPD) Methodologies. i-manager’s Journal on Civil Engineering, 15(1), 1-12. https://doi.org/10.26634/jce.15.1.21742

References

[1]. Abbas, J. L. (2023). Behaviour of steel I beams with web openings. Civil Engineering Journal, 9(3), 596-617.

[2]. Abbas, J. L., & Allawia, A. A. (2019). Structural behavior of axially loaded composite concrete-steel plate shear walls. International Journal of Engineering, 32(11), 1548-1558.

[3]. Abdollahzadeh, G., Mohammadgholipour, A., & Omranian, E. (2019). Seismic evaluation of steel moment frames under mainshock–aftershock sequence designed by elastic design and PBPD methods. Journal of Earthquake Engineering, 23(10), 1605-1628.

[4]. AISC 360. (2016). Specifications for Structural Steel Buildings.

[5]. American Society of Civil Engineers. (2000, February). Minimum Design Loads for Buildings and other Structures.

[6]. Bagherzadeh, R., Riahi Nouri, A., Massoudi, M. S., Ghazi, M., & Haddad Shargh, F. (2022). Evaluation of the seismic behavior based on the performance of special steel moment frames by modified energy method and force design method. Advances in Civil Engineering, 2022(1), 6718796.

[7]. Banihashemi, M. R., Mirzagoltabar, A. R., & Tavakoli, H. R. (2015). Performance-based plastic design method for steel concentric braced frames. International Journal of Advanced Structural Engineering (IJASE), 7, 281-293.

[8]. Chao, S. H., & Goel, S. C. (2006). Errata: Performance- based seismic design of eccentrically braced frames using target drift and yield mechanism as performance criteria. Engineering Journal, 43(4), 311-312.

[9]. Chao, S. H., & Goel, S. C. (2008). Performance-based plastic design of special truss moment frames. Engineering Journal, 45(2), 127.

[10]. Computers and Structures Inc. (2025). ETABS: Building Analysis and Design.

[11]. FEMA. (2011). Quantification of Building Seismic Performance Factors: Component Equivalency Methodology.

[12]. Ghalejoughi, M., & Sheidaii, M. R. (2023). Progressive collapse performance evaluation of shear tab connection subjected to column loss. International Journal of Steel Structures, 23(5), 1387-1398.

[13]. Gholamrezatabar, A., Ganjavi, B., Ghodrati Amiri, G., & Shayanfar, M. A. (2020). Modified seismic design lateral force distribution for the Performance-Based Plastic Design (PBPD) of steel moment structures considering soil flexibility. Scientia Iranica, 27(3), 1050- 1065.

[14]. Gjukaj, A., Salihu, F., Muriqi, A., & Cvetanovski, P. (2023). Numerical behavior of extended end-plate bolted connection under monotonic loading. HighTech and Innovation Journal, 4(2), 294-308.

[15]. Gupta, A. (1999). Seismic Demands for Performance Evaluation of Steel Moment Resisting Frame Structures. Stanford University.

[16]. Hadinejad, A., & Ganjavi, B. (2024). Optimizing seismic parameters of design lateral force pattern in performance-based plastic design of SMR frames with genetic programming. International Journal of Optimization in Civil Engineering, 14(1), 37-60.

[17]. Hazus- MH. (2003). Multi-hazard Loss Estimation Methodology. Department of Homeland Security Federal Emergency Management Agency.

[18]. Ibarra, L. F. (2004). Global Collapse of Frame Structures under Seismic Excitations. Stanford University.

[19]. Ibarra, L. F., Medina, R. A., & Krawinkler, H. (2005). Hysteretic models that incorporate strength and stiffness deterioration. Earthquake Engineering & Structural Dynamics, 34(12), 1489-1511.

[20]. Kianmehr, A. (2021). Collapse probability of immediate and special moment frames in Tehran under MCE. Shock and Vibration, 2021(1), 8144416.

[21]. Kim, J., Park, J. H., & Lee, T. H. (2011). Sensitivity analysis of steel buildings subjected to column loss. Engineering Structures, 33(2), 421-432.

[22]. Kouhestanian, H., Razmkhah, M. H., Shafaei, J., Pahlavan, H., & Shamekhi Amiri, M. (2023). Probabilistic evaluation of seismic performance of steel buildings with torsional irregularities in plan and soft story under mainshock aftershock sequence. Shock and Vibration, 2023(1), 9549121.

[23]. Lee, S. S. (2002). Performance-Based Design of Steel Moment Frames using Target Drift and Yield Mechanism. University of Michigan.

[24]. Leelataviwat, S. (1998). Drift and Yield Mechanism Based Seismic Design and Upgrading of Steel Moment Frames. University of Michigan.

[25]. Leelataviwat, S., Goel, S. C., & Stojadinović, B. (1999). Toward performance-based seismic design of structures. Earthquake Spectra, 15(3), 435-461.

[26]. OpenSees. (2007). Open System for Earthquake Engineering Simulation Manual.

[27]. Reza Banihashemi, M., Mirzagoltabar, A. R., & Tavakoli, H. R. (2015). Development of the performance based plastic design for steel moment resistant frame. International Journal of Steel Structures, 15, 51-62.

[28]. Saberi, H., Saberi, V., Sadeghi, A., Pooyasefat, A., & Noroozinejad Farsangi, E. (2021). Investigation of the occurrence of progressive collapse in high-rise steel buildings with different braced configurations. Civil and Environmental Engineering Reports, 31 (4), 33-54.

[29]. Sadeghi, A., Kazemi, H., & Samadi, M. (2021). Probabilistic seismic analysis of steel moment-resisting frame structure including adamaged column. In Structures, 33, 187-200. Elsevier.

[30]. Sadeghi, A., Kazemi, H., Hossein, M., & Razmkhah, A. S. (2024). Probabilistic investigation of the pounding effect in steel moment resisting frames with equal and unequal heights. Research on Engineering Structures and Materials, 10(4), 1431-1449.

[31]. Sadeghi, A., Kazemi, H., Mehdizadeh, K., & Jadali, F. (2022). Fragility analysis of steel moment-resisting frames subjected to impact actions. Journal of Building Pathology and Rehabilitation, 7(1), 26.

[32]. Sahoo, D. R., & Chao, S. H. (2010). Performance- based plastic design method for buckling-restrained braced frames. Engineering Structures, 32(9), 2950-2958.

[33]. Singh, V., & Sangle, K. (2022). Analysis of vertically oriented coupled shear wall interconnected with coupling beams. HighTech and Innovation Journal, 3(2), 230-242.

[34]. Suita, K., Yamada, S., Tada, M., Kasai, K., Matsuoka, Y., & Sato, E. (2007). E-Defense tests on full-scale steel buildings: Part 2-Collapse experiments on moment frames. In Structural Engineering Research Frontiers (pp. 1-12).

[35]. Vamvatsikos, D., & Cornell, C. A. (2002, September). The incremental dynamic analysis and its application to performance-based earthquake engineering. In Proceedings of the 12th European Conference on Earthquake Engineering, 40, 1375-1392.

[36]. Xiong, E. G., He, H., Cui, F. F., & Bai, L. (2016). Performance-based plastic design method for steel concentrically braced frames using target drift and yield mechanism. Periodica Polytechnica Civil Engineering, 60(1), 127-134.

[37]. Zareian, F., & Krawinkler, H. (2007). Sensitivity of collapse potential of buildings to variations in structural systems and structural parameters. In Structural Engineering Research Frontiers (pp. 1-16).

[38]. Zhang, Q., Xiong, E., Liang, X., & Miao, X. (2017). Performance-based plastic design method of high-rise steel frames. Journal of Vibroengineering, 19(3), 2003- 2018.

Evaluation of the Seismic Collapse Capacity of Steel Moment-Resisting Frames Designed using Elastic Design (ED) and Performance-Based Plastic Design (PBPD) Methodologies

Abstract

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