[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.12989/sem.2019.70.4.381

Mitigation of progressive collapse in steel structures using a new passive connection

Mirtaheri, Masoud (Department of Civil Engineering, K.N.Toosi University of Technology)
Emami, Fereshteh (Department of civil engineering, Science and Research Branch, Islamic Azad University)
Zoghi, Mohammad A. (Department of Civil Engineering, K.N.Toosi University of Technology)
Salkhordeh, Mojtaba (Department of Civil Engineering, K.N.Toosi University of Technology)

Publication Information

Structural Engineering and Mechanics / v.70, no.4, 2019 , pp. 381-394 More about this Journal

Abstract

If an alternative path would not be considered for redistribution of loads, local failure in structures will be followed by a progressive collapse. When a vertical load-bearing element of a steel structure fails, the beams connected to it will lose their support. Accordingly, an increase in span's length adds to the internal forces in beams. The mentioned increasing load in beams leads to amplifying the moments there, and likewise in their corresponding connections. Since it is not possible to reinforce all the elements of the structure against this phenomenon, it seems rational to use other technics like specified strengthened connections. In this study, a novel connection is suggested to handle the stated phenomenon which is introduced as a passive connection. This connection enables the structure to tolerate the added loads after failing of the vertical element. To that end, two experimental models were constructed and thereafter tested in half-scale, one-story, double-bay, and bolted connections in three-dimensional spaces. This experimental study has been conducted to compare the ductility and strength of a frame that has ordinary rigid connections with a frame containing a novel passive connection. At last, parametric studies have been implemented to optimize the dimensions of the passive connection. Results show that the load-bearing capacity of the frame increased up to 75 percent. Also, a significant decrease in the displacement of the node wherein the column is removed was observed compared to the ordinary moment resisting frame with the same loads.

Keywords

progressive collapse; alternative path; passive connection; rigid connection; ductility; strength;

Citations & Related Records

Times Cited By KSCI : 11 (Citation Analysis)

Reference
Cited By KSCI

1	Adom-Asamoah, M. and Ankamah, N.O. (2016), "Effect of design ductility on the progressive collapse potential of RC frame structures designed to Eurocode 8", American J. Civil Eng., 4(2), 24-33. DOI
2	Almusallam, T.H., Elsanadedy, H.M., Abbas, H., Alsayed, S.H. and Al-Salloum, Y.A. (2010), "Progressive collapse analysis of a RC building subjected to blast loads" Struct. Eng. Mech., 36(3), 301-319. DOI
3	Astaneh-Asl, A., Jones, B. and Zhao, Y. and Hwa, R. (2001), "Progressive collapse resistance of steel building floors", UCB/CEE-Steel-2001; University of California, Berkeley, U.S.A.
4	BHRC (Building and Housing Research Center) (2004), Iranian Code of Practice for Seismic Resistant Design of Buildings, Standard No. 2800, BHRC, Tehran, Iran.
5	Byfield, M. and Paramasivam, S. (2007), "Catenary action in steel-framed buildings", Proceedings of the Institution of Civil Engineers-Structures and Buildings, 160(5), 247-257. DOI
6	Chen, J., Huang, X., Ma, R. and He, M. (2011), "Experimental study on the progressive collapse resistance of a two-story steel moment frame", J. Perform. Construct. Facilities, 26(5), 567-575. DOI
7	Chen, C.H., Zhu, Y.F., Yao, Y. and Huang, Y. (2016), "Progressive collapse analysis of steel frame structure based on the energy principle", Steel Compos. Struct., 21(3), 553-571. DOI
8	Crawford, J.E. (2002), "Retrofit methods to mitigate progressive collapse", The Multihazard Mitigation Council of the National Institute of Building Sciences, National Workshop and Recommendations for Future Effort, July.
9	Dinu, F., Marginean, I. and Dubina, D. (2017), "Experimental testing and numerical modelling of steel moment-frame connections under column loss", Eng. Struct., 151, 861-878. DOI
10	Faridmehr, I. and Osman, M.H., Tahir, M., Nejad, A.F. and Azimi, M. (2015), "Seismic and progressive collapse assessment of new proposed steel connection", Adv. Struct. Eng., 18(3), 439-452. DOI
11	Fu, F. (2016), Structural Analysis and Design to Prevent Disproportionate Collapse, CRC Press, London, United Kingdom.
12	Han, Q., Li, X., Liu, M. and Spencer Jr, B.F. (2019), "Experimental investigation of beam-column joints with cast steel stiffeners for progressive collapse prevention", J. Struct. Eng., 145(5), 04019020. DOI
13	Gerasimidis, S., Deodatis, G., Kontoroupi, T. and Ettouney, M. (2015), "Loss-of-stability induced progressive collapse modes in 3D steel moment frames", Struct. Infrastruct. Eng., 11(3), 334-344. DOI
14	Griffiths, H., Pugsley, A. and Saunders, O. (1968), "Report of the inquiry into the collapse of flats at Ronan Point, Canning Town", Minister of Housing and Local Government, United Kingdom.
15	GSA (2013), Alternate Path Analysis and Design Guidelines for Progressive Collapse Resistance, General Services Administration, Washington, U.S.A.
16	Kim, J. and Park, J. (2008), "Design of steel moment frames considering progressive collapse", Steel Compos. Struct., 8(1), 85-98. DOI
17	JalaliLarijani, R., Celikag, M., Aghayan, I. and Kazemi, M. (2013), "Progressive collapse analysis of two existing steel buildings using a linear static procedure", Struct. Eng. Mech., 48(2), 207-220. DOI
18	Khaloo, A. and Omidi, H. (2018), "Evaluation of vierendeel peripheral frame as supporting structural element for prevention of progressive collapse", Steel Compos. Struct., 26(5), 549-556. DOI
19	Khandelwal, K. and El-Tawil, S. (2007), "Collapse behavior of steel special moment resisting frame connections", J. Struct. Eng., 133(5), 646-655. DOI
20	Kim, J., Lee, S. and Min, K.W. (2014), "Design of MR dampers to prevent progressive collapse of moment frames", Struct. Eng. Mech., 52(2), 291-306. DOI
21	Liu, C., Tan, K.H. and Fung, T.C. (2015), "Component-based steel beam-column connections modelling for dynamic progressive collapse analysis", J. Construct. Steel Res., 107, 24-36. DOI
22	Shan, S., Li, S., Xu, S. and Xie, L. (2016), "Experimental study on the progressive collapse performance of RC frames with infill walls", Eng. Struct., 111, 80-92. DOI
23	Lu, X., Lin, K., Li, Y., Guan, H., Ren, P. and Zhou, Y. (2017), "Experimental investigation of RC beam-slab substructures against progressive collapse subject to an edge-column-removal scenario", Eng. Struct., 149, 91-103. DOI
24	Mashhadi, J. and Saffari, H. (2017), "Dynamic increase factor based on residual strength to assess progressive collapse", Steel Compos. Struct., 25(5), 617-624. DOI
25	Mirtaheri, M. and Zoghi, M.A. (2016), "Design guides to resist progressive collapse for steel structures", Steel Compos. Struct., 20(2), 357-378. DOI
26	Ren, P., Li, Y., Lu, X., Guan, H. and Zhou, Y. (2016), "Experimental investigation of progressive collapse resistance of one-way reinforced concrete beam-slab substructures under a middle-column-removal scenario", Eng. Struct., 118, 28-40. DOI
27	Rezvani, F. H. and Asgarian, B. (2014), "Effect of seismic design level on safety against progressive collapse of concentrically braced frames", Steel Compos. Struct., 16(2), 135-156. DOI
28	Suwondo, R., Cunningham, L., Gillie, M. and Bailey, C. (2019), "Progressive collapse analysis of composite steel frames subject to fire following earthquake", Fire Safety J., 103, 49-58. DOI
29	Tan, S. and Astaneh-Asl, A. (2003), "Cable-based retrofit of steel building floors to prevent progressive collapse", UCB/CEESTEEL-2003/02; University of California, U.S.A.
30	Tsitos, A. and Mosqueda, G. (2012), "Experimental investigation of the progressive collapse of a steel special moment-resisting frame and a post-tensioned energy-dissipating frame", Role of Seismic Testing Facilities in Performance-Based Earthquake Engineering, Springer, Dordrecht, Germany.
31	Zoghi, M.A. and Mirtaheri, M. (2016), "Progressive collapse analysis of steel building considering effects of infill panels", Struct. Eng. Mech., 59(1), 59-82. DOI
32	UFC 4-023-03 (2013), Design of Buildings to Resist Progressive Collapse, Department of Defense, Washington, D.C., U.S.A.
33	Yang, B., Tan, K.H., Xiong, G. and Nie, S.D. (2016), "Experimental study about composite frames under an internal column-removal scenario", J. Construct. Steel Res., 121, 341-351. DOI
34	Yi, W.J., He, Q.F., Xiao, Y. and Kunnath, S.K. (2008), "Experimental study on progressive collapse-resistant behavior of reinforced concrete frame structures", ACI Structural J., 105(4), 433.
35	Zahrai, S.M. and Ezoddin, A. (2018), "Cap truss and steel strut to resist progressive collapse in RC frame structures", Steel Compos. Structures., 26(5), 635-648. DOI
36	Zhu, Y.F., Chen, C.H., Yao, Y., Keer, L.M. and Huang, Y. (2018), "Dynamic increase factor for progressive collapse analysis of semi-rigid steel frames", Steel Compos. Structures., 28(2), 209-221. DOI

1	(2021) Earthquakes and structures Seismic progressive collapse mitigation of buildings using cylindrical friction damper / 20 (1) , 1
2	(2019) Steel & Composite structures : an international journal Further study on improvement on strain concentration in through-diaphragm connection / 39 (2) , 135