[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.12989/sem.2018.65.3.251

Modal pushover analysis of self-centering concentrically braced frames

Tian, Li (School of Civil Engineering, Shandong University)
Qiu, Canxing (School of Civil Engineering, Shandong University)

Publication Information

Structural Engineering and Mechanics / v.65, no.3, 2018 , pp. 251-261 More about this Journal

Abstract

Self-centering concentrically braced frames (SCCBFs) are emerging as high performance seismically resistant braced framing system, due to the capacity of withstanding strong earthquake attacks and promptly recovering after events. To get a further insight into the seismic performance of SCCBFs, systematical evaluations are currently conducted from the perspective of modal contributions. In this paper, the modal pushover analysis (MPA) approach is utilized to obtain the realistic seismic demands by summarizing the contribution of each single vibration mode. The MPA-based results are compared with the exact results from nonlinear response history analysis. The adopted SCCBFs originate from existing buckling-restrained braced frames (BRBF), which are also analyzed for purpose of comparison. In the analysis of these comparable framing systems, interested performance indices that closely relate to the structural damage degree include the interstory drift ratio, floor acceleration, and absorbed hysteretic energy. The study shows that the MPA approach produces acceptable predictions in comparison to the exact results for SCCBFs. In addition, the high-modes effect on the seismic behavior increases with the building height, and is more evident in the SCCBFs than the BRBFs.

Keywords

modal contribution; model pushover analysis; seismic performance; self-centering; braced frame;

Citations & Related Records

Times Cited By KSCI : 1 (Citation Analysis)

Reference
Cited By KSCI

1	Somerville, P.G. (1997), Development of Ground Motion Time Histories for Phase 2 of the FEMA/SAC Steel Project, SAC Joint Venture.
2	Tremblay, R., Lacerte, M. and Christopoulos, C. (2008), "Seismic response of multistory buildings with self-centering energy dissipative steel braces", J. Struct. Eng., 134(1), 108-120. DOI
3	Uang, C.M. and Bertero, V.V. (1990), "Evaluation of seismic energy in structures", Earthq. Eng. Struct. D, 19, 77-90. DOI
4	Vargas, R. and Bruneau, M. (2009), "Experimental response of buildings designed with metallic structural fuses. II", J. Struct. Eng., 135(4), 394-403. DOI
5	Wiebe, L., Christopoulos, C., Tremblay, R. and Leclerc, M. (2012), "Mechanisms to limit higher mode effects in a controlled rocking steel frame. 1: Concept, modeling, and low-amplitude shake table testing". Earthq. Eng. Struct. D, 42(7), 1053-1068.
6	Xiang, Y., Luo, Y.F. and Shen, Z.Y. (2017), "An extended modal pushover procedure for estimating the in-plane seismic responses of latticed arches", Soil. Dyn. Earthq. Eng., 93, 42-60. DOI
7	Xie, Q., Zhou, Z., Li, C. and Meng, S. (2016), "Parametric analysis and direct displacement-based design method of self-centering energy-dissipative steel-braced frames", J. Struct. Stab. Dyn., 1750087.
8	Chou, C.C., Chen, Y.C., Pham, D.H. and Truong, V.M. (2014), "Steel braced frames with dual-core SCBs and sandwiched BRBs: Mechanics, modeling and seismic demands", Eng. Struct., 72, 26-40. DOI
9	Christopoulos, C., Filiatrault, A. and Folz, B. (2002), "Seismic response of self-centring hysteretic SDOF systems", Earthq. Eng. Struct. D, 31(5), 1131-1150. DOI
10	Erochko, J., Christopoulos, C., Tremblay, R. and Choi, H. (2011), "Residual drift response of SMRFs and BRB frames in steel buildings designed according to ASCE 7-05", J. Struct. Eng., 137(5), 589-599. DOI
11	Fahnestock, L.A., Ricles, J.M. and Sause, R. (2007), "Experimental evaluation of a large-scale buckling-restrained braced frame", J. Struct. Eng., 133(9), 1205-1214. DOI
12	Fang, C., Wang, W., He, C. and Chen, Y.Y. (2017), "Self-centring behaviour of steel and steel-concrete composite connections equipped with NiTi SMA bolts", Eng. Struct., 150, 390-408. DOI
13	Han, S.W., Moon, K.H. and Chopra, A.K. (2010), "Application of MPA to estimate probability of collapse of structures", Earthq. Eng. Struct. D, 39(11), 1259-1278. DOI
14	Hou, H.T., Li, H., Qiu, C.X. and Zhang, Y.C. (2017), "Effect of hysteretic properties of SMAs on seismic behavior of self-centering concentrically braced frames", Struct. Contr. Health Monitor.
15	Jiang, Y., Li, G. and Yang, D. (2010), "A modified approach of energy balance concept based multimode pushover analysis to estimate seismic demands for buildings", Eng. Struct., 32(5), 1272-1283. DOI
16	McCormick, J., DesRoches, R., Fugazza, D. and Auricchio, F. (2007), "Seismic assessment of concentrically braced steel frames with shape memory alloy braces", J. Struct. Eng., 133(6), 862-870. DOI
17	Zhu, S. and Zhang, Y. (2008), "Seismic analysis of concentrically braced frame systems with self-centering friction damping braces", J. Struct. Eng., 134(1), 121-131. DOI
18	Kunnath, S.K. (2004), "Identification of modal combinations for nonlinear static analysis of building structures", Comput-Aid. Civil Inf., 19, 246-259. DOI
19	Mao, J., Zhai, C. and Xie, L. (2008), "An improved modal pushover analysis procedure for estimating seismic demands of structures", Earthq. Eng. Eng. Vibr., 7(1), 25-31. DOI
20	McCormick, J., Aburano, H., Ikenaga, M. and Nakashima, M. (2008), "Permissible residual deformation levels for building structures considering both safety and human elements", Proceedings of the 14th World Conference on Earthquake Engineering, Beijing, China.
21	McKenna, F., Fenves, G.L. and Scott, M.H. (2000), "Open system for earthquake engineering simulation", University of California, Berkeley, California, U.S.A.
22	Miranda, E. and Taghavi, S. (2005), "Approximate floor acceleration demands in multistory buildings. I: Formulation", J. Struct. Eng., 131(2), 203-211. DOI
23	Paraskeva, T.S., Kappos, A.J. and Sextos, A.G. (2006), "Extension of modal pushover analysis to seismic assessment of bridges", Earthq. Eng. Struct. D, 35, 1269-1293. DOI
24	Neuenhofer, A. and Filippou, F.C. (1997), "Evaluation of nonlinear frame finite-element models", J. Struct. Eng., 123(7), 958-966. DOI
25	Nguyen, A.H., Chintanapakdee, C. and Hayashikawa, T. (2010), "Assessment of current nonlinear static procedures for seismic evaluation of BRBF buildings", J. Constr. Steel Res., 66(8), 1118-1127. DOI
26	Karavasilis, T.L. and Seo, C.Y. (2011), "Seismic structural and non-structural performance evaluation of highly damped self-centering and conventional systems", Eng. Struct., 33(8), 2248-2258. DOI
27	Qiu, C.X., Li, H., Ji, K.F., Hou, H.T. and Tian, L. (2017), "Performance-based plastic design approach for multi-story self-centering concentrically braced frames using SMA braces", Eng. Struct., 153, 628-638. DOI
28	Qiu, C.X. and Zhu, S. (2016), "High-mode effects on seismic performance of multi-story self-centering braced steel frames", J. Constr. Steel Res., 119, 133-143. DOI
29	Qiu, C.X. and Zhu, S. (2017a), "Shake table test and numerical study of self-centering steel frame with SMA braces", Earthq. Eng. Struct. D, 46, 117-137. DOI
30	Qiu, C.X. and Zhu, S. (2017b), "Performance-based seismic design of self-centering steel frames with SMA-based braces", Eng. Struct., 130, 67-82. DOI
31	Roke, D., Sause, R., Ricles, J.M. and Gonner, N. (2009), "Design concepts for damage-free seismic-resistant self-centering steel concentrically braced frames", Proceedings of the Structures Congress: Don't Mess with Structural Engineers: Expanding Our Role.
32	Qiu, C.X., Zhang, Y.C., Li, H., Qu, B., Hou, H.T., and Tian, L. (2018), "Seismic performance of concentrically braced frames with non-buckling braces: a comparative study", Eng. Struct., 154, 93-102. DOI
33	Rahgozar, N., Moghadam, A.S. and Aziminejad, A. (2017), "Response of self-centering braced frame to near-field pulse-like ground motions", Struct. Eng. Mech., 62(4), 497-506. DOI
34	Recommended Provisions for Buckling-Restrained Braced Frames (2001), AISC/SEAOC Recommended Provisions for BRBF.
35	Prasanth, T., Ghosh, S. and Collins, K.R. (2008), "Estimation of hysteretic energy demand using concepts of modal pushover analysis", Earthq. Eng. Struct. D, 37, 975-990. DOI
36	Chintanapakdee, C. and Chopra, A.K. (2004), "Seismic response of vertically irregular frames: Response history and modal pushover analyses", J. Struct. Eng., 130(8), 1177-1185. DOI
37	American Society of Civil Engineers (ASCE), Minimum Design Loads for Buildings and Other Structures, Reston, VA 2010.
38	Bobadilla, H. and Chopra, A.K. (2008), "Evaluation of the MPA procedure for estimating seismic demands: RC-SMRF buildings", Earthq. Spectr., 24(4), 827-845. DOI
39	Chen, C.H. and Mahin, S.A. (2012), Performance-Based Seismic Demand Assessment of Concentrically Braced Steel Frame Buildings, PEER Report, Pacific Earthquake Engineering Research Center, Headquarters at University of California, Berkeley, California, U.S.A.
40	Chopra, A.K. and Geol, R.K. (2002), "A modal pushover analysis procedure for estimating seismic demands for buildings", Earthq. Eng. Struct. D, 31, 561-582. DOI
41	Chou, C.C. and Uang, C.M. (2003), "A procedure for evaluating seismic energy demand of framed structures", Earthq. Eng. Struct. D, 32, 229-244. DOI
42	Sasaki, K.K., Freeman, S.A. and Paret, T.F. (1998), "Multi-mode pushover procedure (MMP)-a method to identify the effects of higher modes in a pushover analysis", Proceedings of the 6th U.S. National Conference on Earthquake Engineering.
43	Seo, C.Y. and Sause, R. (2005), "Ductility demands on self-centering systems under earthquake loading", ACI Struct. J., 102(2), 275.
44	Singh, M.P. and Sharma, A.M. (1985), "Seismic floor spectra by mode acceleration approach", J. Struct. Eng., 111(11), 1402-1419.
45	Chopra, A.K. and Geol, R.K. (2004), "A modal pushover analysis procedure to estimate seismic demands for unsymmeric-plan buildings", Earthq. Eng. Struct. D, 33, 903-927. DOI