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http://dx.doi.org/10.12989/eas.2018.14.5.467

Seismic response of skewed bridges including pounding effects  

Kun, Chern (Department of Civil and Environmental Engineering, Faculty of Engineering, The University of Auckland)
Yang, Ziqi (Department of Civil and Environmental Engineering, Faculty of Engineering, The University of Auckland)
Chouw, Nawawi (Department of Civil and Environmental Engineering, Faculty of Engineering, The University of Auckland)
Publication Information
Earthquakes and Structures / v.14, no.5, 2018 , pp. 467-476 More about this Journal
Abstract
The seismic vulnerability of skewed bridges had been observed in many past earthquakes. Researchers have found that the in-plane rotation of the girders was one of the main reasons for the vulnerability of these types of bridges. To date, not many experimental works have been done on this topic, especially those including pounding between adjacent structures. In this study, shake table tests were performed on a bridge-abutment system consisting of a straight, $30^{\circ}$, and $45^{\circ}$ bridge with and without considering pounding. Skewed bridges with the same fundamental frequency and those having the same girder mass as the straight bridge were studied. Under the loadings considered, skewed bridges with the same frequency as the straight tend to have smaller responses than those with the same mass. The average maximum bending moment developed in the piers of the $30^{\circ}$ bridge with the same mass as that of the straight when pounding was not considered was 1.6 times larger than when the frequencies were the same. It was also found that the NZTA recommendations for the seat lengths of skewed bridges could severely underestimate the relative displacements of these types of bridges in the transverse direction, especially when pounding occurs. In the worst case, the average transverse displacement of the $45^{\circ}$ bridge was about 2.6 times the longitudinal displacement of the straight, which was greatly over the limit suggested by the NZTA of 1.25 times.
Keywords
skewed bridge; pounding; shake table testing; girder unseating; bridge-abutment system;
Citations & Related Records
Times Cited By KSCI : 3  (Citation Analysis)
연도 인용수 순위
1 Makris, N. (2014), "The role of the rotational inertia on the seismic resistance of free-standing rocking columns and articulated frames", Bull. Seismol. Soc. Am., 104(5), 2226-2239.   DOI
2 Maragakis, E. (1985), "A model for the rigid body motions of skew bridges", Casadena, California: California Institute of Technology, Retrieved from http://www.scopus.com/inward/record.url?eid=2-s2.0-0021938781&partnerID=40&md5=213fecabcd83a8e2c7e5c23349bb4ab2.
3 Meng, J.Y., Lui, E.M. and Liu, Y. (2001), "Dynamic response of skew highway bridges", J. Earthq. Eng., 5(2), 205-223.   DOI
4 Mitchell, D., Bruneau, M., Saatcioglu, M., Williams, M., Anderson, D. and Sexsmith, R. (1995), "Performance of bridges in the 1994 Northridge earthquake", Can. J. Civil Eng., 22(2), 415-427.   DOI
5 New Zealand Transport Agency (2016), Bridge Manual (SP/M/022), Wellington, New Zealand.
6 Qin, X., Chen, Y. and Chouw, N. (2013), "Effect of uplift and soil nonlinearity on plastic hinge development and induced vibrations in structures", Adv. Struct. Eng., 16(1), 135-147.   DOI
7 Yang, C.S., Werner, S.D. and DesRoches, R. (2015), "Seismic fragility analysis of skewed bridges in the Central and Southeastern United States", Eng. Struct., 83, 116-128.   DOI
8 Yashinsky, M. (2011), "Lessons learned from the February 27, 2010 Maule, Chile earthquake", Caltrans Office of Earthquake Engineering, Retrieved from http://www.dot.ca.gov/hq/esc/earthquake_engineering/damage_report/Lessons_Learned.pdf.
9 Zakeri, B., Padgett, J. and Amiri, G. (2015), "Fragility assessment for seismically retrofitted skewed reinforced concrete box girder bridges", J. Perform. Constr. Facil., 29(2), 04014043.   DOI
10 Zakeri, B., Padgett, J. and Amiri, G. (2014), "Fragility analysis of skewed single-frame concrete box-girder bridges", J. Perform. Constr. Facil., 28(3), 571-582.   DOI
11 Jennings, P.C. (1971), "Engineering features of the San Fernando earthquake of February 9, 1971", Casadena, California: National Science Foundation and Earthquake Research Affiliates of the California Institute of Technology.
12 Deepu, S.P., Prajapat, K. and Ray-Chaudhuri, S. (2014), "Seismic vulnerability of skew bridges under bi-directional ground motions", Eng. Struct., 71, 150-160.   DOI
13 Dimitrakopoulos, E.G. (2011). "Seismic response analysis of skew bridges with pounding deck-abutment joints", Eng. Struct., 33(3), 813-826.   DOI
14 Dimitrakopoulos, E.G. (2013), "Nonsmooth analysis of the impact between successive skew bridge-segments", Nonlin. Dyn., 74(4), 911-928.   DOI
15 Huang, H., Shenton, H. and Chajes, M. (2004), "Load distribution for a highly skewed bridge: Testing and analysis", J. Bridge Eng., 9(6), 558-562.   DOI
16 Huo, Y. and Zhang, J. (2013), "Effects of pounding and skewness on seismic responses of typical multispan highway bridges using the fragility function method", J. Bridge Eng., 18(6), 499-515.   DOI
17 Kaviani, P., Zareian, F. and Taciroglu, E. (2012), "Seismic behaviour of reinforced concrete bridges with skew-angled seat type abutment", Eng. Struct., 45, 137-150.   DOI
18 Kawashima, K., Unjoh, S., Hoshikuma, J.I. and Kosa, K. (2011), "Damage of bridges due to the 2010 Maule, Chile, earthquake", J. Earthq. Eng., 15(7), 1036-1068.   DOI
19 Khatiwada, S. and Chouw, N. (2013), "A shake table investigation on interaction between buildings in a row", Coupl. Syst. Mech., 2(2), 175-190.   DOI
20 Khatiwada, S., Larkin, T. and Chouw, N. (2014), "Influence of mass and contact surface on pounding response of RC structures", Earthq. Struct., 7(3), 385-400.   DOI
21 Chen, Y., Larkin, T. and Chouw, N. (2017), "Experimental assessment of contact forces on a rigid base following footing uplift", Earthq. Eng. Struct. Dyn., 46, 1835-1854.   DOI
22 Anagnostopoulos, S.A. and Karamaneas, C.E. (2008), "Use of collision shear walls to minimize seismic separation and to protect adjacent buildings from collapse due to earthquakeinduced pounding", Earthq. Eng. Struct. Dyn., 37(12), 1371-1388.   DOI
23 Buckingham, E. (1914), "On physically similar systems: Illustrations of the use of dimensional equations", Phys. Rev., 4(4), 345-376.   DOI
24 Catacoli, S., Ventura, C.E., Finn, W.D.L. and Taiebat, M. (2014), "In-plane rotational demands of skewed bridges due to earthquake induced pounding", The Tenth U.S. National Conference on Earthquake Engineering, Anchorage, Alaska, US.
25 Chouw, N., Hao, H. and Su, H. (2006), "Multi-sided pounding response of bridge structures with non-linear bearings to spatially varying ground excitation", Adv. Struct. Eng., 9(1), 55-66.   DOI
26 Chouw, N. (1996), "Effect of the earthquake on 17th of January 1995 on Kobe", Proceedings of the D-A-CH meeting of the German, Austrian and Swiss Society for Earthquake Engineering and Structural Dynamics, University of Graz, Austria, 135-169.
27 Chouw, N. and Hao, H. (2005), "Study of SSI and non-uniform ground motion effect on pounding between bridge girders", Soil Dyn. Earthq. Eng., 25, 717-728.   DOI
28 Chouw, N. and Hao, H. (2008), "Significance of SSI and nonuniform near-fault ground motions in bridge response II: Effect on response with modular expansion joint", Eng. Struct., 30(1), 154-162.   DOI
29 Soleimani, F., Vidakovic, B., DesRoches, R. and Padgett, J. (2017), "Identification of the significant uncertain parameters in the seismic response of irregular bridges", Eng. Struct., 141, 356-372.   DOI
30 Soleimani, F. (2017), "Fragility of California bridges-Development of modification factors", Doctoral Dissertation, Georgia Institute of Technology, Georgia, USA.
31 Standards New Zealand Technical Committee (2004), Structural design actions Part 5: Earthquake actions - New Zealand, NZS 1170.5: 2004, Wellington, New Zealand.
32 Sullivan, I.T. (2010), "Analytical seismic fragility curves for skewed multi-span steel girder bridges", Doctoral Dissertation, Clemson University, South Carolina, USA.
33 Wakefield, R.R., Nazmy, A.S. and Billington, D.P. (1991), "Analysis of seismic failure in skew RC bridge", J. Struct. Eng., 117(3), 972-986.   DOI
34 Watanabe, G. and Kawashima, K. (2004), "Effectiveness of cablerestrainer for mitigating rotation of a skewed bridge subjected to strong ground shaking", The 13th World Conference on Earthquake Engineering, Vancouver, Canada.
35 Weiser, J. and Maragakis, M. (2013), "Seismic performance of highway bridges with seat-type abutments subjected to nearfault ground motions", Proceedings of the 2013 Structures Congress, 827-838.
36 Won, J., Mha, H., Cho, K. and Kim, S. (2008), "Effects of the restrainer upon bridge motions under seismic excitations", Eng. Struct., 30(12), 3532-3544.   DOI
37 Shao, G., Jiang, L. and Chouw, N. (2014), "Experimental investigations of the seismic performance of bridge piers with rounded rectangular cross-sections", Earthq. Struct., 7(4), 463-484.   DOI
38 Li, B., Bi, K., Chouw, N., Butterworth, J.W. and Hao, H. (2012), "Experimental investigation of spatially varying effect of ground motions on bridge pounding", Earthq. Eng. Struct. Dyn., 41(14), 1959-1976.   DOI
39 Kun, C., Jiang, L. and Chouw, N. (2017), "Influence of pounding and skew angle on seismic response of bridges", Eng. Struct., 148, 890-906.   DOI
40 Kwon, O.S. and Jeong, S.H. (2013), "Seismic displacement demands on skewed bridge decks supported on elastomeric bearings", J. Earthq. Eng., 17(7), 998-1022.   DOI
41 Li, B., Bi, K., Chouw, N., Butterworth, J.W. and Hao, H. (2013), "Effect of abutment excitation on bridge pounding", Eng. Struct., 54, 57-68.   DOI
42 Wood, J. and Jennings, P. (1971), "Damage to freeway structures in the San Fernando earthquake", Bull. NZ Soc. Earthq. Eng., 4(3), 347-76.