Browse > Article
http://dx.doi.org/10.12989/scs.2016.21.1.109

Influence of creep on dynamic behavior of concrete filled steel tube arch bridges  

Ma, Yishuo (School of Civil Engineering, Beijing Jiaotong University)
Wang, Yuanfeng (School of Civil Engineering, Beijing Jiaotong University)
Su, Li (School of Civil Engineering, Beijing Jiaotong University)
Mei, Shengqi (School of Civil Engineering, Beijing Jiaotong University)
Publication Information
Steel and Composite Structures / v.21, no.1, 2016 , pp. 109-122 More about this Journal
Abstract
Concrete creep, while significantly changing the static behaviors of concrete filled steel tube (CFST) structures, do alter the structures' dynamic behaviors as well, which is studied quite limitedly. The attempt to investigate the influence of concrete creep on the dynamic property and response of CFST arch bridges was made in this paper. The mechanism through which creep exerts its influence was analyzed first; then a predicative formula was proposed for the concrete elastic modulus after creep based on available test data; finally a numerical analysis for the effect of creep on the dynamic behaviors of a long-span half-through CFST arch bridge was conducted. It is demonstrated that the presence of concrete creep increases the elastic modulus of concrete, and further magnifies the seismic responses of the displacement and internal force in some sections of the bridge. This influence is related closely to the excitation and the structure, and should be analyzed case-by-case.
Keywords
creep; seismic analysis; time-dependent analysis; concrete; steel; arch bridges;
Citations & Related Records
Times Cited By KSCI : 1  (Citation Analysis)
연도 인용수 순위
1 Huang, R.Y., Mao, I.S. and Lee, H.K. (2010), "Exploring the Deterioration Factors of Bridges: A Rough Set Theory Approach", Computer-Aided Civil Infra. Eng., 25(7), 517-529.   DOI
2 Ma, Y.S. (2013), "Creep influence on static and dynamic reliability of long-span concrete filled steel tube arch bridges", Ph.D. Dissertation; Beijing Jiaotong University, Beijing, China.
3 Ma, Y.S. and Wang, Y.F. (2013), "Creep effects on the reliability of concrete-filled steel tube arch bridge", J. Bridge Eng., 18(10), 1-10.   DOI
4 Ma, Y.S., Wang, Y.F. and Mao, Z.K. (2011), "Creep effects on dynamic behavior of concrete filled steel tube arch bridge", Struct. Eng. Mech., Int. J., 37(3), 321-330.   DOI
5 Malvern, L. (1969), Introduction to the Mechanics of a Continuous Medium, Prentice Hall, New York.
6 Naguib, W. and Mirmiran, A. (2003), "Creep modeling for concrete-filled steel tubes", J. Construct. Steel Res., 59(11), 1327-1344.   DOI
7 Nour-Omid, B. and Rankin, C.C. (1991), "Finite rotation analysis and consistent linearization using projectors", Comput. Method. Appl. Mech. Eng., 93(3), 353-384.   DOI
8 O'Byrne, M., Schoefs, F., Ghosh, B. and Pakrashi, V. (2013), "Texture Analysis Based Damage Detection of Ageing Infrastructural Elements", Computer-Aided Civil Infra. Eng., 28(3), 162-177.   DOI
9 Qin, J. and Faber, M.H. (2012), "Risk management of large RC structures within a spatial information system", Computer-Aided Civil Infra. Eng., 27(6), 385-405.   DOI
10 Rankin, C.C. and Brogan, F.A. (1986), "An element independent corotational procedure for the treatment of large rotations", J. Press. Vessel Technol., 108(2), 165-174.   DOI
11 Sapountzakis, E.J. and Katsikadelis, J.T. (2003), "Creep and shrinkage effect on the dynamic analysis of reinforced concrete slab-and-beam structures", J. Sound Vib., 260(3), 403-416.   DOI
12 Shao, X.D., Peng, J.X., Li, L.F., Yan, B.F. and Hu, J.H. (2010), "Time-dependent behavior of concrete-filled steel tubular arch bridge", J. Bridge Eng., 15(1), 98-107.   DOI
13 Terrey, P.J., Bradford, M.A. and Gilbert, R.I. (1994), "Creep and shrinkage of concrete in concrete-filled circular steel tubes", Proceeding of 6th International Symposium on Tubular Structures, Melbourne, Australia, December.
14 Wang, Y.F. and Zhang, D.J. (2009), "Creep-effect on mechanical behavior of concrete confined by FRP under axial compression", J. Eng. Mech., 135(11), 1315-1322.   DOI
15 Wang, Y.F., Han, B. and Zhang, D.J. (2008), "Advances in creep of concrete filled steel tube members and structures", Proceeding of 8th Concreep Conference, Ise-Shima, Japan, October, pp. 595-600.
16 Wang, Y.F., Ma, Y.S., Han, B. and Deng, S.Y. (2013), "Temperature effect on creep behavior of CFST arch bridges", J. Bridge Eng., 18(12), 1397-1405.   DOI
17 Washa, G.W. and Fluck, P.G. (1950), "Effect of sustained loading on compressive strength and modulus of elasticity of concrete", J. Am. Concrete Inst., 21(9), 693-700.
18 Wu, Q.X., Yoshimura, M., Takahashi, K., Nakamura, S. and Nakamura, T. (2006), "Nonlinear seismic properties of the Second Saikai Bridge: A concrete filled tubular (CFT) arch bridge", Eng. Struct., 28(2), 163-182.   DOI
19 Xin, B. and Xu, S.Q. (2003), "Creep analysis of long-span concrete filled steel tube arch bridges", Railway Standard Design, 4, 31-33.
20 Zhang, D.J., Wang, Y.F. and Ma, Y.S. (2010), "Compressive behaviour of FRP-confined square concrete columns after creep", Eng. Struct., 32(8), 1957-1963.   DOI
21 Aldemir, U., Yanik, A. and Bakioglu, M. (2012), "Control of structural response under earthquake excitation", Comput.-Aided Civil Infra. Eng., 27(8), 620-638.   DOI
22 Alizadeh, R., Beaudoin, J.J. and Raki, L. (2010), "Viscoelastic nature of calcium silicate hydrate", Cement Concrete Compos., 32(5), 369-376.   DOI
23 Bazant, Z.P. (1972), "Prediction of concrete creep effects using age-adjusted effective modulus method", J. Am. Concrete Inst., 69(20), 212-217.
24 Bazant, Z.P. (1988), Mathematical Modeling of Creep and Shrinkage of Concrete, John Wiley & Sons, Chichester and New York, NY, USA.
25 Cook, D.J. and Chindaprasirt, P. (1980), "Influence of loading history upon the compressive properties of concrete", Mag. Concrete Res., 32(111), 89-100.   DOI
26 Bazant, Z.P. and Baweja, S. (2000), "Creep and shrinkage prediction model for analysis and design of concrete structures: Model B3", ACI Special Publications, 194, 1-84.
27 Bazant, Z.P. and Prasannan, S. (1989a), "Solidification theory for concrete creep. I: Formulation", J. Eng. Mech., 115(8), 1691-1703.   DOI
28 Bazant, Z.P. and Prasannan, S. (1989b), "Solidification theory for concrete creep. II: Verification and application", J. Eng. Mech., 115(8), 1704-1725.   DOI
29 Davis, R.E. and Davis, H.E. (1931), "Flow of concrete under the action of sustained load", J. Am. Concrete Inst., 2(7), 837-901.
30 Federation Internationale du Beton (FIB) (2010), CEB-FIP Model Code 2010.
31 Felippa, C.A. and Haugen, B. (2005), "A unified formulation of small-strain corotational finite elements: I. Theory", Comput. Method. Appl. Mech. Eng., 194(21-24), 2285-2335.   DOI
32 Ghodrati Amiri, G., Abdolahi Rad, A. and Khorasani, M. (2012), "Generation of Near-Field Artificial Ground Motions Compatible with Median Predicted Spectra Using PSO-based Neural Network and Wavelet Analysis", Comput.-Aided Civil and Infrastructure Engineering, 27(9), 711-730.   DOI
33 Graf, W., Freitag, S., Kaliske, M. and Sickert, J.U. (2010), "Recurrent neural networks for uncertain timedependent structural behavior", Computer-Aided Civil Infra. Eng., 25(5), 322-333.   DOI
34 Hu, S.D., Wang, J.J., Wei, H.Y. and Ye, A.J. (2001), "Seismic behavior analysis of Yajisha Bridge", Railway Standard Design, 21(6), 21-25.