Seismic Performance of Self-centering Bridge Columns with
External Energy Dissipators and Restorers

doi:10.3969/j.issn.1674-0696.2023.08.02

Abstract

Abstract: In order to develop rocking self-centering (RSC) bridge columns, which was easy to realize damage control, the buckling restrained brace (BRB) was selected as the exterior energy dissipator and the spring was used as the exterior self-centering device, and BS-RSC piers were designed. Firstly, Opensees finite element software was used to establish a numerical analysis model for BS-RSC bridge piers and the correctness of the proposed model was verified. Then, the effects of BRB yield strength, spring stiffness and axial compression ratio on the hysteresis performance of BS-RSC bridge piers were analyzed, and dynamic time-history analysis was also carried out. Finally, the influence of different parameters on the maximum displacement angle on pier top and residual displacement angle was studied. The research results show that the hysteretic curve of BS-RSC pier is full. BRB can significantly improve the energy dissipation capacity of BS-RSC piers, and control spring stiffness can control the residual displacement without affecting the overall energy dissipation. Under dynamic time-history analysis, it is found that under rare earthquakes, the pier residual displacement angle is at a low value, and the maximum displacement angle on pier top decreases significantly with the increase of BRB yield strength, which indicates that the BS-RSC bridge pier is a new type of bridge pier with coordinated work of various components, clear functions, and excellent energy dissipation capacity and self-centering capacity.

Key words: bridge engineering; rocking self-centering bridge columns; buckling restrained brace; pseudo-static analysis; dynamic time-history analysis; Opensees

摘要： 为发展易于实现损伤控制的摇摆自复位（rocking self-centering, RSC）桥墩，选取防屈曲支撑（buckling restrained brace， BRB）作为外置耗能器，弹簧作为外置复位器，设计外置防屈曲支撑与弹簧的自复位（BS-RSC）桥墩。利用Opensees有限元软件建立BS-RSC桥墩的数值分析模型，并验证模型正确性，分析BRB屈服强度、弹簧刚度及轴压比对BS-RSC桥墩滞回性能的影响；进行动力时程分析，研究不同参数对最大墩顶位移角、残余位移角的影响。研究结果表明：BS-RSC桥墩滞回曲线饱满，BRB可显著提升BS-RSC桥墩的耗能能力，控制弹簧刚度可在不影响整体耗能下控制残余位移；进行动力时程分析，在罕遇地震下，桥墩残余位移角处于低值，最大墩顶位移角随着BRB屈服强度的提高而显著降低，说明BS-RSC桥墩是各构件协调工作、功能明确且具有优秀耗能能力与自复位能力的新型桥墩。

关键词: 桥梁工程；摇摆-自复位桥墩；防屈曲支撑；拟静力分析；动力时程分析；Opensees

CLC Number:

U442.5+5

WANG Dapeng1,2,LIANG Yinfeng1. Seismic Performance of Self-centering Bridge Columns with External Energy Dissipators and Restorers[J]. Journal of Chongqing Jiaotong University(Natural Science), 2023, 42(8): 9-17.

王大鹏1,2，梁银丰1. 外置耗能器与复位器的自复位桥墩抗震性能研究[J]. 重庆交通大学学报（自然科学版）, 2023, 42(8): 9-17.

References

［1］ QIANG H, DU X, LIU J, et al. Seismic damage of highway bridges during the 2008 Wenchuan earthquake ［J］. Earthquake Engineering and Engineering Vibration, 2009,8(2):263-273.
［2］孙治国. 钢筋混凝土桥墩抗震变形能力研究［D］. 哈尔滨: 中国地震局工程力学研究所, 2012.
SUN Zhiguo.Research on Seismic Deformation Capacity of RC Bridge Columns ［D］. Harbin: Institute of Engineering Mechanics, China Earthquake Administration,2012.
［3］杜修力,周雨龙,韩强,等.摇摆桥墩的研究综述［J］.地震工程与工程振动,2018,38(5):1-11.
DU Xiuli, ZHOU Yulong, HAN Qiang, et al. State-of-the-art on rocking piers ［J］. Earthquake Engineering and Engineering Vibration, 2018, 38(5):1-11.
［4］韩强,贾振雷,周雨龙,等.震后可恢复功能桥梁结构之摇摆桥梁研究综述［J］.中国公路学报,2021,34(2):118-133.
HAN Qiang, JIA Zhenlei, ZHOU Yulong,et al. Review of seismic resilient bridge structures: Rocking bridges ［J］. China Journal of Highway and Transport, 2021, 34(2): 118-133.
［5］ HEWES J T. Seismic Design and Performance of Precast Concrete Segmental Bridge Columns ［D］. San Diego: University of California, 2002.
［6］ PALERMO A, PAMPANIN S, MARRIOTT D. Design, modeling, and experimental response of seismic resistant bridge piers with posttensioned dissipating connections ［J］. Journal of Structural Engineering, 2007, 133(11): 1648-1661.
［7］ POLLINO M, BRUNEAU M. Seismic retrofit of bridge steel truss piers using a controlled rocking approach ［J］. Journal of Bridge Engineering, 2004, 12(5): 600-610.
［8］ AHMAD R, SHAHRIA A M, ROBERT T. Analytical prediction and finite-element simulation of the lateral response of rocking steel bridge piers with energy-dissipating steel bars ［J］. Journal of Structural Engineering, 2018, 144(11): 1-13.
［9］魏博, 贾俊峰, 欧进萍,等. 外置耗能器对自复位预制RC桥墩抗震性能的影响研究［J］. 中国公路学报, 2021, 34(2):220-229
WEI Bo, JIA Junfeng, OU Jinping, et al. Study on the effect of exterior dampers on the seismic performance of self-centering precast bridge columns ［J］.China Journal of Highway and Transport, 2021, 34(2): 220-229.
［10］石岩, 钟正午, 秦洪果, 等.装配铅挤压阻尼器的摇摆-自复位双柱墩抗震性能及设计方法［J］.工程力学,2021,38(8):166-177.
SHI Yan, ZHONG Zhengwu, QIN Hongguo, et al. Seismic performance and corresponding design method of rocking self-centering bridge bents equipped with lead-extrusion dampers ［J］. Engineering Mechanics, 2021, 38(8): 166-177.
［11］张哲熹, 梁栋, 方成, 等. 采用SMA拉索的摇摆自复位桥墩试验研究与动力分析［J］.世界地震工程,2020,36(4):138-146.
ZHANG Zhexi, LIANG Dong, FANG Cheng,et al. Experimental study and dynamic analysis of self-centering rocking piers equipped with shape memory alloy (SMA) cables ［J］. World Earthquake Engineering, 2020, 36(4): 138-146.
［12］ CHENG F, DONG L A, YUE Z A, et al. Rocking bridge piers equipped with shape memory alloy (SMA) washer springs ［J］. Engineering Structures, 2020, 214: 1-13.
［13］高向宇, 杜海燕, 张惠, 等. 国标Q235热轧钢材防屈曲支撑抗震性能试验研究［J］. 建筑结构, 2008, 38(3):91-95.
GAO Xiangyu, DU Haiyan, ZHANG Hui, et al.Experimental study on seismic performance of buckling-restrained brace made of Q235 hot-rolled steel in China ［J］. Building Structure, 2008, 38(3): 91-95.
［14］曾聪, 张翼飞, 许国山,等. T型内芯防屈曲支撑的拟静力滞回性能试验研究［J］. 工程力学, 2021, 38(9):124-132.
ZENG Cong, ZHANG Yifei, XU Guoshan, et al.Quasi-staticcyclic tests on the hysteretic behavior of buckling-restrained braces with a T-section core ［J］. Engineering Mechanics, 2021, 38(9): 124-132.
［15］钟正午, 石岩, 秦洪果, 等. 摇摆-自复位桥墩的多弹簧模型建模方法研究［J］.世界地震工程,2021,37(4):197-205.
ZHONG Zhengwu, SHI Yan, QIN Hongguo, et al. Simulation method for multi-spring model of rocking self-centering pier ［J］.World Earthquake Engineering, 2021, 37(4): 197-205.
［16］ MARRIOTT D, PAMPANIN S, PALERMO A. Quasi-static and pseudo-dynamic testing of unbonded post-tensioned rocking ridge piers with external replaceable dissipaters ［J］. Earthquake Engineering & Structural Dynamics, 2009, 38(3): 331-354.
［17］ OU Y C, WANG P H, TSAI M S, et al. Large-scale experimental study of precast segmental unbonded posttensioned concrete bridge columns for seismic regions ［J］. Journal of Structural Engineering, 2010, 136(3): 255-264.
［18］许成祥,罗恒,王粘锦.双层高架桥框架式桥墩地震易损性分析［J］.重庆交通大学学报(自然科学版),2022,41(8):95-101.
XU Chengxiang, LUO Heng, WANG Zhanjin. Seismic fragility analysis of double-deck viaducts frame piers［J］. Journal of Chongqing Jiaotong University (Natural Science), 2022,41(8): 95-101.
［19］刘军,徐新,沈逢俊.基于性能的桥梁震后可恢复性快速评估方法［J］.重庆交通大学学报(自然科学版),2022,41(4):63-69.
LIU Jun, XU Xin, SHEN Fengjun. Performance-based rapid evaluation method for seismic resilience of bridges ［J］. Journal of Chongqing Jiaotong University (Natural Science), 2022, 41(4): 63-69.
［20］司炳君, 谷明洋, 孙治国,等. 近断层地震动下摇摆-自复位桥墩地震反应分析［J］. 工程力学, 2017, 34(10):87-97.
SI Bingjun, GU Mingyang, SUN Zhiguo, et al. Seismic response analysis of the rocking self-centering bridge piers under the near-fault ground motions［J］. Engineering Mechanics, 2017, 34 (10): 87-97.
［21］ YAMASHITA R, SANDERS D H. Seismic performance of precast unbonded prestressed concrete columns ［J］. Aci Structural Journal, 2009, 106(6): 821-830.

[1]	LIU Xiaohui, XU Yang, CHEN Sitian, XU Lueqin. Seismic Response Analysis of Pedestrian Suspension Bridge [J]. Journal of Chongqing Jiaotong University(Natural Science), 2021, 40(01): 65-71.
[2]	WANG Xu1，2，WEI Yanjian1，SUN Dezhang3，LIU Lang1，LIU Huailin2. Seismic Analysis on Typical Long Bridges with Restrainer Piers [J]. Journal of Chongqing Jiaotong University(Natural Science), 2017, 36(10): 1-7.
[3]	Li Ming, Yuan Xiaowei, Chen Qi, Hu Jun. Analysis of Mechanics Response for Tunnel Anchorage to Dynamic Tension Force from Main Cable [J]. Journal of Chongqing Jiaotong University(Natural Science), 2015, 34(2): 24-27.
[4]	GUO Xiang-ming，XIAO Sheng-xie，SUI Yan-chun，HAO Yan-guang. Anti-Seismic Analysis and Anti—Seismic Measures for Yuxi Bridge [J]. Journal of Chongqing Jiaotong University(Natural Science), 2007, 26(5): 29-31.
[5]	ZHANG Xin ，ZHOU Zhi xiang ，SONG Lei. Analysis of Seismic Response of Long-span Arch Bridge [J]. Journal of Chongqing Jiaotong University(Natural Science), 2007, 26(3): 5-9.
[6]	HE Bing，WANG Xiao-yi. A method to simulate elastoplastic beam [J]. Journal of Chongqing Jiaotong University(Natural Science), 2003, 22(4): 29-32.
[7]	XU Lueqin1,2, ZHANG Ling1, GONG Hao1. Near-Fault Seismic Response of Large-Span CFST Tied Arch Bridge Considering Soil-Pile Interaction [J]. Journal of Chongqing Jiaotong University(Natural Science), 2021, 40(10): 63-72.
[8]	XU Lueqin1,2, HE Hongtao1, ZHANG Chao1, XU Yihong1. Seismic Performance Evaluation of a Cable-Stayed Bridge along Transverse Direction Based on Fragility Curves [J]. Journal of Chongqing Jiaotong University(Natural Science), 2023, 42(3): 17-25.

Seismic Performance of Self-centering Bridge Columns with External Energy Dissipators and Restorers

外置耗能器与复位器的自复位桥墩抗震性能研究

PDF

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 8

Recommended Articles

Metrics