Parametric analysis on seismic behavior of integral abutment steel bridge considering SSI
Article Text (Baidu Translation)
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摘要: 利用SAP2000建立了某整体式钢桥的三维有限元模型, 采用非线性弹簧单元和阻尼单元模拟地震作用下桥台-土和桩-土之间的相互作用, 分析了桥梁的模态、非线性时程与相应的参数, 研究了考虑土-结构非线性相互作用的整体式钢桥动力特性和抗震性能, 以及整体式桥台系统的主要设计参数对此类桥梁动力特性和抗震性能的影响。研究结果表明: 压实台后填土、增加桥台高厚比、增加桩周土刚度将使桥梁结构纵向主频增加约6.5%~16.0%, 而H型钢桩的朝向影响仅为1.6%左右; 结构地震响应随着桥台高厚比增加而明显降低, 桥台高厚比为1.44时, 桩顶截面处于塑性阶段, 而高厚比增大到3.15和3.85后, 桩保持弹性状态; 随着台后土密实度的减小, 结构的地震响应明显增大, 增幅大都在40%以上; 桩的朝向由绕强轴弯曲调整为绕弱轴弯曲时, 桩的最大弯矩减小, 但弯曲应力增大, 材料由弹性进入塑性阶段; 随着桩周土刚度增大, 桥梁位移响应明显减小, 桩顶、台顶最大位移及墩底弯矩减小50%左右, 但是桩顶弯矩增大40%以上, 桩的朝向对此几乎无影响; 在满足设计要求及合理范围内, 建议采用高厚比较大与柔性较高的桥台, 并压实台后填土以减小整体桥结构的地震响应, 桥台基础采用H型钢桩时, 建议将其朝向调整为绕强轴弯曲以减小桩、桥台和墩柱的最大弯曲应力与位移。Abstract: A 3D finite element model of integral abutment steel bridge was established by the SAP2000 software, the nonlinear spring elements and damping elements were used to simulate the soil reactions behind the abutment and around the piles under the earthquake action, and the mode, nonlinear time history and relevant parameters of the bridge were analyzed, In addition, the dynamic and seismic behaviors of integral abutment steel bridge considering the nonlinear soilstructure interaction, as well as the influence of the main design parameters of integrated abutment system on the behaviors were studied.Research result indicates that compacting the abutment backfill, increasing the abutment height-to-thickness ratio, and increasing the foundation stiffness will increase the dominant longitudinal frequency of the bridge structure byabout 6.5%-16.0%, while H pile orientation has a minimal influence of about 1.6%.The structural seismic response significantly reduces as the abutment height-thickness ratio increases.When the abutment height-to-thickness ratio is 1.44, the top of the pile enters the plastic stage.When the height-to-thickness ratio increases to 3.15 and 3.85, the pile remains elastic.When the compactness of the abutment backfill decreases, the seismic response of the structure increases significantly, and the increment is mostly above 40%.When the orientation of the pile is adjusted from bending about the strong axis to bending about the weak axis, the maximum bending moment of the pile decreases, but the bending stress increases, and the material enters the plastic stage from the elastic stage.As the soil stiffness around the pile increases, the displacement response of the bridge decreases significantly.The maximum displacements at the top of the pile and abutment, as well as the bending moment at the pier bottom decrease by about 50%.However, the bending moment at the pile top increases by more than 40%, and the orientation of the pile has almost no effect on the displacement responses.As long as the design requirements are satisfied and in a reasonable range, the larger height-to-thickness ratio, more flexible abutment, and compacted abutment backfilling are recommended to reduce the seismic response of integral abutment bridge.When the steel H pile is used as the abutment foundation, orienting the H pile to bend about its strong axis is recommended to reduce the maximum bending stresses and displacements of the pile, abutment and pier.
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图 4 循环荷载作用下桩周土弹簧力-位移曲线
Figure 4. Force-deflection curves of pile springs under cyclic load
图 6 峰值加速度为0.3g的El Centro地震波记录
Figure 6. El Centro seismic wave record with peak acceleration of 0.3g
图 7 模型M-1~M-6的桩身位移和弯矩分布
Figure 7. Distributions of displacement and moment along piles of models M-1-M-6
图 8 模型M-1、M-7~M-9的桩身位移和弯矩分布
Figure 8. Distributions of displacement and moment along piles of models M-1and M-7-M-9
表 3 不同桥台厚度下桥梁的地震响应
Table 3. Seismic responses of bridges with different abutment thicknesses
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表 5 不同桥台高厚比下桥梁的地震响应
Table 5. Seismic responses of bridges with different abutment height-thickness ratios
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表 6 采用密实和松散台后土时桥梁的地震响应
Table 6. Seismic responses of bridges with densely and loosely compacted backfill
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表 7 桥台桩绕强轴弯曲和绕弱轴弯曲时桥梁的地震响应
Table 7. Seismic responses of bridges with abutment piles bending around strong and weak axis
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表 8 不同桩周土质下桥梁的地震响应
Table 8. Seismic responses of bridges with different clay types around piles
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[1] 张喜刚, 刘高, 马军海, 等. 中国桥梁技术的现状与展望[J]. 科学通报, 2016, 61 (4/5): 415-425. https://www.cnki.com.cn/Article/CJFDTOTAL-KXTB2016Z1005.htmZHANG Xi-gang, LIU Gao, MA Jun-hai, et al. Status and prospect of technical development for bridges in China[J]. Chinese Science Bulletin, 2016, 61 (4/5): 415-425. (in Chinese). https://www.cnki.com.cn/Article/CJFDTOTAL-KXTB2016Z1005.htm [2] 邹友泉, 顾水友, 李莉, 等. 赣粤高速公路桥梁伸缩缝破坏模式及原因浅析[J]. 公路, 2015 (2): 90-93. https://www.cnki.com.cn/Article/CJFDTOTAL-GLGL201502020.htmZOU You-quan, GU Shui-you, LI Li, et al. Analyse of the failure mode and reason of Ganyue expressway bridge expansion joints[J]. Highway, 2015 (2): 90-93. (in Chinese). https://www.cnki.com.cn/Article/CJFDTOTAL-GLGL201502020.htm [3] 陈曦. 山区公路桥梁伸缩装置行车安全评估技术研究[D]. 重庆: 重庆交通大学, 2011.CHEN Xi. Research on assessment of traffic safety in expantion joints of mountain road bridge[D]. Chongqing: Chongqing Jiaotong University, 2011. (in Chinese). [4] 上海市路政局. 上海市城市桥梁技术状况分析报告[R]. 上海: 上海市路政局, 2014.Shanghai Road Administration Bureau. Technique condition analysis report of bridges in Shanghai[R]. Shanghai: Shanghai Road Administration Bureau, 2014. (in Chinese). [5] 孙小龙. 整体式桥台桥梁受力性能研究[D]. 哈尔滨: 东北林业大学, 2014.SUN Xiao-long. Research of mechanical property for integral abutment bridge[D]. Harbin: Northeast Forestry University, 2014. (in Chinese). [6] 彭大文, 洪锦祥, 郭爱民, 等. 无伸缩缝桥梁的动力特性计算与试验研究[J]. 地震工程与工程振动, 2005, 25 (2): 72-76. https://www.cnki.com.cn/Article/CJFDTOTAL-DGGC20050200C.htmPENG Da-wen, HONG Jin-xiang, GUO Ai-min, et al. Dynamic analysis and field-test of jointless bridge[J]. Earthquake Engineering and Engineering Vibration, 2005, 25 (2): 72-76. (in Chinese). https://www.cnki.com.cn/Article/CJFDTOTAL-DGGC20050200C.htm [7] ERHAN S, DICLELI M. Effect of dynamic soil-bridge interaction modeling assumptions on the calculated seismic response of integral bridges[J]. Soil Dynamics and Earthquake Engineering, 2014, 66: 42-55. doi: 10.1016/j.soildyn.2014.06.033 [8] DICLELI M, ERHAN S. Low cycle fatigue effects in integral bridge steel H-piles under seismic displacement reversals[J]. Bridge Structures, 2013, 9 (4): 185-190. doi: 10.3233/BRS-130064 [9] CIVJAN S A, BONCZAR C, BREÑA S F, et al. Integral abutment bridge behavior: parametric analysis of a Massachusetts bridge[J]. Journal of Bridge Engineering, 2007, 12 (1): 64-71. doi: 10.1061/(ASCE)1084-0702(2007)12:1(64) [10] 彭大文, 汪新惠, 洪锦祥. 无伸缩缝桥梁的动力特性研究[J]. 地震工程与工程振动, 2003, 23 (4): 95-99. https://www.cnki.com.cn/Article/CJFDTOTAL-DGGC200304016.htmPENG Da-wen, WANG Xin-hui, HONG Jin-xiang. Research on dynamic characteristics of jointless bridges[J]. Earthquake Engineering and Engineering Vibration, 2003, 23 (4): 95-99. (in Chinese). https://www.cnki.com.cn/Article/CJFDTOTAL-DGGC200304016.htm [11] SPYRAKOS C, LOANNIDIS G. Seismic behavior of a posttensioned integral bridge including soil-structure interaction (SSI)[J]. Soil Dynamics and Earthquake Engineering, 2003, 23 (1): 53-63. doi: 10.1016/S0267-7261(02)00150-1 [12] ERHAN S, DICLELI M. Comparative assessment of the seismic performance of integral and conventional bridges with respect to the differences at the abutments[J]. Bulletin of Earthquake Engineering, 2015, 13 (2): 653-677. doi: 10.1007/s10518-014-9635-8 [13] GOEL R K. Earthquake characteristics of bridges with integral abutments[J]. Journal of Structural Engineering, 1997, 123 (11): 1435-1443. doi: 10.1061/(ASCE)0733-9445(1997)123:11(1435) [14] 彭大文, 洪锦祥, 郭爱民, 等. 整体式桥台桥梁的动力试验研究[J]. 中国公路学报, 2004, 17 (4): 59-63. https://www.cnki.com.cn/Article/CJFDTOTAL-ZGGL200404013.htmPENG Da-wen, HONG Jin-xiang, GUO Ai-min, et al. Dynamic field-test of integral abutment bridge[J]. China Journal of Highway and Transport, 2004, 17 (4): 59-63. (in Chinese). https://www.cnki.com.cn/Article/CJFDTOTAL-ZGGL200404013.htm [15] 黄福云, 庄一舟, 付毳, 等. 无伸缩缝梁桥抗震性能与设计计算方法研究[J]. 地震工程与工程振动, 2015, 35 (5): 15-22. https://www.cnki.com.cn/Article/CJFDTOTAL-DGGC201505003.htmHUANG Fu-yun, ZHUANG Yi-zhou, FU Cui, et al. Review on the seismic performance and simplified design method of jointless bridge[J]. Earthquake Engineering and Engineering Dynamics, 2015, 35 (5): 15-22. (in Chinese). https://www.cnki.com.cn/Article/CJFDTOTAL-DGGC201505003.htm [16] 石丽峰, 徐明. 整体式桥台地震反应机理分析[J]. 岩土力学, 2014, 35 (11): 3289-3297. https://www.cnki.com.cn/Article/CJFDTOTAL-YTLX201411038.htmSHI Li-feng, XU Ming. Analysis of seismic response of integral bridge abutments[J]. Rock and Soil Mechanics, 2014, 35 (11): 3289-3297. (in Chinese). https://www.cnki.com.cn/Article/CJFDTOTAL-YTLX201411038.htm [17] FENNEMA J L, LAMAN J A, LINZELL D G. Predicted and measured response of an integral abutment bridge[J]. Journal of Bridge Engineering, 2005, 10 (6): 666-677. [18] LAFAVE J M, FAHNESTOCK L A, KOZAK D L. Seismic performance of integral abutment highway bridges in Illinois[R]. Urbana: University of Illinois at Urbana-Champaign, 2018. [19] ZORDAN T, BRISEGHELLA B B, LAN Cheng. Parametric and pushover analyses on integral abutment bridge[J]. Engineering Structures, 2011, 33 (2): 502-515. [20] VASHEGHANI-FARAHANI R, ZHAO Qiu-hong, BURDETTE E G. Seismic analysis of integral abutment bridge in Tennessee, including soil-structure interaction[J]. Transportation Research Record, 2010 (2201): 70-79. [21] ARSOY S, DUNCAN J M, BARKER R M. Performance of piles supporting integral bridges[J]. Transportation Research Record, 2002 (1808): 162-167. [22] AHN J H, YOON J H, KIM J H, et al. Evaluation on the behavior of abutment-pile connection in integral abutment bridge[J]. Journal of Constructional Steel Research, 2011, 67 (7): 1134-1148. [23] SHERAFATI A, AZIZINAMINI A. Flexible pile head in jointless bridges: experimental investigation[J]. Journal of Bridge Engineering, 2014, 20 (4): 04014071-1-12. [24] 齐朝阳. 整体式桥台-桩节点抗震性能试验研究[D]. 天津: 天津大学, 2017.QI Zhao-yang. Experimental research on seismic behavior of integral abutment-pile joint[D]. Tianjin: Tianjin University, 2017. (in Chinese). [25] SHAMSABADI A, ROLLINS K M, KAPUSKAR M. Nonlinear soil-abutment-bridge structure interaction for seismic performance-based design [J]. Journal of Geotechnical and Geoenvironmental Engineering, 2007, 133 (6): 707-720. [26] 洪锦祥, 彭大文, 汪新惠. 整体式桥台桥梁的台后被动土压力研究[J]. 福州大学学报: 自然科学版, 2003, 31 (6): 721-725. https://www.cnki.com.cn/Article/CJFDTOTAL-FZDZ200306020.htmHONG Jin-xiang, PENG Da-wen, WANG Xin-hui. Passive earth pressure behind abutment of integral abutment bridges[J]. Journal of Fuzhou University: National Science, 2003, 31 (6): 721-725. (in Chinese). https://www.cnki.com.cn/Article/CJFDTOTAL-FZDZ200306020.htm [27] CHAKRABARTI M A, MWSTRI P T. Seismic analysis of cantilever RCC retaining walls[C]∥Earthquake Engineering Research Institute. 9th US National and 10th Canadian Conference on Earthquake Engineering 2010, Including Papers from the 4th International Tsunami Symposium. Oakland: Earthquake Engineering Research Institute, 2010: 3008-3016. [28] ANANDARAJAH A, ZHANG J, EALY C. Calibration of dynamic analysis methods from field test data[J]. Soil Dynamics and Earthquake Engineering, 2005, 25 (7-10): 763-772. [29] 彭大文, 陈朝慰, 洪锦祥. 整体式桥台桥梁的桥台结点受力性能研究[J]. 中国公路学报, 2005, 18 (1): 46-50. https://www.cnki.com.cn/Article/CJFDTOTAL-ZGGL200501011.htmPENG Da-wen, CHEN Chao-wei, HONG Jin-xiang. Study of loaded property of abutment node of integral abutment bridges[J]. China Journal of Highway and Transport, 2005, 18 (1): 46-50. (in Chinese). https://www.cnki.com.cn/Article/CJFDTOTAL-ZGGL200501011.htm [30] DICLELI M, ALBHAISI S M. Performance of abutmentbackfill system under thermal variations in integral bridges built on clay[J]. Engineering Structures, 2004, 26 (7): 949-962. [31] FARAJI S, TING J M, CROVO D S, et al. Nonlinear analysis of integral bridges: finite-element model[J]. Journal of Geotechnical and Geoenvironmental Engineering, 2001, 127 (5): 454-461. -
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