隔震桥梁子结构拟动力实验中加载速率的影响因素研究被引量：1

The Study on Effect of Loading Ratio to the Results of Substructure Hybrid Experiment System

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摘要本研究运用DSP高速数字信号处理器的实时信号处理与控制技术,研究了基于速度控制法、OS数值积分法和相应的实验误差控制法的子结构拟动力实验系统。该试验系统对动力加载装置采用速度控制,在加载过程中考虑了加载速率对实验结果的影响,使隔震橡胶支座的速度相关性能在试验中得到充分体现,同时采用OS数值积分法,充分地减少了试验的时滞误差,提高了试验精度。并通过不同加载速率的子结构拟动力实验研究了天然橡胶支座、高阻尼橡胶隔震支座和超高阻尼橡胶隔震支座对桥梁的隔震效果,在对实验结果进行分析对比后,定量地研究了不同的加载速率对隔震桥梁子结构拟动力实验结果的影响。 The development real-time substructure hybrid loading test system based on the velocity-based loading concept is studied. A series of real-time hybrid loading tests on velocity-dependent rubber beatings are conducted by using the test system. The developed components of the loading test system include： a real-time test control algorithm using the velocity-based loading concept, a PC-DSP control system framework for the actuator signal processing, and the Operator Splitting （OS） being used as the numerical time integration scheme. The operator splitting analysis method avoids the complex programming and time lag. So, the development real-time substructure hybrid loading test system successfully pursues accurate prediction of the dynamic response and isolation effects of rubber bearings under realistic earthquake conditions. A series of real-time hybrid loading tests on velocitydependent rubber bearings are conducted by using the test system in order to study the influence of loading velocity.

作者袁涌熊世树资道铭庞军

机构地区华中科技大学土木工程与力学学院中国地质大学柳州欧维姆机械股份有限公司

出处《震灾防御技术》 2008年第1期37-44,共8页 Technology for Earthquake Disaster Prevention

基金国家自然科学基金(50708041) 教育部留学回国人员科研启动基金资助

关键词子结构拟动力实验速度控制法 DSP高速数字信号处理器橡胶隔震支座 The real-time substructure hybrid test Velocity control Digital signal processor Rubber isolator

分类号 U442.55 [建筑科学—桥梁与隧道工程]

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1[2]Hirokazu I.and Akira I.,2005.Real-time Substructure Hybrid Earthquake Loading System for Super-highdamping Rubber Bearing.See:The First International Conference on Advances in Experimental Structural Engineering,AESE,Nagoya,Japan,401-408.
2[3]Nakashima M.,Kato H.and Takaoka E.,1992.Development of real-time pseudo dynamic testing.Earthquake Engineering and Structural Dynamic,21:79-92.
3[4]Nakashima M.and Kato H.,1987.Experimental Error Growth Behavior and Error Growth Control in On-line Computer Test Control Method.Building Research Institute,Ministry of Construction,Research Paper 123.
4[5]Yuan Y.,Aoki T.and Yamamoto Y.,2005.Experiment Study of the Dynamic Behavior of High-damping-rubber Bearing Isolator.See:The First International Conference on Advances in Experimental Structural Engineering,AESE,Nagoya,Japan,505-511.

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2王进廷,金峰,张楚汉.结构抗震试验方法的发展[J].地震工程与工程振动,2005,25(4):37-43. 被引量：34
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4Wu B, Bao H, Ou J, Tian S. Stability and accuracy analysis of central difference method for real-time substructure testing [J]. Earthquake Engineering and Structural Dynamics, 2005, 34: 705-718.
5Wu B, Xu G- Wang Q, Williams M. Operator-splitting method for real-time substructure testing [J]. Earthquake Engineering and Structural Dynamics, 2006, 35: 293- 314.
6Tada M, Pan R A modified operator splitting (OS) method for collaborative structural analysis (CSA) [J]. International Journal for Numerical Methods in Engineering, 2007, 72: 379-396.
7Bayer V, Dorka U, Fiillekrug U, Gschwilm J. On real-time pseudodynamic substructure testing: algorithm, numerical and experimental results [J]. Aerospace Science and Technology, 2005, 9:223 -232.
8Shing P B, Wei Z, Jung R Y, Stauffer E. NEES fast hybrid test system at the university of Colorado [C]. Proceedings of the 13th World Conference on Earthquake Engineering. Vancouver, B. C.: Venue West Conference Services Ltd., 2004:1 -6.
9Wu B, Wang Q, Benson S P, Ou J P. Equivalent force control method for generalized real-time substructure testing with implicit integration [J]. Earthquake Engineering and Structural Dynamics, 2007, 36: 1127- 1149.
10Xie Y M, Steven G P. Instability, chaos, and growth and decay of energy of time-stepping schemes for non-linear dynamic equations [J]. Communications in Numerical Methods in Engineering, 1994, 10: 393-401.

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隔震桥梁子结构拟动力实验中加载速率的影响因素研究被引量：1

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隔震桥梁子结构拟动力实验中加载速率的影响因素研究被引量：1