|Table of Contents|

RTMD Damping Technology Based on Hollow Floor and Experimental Study(PDF)

《建筑科学与工程学报》[ISSN:1673-2049/CN:61-1442/TU]

Issue:
2020年03期
Page:
37-44
Research Field:
Publishing date:

Info

Title:
RTMD Damping Technology Based on Hollow Floor and Experimental Study
Author(s):
LI Shu-jin DING Zhu-qiu SUN Lei KONG Fan
(School of Civil Engineering and Architecture, Wuhan University of Technology, Wuhan 430070, Hubei, China)
Keywords:
vibration control energy dissipation system hollow-floor structure rolling tuned mass damper shaking table test
PACS:
TU352
DOI:
10.19815/j.jace.2019.07050
Abstract:
Based on the cavity characteristics of reinforced concrete hollow-floor structural system, which was widely used in buildings at present, a rolling tuned mass damper(RTMD)which could be placed in the hollow-floor was proposed. The theoretical and experimental research on this kind of damping device was carried out, the calculation model of the interaction between the device and the structure was established, and the motion differential equation of the controlled structure was derived by using the Lagrange principle. The shaking table test of single-layer frame equipped with the device was carried out. The vibration reduction of the structure equipped with the device was studied by three kinds of dynamic action forms of free vibration, simple harmonic excitation and seismic excitation. Through numerical calculation and experimental study, the dynamic characteristics and damping performance of the system were analyzed. The results show that the proposed device can effectively reduce the dynamic response of the structure, especially the resonance response of the structure, and greatly reduce the resonance effect of the structure. The device does not occupy the use space of the building, does not affect the use function of the structure, so it can effectively solve the conflict between the setting of control device and the function of the building, and has a certain damping effect on the seismic response of the structure, so it has a broad application prospect.

References:

[1] YAO J T P.Concept of Structural Control[J].Journal of the Structural Division,1972,98(7):1567-1574.
[2]欧进萍.结构振动控制——主动、半主动和智能控制[M].北京:科学出版社,2003.
OU Jin-ping.Structural Vibration Control — Active,Semi-active and Intelligent Control[M].Beijing:Science Press,2003.
[3]李春祥.地震作用下高层建筑TMD控制研究与设计[J].上海交通大学学报,1999,33(6):746-749.
LI Chun-xiang.TMD Control Research and Design of Tall Buildings Subjected to Seismic Excitation[J].Journal of Shanghai Jiaotong University,1999,33(6):746-749.
[4]ZHANG P,SONG G,LI H N,et al.Seismic Control of Power Transmission Tower Using Pounding TMD[J].Journal of Engineering Mechanics,2013,139(10):1395-1406.
[5]李保德,李晶晶,傅礼铭.现浇钢筋混凝土密肋空腔楼盖的协同工作性能[J].武汉理工大学学报,2009,31(10):44-47.
LI Bao-de,LI Jing-jing,FU Li-ming.Research on the Bonding Properties of Case-in-place Reinforced Concrete Dense Rib Cavity Ceiling[J].Journal of Wuhan University of Technology,2009,31(10):44-47.
[6]陈颖环,傅礼铭.双向密肋空腔楼盖技术在大型商业建筑中的应用[J].华中建筑,2007,25(10):32-34.
CHEN Ying-huan,FU Li-ming.Application of Waffle Cavity Slab Technology in Large-scale Commercial Architecture[J].Huazhong Architecture,2007,25(10):32-34.
[7]LI S J,FU L M,KONG F.Seismic Response Reduction of Structures Equipped with a Voided Biaxial Slab-based Tuned Rolling Mass Damper[J].Shock and Vibration,2015,2015:760394.
[8]PIRNER M.Actual Behaviour of a Ball Vibration Absorber[J].Journal of Wind Engineering and Industrial Aerodynamics,2002,90(8):987-1005.
[9]ZHANG Z L,CHEN J B,LI J.Theoretical Study and Experimental Verification of Vibration Control of Offshore Wind Turbine by a Ball Vibration Absorber[J].Structure and Infrastructure Engineering:Maintenance,Management,Life-cycle Design and Performance,2013,10(8):1087-1100.
[10]CHEN J,GEORGAKIS C T.Tuned Rolling-ball Dampers for Vibration Control in Wind Turbines[J].Journal of Sound and Vibration,2013,332(21):5271-5282.
[11]李书进,王见祥,孙 磊,等.基于空腔楼盖的新型耗能减震装置参数优化[J].建筑科学与工程学报,2017,34(2):10-17.
LI Shu-jin,WANG Jian-xiang,SUN Lei,et al.Parameter Optimization of New Energy Dissipation Device Based on Hollow Floor Slab[J].Journal of Architecture and Civil Engineering,2017,34(2):10-17.
[12]陈 鑫,李爱群,张志强,等.自立式高耸结构悬吊式TMD减振动力试验与分析[J].振动工程学报,2016,29(2):193-200.
CHEN Xin,LI Ai-qun,ZHANG Zhi-qiang,et al.Dynamic Experiment and Analysis of Self-standing High-rise Structures with Pendulum TMD[J].Journal of Vibration Engineering,2016,29(2):193-200.
[13]秦 丽,李业学,徐福卫.TMD对结构地震响应控制效果的研究[J].世界地震工程,2010,26(1):202-206.
QIN Li,LI Ye-xue,XU Fu-wei.Research on Control Effectiveness of TMD to Structural Seismic Response[J].World Earthquake Engineering,2010,26(1):202-206.
[14]RANA R,SOONG T T.Parametric Study and Simplified Design of Tuned Mass Dampers[J].Engineering Structures,1998,20(3):193-204.
[15]SINGH M P,SINGH S,MORESCHI L M.Tuned Mass Dampers for Response Control of Torsional Buildings[J].Earthquake Engineering & Structural Dynamics,2002,31(4):749-769.
[16]周锡元,阎维明,杨润林.建筑结构的隔震、减振和振动控制[J].建筑结构学报,2002,23(2):2-12,26.
ZHOU Xi-yuan,YAN Wei-ming,YANG Run-lin.Seismic Base Isolation,Energy Dissipation and Vibration Control of Building Structures[J].Journal of Building Structures,2002,23(2):2-12,26.
[17]XIANG P,NISHITANI A.Seismic Vibration Control of Building Structures with Multiple Tuned Mass Damper Floors Integrated[J].Earthquake Engineering & Structural Dynamics,2014,43(6):909-925.
[18]CARMONA J E C,AVILA S M,DOZ G.Proposal of a Tuned Mass Damper with Friction Damping to Control Excessive Floor Vibrations[J].Engineering Structures,2017,148:81-100.
[19]GHARIB M,KARKOUB M.Shock-based Experimental Investigation of the Linear Particle Chain Impact Damper[J].Journal of Vibration and Acoustics,2015,137(6):061012.
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Last Update: 2020-06-08