Modeling and experimental validation of a new electromechanical damping device

被引:0
|
作者
Caruso, G. [1 ]
Ben Mekki, O. [2 ]
Bourquin, F. [3 ]
机构
[1] CNR, Area Ric, ITC, Rome, Italy
[2] LGC, Ecole Natl Ingn Tunis, Tunis, Tunisia
[3] LCPC MI, F-75732 Paris 12, France
来源
JOURNAL OF VIBROENGINEERING | 2009年 / 11卷 / 04期
关键词
Passive vibration control; energy harvesting; electromechanical coupling; tuned mass damper; electrical dissipation;
D O I
暂无
中图分类号
R318 [生物医学工程];
学科分类号
0831 ;
摘要
In this paper an innovative passive vibration damping system is proposed, effective on large flexible structures like tall buildings or long-span bridges. It employs an electromechanical actuator composed of a pendulum hinged to the vibrating structure and connected to an electric alternator. Once the pendulum has been tuned on a specific structural eigenmode, like a classical tuned mass damper, vibrational energy can be dissipated or harvested by connecting a resistive electric load to the alternator pins. Some experimental results are presented showing the effectiveness of the device both in vibration control and in energy harvesting.
引用
收藏
页码:617 / 626
页数:10
相关论文
共 50 条
  • [1] Electromechanical properties of smart aggregate: theoretical modeling and experimental validation
    Wang, Jianjun
    Kong, Qingzhao
    Shi, Zhifei
    Song, Gangbing
    SMART MATERIALS AND STRUCTURES, 2016, 25 (09)
  • [2] Dynamics of an electromechanical damping device with magnetic coupling
    Yamapi, René
    Communications in Nonlinear Science and Numerical Simulation, 2006, 11 (08) : 907 - 921
  • [3] Experimental investigation of electromechanical surface damping
    Orsagh, R
    Ghoneim, H
    SMART STRUCTURES AND MATERIALS 1999: PASSIVE DAMPING AND ISOLATION, 1999, 3672 : 234 - 241
  • [4] Experimental Validation of an Electromechanical Device to Convert Vehicles Mechanical Energy into Electrical Energy
    Duarte, Francisco
    Ferreira, Adelino
    Fael, Paulo
    PROCEEDINGS OF 2019 7TH INTERNATIONAL RENEWABLE AND SUSTAINABLE ENERGY CONFERENCE (IRSEC), 2019, : 434 - 439
  • [5] Experimental validation of a novel smart electromechanical tuned mass damper beam device
    Rafique, S.
    Bonello, P.
    Shuttleworth, R.
    JOURNAL OF SOUND AND VIBRATION, 2013, 332 (20) : 4912 - 4926
  • [6] Experimental validation of electromechanical buckling
    Abu-Salih, Samy
    Elata, David
    JOURNAL OF MICROELECTROMECHANICAL SYSTEMS, 2006, 15 (06) : 1656 - 1662
  • [7] Modeling and experimental validation of lever-based electromechanical actuator for dry clutches
    Liu, Fengyu
    Chen, Li
    Fang, Chengliang
    Yin, Chengliang
    Zhang, Xi
    ADVANCES IN MECHANICAL ENGINEERING, 2017, 9 (08): : 1 - 18
  • [8] Near Vacuum Gas Damping in MEMS: Numerical Modeling and Experimental Validation
    Frangi, Attilio
    Fedeli, Patrick
    Laghi, Giacomo
    Langfelder, Giacomo
    Gattere, Gabriele
    JOURNAL OF MICROELECTROMECHANICAL SYSTEMS, 2016, 25 (05) : 890 - 899
  • [9] Analysis and experimental validation of electromechanical buckling
    Elata, D.
    Abu-Salih, S.
    TRANSDUCERS '07 & EUROSENSORS XXI, DIGEST OF TECHNICAL PAPERS, VOLS 1 AND 2, 2007,
  • [10] ELECTROMECHANICAL MODELING AND EXPERIMENTAL VALIDATION OF A DUAL-TRANSDUCTION ELECTRODYNAMIC WIRELESS POWER RECEIVER
    Halim, Miah A.
    Smith, Spencer E.
    Rendon-Hernandez, Adrian A.
    Arnold, David P.
    2021 21ST INTERNATIONAL CONFERENCE ON SOLID-STATE SENSORS, ACTUATORS AND MICROSYSTEMS (TRANSDUCERS), 2021, : 1335 - 1338
12345