VIBRATION CONTROL OF A ROTATING CANTILEVER BEAM BY USING THE GIANT MAGNETOSTRICTIVE ACTUATOR

被引:0
作者
Xu, Xueping [1 ]
Han, Qinkai [1 ]
Chu, Fulei [1 ]
机构
[1] Tsinghua Univ, Dept Mech Engn, Beijing 100084, Peoples R China
来源
PROCEEDINGS OF THE ASME INTERNATIONAL DESIGN ENGINEERING TECHNICAL CONFERENCES AND COMPUTERS AND INFORMATION IN ENGINEERING CONFERENCE, 2017, VOL 8 | 2017年
关键词
vibration control; magnetostrictive; rotating cantilever beam; magnetic field; LAMINATED COMPOSITE BEAMS; TERFENOL-D RODS; PIEZOELECTRIC MATERIALS; NUMERICAL-SIMULATION; MODEL; SUPPRESSION;
D O I
暂无
中图分类号
TH [机械、仪表工业];
学科分类号
0802 ;
摘要
The dynamic model and control strategy of a rotating cantilever beam are investigated in the paper. The magnetostrictive layer is applied as the actuator and the nonlinear constitutive relation is analyzed. The kinetic energy and potential energy of the beam are obtained. The Hamilton method and Galerkin approach are adopted to obtain and disperse the dynamic equations, respectively. The negative feedback control methodology is used in the control system, which is performed by the solenoid coils. Numerical results show that the magnetostrictive control method is effective and plays the role of damping in the dynamic equations. The nonlinear constrictive characteristics of the magnetostrictive material can affect the control results deeply and should be paid enough attention. The magnetostrictive control performances are influenced by many parameters such as the bias magnetic field, control gain and pre-stress etc.
引用
收藏
页数:10
相关论文
共 18 条
[1]   Active vibration control of flexible cantilever plates using piezoelectric materials and artificial neural networks [J].
Abdeljaber, Osama ;
Avci, Onur ;
Inman, Daniel J. .
JOURNAL OF SOUND AND VIBRATION, 2016, 363 :33-53
[2]   Constitutive modeling of nonlinear reversible and irreversible ferromagnetic behaviors and application to multiferroic composites [J].
Avakian, Artjom ;
Ricoeur, Andreas .
JOURNAL OF INTELLIGENT MATERIAL SYSTEMS AND STRUCTURES, 2016, 27 (18) :2536-2554
[3]   Statistical analysis of terfenol-D material properties [J].
Dapino, Marcelo J. ;
Flatau, Alison B. ;
Calkins, Frederick T. .
JOURNAL OF INTELLIGENT MATERIAL SYSTEMS AND STRUCTURES, 2006, 17 (07) :587-599
[4]   Robust adaptive sliding mode attitude control and vibration damping of flexible spacecraft subject to unknown disturbance and uncertainty [J].
Hu, Qinglei .
TRANSACTIONS OF THE INSTITUTE OF MEASUREMENT AND CONTROL, 2012, 34 (04) :436-447
[5]   Active vibration control of cantilever beam by using PID based output feedback controller [J].
Khot, S. M. ;
Yelve, Nitesh P. ;
Tomar, Rajat ;
Desai, Sameer ;
Vittal, S. .
JOURNAL OF VIBRATION AND CONTROL, 2012, 18 (03) :366-372
[6]   Dynamic model for free vibration and response analysis of rotating beams [J].
Kim, Hyungrae ;
Yoo, Hong Hee ;
Chung, Jintai .
JOURNAL OF SOUND AND VIBRATION, 2013, 332 (22) :5917-5928
[7]   Active control of beam with magneto strictive layer [J].
Kumar, JS ;
Ganesan, N ;
Swarnamani, S ;
Padmanabhan, C .
COMPUTERS & STRUCTURES, 2003, 81 (13) :1375-1382
[8]   Adaptive Modified Positive Position Feedback for Active Vibration Control of Structures [J].
Mahmoodi, S. Nima ;
Ahmadian, Mehdi ;
Inman, Daniel J. .
JOURNAL OF INTELLIGENT MATERIAL SYSTEMS AND STRUCTURES, 2010, 21 (06) :571-580
[9]   Vibration Control of Rotating Blades Using Root-Embedded Piezoelectric Materials [J].
Malgaca, L. ;
Al-Qahtani, H. ;
Sunar, M. .
ARABIAN JOURNAL FOR SCIENCE AND ENGINEERING, 2015, 40 (05) :1487-1495
[10]   Structural vibration control using linear magnetostrictive actuators [J].
Moon, Seok-Jun ;
Lim, Chae-Wook ;
Kim, Byung-Hyun ;
Park, Youngjin .
JOURNAL OF SOUND AND VIBRATION, 2007, 302 (4-5) :875-891
12