Multi-tone Switching Shunt Control by a PZT Network Embedded into a Fiberglass Panel: Design,Manufacture,and Test

Abstract

Research in noise and vibration control has partially focused on semi-active attenuation techniques such as switching shunt control (SSC) systems. Among the various methods, SSC architectures exhibit several interesting advantages such as low power absorption and intrinsic adaptive capabilities. This approach may represent an acceptable compromise between passive and active solutions. In previous work the authors implemented and validated 1D and 2D numerical models, addressed to describe continuous simple isotropic structures under tonal excitations controlled by single-element SSC system. Further efforts were then directed to extend the applicability of those models to non-isotropic structures and to multi-tone control devices. In this article, a 6-PZT network multi-tone SSC system is presented, and embedded into a balanced fiberglass laminate. The network geometry is defined according to an optimization process following modal information. The former 1-channel control circuit was extended to drive up to four independent channels. The complete system dynamics was simulated by assembling the structural matrices into a Matlab code, where both the electromechanical coupling and the control circuit behavior were taken into account. The structure was excited by broadband sweep signals in a selected range. Numerical and experimental results were compared and discussed.

Keywords

switch shunt control semi-active control embedded piezoceramic.

Get full access to this article

View all access options for this article.

References

Adhikari, S. 2006. ‘‘Damping Modelling using Generalized Proportional Damping,’’ Journal of Sound and Vibration, 293:156-170.

Anonymous. P-876 DuraActTM Piezoelectric Patch Transducers, Datasheet from www.pi.ws

Anonymous 1976. National Semiconductor Application Note 162, LM2907 Tachometer/Speed Switch Building Block Applications , June.

Anonymous 2000. National Semiconductor Corporation, LM324 Low Power Quad Operational Amplifiers, August.

Anonymous 2004. Analog Device, LC2MOS 5W Ron SPST Switches, ADG452, Datasheets Downloaded from ChipDocs.

Ciminello, M. , Ameduri, S. and Concilio, A. 2008a. ‘‘FE Modelling of an Innovative Vibration Control Shunt Technique,’’ Journal of Intelligent Material Systems and Structures, 19(8):875-887.

Ciminello, M. , Calabrò, A. , Ameduri, S. and Concilio, A. 2008b. ‘‘Synchronized Switched Shunt Control Technique Applied on a Cantilevered Beam: Experimental Investigations, ’’ Journal of Intelligent Material Systems and Structures, 19(9):1089-1100.

Clark, W. 1999. ‘‘State Switched Piezoelectric Systems for Vibration Control,’’ Structure , Structural Dynamics and Materials AIAA Journal, 1533:2623-2629.

Clark, W. 2000. ‘‘Vibration Control with State-switched Piezoelectric Materials,’’ Journal of Intelligent Material Systems and Structures, 11:263-273.

10.

Concilio, A. 1992. ‘‘Teoria ed Applicazioni dei Materiali e Delle Strutture Intelligenti,’’ Lectures on Smart Materials & Structures (in Italian). Available at: http://www.dpa.unina.it/corsi/

11.

Corr, L. and Clark, W. 2001. ‘‘Energy Dissipation of Piezoelectric Semi-active Vibration Control,’’ Journal of Intelligent Material Systems and Structures, 12:729-736.

12.

Corr, L. and Clark, W. 2002. ‘‘Comparison of Low-frequency Piezoelectric Switching Shunt Technique for Structural Damping,’’ Smart Materials and Structures, 11:370-376.

13.

Corr, L. and Clark, W. 2003. ‘‘A Novel Semi-active Multimodal Vibration Control Law for a Piezoceramic Actuator,’’ Journal of Vibration and Acoustics, 125:214-222.

14.

Corr, L.R. 2001. ‘‘Investigation of Real-time Switching of Piezoceramic Shunts for Structural Vibration Control,’’ PhD Thesis, School of Engineering, University of Pittsburg.

15.

Crawley, E.F. and Anderson, E.H. 1990. ‘‘Detailed Models of Piezoceramic Actuation of Beams,’’ Journal of Intelligent Material Systems and Structures, 1:4-25.

16.

Crawley, E.F. and de Luis, J. 1987. ‘‘Use of Piezoelectric Actuators as Elements of Intelligent Structures,’’ AIAA Journal, 25(10):1373-1385.

17.

Dimitriadis, E.K. , Fuller, C.R. and Rogers, C.A. 1991. ‘‘Piezoelectric Actuators for Distributed Vibration Excitation of Thin Plates,’’ ASME Journal of Vibration and Acoustics, 113:100-107.

18.

Guyomar, D. and Badel, A. 2006. ‘‘Nonlinear Semi-passive Multimodal Vibration Damping: an Efficient Probabilistic Approach,’’ Journal of Sound and Vibration, 294:249-268.

19.

Imregun, M. and Ewins, D.J. 1995. Complex Modes-Origin and Limits, In: Proceedings of the 13th International Modal Analysis Conference (IMAC), Nashville, TN, pp. 496-506.

20.

Lallart, M. , Badel, A. , Guyomar, D. and Lebrun, L. 2005. Non-linear Semi-passive Damping Using Constant or Adaptive Voltage Source: A Stability Analysis, In: ICAST 2005 - Sixteenth International Conference on Adaptive Structures and Technologies, October 9-12, 2005, Paris, France, pp. 158-165.

21.

Lefeuvre, E. , Badel, A. , Petit, L. , Richard, C. and Guyomar, D. 2006. ‘‘Semi-passive Piezoelectric Structural Damping by Synchronized Switching on Voltage Source,’’ Journal of Intelligent Material Systems and Structures, 17:653-660.

22.

Lefeuvre, E. , Badel, A. , Richard, C. , Petit, L. and Guyomar, D. 2006. ‘‘A Comparison between Several Vibration-powered Generators for Standalone Systems,’’ Sensors & Actuators A Physical, 126(2):405-416.

23.

Petit, L. , Lefeuvre, E. , Richard, C. and Guyomar, D. 2004. ‘‘A Broadband Semi Passive Piezoelectric Technique for Structural Damping,’’ Proceedings of SPIE , 5386:414-425.

24.

Richard, C. , Guyomar, D. , Audigier, D. and Ching, G. 1999. ‘‘Semi-passive Damping Using Continuous Switching of a Piezoelectric Device,’’ Society of Photo-Optical Instrumentation Engineering (SPIE) Conference Series, 3672:104-111.

25.

Richard, C. , Guyomar, D. , Audigier, D. and Bassaler, H. 2000. ‘‘Enhanced Semi-passive Damping Using Continuous Switching and Isolation,’’ SPIE, 3989:288-299.