Multi-mode piezoelectric shunt damping with residual mode correction by evaluation of modal charge and voltage

Abstract

A resonant, piezoelectric shunt tuning procedure is based on the limiting eigenvalue problems associated with short and open circuiting of the piezoelectric domains attached to a vibrating structure. Whereas short circuit and open circuit frequencies are directly obtained from the eigenvalues, the associated electrical equation further determines a modal charge as an short circuit reaction force and a new modal voltage from the electric deflection in the open circuit limit. By a modal representation with short circuit mode shapes the structural equation fully decomposes, while the inherent contributions from non-resonant vibration modes in the corresponding electrical equation consistently define an effective modal capacitance, conveniently estimated by the modal charge to voltage ratio. The shunt tuning is obtained from the governing characteristic equation for the targeted vibration mode, in which the residual mode correction is explicitly represented by the effective modal capacitance. The tuning procedure with an effective modal capacitance is generalized to multiple piezoelectric domains with independent shunts for simultaneous damping of multiple vibration modes. The accuracy of the proposed shunt tuning methods is demonstrated by a numerical beam example with three piezoceramic patch pairs and independent resistive–inductive shunts. The analysis is carried out in a commercial finite element program, in which the required modal frequencies, charge and voltage are readily available as output to the short circuit and open circuit eigenvalue problems.

Keywords

Piezoelectric shunt damping resonant shunt calibration residual mode correction effective electromechanical coupling coefficient

Get full access to this article

View all access options for this article.

References

Anderson

Hagood

(1994) Simultaneous piezoelectric sensing/actuation: analysis and application to controlled structures. Journal of Sound and Vibration 174: 617–639.

ANS/IEEE 176-1987 (1988) Standards on piezoelectricity.

Berardengo

Manzoni

Thomas

, et al. (2018) Piezoelectric resonant shunt enhancement by negative capacitances: optimisation, performance and resonance cancellation. Journal of Intelligent Material Systems and Structures 29(12): 2581–2606.

Berardengo

Thomas

Giraud-Audine

, et al. (2016) Improved resistive shunt by means of negative capacitance: new circuit, performances and multi-mode control. Smart Materials and Structures 25: 075033.

Caruso

(2001) A critical analysis of electric shunt circuits employed in piezoelectric passive vibration damping. Smart Materials and Structures 10: 1059–1068.

De Marneffe

Preumont

(2008) Vibration damping with negative capacitance shunts: theory and experiment. Smart Materials and Structures 17: 035015.

Ducarne

Thomas

Deü

(2010) Structural vibration reduction by switch shunting of piezoelectric elements: modeling and optimization. Journal of Intelligent Material Systems and Structures 21: 797–816.

eFunda Portal ( 2019) Lead Zirconate Titanate (PZT-5H). Available at: http://www.efunda.com/materials/piezo/material_data/matdata_output.cfm?Material_ID=PZT-5H (accessed 1 July 2019).

Fleming

Behrens

Moheimani

SOR

(2000) Synthetic impedance for implementation of piezoelectric shunt-damping circuits. Electronics Letters 36: 1525–1526.

10.

Forward

(1979) Electronic damping of vibrations in optical structures. Applied Optics 18: 690–697.

11.

Gardonio

Casagrande

(2017) Shunted piezoelectric patch vibration absorber on two-dimensional thin structure: tuning considerations. Journal of Sound and Vibration 395: 26–47.

12.

Hagood

von Flotow

(1991) Damping of structural vibrations with piezoelectric materials and passive electrical networks. Journal of Sound and Vibration 146: 243–268.

13.

Høgsberg

Krenk

(2012) Balanced calibration of resonant shunt circuits for piezoelectric vibration control. Journal of Intelligent Material Systems and Structures 23: 1937–1948.

14.

Høgsberg

Krenk

(2017) Calibration of piezoelectric RL shunts with explicit residual mode correction. Journal of Sound and Vibration 386: 65–81.

15.

Hollkamp

(1994) Multimodal passive vibration suppression with piezoelectric materials and resonant shunts. Journal of Intelligent Material Systems and Structures 5: 49–57.

16.

Krenk

Høgsberg

(2013) Equal modal damping design for a family of resonant vibration control formats. Journal of Vibration and Control 19: 1294–1315.

17.

Krenk

Høgsberg

(2016) Tuned resonant mass or inerter-based absorbers: unified calibration with quasi-dynamic flexibility and inertia correction. Proceedings of the Royal Society 472: 20150718.

18.

Larbi

Deü

(2019) Reduced order finite element formulations for vibration reduction using piezoelectric shunt damping. Applied Acoustics 147: 111–120.

19.

Lossouarn

Aucejo

Deü

, et al. (2017) Design of inductors with high inductance values for resonant piezoelectric damping. Sensors and Actuators A: Physical 259: 68–76.

20.

Lossouarn

Aucejo

Deü

, et al. (2018) Design of a passive electrical analogue for piezoelectric damping of a plate. Journal of Intelligent Material Systems and Structures 29(7): 13011314.

21.

Park

Inman

(1999) A uniform model for series R-L and parallel R-L shunt circuits and power consumption. SPIE Proceedings 3668: 797–804.

22.

Preumont

(2011) Vibration Control of Active Structures: An Introduction. 3rd ed. Heidelberg: Springer.

23.

Soltani

Kerschen

Tondreau

, et al. (2014) Piezoelectric vibration damping using resonant shunt circuits: an exact solution. Smart Materials and Structures 23: 125014.

24.

Thomas

Ducarne

Deü

(2012) Performance of piezoelectric shunts for vibration reduction. Smart Materials and Structures 21: 015008.

25.

Toftekær

Benjeddou

Høgsberg

, et al. (2018) Optimal piezoelectric RL shunt damping of plates with residual mode correction. Journal of Intelligent Material Systems and Structures 29: 3346–3370.

26.

Toftekær

Benjeddou

Høgsberg

, et al. (2019) General numerical implementation of a new piezoelectric shunt tuning method based on the effective electromechanical coupling coefficient. Mechanics of Advanced Materials and Structures. Epub ahead of print 25 January 2019. DOI: 10.1080/15376494.2018.1549297.

27.

(1996) Piezoelectric shunts with a parallel R-L circuit for structural damping and vibration control. SPIE Proceedings 2720: 259–269.

28.

(1998) Method for multiple mode piezoelectric shunting with single PZT transducer for vibration control. Journal of Intelligent Material Systems and Structures 12: 991–998.

29.

Yamada

Matsuhisa

Utsuno

, et al. (2010) Optimum tuning of series and parallel LR circuits for passive vibration suppression using piezoelectric elements. Journal of Sound and Vibration 329: 5036–5057.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.00 MB