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Active vibration control: considering effect of electric field on coefficients of PZT patches
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  • Journal title : Smart Structures and Systems
  • Volume 16, Issue 6,  2015, pp.1091-1105
  • Publisher : Techno-Press
  • DOI : 10.12989/sss.2015.16.6.1091
 Title & Authors
Active vibration control: considering effect of electric field on coefficients of PZT patches
Sharma, Sukesha; Vig, Renu; Kumar, Navin;
 Abstract
Piezoelectric coefficient and dielectric constant of PZT-5H vary with electric field. In this work, variations of these coefficients with electric field are included in finite element modelling of a cantilevered plate instrumented with piezoelectric patches. Finite element model is reduced using modal truncation and then converted into state-space. First three modal displacements and velocities are estimated using Kalman observer. Negative first modal velocity feedback is used to control the vibrations of the smart plate. Three cases are considered v.i.z case 1: in which variation of piezoelectric coefficient and dielectric constant with electric field is not considered in finite element model and not considered in Kalman observer, case 2: in which variation of piezoelectric coefficient and dielectric constant with electric field is considered in finite element model and not considered in Kalman observer and case 3: in which variation of piezoelectric coefficient and dielectric constant with electric field is considered in finite element model as well as in Kalman observer. Simulation results show that appreciable amount of change would appear if variation of piezoelectric coefficient and dielectric constant with r.m.s. value of electric field is considered.
 Keywords
active vibration control;finite element modelling;piezoelectric;Kalman;smart structure;
 Language
English
 Cited by
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An experimental study of vibration control of wind-excited high-rise buildings using particle tuned mass dampers,;;;;

Smart Structures and Systems, 2016. vol.18. 1, pp.93-115 crossref(new window)
1.
Temperature compensation in a smart structure by application of DC bias on piezoelectric patches, Journal of Intelligent Material Systems and Structures, 2016, 27, 18, 2524  crossref(new windwow)
2.
AVC of a smart plate with PZT sensor-actuator using direct method of model updating, Ferroelectrics, 2017, 510, 1, 184  crossref(new windwow)
3.
An experimental study of vibration control of wind-excited high-rise buildings using particle tuned mass dampers, Smart Structures and Systems, 2016, 18, 1, 93  crossref(new windwow)
 References
1.
ANSI/IEEE Std 176-1987 (1988), IEEE Standard on Piezoelectricity.

2.
Apte, D.A. and Ganguli, R. (2009), "Influence of temperature and high electric field on power consumption by piezoelectric actuated integrated structure", Comput. Mat. Cont., 329(1), 1-23.

3.
Baz, A. and Poh, S. (1988), "Performance of an active control system with piezoelectric actuators", J. Sound Vib., 126(2), 327-343. crossref(new window)

4.
Birman, V. (2005), Physically nonlinear behaviour of piezoelectric actuators subject to high electric fields, final report, US army research, Feb.

5.
Bruant, I., Coffignal, G., Lene, F. and Verge, M. (2001), "Active control of beams structures with piezoelectric actuators and sensors: modeling and simulation", Smart Mater. Struct., 10(2), 404-408. crossref(new window)

6.
Cady, W.G. (1964), Piezoelectricity, vol 1, Dover Publications, New York.

7.
Cao, W., Cudney, H. and Waser, R. (1999), "Smart materials and structures", Proc. National Acad. American Sci.USA, 96, 8330-8331. crossref(new window)

8.
Friswell, M. (2003), "Modal sensors and actuators for beam and plate structures", Smart Struct. Mat., 5050, 92-100.

9.
Gopal, M. (2010), Digital Control and State Variable Methods, (3rd Ed.), Tata McGraw Hill, New Delhi.

10.
Gupta, V., Sharma, M. and Thakur, N. (2012), "Active structural vibration control: robust to temperature variations", Mech. Syst. Signal. Pro., 33, 167-180. crossref(new window)

11.
Gupta, V., Sharma, M. and Thakur, N. (2011), "Active vibration control of a smart plate using a piezoelectric sensor-actuator pair at elevated temperatures", Smart Mater. Struct., 20, 105023-1 - 105023-13. crossref(new window)

12.
Gupta, V., Sharma, M. and Thakur, N. (2011), "Mathematical modeling of actively controlled piezo smart structures:A review", Smart Struct. Syst., 8(3), 275-302. crossref(new window)

13.
Hu, J. (2012), "Vibration control of smart structure using sliding mode control with observer", J. Comput., 7(2), 411-418.

14.
Hu, T., Ma, L. and Lin, Z. (2007), "Active vibration control for uncertain time varying systems via output feedback", IEEE American Cont. Conf., July.

15.
Ikeda, T. (1996), Fundamentals of Piezoelectricity, Oxford University Press, New York.

16.
Kim, B., Washington, G.N. and Yoon, H.S. (2013), "Active vibration suppression of a 1D piezoelectric bimorph structure using model predictive sliding mode control", Smart Struct. Syst., 11(6), 623-635. crossref(new window)

17.
Kugal, V. D. and Cross, L.E. (1998), "Behavior of soft piezoelectric ceramics under high sinusoidal electric fields", J Appl. Phys., 84(5), 2815-2830. crossref(new window)

18.
Li, S., Zhao, R., Li, J., Mo, Y. and Zhenyu, S. (2014), "DOB-based piezoelectric vibration control for stiffened plate considering accelerometer", Smart Struct. Syst., 14(3), 327-345. crossref(new window)

19.
Li, J. and Narita, Y. (2014), "Reduction of wind induced vibrations of a laminated plate with an active constrained layer", J. Vib. Control, 20(6), 901-912. crossref(new window)

20.
Lin, C.Y. and Chan, C.M. (2013), "Hybrid proportional derivative/repetitive control for active vibration control of smart piezoelectric structure", J. Vib. Control, 19, 992-1003. crossref(new window)

21.
Lin, C.C. and Huang, H.N. (1999), "Vibration control of beam and plates with bonded piezoelectric sensors and actuators", Comput. Struct., 73, 239-248. crossref(new window)

22.
Malgaca, L. and Karagulle, H. (2009), "Simulation and experimental analysis of active vibration control of smart beams under harmonic excitation", Smart Struct. Syst., 5(1), 55-68. crossref(new window)

23.
Masys, A.J., Ren, W., Yang, G. and Mukherjee, B.K. (2003), "Piezoelectric strain in lead zirconate titanate ceramics as a function of electric field, frequency and DC bias", J Appl. Phys., 94(2), 1155-1162. crossref(new window)

24.
Petyt, M. (1998), Introduction to Finite Element Vibration Analysis, (2nd Ed.), Cambridge University Press, New York.

25.
Raja, S., Sinha, P.K., Partap, G. and Bhattacharya, P. (2002), "Influence of one and two dimensional piezoelectric actuation on active vibration control of smart panels", Aerosp. Sci. Technol., 6(3), 209-206. crossref(new window)

26.
Sharma, M., Singh, S.P. and Sachdeva, B.L. (2005), "Fuzzy logic based modal space control of a cantilevered beam instrumented with piezoelectric patches", Smart Mater. Struct., 14(5), 1017-1024. crossref(new window)

27.
Sharma, M., Singh, S.P. and Sachdeva, B.L. (2007), "Modal control of a plate using fuzzy logic controller", Smart Mater. Struct., 16(4), 1331-1341. crossref(new window)

28.
Shin, C., Hong, C. and Jeong, W.B. (2013), "Active vibration control of beams using filtered velocity feedback controllers with moment pair actuators", J. Sound Vib., 332(12), 2910-2922. crossref(new window)

29.
Sirohi, J. and Chopra, I. (2000), "Fundamental behavior of piezoceramic sheet actuators", J. Intel. Mat. Syst. Str., 11(1), 47-61. crossref(new window)

30.
Smittakorn, W. and Heyliger, P.R. (2000), "A discrete-layer model of laminated hygrothermopiezoelectric plates", Mech. Compos. Mater., 7(1), 79-104.

31.
Wang, D., Fotinich, Y. and Carman, G.P. (1998), "Influence of temperature on electromechanical and fatigue behaviour of piezoelectric ceramics", J. Appl. Phys., 83(10), 5342-5350. crossref(new window)

32.
Wang, Q.M., Zhang, T., Chen, Q. and Du, X.H. (2003), "Effect of DC bias field on complex materials coefficients of piezoelectric resonators", Sensor. Actuat. A- Phys., 109(10), 149-155. crossref(new window)

33.
Zabihollah, A., Sedagahti, R. and Ganesan, R. (2007), "Active vibration suppression of smart laminated beams using layer wise theory and optimal control strategy", Smart Mater. Struct., 16(6), 2190-2201. crossref(new window)

34.
Zenz, G., Berger, W., Nader M. and Krommer, M. (2013), "Design of piezoelectric transducer arrays for passive and active modal control of thin plates", Smart Struct. Syst., 12(5), 547-577. crossref(new window)

35.
Zhang, Q.M., Wang, H. and Zhao, J. (1995), "Effect of driving field and temperature on the response behaviour of ferroelectric actuator and sensor materials", J. Intel. Mat. Syst. Str., 6(1), 84-93. crossref(new window)

36.
Zhang, T., Li, H.G. and Cai, G.P. (2013), "Hysteresis identification and adaptive vibration control for a smart cantilevered beam by a piezoelectric actuators", Sensor. Actuat. A- Phys., 203, 168-175. crossref(new window)