Abstract
A structural-parametric model and parametric block diagrams of a piezoelectric transducer in the transverse piezoelectric effect are obtained with regard to the counter-electromotive force. The transfer functions of the multi-layer piezoelectric transducer of nano- and microdisplacements are determined with regard to the influence of geometric and physical parameters of the multi-layer piezoelectric transducer, the counter-electromotive force, and the external load.
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References
V. L. Mironov, Fundamentals of Scanning ProbeMicroscopy (Tekhnosfera, Moscow, 2004) [in Russian].
V. A. Akopian, A. E. Panich, A. N. Soloviev, et al., “Several Physical-Mechanical Problems of Piezoelectric Actuators and the Domains of Their Application,” Nano-Mikrosist. Tekhn., No. 10, 35–40 (2006).
V. M. Klimashkin, V. G. Nikiforov, and A. Ya. Safronov, “Multi-Layer Piezoelectic Actuators and Specific Features of Their Application,” Komponenty Tekhnol.. No. 6, 62–65 (2007).
A. E. Panich, Piezoceramic Actuators (Yuzhn. Fed. Univ., Rostov-on-Don, 2008) [in Russian].
S. M. Afonin, “Static and Dynamic Characteristics of a Multi-Layer Electroelastic Solid,” Izv. Ross. Akad. Nauk. Mekh. Tverd. Tela, No. 6, 149–168 (2009) [Mech. Solids (Engl. Transl.) 44 (6), 935–950 (2009)].
S. M. Afonin, “Parametric Block Diagrams ofMulti-Layer Piezoactuator of Nano-and Microdisplacements in the Longitudinal Piezoeffect,” Elektrichestvo, No. 2, 61–67 (2014).
W. Mason (Editor) Physical Acoustics, Vol. 1, Part A: Methods and Devices of Ultrasonic Studies (Mir, Moscow, 1966) [in Russian].
Y. Estanbouli, G. Hayward, S. Radamas, and J. Barbenel, “A Block Diagram Model of the Thickness Mode Piezoelectric Transducer Containing Dual Oppositely Polarized Piezoelectric Zones,” IEEE Trans. Ultrason., Ferroel., Freq. Control 53 (5), 1028–1036 (2006).
T. Shigematsu and M. K. Kurosawa, “Friction Drive of an SAW Motor. Part III: Modeling,” IEEE Transac. Ultrason. Ferroel. Freq. Control 55 (10), 2266–2276 (2008).
M. K. Kurosawa, “Ultrasonic Linear Motor Using Travelling Surface Acoustic Wave,” in Proc. IEEE Ultraxon. Symp., 2009 (2009), pp. 1096–1105.
K. Smyth and S.-G. Kim, “Experiment and Simulation Validated Analytical Equivalent Circuit Model for PiezoelectricMicromachined Ultrasonic Transducer,” IEEE Transac. Ultrason. Ferroel. Freq. Control 62 (4), 744–765 (2015).
F. Sammoura and S.-G. Kim, “TheoreticalModeling and Equivalent Electric Circuit of a Bimorph PiezoelectricMicromachinedUltrasonic Transducer,” IEEE Transac. Ultrason. Ferroel. Freq. Control 59 (5), 990–998 (2012).
K. Uchino, Piezoelectric Actuator and Ultrasonic Motors (Kluwer, Boston, 1997).
A. Borboni, Meso-to Micro-Actuators: A Theoretical and Practical Approach (CRC Press, Boca Raton, 2008).
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Original Russian Text © S.M. Afonin, 2017, published in Izvestiya Akademii Nauk, Mekhanika Tverdogo Tela, 2017, No. 1, pp. 99–116.
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Afonin, S.M. Parametric block diagrams of a multi-layer piezoelectric transducer of nano- and microdisplacements under transverse piezoelectric effect. Mech. Solids 52, 81–94 (2017). https://doi.org/10.3103/S0025654417010101
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DOI: https://doi.org/10.3103/S0025654417010101