Abstract
The properties of TBC-3 and PZT-23 piezoelectric ceramics have been studied by the method of loaded three-element complex oscillator. Changes in the higher-order (up to fifth) parameters are considered for large mechanical (0–120 MPa) and electric (0–600 kV/m) loads. Results of studying the longitudinal flexibility s E11 , piezoelectric modulus d 31, and dielectric permittivity ε σ33 are presented within a frequency range of 20–200 kHz, where the frequency dispersion of dielectric as well as piezoelectric and elastic parameters is observed.
Similar content being viewed by others
References
Tsaplev, V., Konovalov, R., and Abbakumov, K., Disk bimorph-type piezoelectric energy harvester, J. Power Energy Eng., 2015, vol. 3, no. 4, pp. 63–68.
Tsaplev, V.M., Abbakumov, K.E., and Konovalov, R.S., Nelineinye p’ezokeramicheskie materialy i malogabaritnye generatory energii (Nonlinear Piezoceramic Materials and Small-Size Energy Harvesters), St. Petersburg: St. Petersburg Electrotech. Univ LETI, 2016.
Bogoroditskii, N.P. and Verbitskaya, T.N., Peculiarities in the behavior of ferroelectric ceramics near the Curie point, Dokl. Akad. Nauk SSSR, 1953, vol. 89, no. 3, pp. 447–449.
Physical Acoustics: Principles and Methods, Mason, W.P., Ed., Academic Press, 1964.
Yakovlev, L.A. and Kirov, E.A., An ultrasonic method for determining piezoelectric and elastic constants of piezomaterials, Zavod. Lab., 1971, no. 12, pp. 1460–1463.
Yakovlev, L.A. and Serebrennikova, N.P., Ultrasonic research into characteristics of piezoceramics, Defektoskopiya, 1980, no. 7, pp. 52–57.
Yakovlev, L.A., Ultrasonic research into characteristics of TsTBS-3 piezoceramics, Defektoskopiya, 1986, no. 6, pp. 47–50.
El’gard, A.M., Studying the dependences of permittivity and loss tangent in polarized ferroelectric ceramics on electric field strength in the range of 50 Hz–100 kHz, Fiz. Tverd. Tela, 1961, vol. 3, no. 5, pp. 1515–1521.
Parenthoine, D., Tran-Huu-Hue, L.-P., Haumesser, I., Vander Meulen, F., Lematre, M., and Lethiecq, M., Modelling nonlinearity in piezoceramic transducers: from equations to nonlinear equivalent circuits, Ultrason., 2011, vol. 51, pp. 109–114.
Tsaplev, V.M., Nelineinaya akustouprugost’ p’ezokeramicheskikh materialov. Ch. II. Akusticheskie metody izmerenii (Nonlinear Acoustoelasticity of Piezoceramic Materials. Part II: Acoustic Measurement Methods), St. Petersburg: St. Petersburg Electrotech. Univ LETI, 2014.
Mason, W. P., Piezoelectric Crystals and Their Application to Ultrasonics, Princeton, NJ: D Van Nostrand Company Inc., 1954.
Tsaplev, V.M., Nelineinye svoistva i polzuchest’ p’ezokeramiki (Nonlinear Properties and Creep of Piezoceramics), St. Petersburg: North-West Tech. Univ., 2003.
Tsaplev, V.M., Nelineinaya akustouprugost’ p’ezokeramicheskikh materialov. Ch. I. Fizicheskaya akustika p’ezokeramiki (Nonlinear Acoustoelasticity of Piezoceramic Materials. Part I: Physical Acoustics of Piezoceramics), St. Petersburg: St. Petersburg Electrotech. Univ LETI, 2013.
OST (Industry Standard) 11-0444-87. Piezoelectric materials. Technical conditions.
Author information
Authors and Affiliations
Corresponding author
Additional information
Original Russian Text © V.M. Tsaplev, R.S. Konovalov, 2017, published in Defektoskopiya, 2017, No. 7, pp. 14–22.
Rights and permissions
About this article
Cite this article
Tsaplev, V.M., Konovalov, R.S. Frequency dependences of higher-order constants of piezoelectric ceramics. Russ J Nondestruct Test 53, 485–492 (2017). https://doi.org/10.1134/S1061830917070087
Received:
Published:
Issue Date:
DOI: https://doi.org/10.1134/S1061830917070087