Electrical properties of cylindrical piezoceramic emitters with power and compensated design with circumferential polarization
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Abstract
Based on the common technical positions, obtained extensive numerical data on the electrical properties of cylindrical piezoceramic emitters with compensated and power design. On its base, was found quantitative relationship between electric current module, active and reactive components of the electrical resistance of these emitters and the type of used polarization, the physical parameters of different formulations of the piezoceramic shell emitters, the geometrical dimensions of the emitter design and physical characteristics of the medium filling their internal cavity. Comparative analysis of the obtained data allowed us to establish a few of subtle effects in the behavior of the electric fields of this type emitters.
Reference 8, figures 10.
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References
Aronov B.S. (1990) “Electromechanical transducers of a piezoelectric ceramic”. Leningrad. Ener-goatomizdat izdat., P. 272. (Rus)
Bogorodskiy V.V., Zubarev L.A. Korepin E.A. Yakushev V.I. (1983) “Underwater electroacoustic trans-ducers. (Calculation and design). Handbook”. Leningrad, Shipbuilding. P. 248. (Rus)
Grinchenko V.T., Ulitko A.F., Shulga N.A. (1989), “Mechanics related fields in structural elements. Vol.5. Electroelasticity”. Kiev, Naukova dumka. P. 280. (Rus)
Dіdkovskij V.S., Lejko O.G., Savіn V.G. (2006), “Electroacoustic piezoceramic transducers (calcula-tion, design, construction). Education manual”. Kirovograd, "Imex-LTD". P.448 (Ukr)
Korzhyk O.V. (2014) “Accounting the electroding type of spherical electroelastic transducer at through objectives receiving sound by multimode systems“. Electronics and Communication, №1, pp. 76-86. (Rus)
Leiko A.G., Nyzhnyk A.I, Starovoyt Y.I. (2013), “Sound fields of piezoceramic emitters with different piezoelectric effect”. Electronics and Communication. №4. pp. 50-55. (Rus)
Leiko A.G., Nyzhnyk A.I, Starovoyt Y.I. (2013), “Acoustic properties of cylindrical piezoceramic emit-ters with power and compensated design with longitudinal and transverse piezoelectric effect”. Elec-tronics and Communication. №6. pp. 62-73. (Rus)
Sverdlin G.M. (1988) “Sonar transducers and antennas”. Leningrad, Shipbuilding. P. 200. (Rus)
