Zhurnal Radioelektroniki - Journal of Radio Electronics. eISSN 1684-1719. 2021. №10
ContentsFull text in Russian (pdf)
DOI: https://doi.org/10.30898/1684-1719.2021.10.10
UDC: 537.874; 537.624
NONLINEAR EXCITATION OF HYPERSOUND VIBRATIONS IN FERRITE PLATE IN CONDITIONS OF COMBINE INFLUENCE IN TWO FREQUENCIES.
PART 3. VARIATION OF PLATE THICKNESS
V. S. Vlasov1, D. A. Pleshev1, V. G. Shavrov2, V. I. Shcheglov2
1 Syktyvkar State University of Sorokin, Oktyabrsky prosp. 55, Syktyvkar 167001, Russia
2 Kotel’nikov Institute of Radio Engineering and Electronics RAS, Mokhovaya 11-7, Moscow 125009, Russia
The paper was received July 1, 2021.
Abstract. The task about nonlinear excitation of hypersound vibrations in ferrite plate in conditions of combine influence in two frequencies is investigated. As a most important parameter which is varied it is proposed the relative thickness of plate which is determined as relation of real thickness to the thickness which correspond to elastic resonance on the difference of excitation frequencies. It is established the necessity of choosing of character value of constant field which is determined by enough effective excitation of elastic vibrations. The system of nonlinear equations of motion of magnetization and elastic displacement is described. For solving of this system the numerical Rounge-Cutta method is applied. The results of this calculation are the time-evolvent of vibrations, dependencies magnetic end elastic vibrations amplitudes and also the spectra of vibrations in permanent conditions after end of relaxation processes. It is found the multi-regime character of elastic vibrations which takes place by variation of plate thickness. In the character of development of elastic vibrations in time by the increasing of plate thickness it is found four regimes: regime №1 – regular beatings, regime №2 – established resonance, regime №3 – displacement of center of established vibrations, regime №4 – gigantic oscillations. The intervals of thickness values which are necessary or realization of these regimes are determined. The properties of each regimes taken separately are investigated. It is found that the regime №1 is realized when the thickness of plate is more less then the thickness of resonance on differential frequency. In this case the elastic vibrations in generally repeats the vibrations of magnetization which are realized as beating between two frequencies of excitation. The regime №2 takes place when the plate thickness is near to resonance on differential frequency. When thickness is corresponds to resonance on differential frequency it is found large raising of resonance character. In the vibrations of elastic displacement the constant component is discovered. The regime №3 takes place when the plate thickness is exceeded of resonance on several (from two to seven) times. The vibrations of magnetization in this regime are the same as in regimes №1 and №2. The elastic displacement has two components: oscillatory on differential frequency and constant which value by increasing of thickness smoothly is increased. The displacement of center of oscillatory component by thickness is increased has quadratic character. The regime №4 takes place by plate thickness exceeds resonance thickness on the order and more. The vibrations of magnetization maintain the character of beating which are the same as in regimes №1, №2 and №3. The vibrations of elastic displacement are characterized by extremely large amplitude which is more then the amplitude in regime №3 on order and more and also has extremely large period which is more then period of differential frequency vibrations on two-three order and more. The amplitude of vibrations and its period by the thickness is increases also increase by linear meaning. The some quality opinions about the nature of observed phenomena are proposed. It is established the specific character of two-frequency excitation in comparison to single-frequency excitation. As the possible task it is proposed the plan of singing the part of solution as dependence of vibration amplitude from plate thickness has quadratic character with necessary appreciation of two-frequency excitation. The mechanical analogy for vibrations of hard rod which is compressed on both ends by approaching forces is proposed. This analogy allows to interpret the displacement of vibrations center and gigantic oscillations regime.
Key words: magnetostriction transducer, nonlinear vibrations, magnetoelastic resonance.
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For citation:
Vlasov V.S., Pleshev D.A., Shavrov V.G., Shcheglov V.I. Nonlinear excitation of hypersound vibrations in ferrite plate in conditions of combine influence in two frequencies. Part 3. Variation of plate thickness. Zhurnal radioelektroniki [Journal of Radio Electronics] [online]. 2021. №10. https://doi.org/10.30898/1684-1719.2021.10.10 (In Russian)