Parametric Structural Schemes of Piezoactuators for Nano-and Micrometric Movements at a Longitudinal Piezoeffect

Solutions to the wave equation and structural-parametric models of piezoactuators at a longitudinal piezoeffect were obtained. Effects of the geometric and physical parameters of the piezoactuators and external load on its static and dynamic characteristics were determined. The parametric structural schemes for piezoactuators for nano- and micrometric movements at a longitudinal pie-zoeffect were obtained. The transfer functions were determined. The parametric structural schemes and the transfer functions of the piezoactuators were obtained for calculation of the automatic control systems for nano- and micrometric movements with piezoac-tuators at a longitudinal piezoeffect. The static and dynamic characteristics of the piezoactuators were determined. Application of the piezoactuators solves the problems of precise matching in microelectronics and nanotechnology, compensation for the temperature and gravitational deformations, atmospheric turbulence by a wave front correction. By solving the wave equation with allowance for the corresponding equations of the piezoelectric effect, the boundary conditions on the loaded working surfaces of a piezoactuator, the strains along the coordinate axes, it is possible to construct a structural parametric model of a piezoactuator. The transfer functions and the parametric structural schemes of the piezoelectric actuator were obtained from the equations describing the corresponding structural parametric models of the piezoactuators for nano- and micrometric movements at a longitudinal piezoeffect.

пьезоактюатор, деформация, нано- и микроперемещения, параметрическая структурная схема, структурно-параметрическая модель, продольный пьезоэффект, противоэлектродвижущая сила, передаточная функция, piezoactuator, deformation, nano- and micrometric movements, parametric structural scheme, structural-parametric model, longitudinal piezoelectric effect, transfer function

1. Панич А. Е. Пьезокерамические актюаторы. Ростов-на-Дону: Южный федеральный университет, 2008. 159 с.

2. Физическая акустика. Т. 1. Часть А. Методы и приборы ультразвуковых исследований / Под ред. У. Мэзона. М.: Мир, 1966. 592 с.

3. Афонин С. М. Решение матричных уравнений в задачах электроупругости для многослойных актюаторов наноперемещений // Мехатроника, автоматизация, управление. 2010. № 8. С. 39-45.

4. Афонин С. М. Исследование статических и динамических характеристик пьезодвигателя нано- и микроперемещений // Изв. РАН. Теория и системы управления. 2008. № 5. С. 114-121.

5. Afonin S. M. Structural-parametric model and transfer functions of electroelastic actuator for nano- and microdisplacement // Chapter 9 in: Piezoelectrics and Nanomaterials: Fundamentals, Developments and Applications. Editor: Parinov I. A. New York: Nova Science Publisher. 2015. P. 225-242.

6. Афонин С. М. Статические характеристики и упругие податливости многослойных пьезоактюаторов нано- и микроперемещений // Нано- и микросистемная техника. 2016. Т. 18, № 1. С.40-48.

7. Полянин А. Д. Справочник по линейным уравнениям математической физики. М.: Физматлит. 2001. 576 с.

8. Estanbouli Y., Hayward G., Radamas S., Barbenel J. A block diagram model of the thickness mode piezoelectric transducer containing dual oppositely polarized piezoelectric zones // IEEE Transactions on Ultrasonics, Ferroelectrics, and Frequency Control. 2006. Vol. 53. № 5. P. 1028-1036.

9. Smyth K., Kim S.-G. Experiment and simulation validated analytical equivalent circuit model for piezoelectric micromachined ultrasonic transducers // IEEE Transactions on Ultrasonics, Ferro-electrics, and Frequency Control, 2015. Vol. 62, № 4, P. 744-765.

10. Uchino K. Piezoelectric actuator and ultrasonic motors. Boston, MA: Kluwer Academic Publisher, 1997. 347 p.

11. Borboni A. Meso- to micro-actuators: a theoretical and practical approach. New York: CRC Press. 2008. 400 p.