Research of rotary piezotable driven by two harmonic signals/Sukamojo staliuko, varomo dviem harmoniniais signalais, tyrimas.
Grybas, I. ; Bubulis, A. ; Bansevicius, R. 等
1. Introduction
Rotary piezoelectric stages and motors exploiting ultrasonic
vibrations are found in many mechatronical applications including
positioning, metrology, manufacturing process control, pick-and-place
assembly, consumer electronics, medicine, aerospace systems, etc [1-5].
This tendency is governed by such prevalent benefits over conventional
electromagnetic actuators as high precision and accuracy, compactness,
high torque output at low speed, simple structure, nearly zero noise
level, insensitivity to magnetic field and high efficiency [1, 6-8].
Despite piezopositioning stages mostly make use of standing and/or
travelling waves there is a very limited amount of information about
rotational oscillations and their positive impacts.
2. System construction and operation principle
Schematic construction of the system to be analysed is given in
Fig. 1, while relevant operation principle is explained in the
subsequent text.
This table structure contains rotor 1 contacting with ring shaped
piezoelement 3 via five frictional elements 2 (three units) and 5 (two
units), what ensures precise positioning of the rotor with respect to
its axis of rotation. When rotational motion takes place these five
supporting points become vibroactive, and this significantly reduces
resisting moment of friction forces. Ring-shaped piezoelectric
transducer is composed of two groups of control electrodes, with one
group inducing rotation of the rotor, while the other initiates motion
of opposite direction under operational regime voltage supply.
[FIGURE 1 OMITTED]
In order to excite specific rotational type oscillations within the
rotor two harmonic signals ([U.sub.1] and [U.sub.2]) of different
frequency and amplitude are supplied to both groups of control
electrodes. Signal expressions are presented in Eqs. (1) and (2) [9]:
[U.sub.1] (t) = [U.sub.01] cos([[omega].sub.1]t - [[phi].sub.1]),
(1)
[U.sub.2] (t) = [U.sub.02] cos([[omega].sub.2]t - [[phi].sub.2]),
(2)
where [U.sub.01], [U.sub.02] are voltage amplitudes,
[[omega].sub.1], [[omega].sub.2] are angular frequencies, t is time and
[[phi].sub.1], [[phi].sub.2] are phases of harmonic signals. Here
[[omega].sub.2] > [[omega].sub.1] and [[omega].sub.2] -
[[omega].sub.1] [much less than] [[omega].sub.1].
In the presence of such conditions the moving member (i.e. rotor)
performs a periodic motion, which is defined by the following law [9]:
A = [A.sub.max] cos([[omega].sub.2] - [[omega].sub.1]/2 t), (3)
where [A.sub.max] is the maximal amplitude and t is time of
rotational type vibrations.
In this case harmonic oscillations are excited in frequency range
from 0 Hz at [[omega].sub.2] = [[omega].sub.1], A = [A.sub.max].
3. Experimental setup and investigation
A prototype of the piezotable researched has the piezoelectric
ring-shaped transducer, in which the alternating strain is excited by an
AC electrical field, preferably operating at the mechanical resonance
frequency. In order to determine the resonance frequency of the designed
piezoelectric ring-shaped transducer, an impedance analyzer Wayne Kerr
6500B (Fig. 2) is used to measure the impedance characteristics of the
prototype, and the measurement plot of electric impedance within the
measured frequencies is shown in Fig. 4.
So as to measure the dynamic characteristics of the piezotable, an
experimental setup, which includes two function generators and high
voltage amplifiers, the laser Doppler interferometer, vibrometer,
oscilloscope and PC, was used. A simplified structural scheme can be
seen in Fig. 3, a and its actual components are shown in Fig. 3, b.
[FIGURE 2 OMITTED]
[FIGURE 3 OMITTED]
4. Results of experimental analysis
[FIGURE 4 OMITTED]
A prototype of the piezotable was built and tested. In order to
determine the operational AC frequency of the researched piezotable the
measurement plot of electric impedance and phase of the ring-shaped
piezoelectric transducer within the measured frequencies is shown in
Fig. 4.
By observing the measured impedance vs. frequency characteristic,
shown in Fig. 4, there are three resonant frequencies (around 44 kHz, 92
kHz and 132 kHz) at which the impedance reaches maximum. The operation
frequency of the piezotable is 44.1 kHz, and it was determined
experimentally.
[FIGURE 5 OMITTED]
[FIGURE 6 OMITTED]
[FIGURE 7 OMITTED]
However, it should be noted that rotary piezotable can also operate
in a slightly wider frequency range, which is determined by width of the
characteristic impedance curve in the peak zone.
Two oscillation regimes of investigated piezotable rotor were
obtained with one of them exhibiting maximal vibration amplitudes (0.2
rad) and another one featured by minimal vibration amplitudes (~10
[mu]rad). Respective plots are given in Figs. 5 and 6. In each case
rotating motion of the rotor is absent, i.e. rotor just vibrates
rotationally forth and back. Two harmonic signals ([U.sub.1] and
[U.sub.2]) of different frequencies and equal amplitudes are supplied to
both groups of control electrodes. On the contrary, a possibility to
combine rotational motion with rotational oscillations of the rotor is
presented in Fig. 7. It has to be pointed that the latter opportunity
implementation is only feasible, if two harmonic excitation frequencies
are not the same and their voltage amplitudes are different (i.e.
[f.sub.1] [not equal to] [f.sub.2], [U.sub.1] [not equal to] [U.sub.2]).
Furthermore, although measured rotor angular speed was 3.5 [mu]rad/s, it
can be increased/decreased by setting higher/ lower values of voltage
amplitudes. Emphasis should also be placed on capability of
bidirectional rotational motion in this case too. Despite this
characteristic is not shown in the paper it will definitely be discussed
more in details in future work.
4. Conclusions
Developed piezoelectric rotary table driven by two harmonic signals
was discussed and analysed in this article. The following conclusions
are formed.
1. A new design and operation principle of the rotary piezotable
was described.
2. Experimental setup for determination of rotary piezotable
resonant frequencies and investigation of major dynamic characteristics
was presented.
3. Maximal vibration amplitudes (0.2 rad) and minimal vibration
amplitudes (~10 [mu]rad) of the rotor were obtained.
4. Specific regime combining ordinary rotational motion with
rotational oscillations was demonstrated to be possible (rotor angular
speed 3.5 [mu]rad/s).
Acknowledgement
This research has been funded by Research Council of Lithuania
(Project PiezoTable, No. MIP 094/12).
Received September 03, 2014
Accepted December 15, 2014
References
[1.] Iulaa, A.; Corbo, A.; Pappalardo, M. 2010. FE analysis and
experimental evaluation of the performance of a travelling wave rotary
motor driven by high power ultrasonic transducers, Sensors and Actuators
A: Physical 160: 94-100. http://dx.doi.org/i0.l0l6/j.sna.20l0.03.037.
[2.] Uchino, K.; Cagatay, S.; Koc, B.; Dong, S.; Bouchilloux, P.;
Strauss, M. 2004. Micropiezoelectric ultrasonic motors, J of
Electroceramics 13: 93-401. http://dx.doi.org/10.1007/s10832-004-5131-x.
[3.] Shigematsu, T.; Kurosawa, K.M.; Asai, K. 2003. Nanometer
stepping drives of surface acoustic wave motor, IEEE Transactions on
Ultrasonics, Ferroelectrics and Frequency Control 50 (4): 376-385.
http://dx.doi.org/10.1109/TUFFC.2003.1197960.
[4.] Flueckiger, M.; Fernandez, M.J.; Perriard, Y. 2010. Finite
element method based design and optimisation methodology for
piezoelectric ultrasonic motors, Mathematics and Computers in Simulation
81: 446-459. http://dx.doi.org/10.1016/j.matcom.2010.09.001.
[5.] Spanner, K. 2006. Survey of the various operating principles
of ultrasonic piezomotors, Proc. of the international conference
Actuator 2006.
[6.] Smith, L.G.; Rudya, Q.R.; Polcawich, G.R.; DeVoe, L.D. 2012.
Integrated thin-film piezoelectric traveling wave ultrasonic motors,
Sensors and Actuators A: Physical 188: 305-311.
http://dx.doi.org/doi:10.1016/j.sna.20n.12.029.
[7.] Uchino, K. 1998. Piezoelectric ultrasonic motors: overview,
Smart Material Structures 7: 273-285.
http://dx.doi.org/10.1088/0964-1726/7/3/002.
[8.] Xiaoyan, H.; Pueh, H.L.; Jin, C.O.; Piang, S.L. 2013.
Development and numerical characterization of a new standing wave
ultrasonic motor operating in the 30-40 kHz frequency range, Ultrasonics
53: 928-934. http://dx.doi.org/doi:10.1016/j.ultras.2012.10.016.
[9.] Ragulskis, M.K.; Bansevicius, R.; Barauskas, R.; Kulvietis, G.
1988. Vibromotors for Precision Microrobots, Hemisphere Publishing
Corporation, 310 p. http://dx.doi.org/10.1017/S026357470000624X.
I. Grybas *, A. Bubulis **, R. Bansevicius ***, V. Jurenas ****
* Kaunas University of Technology, Kestucio 27, 44025 Kaunas,
Lithuania, E-mail:
[email protected]
** Kaunas University of Technology, Kestucio 27, 44025 Kaunas,
Lithuania, E-mail:
[email protected]
*** Kaunas University of Technology, Kestucio 27, 44025 Kaunas,
Lithuania, E-mail:
[email protected]
**** Kaunas University of Technology, Kestucio 27, 44025 Kaunas,
Lithuania, E-mail:
[email protected]
cross ref http://dx.doi.Org/ 10.5755/j01.mech.20.6.8797