Analysis of cylindrical piezoelectric actuator used in flow control device/Cilindrinio pjezoelektrinio vykdiklio, naudojamo srautu valdymo irenginyje, tyrimas.
Bansevicius, R. ; Rimasauskiene, R. ; Mazeika, D. 等
1. Introduction
Piezoelectric actuators are widely used for high precision
mechanical systems such as positioning devices, manipulating systems,
control or flow control equipment and etc [1 - 3]. Piezoelectric
actuators have advanced features such as high resolution, short response
time, compact size, and good controllability [1, 2, 4]. Many design
principles of piezoelectric actuators are proposed and used [5].
Summarizing its all the following types of piezoelectric actuators can
be specified: traveling wave, standing wave, hybrid transducer, and
multimode vibrations actuators [2, 6].
Demand of new displacement transducers that can achieve high
resolution and accuracy of the driving object increases in nowadays.
Piezoelectric actuators have advanced features compare to others and are
widely used for different commercial applications [1, 6]. A lot of
design and operating principles are investigated to transform mechanical
vibrations of piezoceramic elements into elliptical movement of the
contact zone of actuator [2, 4, 7]. However summarizing its all the
following types of piezoelectric actuators can be specified - traveling
wave, standing wave, hybrid transducer, and multivibration mode [5, 8].
Traveling wave piezoelectric actuators fall under two types - rotary and
linear. Rotary type actuators are one of the most popular because of
high torque density at low speed, high holding torque, quick response
and simple construction. Linear type traveling wave actuators feature
these advantages as well but development of these actuators is complex
problem [9]. Usually elastic beam is used as the main part of linear
traveling wave actuator design and traveling wave oscillations are
generated on it [5, 6].
Traveling wave piezoelectric actuator which type is rotary is
studied numerically and experimentally in this paper. This acting method
of the actuator allows using it in the flow control systems.
[FIGURE 1 OMITTED]
2. Design of flow control device
The flow control device construction, which is analyzed in the
paper, in practice can be adapted in various areas: in the laser beam,
gas, liquid or light flow control systems. The scheme of this flow
control device presented in Fig. 1 has been developed and patented [10]
at Kaunas University of Technology.
The flow control device consist of cylindrical body 1 , mounting
ring 2 is rigidly entrenched in it. This ring 2 is used like a support
of piezoceramic actuator (cylinder) 3. On the piezoceramic actuator 3 is
loaded mounting ring 4 of the plate with a pad. The plate 5 with
micropores or notches is glued on the mounting ring 4. Another mounting
ring 7 is threaded and plate 6 is rigidly entrenched on it, then both of
them are screwed on the cylindrical body 1. A center tab 8 fastened on
cross-plates, and their mutual compression is adjusted on mounting ring
7 threaded support. From the plates (with micropores or notches) 5 and 6
is formed the flow permeability regulating membrane.
The principle of operation can be explained as follow. Traveling
deformation waves are generated on piezoceramic actuator (cylinder) 3
and mounting ring 4 with glued plate 5 in contact with the actuators
output link can be rotated by the clockwise direction or against it.
During the initial operation at the time of the plate 5 and 6 is
geometrically adjusted so that the adjacent micropores or notches do not
overlap and flow control membrane permeability would be minimal or zero.
Optical moire interference pattern is generated as the geometric
location of the adjacent micropores or notches of the two plates change
when one of the plates rotates. This interference effect alters the flow
permeability. When piezoceramic actuator gets signal, it generates
traveling deformation waves and optical Moire interference pattern is
generated between two plates 5 and 6.
In cases where the membranes are made up of plates of round or
hexagonal micropores contained in a regular rectangular or shifted array
of nodes, permeability is maximized when the optical Moire interference
generated and overlaps of the micropores in Moire circles is the
greatest possible amount. This may be precisely and quickly heated
liquids or gases microflow control. This device can be applied to drug
dosing, and others.
3. Design and operating principle of piezoelectric actuator
Sinusoidal voltage with the phase shift by n/3 is applied on each
piezoceramic element.
[FIGURE 2 OMITTED]
Operating principle of the actuator is based on the modified first
way described in Section 1 of this paper. Travelling wave is generated
in the upside beam when mechanical harmonic forces from piezoceramic
plates are applied and actuator starts to vibrate. Excitation frequency
near 4th flexural mode of upside beam is used. Due to height difference
between up and down sides, the downside beam oscillates on 2nd flexural
mode at the same frequency (Fig. 2, b). Phase difference between
oscillations of the ends of upside and downside beams appears when
excitation frequency is close to resonance. Therefore one end of the
upside beam is excited while another is damped and travelling wave
oscillations without reflection are obtained. Travelling wave motion is
illustrated at four points in time during the vibration period of the
actuator (Fig. 3).
[FIGURE 3 OMITTED]
4. Results of numerical modeling
Numerical modeling of piezoelectric actuator was performed to
validate actuator design and operating principle through the modal and
harmonic response analysis. FEM software ANSYS 10.0 was employed for
simulation. FEM model (Fig. 4) was built and the following materials
were used for actuator modeling: bronze was used for the oscillator and
piezoceramic PZT-8 was used for piezoelements.
Modal analysis of piezoelectric actuator was performed to find
proper resonance frequency. Material damping was assumed in the finite
element model. No structural boundary conditions were applied. Examining
results of modal analysis it was determined that vibration mode No. 71
(61 kHz) is exploitable for further investigation.
[FIGURE 4 OMITTED]
Harmonic response analysis was performed with the aims to find out
the actuator's response to sinusoidal voltage applied on electrodes
of the piezoceramic elements, to verify the operating principle.
Analyzing oscillation characteristics travelling wave vibrations on the
upside cylinder of the actuator will be manifested. Excitation scheme of
the electrodes was used as shown in Fig. 2, b. A 60 V AC signal was
applied. A frequency range from 50 to 70 kHz with a solution at 0.25 kHz
intervals was chosen and adequate response curves of upper points'
oscillation amplitudes and components were calculated.
Graphs of oscillation amplitudes of the upper contact points
indicate that resonant oscillations are obtained at 61 kHz. Fig. 5
illustrates global displacements and their components of upper points of
the cylinder.
[FIGURE 5 OMITTED]
5. Experimental study of cylindrical actuators' dynamic
characteristics
Experiments were carried out to find voltage and frequency, which
will let to achieve the largest output link's shift of
piezoelectric actuators (cylinder) and validate results of numerical
simulation.
[FIGURE 6 OMITTED]
In order to determine these parameters were carried out experiments
by using an experimental stand (Fig. 6), which consists of a
programmable signal generator (Aligent 33220, 20 MHz), high voltage
amplifier (1 150 kHz frequency zone), multimeter (Mastech 8218), laser
doppler vibrometer PolytecTM ([V.sub.max] = 10 m/s, frequency zone 0.5
Hz - 1.5 MHz; resolution from 0.1 to 2.5 (mm/s)/[square root of Hz]),
analog capture card (National Instruments PCI 5102, 20 MS/s) and a
computer with installed with LabView software.
[FIGURE 7 OMITTED]
For the collection and processing of measurement data a specific
program in LabView graphical programming environment was designed
allowing to receive the amplitude frequency characteristics of the
experimental output link.
Using laser vibrometer PolytecTM and computer with specially made
LabView program the dependence of shift on frequency was found. During
experimental the excitation voltage 10 V was kept constant, the
frequency was variable and the shift of piezoelectric actuator's
output link was measured.
From the dependence (Fig. 7) can be seen that the greatest
displacement improvement is achieved when the frequency is resonant
(61.83 kHz).
Once the main resonant frequency is obtained then the maximum
displacement of the excitation voltage is 10 V, the displacement
dependence on excitation voltage can be determined. In the graphic shown
in Fig. 8 can be seen the dependence of the displacement on excitation
voltage when the resonant frequency is 61.83 kHz.
[FIGURE 8 OMITTED]
From the theory is known that the best mechanical and piezoelectric
properties of piezo ceramics are kept when it is working up to
60[degrees]C. Therefore, the experiment was continued by keeping the
excitation voltage at 56 V.
From the dependence (Fig. 8) it can be seen that while the
excitation voltage is 56 V the maximum displacement can be obtained. It
means that using this voltage the actuator's output link performs
the necessary shift in the shortest period of time and turns the steel
ring with the plate. Therefore, further experiments have been carried
out at such an excitation voltage.
[FIGURE 9 OMITTED]
During the experiment with a laser thermometer "Testing
825" the temperature of the output link in piezoelectric actuator
(cylinder) was measured. In the dependence (Fig. 9) can be seen that the
piezoelectric actuators (cylinder form) begins to operate when it's
first resonant frequency, which gives the maximum output of the link
shift (700 nm), is 62.34 kHz. Then the experimental stand was readjusted
and found the new frequency (62.2 kHz) at which the displacement of the
output link rose again to 700 nm. In this case the five frequencies at
which the maximum displacement is obtained at that temperature were
found.
From the shift dependence of the temperature (Fig. 9), it can be
seen that the maximum output displacement of the link is obtained about
800 nm, when the frequency is 61.83 kHz. This frequency is the most
appropriate for the actuator of flow control device and further
experiments were carried out at this frequency.
From the dependence (Fig. 9) it can be seen that after a certain
period of time the output link of piezoelectric actuators, which is
working at specific resonance mode, is reached a temperature of
48[degrees]C and then the temperature is raising slowly. According to
the characteristics of piezo ceramics it is known that it can operate at
such temperatures. Therefore, in this case the frequency of 61.83 kHz is
a suitable operating frequency.
Dependence of the experimental excitation frequency on temperature
is shown Fig. 10. After completing the experiment, it can be said that
with rising the temperature the excitation frequency is decreasing.
[FIGURE 10 OMITTED]
Using the same experimental stand (Fig. 6) the resolution of the
flow control device with piezoelectric actuators (cylinder shape) was
found. Displacements of the reference point were measured in the
following way: on an output link of piezoelectric cylinder was fitted a
steel ring, in which a plate with micropores was fixed tightly. The some
piece was fixed on steel ring as the starting point. The measurement
data was collected and processed by LabView graphical programming
environment with specifically designed program, which allows to receive
the experimental characteristics of the reading point's amplitude.
After the experiment, the shifts of reading point have been converted
into the angular degrees of shift.
[FIGURE 11 OMITTED]
For resolution investigation of the flow control device the
package, which contains some number of periods of harmonic signal
([U.sub.RMS] = 56 V, f = 61.83 kHz) was used. Shift dependence on
harmonic number of signal cycles package is presented in Fig. 11.
The rotor starts to rotate after forming two harmonic signals whose
amplitude [U.sub.RMS] = 56 V and frequency f = 61.83 kHz for periods of
package, the transition process ended after 12 ms from the end of the
excitation package. After recalculating the displacement in turn a
resolution of 0027' was received.
7. Conclusions
The construction of flow control device in which can be reached the
light, gas or fluid flow throughput and high accuracy by the aid of the
positioning of piezo actuator and moire effect properties of membrane
was designed and presented in this paper.
Selection of electrode configuration and the result of numerical
simulation showed that the piezoceramic cylinder output link formed
unsymmetrical running-wave type of oscillation with different excitation
frequencies. The best operating frequency (61 kHz) was found by finite
element method. Theoretical simulation results were validated by
experiments.
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Received February 15, 2011 Accepted June 30, 2011
R. Bansevicius, Kaunas University of Technology, K. Donelaicio 73,
44029 Kaunas, Lithuania, E- mail:
[email protected]
R. Rimasauskiene, Kaunas University of Technology, K. Donelaicio
73, 44029 Kaunas, Lithuania, E-mail:
[email protected]
D. Mazeika, Vilnius Gediminas Technical University, Sauletekio al.
11, Vilnius, 10223, Lithuania, E-mail:
[email protected]
G. Kulvietis, Vilnius Gediminas Technical University, Sauletekio
al. 11, Vilnius, 10223, Lithuania, E-mail:
[email protected]