CN108448928A - A kind of more stacked piezoelectric actuator independence time-sharing driving devices and method - Google Patents

Abstract

The present invention provides a kind of more stacked piezoelectric actuator independence time-sharing driving devices and method, it is related to applying and is independently driven in precision displacement platform field, including each piezo-electric actuators；Drive signal according to etc. voltage spaces rule be separated into the connected subsignal of sequential；The signal being applied on each layer of separate piezoelectric actuator is the amplified subsignal of difference；Voltage at equal intervals by demultiplexing circuit realized by rule；Drive signal can be the signal of arbitrary needs.Piezo electric stack relative to the parallel connection of more stacked piezoelectric actuators, driving method shown in through the invention can effectively eliminate it due to sluggish cumulative caused by parallel drive, it is carved with when same and the presence of only piezo-electric actuators sluggishness, effectively reduce the sluggishness in more stacked piezoelectric actuator displacement process, motion positions precision is improved, while having the characteristics that easy to operate, cost is relatively low.

Description

A kind of more stacked piezoelectric actuator independence time-sharing driving devices and method

Technical field

The present invention relates to apply in precision micro-displacement platform field, and in particular to a kind of more stacked piezoelectric actuators independently divide When driving device and method, for by realizing that more stacked piezoelectric actuator independence timesharing drive, and then realizing that reduce displacement slow Stagnant method.

Background technology

In precision displacement platform field, it usually needs nano-precision.Piezoceramic material has small, resolution ratio The feature high, frequency response is fast, noise is low and bearing capacity is big.But piezoelectric ceramics itself has lagging characteristics and creep Characteristic etc., these characteristics can limit its precision when piezoelectric ceramics carries out accurate displacement, and wherein piezoelectric ceramics sluggishness is to precision It influences maximum.Therefore, how to improve or reduce the lagging characteristics of piezoelectric ceramics becomes the one extremely heavy of required solution at present The problem of wanting.

Currently, common hysteresis compensation method has charge driving instead of voltage driving method, the feed forward open loop control based on model Preparation method and the feedforward including PID complex controlls, self application complex controll, NN complex controlls and fuzzy compound controller and closed loop phase In conjunction with co-operated control etc..But all there is control complexity, the higher defects of cost for these methods.

Invention content

The present invention is that it is only to provide a kind of more stacked piezoelectric actuators to avoid above-mentioned existing deficiencies in the technology Vertical time-sharing driving device and method, to which effectively reducing more piezo electric stack driving processes, there are may be used also while braking problems To reduce cost.

To achieve the goals above, the technical solution adopted by the present invention is：

A kind of more stacked piezoelectric actuator independence time-sharing driving devices, the device working method are：Each piezo-electric actuators Independent driving；Drive signal according to etc. voltage spaces rule be separated into the connected subsignal of sequential；It is applied to each layer of independent pressure Signal on electric actuator is the amplified subsignal of difference；Voltage at equal intervals by demultiplexing circuit realized by rule；Driving Signal can be the signal of arbitrary needs.

The connected subsignal of the sequential, which is drive signal, passes through the sequential close alignment generated after demultiplexing circuit Drive signal.

The signal being applied on each layer of separate piezoelectric actuator is that each layer of piezo electric stack is all corresponding unique Amplified subsignal all the way.

Rule is by voltage according to piezoelectric actuator number of plies decile to the voltage at equal intervals.

The independent time-sharing driving device includes demultiplexing circuit, and demultiplexing circuit includes cut-point voltage electricity Road, four part of voltage comparator circuit, sampling hold circuit and subtraction circuit.

Be first delivered to after drive signal entering signal split circuit the roads n voltage compare on sampling hold circuit；Segmentation Drive signal amplitude was divided voltage by point potential circuit according to piezoelectricity number of plies n etc. minutes road output n；It is logical per voltage comparator circuit all the way It crosses and exports square wave control signal with the comparison of corresponding cut-point voltage；The control pair that sampling hold circuit passes through square wave control signal The drive signal of input carries out sampling holding；Output signal does subtraction with corresponding cut-point voltage by subtraction circuit and carries out signal Minimum voltage is zeroed and exports.

A kind of more stacked piezoelectric actuator independence timesharing driving methods, this method type of drive are：Each piezo-electric actuators Independent driving；Drive signal according to etc. voltage spaces rule be separated into the connected subsignal of sequential；It is applied to each layer of independent pressure Signal on electric actuator is the amplified subsignal of difference；Voltage at equal intervals by demultiplexing circuit realized by rule；Driving Signal can be the signal of arbitrary needs.

Its specific work process is：

Step 1, drive signal generate the separation subsignal of the amplitudes such as the roads n after demultiplexing circuit；

Step 2, the roads n separation subsignal carry out being coupled with n-layer piezoelectric actuator after accordingly amplifying by voltage amplifier On；

Step 3, when driving more stacked piezoelectric actuators, for boost process, add just to the 1st piezo-electric actuators first Voltage, as the 1st piezo-electric actuators of raising of voltage extend output displacement, the displacement of entire more stacked piezoelectric actuators increases Amount is the incremental displacement value of the 1st piezo-electric actuators, and the voltage on remaining piezo-electric actuators is 0 at this time；When the 1st lamination is electroluminescent When voltage on dynamic device reaches the maximum value of sequential 1, keep its voltage invariable in entire pressure process；The 2nd layer at this time Piezoelectric actuator starts plus positive voltage, with the raising of voltage, the elongation of the 2nd piezo-electric actuators and output displacement, and the 1st layer at this time Voltage on piezoelectric actuator remains unchanged, and the voltage of remaining piezo-electric actuators remains 0 constant, entire more stacked piezoelectrics causes The output displacement of dynamic device is the displacement of output displacement and 2nd piezo-electric actuators of the 1st piezo-electric actuators in maximum voltage The sum of incrementss are kept when voltage reaches the maximum value of sequential 2 on the 2nd piezo-electric actuators on the 2nd piezo-electric actuators Voltage remains unchanged in entire pressure process；The 3rd piezo-electric actuators start plus positive voltage at this time, with the raising the of voltage 3 piezo-electric actuators start output displacement, and the output displacement of entire more stacked piezoelectric actuators causes for layers 1 and 2 piezoelectricity Dynamic output displacement and 3rd piezo-electric actuators incremental displacement value the sum of of the device in maximum voltage, when on the 3rd piezo-electric actuators Voltage reach sequential 3 on maximum value when, keep the 1st piezo-electric actuators, the 2nd piezo-electric actuators and the 3rd lamination it is electroluminescent The voltage of dynamic device is constant, and remainder layer voltage is 0, and being then followed successively by follow-up piezoelectric actuator according to same manner pressurizes；Wherein, institute The sequential maximum voltage value stated is the maximum voltage value through the amplified constant amplitude subsignal of voltage amplifier；Signal sequence is wanted It asks and ensures relative time axis close alignment, is i.e. the n-th layer piezoelectric actuator when the (n-1)th piezo-electric actuators reach maximum voltage value Pressurization should be got started；

Step 4, for pressure reduction, first give n-th layer piezoelectric actuator be depressured, when voltage on n-th layer piezoelectric actuator When voltage is reduced to 0, gets started and be depressured to the (n-1)th piezo-electric actuators, when (n-1)th layer of voltage is reduced to 0, started to n-th -2 Then layer decompression is followed successively by follow-up piezoelectric actuator decompression until all piezoelectric actuated layer voltages are all 0 according to same manner.

Compared with the prior art, the present invention has the beneficial effect that：

1, as shown in figure 5, driving method shown in through the invention can effectively eliminate it since parallel drive causes Sluggishness it is cumulative, be carved with when same and the presence of only piezo-electric actuators sluggishness, effectively reduce more lamination pressures Sluggishness in electric actuator displacement process.

2, driving method shown in the present invention improves motion positions precision, while having easy to operate, the more low spy of cost Point.

Description of the drawings

Fig. 1 illustrates for whole control scheme of the present invention；

Fig. 2 is n stacked piezoelectric actuator piezo electric stack bonding modes；

Fig. 3 is n stacked piezoelectric actuator signal control sequential figures；

Fig. 4 is the structural schematic diagram of demultiplexing circuit；

Fig. 5 is result schematic diagram；

Fig. 6 is three stacked piezoelectric actuator independence timesharing drivings and parallel drive measurement result, wherein Fig. 6 (a) is to use The piezoelectric actuator hysteresis curve of parallel drive, Fig. 6 (b) are the piezoelectric actuator hysteresis curve using independent timesharing driving.

Specific implementation mode

Below in conjunction with the accompanying drawings and specific implementation mode further illustrates the present invention.

This example uses the triangular signal generated by signal generator as drive signal.Using n-layer piezoelectric actuator Head and the tail bonding is at structure shown in Fig. 2.Whole control scheme is attached according to scheme shown in Fig. 1.

As shown in Fig. 1,2,4, for more stacked piezoelectric actuator independence time-sharing driving devices, working method is：Driving Be first delivered to after signal entering signal split circuit the roads n voltage compare on sampling hold circuit.Cut-point potential circuit will Drive signal amplitude divides voltage according to piezoelectricity number of plies n etc. points of roads output n.Per voltage comparator circuit all the way by dividing with corresponding The comparison of point voltage exports square wave control signal.Sampling hold circuit believes the driving of input by the control of square wave control signal Number carry out sampling holding.Output signal does subtraction with corresponding cut-point voltage by subtraction circuit and carries out signal minimum voltage zero And it exports.

As shown in figure 3, for more stacked piezoelectric actuator independence timesharing driver' s timing control methods, the course of work is：

Step 1, drive signal generate the separation subsignal of the amplitudes such as the roads n, 3 left side of corresponding diagram after demultiplexing circuit N way signal timing diagrams.

Step 2, the roads n separation subsignal carry out being coupled with n-layer pressure after accordingly amplifying by voltage amplifier shown in FIG. 1 On electric actuator.

Step 3, when driving more stacked piezoelectric actuators, for boost process, add just to the 1st piezo-electric actuators first Voltage, as the 1st piezo-electric actuators of raising of voltage extend output displacement, the displacement of entire more stacked piezoelectric actuators increases Amount is the incremental displacement value of the 1st piezo-electric actuators, and the voltage on remaining piezo-electric actuators is 0 at this time；When the 1st lamination is electroluminescent When voltage on dynamic device reaches the maximum value of sequential 1, keep its voltage invariable in entire pressure process；The 2nd layer at this time Piezoelectric actuator starts plus positive voltage, with the raising of voltage, the elongation of the 2nd piezo-electric actuators and output displacement, and the 1st layer at this time Voltage on piezoelectric actuator remains unchanged, and the voltage of remaining piezo-electric actuators remains 0 constant, entire more stacked piezoelectrics causes The output displacement of dynamic device is the displacement of output displacement and 2nd piezo-electric actuators of the 1st piezo-electric actuators in maximum voltage The sum of incrementss are kept when voltage reaches the maximum value of sequential 2 on the 2nd piezo-electric actuators on the 2nd piezo-electric actuators Voltage remains unchanged in entire pressure process；The 3rd piezo-electric actuators start plus positive voltage at this time, with the raising the of voltage 3 piezo-electric actuators start output displacement, and the output displacement of entire more stacked piezoelectric actuators causes for layers 1 and 2 piezoelectricity Dynamic output displacement and 3rd piezo-electric actuators incremental displacement value the sum of of the device in maximum voltage, when on the 3rd piezo-electric actuators Voltage reach sequential 3 on maximum value when, keep the 1st piezo-electric actuators, the 2nd piezo-electric actuators and the 3rd lamination it is electroluminescent The voltage of dynamic device is constant, and remainder layer voltage is 0, and being then followed successively by follow-up piezoelectric actuator according to same manner pressurizes；Herein, The sequential maximum voltage value is the maximum voltage value through the amplified constant amplitude subsignal of voltage amplifier；For signal sequence It is required that ensureing relative time axis close alignment, i.e., when the (n-1)th piezo-electric actuators reach maximum voltage value, n-th layer is piezoelectric actuated Device should get started pressurization.

Step 4, as shown in Fig. 3 sequence diagrams, for pressure reduction, first give n-th layer piezoelectric actuator be depressured, work as n-th layer Piezoelectric actuator power on piezoelectricity pressure drop be 0 when, get started give the (n-1)th piezo-electric actuators decompression, when (n-1)th layer of voltage is reduced to When 0, start to be depressured to the n-th -2 layers, is then followed successively by follow-up piezoelectric actuator decompression until all piezoelectricity cause according to same manner Dynamic layer voltage is all 0.

One independent timesharing driving of embodiment and parallel drive sluggishness measure

Experiment uses piezoelectric actuator to be driven with three laminated piezoelectrics for the AL 1.65*1.65*5D-4F of Japanese NEC Corporation The triangular signal that dynamic signal amplitude is 0-6V is tested under unlike signal frequency.Independent timesharing is driven, according to Fig. 1 Shown structure connects experimental provision.0-6V triangular wave drive signals are input to independent time-sharing driving device (Signal separator electricity Road), the three way signals that amplitude is 0-2V will be automatically separated out by the circuit signal.Three way signals are passed through corresponding three Road voltage amplifier is output to after amplifying 45 times in corresponding piezo electric stack.For parallel drive, 0-6V triangular waves are driven and are believed It is connected in parallel to each lamination voltage input end after number directly amplifying 15 times.

When given driving signal frequency is 10Hz, experimental result is as shown in Figure 6.For the piezoelectric actuated of parallel drive Device, sluggishness be 1.1102 μm, and for using independent timesharing driving method piezoelectric actuator, sluggishness for 0.4617 μm compared with Parallel drive sluggishness reduces 58.4%.It follows that sluggishness can be eliminated compared with parallel drive using independent timesharing driving method It is cumulative, effectively reduce sluggishness when piezoelectric actuator back and forth movement.

The experimental results are shown inthe following table for remaining frequency：

Wherein, S₁Sluggishness when being driven using independent timesharing；S₂Sluggishness when for using parallel drive；K is sluggish reduces Value.

Claims (8)

1. a kind of more stacked piezoelectric actuator independence time-sharing driving devices, it is characterized in that：The device working method is：Each lamination electricity Actuator independently drives；Drive signal according to etc. voltage spaces rule be separated into the connected subsignal of sequential；It is applied to each layer Signal on separate piezoelectric actuator is the amplified subsignal of difference；Rule passes through demultiplexing circuit reality to voltage at equal intervals It is existing；Drive signal can be the signal of arbitrary needs.

2. a kind of more stacked piezoelectric actuator independence time-sharing driving devices according to claim 1, it is characterized in that：Described The connected subsignal of sequential is drive signal of the drive signal by the sequential close alignment generated after demultiplexing circuit.

3. a kind of more stacked piezoelectric actuator independence time-sharing driving devices according to claim 1, it is characterized in that：Described The signal being applied on each layer of separate piezoelectric actuator is all corresponding unique son amplified all the way of each layer of piezo electric stack Signal.

4. a kind of more stacked piezoelectric actuator independence time-sharing driving devices according to claim 1, it is characterized in that：Described Rule is by voltage according to piezoelectric actuator number of plies decile to voltage at equal intervals.

5. a kind of more stacked piezoelectric actuator independence time-sharing driving devices according to claim 1, it is characterized in that：Described Independent time-sharing driving device includes demultiplexing circuit, demultiplexing circuit include cut-point potential circuit, voltage comparator circuit, Four part of sampling hold circuit and subtraction circuit.

6. a kind of more stacked piezoelectric actuator independence time-sharing driving devices according to claim 5, it is characterized in that：Driving letter Be first delivered to after number entering signal split circuit the roads n voltage compare on sampling hold circuit；Cut-point potential circuit will drive Dynamic signal amplitude divides voltage according to piezoelectricity number of plies n etc. points of roads output n；Per voltage comparator circuit all the way by with corresponding cut-point The comparison of voltage exports square wave control signal；Sampling hold circuit is by the control of square wave control signal to the drive signal of input Carry out sampling holding；Output signal does subtraction with corresponding cut-point voltage by subtraction circuit and carries out signal minimum voltage zero simultaneously Output.

7. a kind of more stacked piezoelectric actuator independence timesharing driving methods, it is characterized in that：This method type of drive is：Each lamination electricity Actuator independently drives；Drive signal according to etc. voltage spaces rule be separated into the connected subsignal of sequential；It is applied to each layer Signal on separate piezoelectric actuator is the amplified subsignal of difference；Rule passes through demultiplexing circuit reality to voltage at equal intervals It is existing；Drive signal can be the signal of arbitrary needs.

8. a kind of more stacked piezoelectric actuator independence timesharing driving methods according to claim 7, it is characterized in that：It is specific The course of work is：

Step 1, drive signal generate the separation subsignal of the amplitudes such as the roads n after demultiplexing circuit；

Step 2, the roads n separation subsignal by voltage amplifier be coupled on n-layer piezoelectric actuator after accordingly amplifying；

Step 3, when driving more stacked piezoelectric actuators, for boost process, add positive electricity to the 1st piezo-electric actuators first Pressure, as the 1st piezo-electric actuators of raising of voltage extend output displacement, the incremental displacement value of entire more stacked piezoelectric actuators For the incremental displacement value of the 1st piezo-electric actuators, the voltage on remaining piezo-electric actuators is 0 at this time；When the 1st lamination electric actuation When voltage on device reaches the maximum value of sequential 1, keep its voltage invariable in entire pressure process；2nd lamination at this time Electric actuator starts plus positive voltage, with the raising of voltage, the elongation of the 2nd piezo-electric actuators and output displacement, and the 1st lamination at this time Voltage on electric actuator remains unchanged, and the voltage of remaining piezo-electric actuators remains 0 constant, entire more stacked piezoelectric actuatings The output displacement of device is that the displacement of output displacement and 2nd piezo-electric actuators of the 1st piezo-electric actuators in maximum voltage increases The sum of dosage keeps the electricity on the 2nd piezo-electric actuators when voltage reaches the maximum value of sequential 2 on the 2nd piezo-electric actuators It is pressed in entire pressure process and remains unchanged；The 3rd piezo-electric actuators start to add positive voltage at this time, with the raising the 3rd of voltage Piezo-electric actuators start output displacement, and the output displacement of entire more stacked piezoelectric actuators is that layers 1 and 2 is piezoelectric actuated Output displacement and 3rd piezo-electric actuators incremental displacement value the sum of of the device in maximum voltage, when on the 3rd piezo-electric actuators When voltage reaches the maximum value in sequential 3, the 1st piezo-electric actuators, the 2nd piezo-electric actuators and the 3rd lamination electric actuation are kept The voltage of device is constant, and remainder layer voltage is 0, and being then followed successively by follow-up piezoelectric actuator according to same manner pressurizes；Wherein, described Sequential maximum voltage value be the maximum voltage value through the amplified constant amplitude subsignal of voltage amplifier；For signal sequence requirement Ensure relative time axis close alignment, i.e., n-th layer piezoelectric actuator is answered when the (n-1)th piezo-electric actuators reach maximum voltage value Get started pressurization；

Step 4, for pressure reduction, first give n-th layer piezoelectric actuator be depressured, when voltage on n-th layer piezoelectric actuator It when being reduced to 0, gets started and is depressured to the (n-1)th piezo-electric actuators, when (n-1)th layer of voltage is reduced to 0, start to drop to the n-th -2 layers Then pressure is followed successively by follow-up piezoelectric actuator decompression until all piezoelectric actuated layer voltages are all 0 according to same manner.