CN209731109U - piezoelectric ceramic displacement driver - Google Patents

Abstract

The utility model discloses a piezoceramics displacement driver, including crooked displacement stack and swing arm. The bending displacement stack is formed by stacking a plurality of piezoelectric ceramic pieces or directly manufactured by a multilayer co-firing process, and the surfaces of the piezoelectric ceramic pieces are covered with spaced electrode layers so as to form a first group of electrode layers and a second group of electrode layers. And a swing arm is used to amplify the amount of displacement of the bending displacement stack. The utility model discloses a piezoceramics displacement driver has higher displacement precision, can accomplish stronger drive power and lower driving voltage to and better environmental characteristic and life.

Description

Piezoelectric ceramics displacement driver

Technical field

The utility model relates to integrated circuit equipment manufacturing fields, more particularly relate to a kind of high-precision piezoelectric ceramics position Move driver.

Background technique

In recent years, as LSI devices integrated level is continuously improved, the accuracy requirement of work stage is continuously improved, The kinematic accuracy of the modules such as the regulation of microscope carrier and object lens especially in litho machine and film thickness detection, movement travel is with work The raising of part platform demand and rise year by year.Displacement drive technology is also constantly being improved, and piezoelectric micro-displacement actuator is obtained To a large amount of application.At this stage, main mode has in precision actuation: mechanical lead screw, linear motor and piezoelectric ceramic actuator Device, and in nanoscale displacement drive it is mainly piezoelectric ceramics displacement driver.In the prior art, piezoelectric ceramics displacement drive The drive mode of device mainly include the following types:

(1), it is displaced the combination stacked using multiple thickness, forms pressurization and drive actions to mover, structure is complicated, makes High price is expensive, complex manufacturing technology, it is not easy to be commercialized.

(2), using interior segmentation electrode is individually stacked, the left and right electrode individually stacked is separately added into sin (wt) and COS (wt) electric field, swings piezoelectric ceramics, forms the driving force of continuous mover by multiple piezoelectric elements, enables mover Continuous quickly movement, this structure is complicated and stacks flatness requirement height, and non-displacement precision to multiple.

(3), the combination stacked with tangential displacement is stacked using four groups of thickness displacements drive central axis stepwise motion, it is this It stacks on the make tangential piezoelectric and stacks complex process in the production process, and organic colloid is needed to be bonded, it cannot be with altogether Firing technique is realized, due to the presence of organic colloid, makes piezoelectric ceramics displacement driver in anti-time aging and compared with severe temperatures Under light environment, it is easy to fail.

(4), mover being driven using double wafer structure flexural oscillations, structure is simple but in ceramic thickness thickness, Need very high voltage that could drive, and when tile thickness is thin, driving force is weak, and since internal stress is big, it is easy to be broken tile, Keep service life in practical application shorter.

Utility model content

The purpose of the utility model is to provide a kind of piezoelectric ceramics displacement drivers, to solve above-mentioned exist in the prior art The problem of.

To solve the above-mentioned problems, one aspect according to the present utility model provides a kind of piezoelectric ceramics displacement drive Device, the mover for driving motor move, and the piezoelectric ceramics displacement driver includes that bending displacement stacks and swing arm, described curved Qu Weiyi is stacked to be stacked by multiple piezoelectric ceramic pieces and be formed, and is also possible to cofiring and is formed, wherein the pressure that the bending displacement stacks The surface covering of electroceramics piece electrode layer spaced apart to form first group of electrode layer and second group of electrode layer,

It is first powered on to first group of electrode layer when operation, the bending displacement is made to stack the bending to form certain angle, Then it is powered on again to second group of electrode layer, the bending displacement is made to stack recovery vertical state, then by first group of electrode layer Or the voltage drop of second group of electrode layer makes the bending displacement stack the bending for forming certain angle again down to zero, from And makes mover reciprocally swinging or be used to amplify the displacement that the bending displacement stacks to same direction movement and the swing arm Amount.

In one embodiment, the piezoelectric ceramics displacement driver further includes that thickness displacement stacks, the thickness displacement It stacks to be stacked by multiple piezoelectric ceramic pieces and be formed, the surface for the piezoelectric ceramic piece that the thickness displacement stacks covers full electrode layer.

In one embodiment, one end of the swing arm contacts and the other end of the swing arm and institute with the mover State that bending displacement stacks or thickness displacement stacks contact, the thickness is displaced and stacks for making the mover not acted when institute The separation of swing arm Yu the mover is stated, and in the mover when being acted, so that the swing arm is contacted and is applied with the mover Add certain pressure.

In one embodiment, one end connection bending displacement that the thickness displacement stacks stacks and the thickness The other end that degree displacement stacks connects the swing arm.

In one embodiment, the bending displacement stacks one end connects the thickness displacement and stacks and described curved The other end that Qu Weiyi is stacked connects the swing arm.

In one embodiment, one end connection thickness displacement of the swing arm stacks and the other end of the swing arm connects The bending displacement is connect to stack.

In one embodiment, the piezoelectric ceramics displacement driver includes that multiple bending displacements stack and/or more A thickness displacement stacks.

In one embodiment, thickness displacement stacks that stack with the bending displacement be that cofiring stacks and/or institute State thickness displacement stack stacked with the bending displacement be organic adhesion agent bonding stack and/or the thickness displacement stack and It is stacking for glass paste sintering process formation that the bending displacement, which stacks,.

In one embodiment, the connection that the thickness displacement stacks, bending displacement stacks between swing arm is that cofiring connects Connect, and/or Organic adhesive bonding connection, and/or glass paste sintering process connection.

In one embodiment, the cross sectional shape of the swing arm is rectangle, triangle, hemispherical, the shape of falling T and/or described The bottom surface of swing arm is rectangular and top is arc-shaped, hemispherical and/or inverted T-shaped；

In one embodiment, the electrode layer that the thickness displacement stacks is the edge of complete electrode or the electrode layer Apart from ceramic edge spacing between 0-1mm；

In one embodiment, the electrode layer that the bending displacement stacks is two parts or multiple portions by separating Divide electrode composition, wherein in two parts electrode apart from gap between 0.1mm-2mm；

In one embodiment, the section side size range of the piezoelectric ceramics displacement driver is between 1mm-50mm；

In one embodiment, the height that the thickness displacement stacks is between 0.1mm-100mm；

In one embodiment, the height that the bending stacks can be between 0.1mm-100mm；

In one embodiment, the height of the swing arm is between 0.1mm-100mm.

The piezoelectric ceramics displacement driver of the utility model can externally export tangential active force and tangential displacement, Displacement and the active force of the more a freedom degrees of X, Y, Z can also be provided, and can be made up of a molding production method of cofiring. Compared with existing piezoelectric ceramic actuator, the utility model has higher displacement progress, can accomplish stronger driving force and Lower driving voltage, and preferably environmental characteristics and service life.

Detailed description of the invention

Fig. 1 is the piezoelectric ceramics displacement driver schematic cross-section of an embodiment of the present invention.

Fig. 2 a-d is the schematic diagram for showing the movement of piezoelectric ceramics displacement driver of Fig. 1.

Fig. 3 a-d is that the electrode layer polarization direction of the piezoelectric ceramics displacement driver of Fig. 1 and electric field apply status diagram.

Fig. 4 is the structural schematic diagram of the piezoelectric ceramics displacement driver of an embodiment of the present invention.

Fig. 5 is the structural schematic diagram of the piezoelectric ceramics displacement driver of an embodiment of the present invention.

Fig. 6 is the electrode structure schematic diagram that the bending displacement of an embodiment of the present invention stacks.

Fig. 7 is the structural schematic diagram of the piezoelectric ceramics displacement driver of an embodiment of the present invention.

Fig. 8 is the structural schematic diagram of the piezoelectric ceramics displacement driver of an embodiment of the present invention.

Specific embodiment

The preferred embodiment of the utility model is described in detail below with reference to attached drawing, to be clearer to understand this reality With novel objects, features and advantages.It should be understood that embodiment shown in the drawings is not the limit to the scope of the utility model System, and simply to illustrate that the connotation of technical solutions of the utility model.

In the following description, elaborate certain details to provide for the purpose for illustrating various disclosed embodiments To the thorough understanding of various open embodiments.But it one skilled in the relevant art will recognize that can be in without these details One or more details the case where get off to practice embodiment.Under other circumstances, well known device associated with this application, Structure and technology may not be illustrated in detail or describe to avoid unnecessarily obscuring the description of embodiment.

Expression is in conjunction with the embodiments described to be referred to " one embodiment " or " embodiment " throughout the specification Certain features, structure or feature are included at least one embodiment.Therefore, in each position of the whole instruction " at one In embodiment " or " in an embodiment " in appearance without all referring to identical embodiment.In addition, certain features, structure or feature It can combine in any way in one or more embodiments.

In the following description, the structure and working method of the utility model in order to clearly demonstrate, will be by all multidirectionals Word is described, but should be by "front", "rear", "left", "right", "outside", "inner", " outside ", " inside ", "upper", "lower" Equal Word Understandings are not construed as word of limitation for convenience of term.

The High Precision Piezoelectric Ceramic displacement driver of the utility model include bending displacement stack with two modules of swing arm, it is curved Qu Weiyi is stacked to be stacked by multiple piezoelectric ceramic pieces and be formed, and the surface for the piezoelectric ceramic piece that these bending displacements stack covers interval To form first group of electrode layer and second group of electrode layer, when operation, is first powered on to first group of electrode layer for the electrode layer opened, So that bending displacement is stacked the bending to form certain angle, is then powered on again to second group of electrode layer, bending displacement is made to stack recovery Vertical state, then stack the bending displacement again down to zero the voltage drop of first group of electrode layer or second group of electrode layer The bending of certain angle is formed, thus make mover reciprocally swinging or mobile to same direction, and swing arm is for amplifying bending displacement The displacement stacked.

In another embodiment, High Precision Piezoelectric Ceramic displacement driver includes that thickness displacement stacks, bending displacement is folded Three modules of heap and swing arm.It is stacking for full electrode that thickness displacement, which stacks as ceramic surface, and bending displacement stacks single layer tile table Face electrode is segmentation electrode form, first not powered on one side, and in addition one side electrode power-up, makes to stack to form the curved of certain angle Song, stacking for being then in addition not powered on are begun to power up, to stack both sides displacement it is consistent when, stack and be returned to plumbness, then will The voltage drop on one side makes to stack continuation in addition swinging on one side down to zero, thus reach to form certain tangential displacement in purpose, In this motion process, thickness displacement stacks and swing arm can be made to separate when not acted with mover, and is being moved When making, contacts swing arm with mover and apply certain pressure；Simultaneously during the swing as needed, thickness displacement stacks position Move the displacement fluctuation that can balance vertical direction；And swing arm is used for displacement enlargement amount.

On specific structure, this piezoelectric ceramics displacement driver structure can be thickness displacement stack both ends be separately connected it is curved Qu Weiyi is stacked and swing arm, is also possible to bending displacement and stacks both ends and be separately connected thickness displacement stack and swing arm, be also possible to Swing arm both ends are separately connected thickness displacement and stack and stack with bending displacement, are also possible to that direct bending displacement stacks and swing arm connects Connect, be also possible to bending displacement stack with thickness displacement stack connection；There can also be multiple bending displacement to stack and thickness position Move the connection stacked with swing arm.

The displacement of this piezoelectric ceramics displacement driver structural thickness, which stacks to stack with bending displacement, can be cofiring and stacks, can also Be organic adhesion agent bonding stack, be also possible to glass paste sintering process formation stack and thickness displacement stack, be curved Qu Weiyi, which stacks the connection between swing arm, can be the connection of cofiring, be also possible to Organic adhesive bonding connection, can also be with It is the connection of glass paste sintering process.

The shape of swing arm can be rectangular, can be triangle, can be that bottom surface is rectangular and top be it is arc-shaped, It can be hemispheric, can be inverted T-shaped.

This piezoelectric ceramics displacement driver thickness displacement stack, bending displacement stacks, the section of swing arm can be it is rectangular Be also possible to rectangular, be also possible to circular, be also possible to annulus shape.

The electrode that the displacement of this piezoelectric ceramics displacement driver thickness stacks can be complete electrode, be also possible to electrode side For edge apart from ceramic edge spacing 0-1mm, the interior electrode that bending displacement stacks is the segmentation electrode group by two parts or multiple portions At, in two parts electrode apart from gap between 0.1mm-2mm.

In one embodiment, the section side size range of entire piezoelectric ceramics displacement driver is in 1mm-50mm, thickness position Shifting stacks height can be between 0.1mm-100mm, and being bent the height stacked can be between 0.1mm-100mm, swing arm Height can be between 0.1mm-100mm.

Some embodiments of the utility model is described in detail in 1-8 with reference to the accompanying drawings.

Fig. 1 is the high-precision piezoelectric ceramics displacement driver schematic cross-section of the utility model first embodiment.Fig. 2 a- D shows the schematic diagram of the movement of the piezoelectric ceramics displacement driver of Fig. 1, and Fig. 3 a-d is the piezoelectric ceramics displacement driver of Fig. 1 Electrode layer polarization direction and electric field apply status diagram.As shown in Fig. 1-3, piezoelectric ceramics displacement driver includes thickness position Shifting stacks 101, bending displacement and stacks 102, swing arm 103.Wherein thickness displacement stacks 101 connection pedestals 30, the contact of swing arm 103 is moved Son 20.Wherein thickness displacement stacks 101 and covers complete 107 groups of electrode layer by 10 layers of 106 top and bottom of 0.5mm thickness piezoelectric potsherd It closes, the polarization direction of adjacent two panels piezoelectric ceramic piece 106 is on the contrary, as illustrated in figs. 3 a-3d.

Bending displacement stacks 102 and is formed by 10 layers with a thickness of the stacking of 0.5mm piezoelectric ceramic piece 106, and upper and lower surface is covered respectively Segmentation electrode 108a and 108b composition, with the polarization direction phase of two parts electrode 108a and 108b of a piece of piezoelectric ceramic piece Together, the polarization direction of adjacent two panels piezoelectric ceramics between segmentation electrode 108a and 108b on the contrary, as illustrated in figs. 3 a-3d, have certain Gap, which for example can be 1mm.103 bottom surface of swing arm is square, and the height of side length 10mm, swing arm 103 are 5arctan60°。

In the first embodiment of the utility model, original state is as shown in Figure 2 a, piezoelectric ceramics displacement driver and bottom Seat 30 connects, and 103 end face of swing arm and mover 20 are distance away, about 5um；Thickness displacement stacks 101 and bending position Shifting stacks 102 and does not apply electric field；Second step, the part electrode 108a for stacking 102 to bending displacement apply electric field E, make porcelain Piece the degree of bending reaches maximum, then stacks 101 application electric field E to thickness displacement, and the endpoint of swing arm 103 is made to contact mover 20 simultaneously Apply certain pressure, as shown in Figure 2 b；Third step, the part electrode 108b for stacking 102 to bending displacement apply electric field E, directly Consistent to the electric field applied with the part 108a, driving swing arm 103 is returned to middle position, while pushing mover 20 is past to move right, Thickness displacement stacks 101 application electric field E, the pressure for keeping swing arm 103 to apply mover 20, as shown in Figure 2 c；4th step reduces The electric field applied to electrode 108a, makes bending displacement stack 102 swings bending to the right, and mover 20 is pushed to continue to move right, thick Degree displacement folded 101 applies electric field, the pressure for keeping swing arm to apply mover, as shown in Figure 2 d；5th step, removal are applied to thickness Displacement stacks the electric field on 101, makes the disengaging of swing arm 103 and the contact of mover 20, then removal is applied to bending displacement and stacks Electric field on 102 makes piezoelectric ceramics displacement driver finally be returned to original state as shown in Figure 2 a.

In the first embodiment, can achieve full swing displacement size by piezoelectric ceramics performance characteristics and swing arm Displacement equations multiplying power determine that in the present embodiment, the displacement that piezoelectric ceramics can achieve is the 0.1% of tile height, pendulum The enlargement ratio of arm is 1 times, is determined by the maximum voltage being applied on electrode 106；Half maximum displacement swung in this example Amount is 5um, and the maximum displacement swung entirely is 10um.

In the present embodiment, it is 4000 Ns that thickness displacement, which stacks the maximum thrust that can be provided, and bending displacement stacks most High thrust is 1800 Ns, so the maximum driving force that this piezoelectric ceramics displacement driver can export is no more than 1800 Ns；It is practical The swing arm that driving force depends on the confficient of static friction of the contact surface of mover and swing arm and thickness displacement stacks driving hangs down to mover Histogram to thrust product, the available maximum thrust of this example be 800 Ns.

Fig. 4 is the structural schematic diagram of the piezoelectric ceramics displacement driver of the utility model second embodiment, as shown in Fig. 2, The piezoelectric ceramics displacement driver of the present embodiment include bending displacement stack 102, thickness displacement stack 101 and swing arm 103, In, bending displacement stacks 102 one end connection pedestal 30, and the other end that bending displacement stacks 102 is connected to thickness displacement and stacks 101, thickness displacement stacks 101 reconnection swing arms 103.The height that bending displacement stacks is 6mm, and the height that thickness displacement stacks is 10mm, the height of swing arm are 2mm, stack formed bending displacement stack 102 and thickness displacement to stack 101 tile section be side length For the square of 10mm.Since bending displacement stacks 102 in movement, thickness displacement stacks 101 effects for being also rendered as swing arm, Make 1.3 times of the swing displacement equations multiplying power of the utility model, so the single step of the piezoelectric ceramics displacement driver of the present embodiment Maximum drive displacement is 13um.

The difference of the present embodiment and first embodiment is that bending displacement is stacked and is displaced the position stacked with thickness, and first is real Apply bending displacement in example stack positioned at thickness displacement stack between arm of flapping, and be in second embodiment thickness displacement stack position It is stacked between swing arm in bending displacement, specific bending displacement stacks 102 and thickness displacement stacks 101 structure and first real The identical of example is applied, details are not described herein again.

Fig. 5 is the structural schematic diagram of the piezoelectric ceramics displacement driver of the utility model 3rd embodiment, and Fig. 6 is Fig. 5 The electrode structure schematic diagram for the electrode layer that bending displacement stacks.As seen in figs. 5-6, in the present embodiment, piezoelectric ceramics displacement is driven Dynamic device still includes that thickness displacement stacks 101, bending displacement and stacks 102 and swing arm 104.Wherein thickness displacement stacks 101 use Mover is contacted in connection pedestal, swing arm 104.In embodiment, the structure of electrode layer it is not but mainly, as shown in fig. 6, electrode Layer includes electrode layer 109a, 109b, 109c and 109d spaced apart.Electrode layer 109a, 109b, 109c and 109d are fan-shaped knot Structure, each electrode are spaced apart with another electrode.

When operation, bending displacement stacks can be by applying positive displacement electric field to electrode layer 109a and 109d, and to electrode Layer 109b and 109c does not apply electric field then or applies the electric field of opposite direction, to make to stack the swing to form left direction；Or By applying positive displacement electric field to electrode layer 109b and 109c, and electric field is not applied to electrode layer 109a and 109d or is applied opposite The electric field in direction, to form the swing of right direction；Or by applying positive displacement electric field to electrode layer 109a and 109b, and it is right Electrode layer 109c and 109d do not apply electric field or apply the electric field of opposite direction, to make to stack to be formed backward (towards upper in Fig. 6 Just) the swing in direction；Or by applying positive displacement electric field to electrode layer 109c and 109d, and electrode layer 109a and 109b are not applied Added electric field or the electric field for applying opposite direction, to form the swing of forward direction (in Fig. 6 downward).Therefore, this implementation The position that control two freedom degrees of X and Y-direction are stacked by a bending displacement may be implemented in the piezoelectric ceramics displacement driver of example Move control.

Fig. 7 is the structural schematic diagram of the utility model embodiment 4.As shown in fig. 7, piezoelectric ceramics displacement driver includes thickness Degree displacement stacks 101, bending displacement and stacks 102 and swing arm 105.Wherein thickness displacement stack 101 and bending displacement stack 102 Structure is basically the same as those in the first embodiment, and is not repeated herein.As shown in fig. 7, swing arm 105 be it is cylindric, end face is equipped on it Groove 105a, the bottom surface of mover 20 stretch out protrusion ball 201, and protrusion ball 201 and groove 105a cooperate, so that bending displacement is folded The tangential driving force that the swing of heap 102 provides can be transmitted by 105 structure of swing arm, directly be carried out to the structure 201 of mover 20 It pushes, acts mover 20.

In the present embodiment, swing arm 105 but passes through pendulum to the effect of mover 20 not by the mode of stiction Protrusion ball 201 on groove 105a and mover 20 on arm 105 cooperates, to be directly driven by the swing that bending displacement stacks The movement of mover, therefore, the piezoelectric ceramics displacement driver of the utility model are not limited to the driving method of stiction.

Fig. 8 is the structural schematic diagram of the piezoelectric ceramics displacement driver of the 5th embodiment of the utility model.As shown in figure 8, Piezoelectric ceramics displacement driver includes that thickness displacement stacks 101, bending displacement and stacks 102 and swing arm 106.Wherein thickness displacement is folded The structure that heap 101 and bending displacement stack 102 is basically the same as those in the first embodiment, and is not repeated herein.The present embodiment and above-mentioned reality The difference for applying example essentially consists in the structure of swing arm 106.In the present embodiment, swing arm 106 is cylinder, and is set on an upper There are protrusion 106a, protrusion 106a to contact with mover and mover is driven to move.The drive when bending displacement stacks 102 flexure operation The movement of 106 tangential displacement of movable pendulum arm, so that swing arm be enable to export tangential displacement and thrust.Those skilled in the art can be with Understand, the structure of swing arm 106 can be T-type structure as shown in the figure, however, the shape of swing arm is also possible to the knot of other shape Structure, and it is not limited to triangle, hemispherical, T shape etc..

To sum up, the piezoelectric ceramics displacement driver of the utility model can externally export tangential active force and tangential position It moves, displacement and the active force of the more a freedom degrees of X, Y, Z can also be provided, and a molding production method of cofiring can be passed through It is made.Compared with existing piezoelectric ceramic actuator, the utility model has higher displacement accuracy, can accomplish stronger driving Power and lower driving voltage, and preferably environmental characteristics and service life.

The preferred embodiment of the utility model has already been described in detail above, it is understood that having read the utility model Above-mentioned teaching content after, those skilled in the art can make various changes or modifications the utility model.These shapes of equal value Formula is also fallen within the scope of the appended claims of the present application.

Claims (10)

1. a kind of piezoelectric ceramics displacement driver, the mover for driving motor is moved, which is characterized in that the piezoelectric ceramics position Moving driver includes that bending displacement stacks and swing arm, the bending displacement are stacked to be stacked by multiple piezoelectric ceramic pieces and be formed, wherein The surface covering for the piezoelectric ceramic piece that the bending displacement stacks electrode layer spaced apart is to form first group of electrode layer and the Two groups of electrode layers.

2. piezoelectric ceramics displacement driver according to claim 1, which is characterized in that the piezoelectric ceramics displacement driver It further include that thickness displacement stacks, the thickness displacement, which stacks to be stacked by multiple piezoelectric ceramic pieces, to be formed, and the thickness displacement stacks The surface of piezoelectric ceramic piece cover full electrode layer.

3. piezoelectric ceramics displacement driver according to claim 2, which is characterized in that moved with described one end of the swing arm The other end of son contact and the swing arm is stacked with the bending displacement or thickness displacement is stacked and contacted, the thickness displacement The separation for making mover swing arm and the mover when not acted is stacked, and is being acted in the mover When, it contacts the swing arm with the mover and applies pressure.

4. piezoelectric ceramics displacement driver according to claim 2, which is characterized in that the thickness is displaced the one end stacked It connects the other end that the bending displacement stacks and thickness displacement stacks and connects the swing arm.

5. piezoelectric ceramics displacement driver according to claim 2, which is characterized in that one end that the bending displacement stacks It connects the other end that the thickness displacement stacks and the bending displacement stacks and connects the swing arm.

6. piezoelectric ceramics displacement driver according to claim 2, which is characterized in that one end of the swing arm connects thickness Displacement stacks and the other end of the swing arm connects the bending displacement and stacks.

7. piezoelectric ceramics displacement driver according to claim 2, which is characterized in that the piezoelectric ceramics displacement driver It is stacked including multiple bending displacements and/or multiple thickness displacements stacks.

8. piezoelectric ceramics displacement driver according to claim 2, which is characterized in that thickness displacement stack with it is described It is that cofiring stacks and/or thickness displacement stacks that stack with the bending displacement be that organic adhesion agent is viscous that bending displacement, which stacks, Connect stack and/or the thickness displacement stack stacked with the bending displacement be glass paste sintering process formed stack.

9. piezoelectric ceramics displacement driver according to claim 2, which is characterized in that the thickness displacement is stacked, is bent It is cofiring connection, and/or Organic adhesive bonding connection, and/or glass paste sintering that displacement, which stacks the connection between swing arm, Technique connection.

10. piezoelectric ceramics displacement driver according to claim 2, which is characterized in that the cross sectional shape of the swing arm is Rectangle, triangle, hemispherical, inverted T-shaped and/or the bottom surface of the swing arm are rectangular and top is arc-shaped, hemispherical and/or falls T shape.