CN100566116C - Piezoelectric vibrator array and adopt the micromotion platform of the planar three freedom of this array - Google Patents

Abstract

Piezoelectric vibrator array and adopt the micromotion platform of the planar three freedom of this array, it belongs to the ultrasonic vibration application, and it has solved micromotion platform can realize accurate rectilinear motion and the problem that rotatablely moves simultaneously in same plane.Piezoelectric vibrator array of the present invention is made of the oscillator group in the east in the same plane, south, west, four orientation, north, above-mentioned four oscillator groups are made of at least one forward strip oscillator (B1) and at least one reverse strip oscillator (B2) respectively, two adjacent groups moving tooth group (3) on the described forward strip oscillator (B1) is separately positioned on 1/8th and 5/8ths places of this bar shaped vibrating body (2) vibration wavelength, and the two adjacent groups moving tooth group (3) on the described reverse strip oscillator (B2) is separately positioned on 3/8ths and 7/8ths places of this bar shaped vibrating body (2) vibration wavelength.Adopt the micromotion platform of this array in same plane, to realize three degrees of freedom of movement, and improved the response speed and the kinematic accuracy of micropositioner.

Description

Piezoelectric vibrator array and adopt the micromotion platform of the planar three freedom of this array

Technical field

The invention belongs to the ultrasonic vibration application, be specifically related to a kind of piezoelectric vibrator array and adopt the micromotion platform of the planar three freedom of this array.

Background technology

Now the type of drive of pinpoint micropositioner have varied, but may be summarized to be worm drive drive-type and direct drive-type basically.During worm drive drive again because the difference of the power of using is divided into manually, electromagnetic motor driving and other.Because shortcomings such as all the ubiquity transmission accuracy is low, response speed slow for the defective of worm drive itself, these patterns, complex structure.After ultrasonic motor occurs,, arrived in the micromotion mechanism by widespread usage because it has advantages such as response speed is fast, volume is little, no electromagnetic interference.The application of piezoelectric ceramic motor at present mainly is divided into orthoscopic ultrasonic motor and rotary type ultraphonic motor, and both can realize accurate orthoscopic motion respectively and rotatablely move.The rotary type ultraphonic motor generally still adopts worm drive in micromotion mechanism.This makes the fine motion system that certain loss be arranged on the response time, and precision is not high, and efficient is lower.Present a lot of applications all require micropositioner can realize accurate rectilinear motion simultaneously and rotatablely move.Can't well satisfy for the existing already present ultrasonic motor application mode of this requirement.On the micropositioner structure, present micropositioner can only be realized the rectilinear motion and the complex structure on plane mostly.

Summary of the invention

In order to make micromotion platform can in same plane, realize accurate rectilinear motion and rotatablely moving simultaneously, the invention provides a kind of piezoelectric vibrator array and adopt the micromotion platform of the planar three freedom of this array.

Piezoelectric vibrator array of the present invention is made of the oscillator group in the east in the same plane, south, west, four orientation, north, east, south, west, four oscillator groups in north are made of at least one forward strip oscillator B1 and at least one reverse strip oscillator B2 respectively, the horizontal placement of each strip oscillator that constitutes south, north orientation oscillator group is arranged into row, and formation east, west are vertically placed to each strip oscillator of oscillator group and be arranged into delegation.Described forward strip oscillator B1 and oppositely strip oscillator B2 all form by a bar shaped vibrating body 2, at least two piezoelectric ceramic pieces 1 and at least two group moving tooth groups 3; In each strip oscillator, at least two adjacent successively arrangements of piezoelectric ceramic piece 1 also are affixed on the lower surface of bar shaped vibrating body 2, and described piezoelectric ceramic piece 1 and bar shaped vibrating body 2 be with wide, the length of described piezoelectric ceramic piece 1 equal bar shaped vibrating body 2 natural frequency definite wavelength 1/2nd; The two adjacent groups moving tooth group 3 of bar shaped vibrating body 2 upper surfaces is separately positioned on 1/8th and 5/8ths places of these bar shaped vibrating body 2 vibration wavelengths among the described forward strip oscillator B1, and the upper surface two adjacent groups moving tooth group 3 of bar shaped vibrating body 2 is separately positioned on 3/8ths and 7/8ths places of these bar shaped vibrating body 2 vibration wavelengths among the described reverse strip oscillator B2; Each group moving tooth group 3 contains at least one moving tooth, and in each group moving tooth group 3 of each strip oscillator, at least one moving tooth forms a line along the Width of bar shaped vibrating body 2.In forward strip oscillator B1 or reverse strip oscillator B2, the number of the piezoelectric ceramic piece 1 of each strip oscillator lower surface is two or two integral multiple, and the group number of the moving tooth group 3 of each strip oscillator upper surface equates with the number of piezoelectric ceramic piece 1.Described moving tooth height is 3.5～4.5 millimeters.Adopt standing wave to drive for each strip oscillator, it is the elastomeric material that bar shaped vibrating body 2 adopts conduction, with bar shaped vibrating body 2 ground connection, apply the sinusoidal voltage of 180 ° of phasic differences mutually then on adjacent two piezoelectric ceramic pieces 1 to forward strip oscillator B1 and reverse strip oscillator B2 lower surface.

Adopt the micromotion platform of the planar three freedom of above-mentioned piezoelectric vibrator array to form by support 13, fixed mount, rolling frame, supporter 6, material carrier platform 7, stressed plate 8, friction material layer 9, piezoelectric vibrator array 10, bottom supporting platform 11 and precompression device 12, two relative on fixed mount sidewalls are fixedlyed connected with support 13 respectively, and be provided with guide rail between relative two sidewalls on described two sidewalls and the rolling frame, in addition be provided with guide rail between relative two sidewalls on the inboard of two sidewalls and the supporter 6 on the rolling frame, described guide rail is arranged in the same plane.Described material carrier platform 7 is divided into top disk and bottom rotation axis two parts, the top disk of described material carrier platform 7 embeds in the upper surface of described supporter 6, the center of described supporter 6 has a manhole, fixedly connected with the upper surface of described stressed plate 8 by the manhole of supporter 6 in the lower end of the bottom rotation axis of described material carrier platform 7, the lower surface of described stressed plate 8 is coated with friction material layer 9, the lower surface of described friction material layer 9 contacts with the upper surface of each moving tooth of piezoelectric vibrator array 10, piezoelectric ceramic piece one side of piezoelectric vibrator array 10 contacts with the upper surface of described bottom supporting platform 11, and described precompression device 12 is the mechanisms that can apply precompression to the lower surface of described bottom supporting platform 11.Described guide rail can adopt two v type spherical guides, as shown in Figure 3.Can use bearing or other parts, the no gap of structure realization between the supporter 6 of described micromotion platform and the material carrier platform 7, rotate freely cooperation, the top disk of described material carrier platform 7 can move, also can rotate freely by relative its with supporter 6 no gap level of synchronization.

Operation principle: single piezoelectric ceramic piece upper and lower surface adds after the voltage signal of sinusoidal variations, because the piezoelectric effect of piezoelectric ceramic, drive oscillator with standing wave form up-down vibration, this moment, vibrational waveform promptly was equivalent to the waveform of sinusoidal wave half wavelength, so when on single strip oscillator, applying phase difference on adjacent two piezoelectric ceramic pieces and be 180 ° sinusoidal voltage, just can on oscillator, produce a complete sinusoidal standing wave.Because the motion of each particle vertical direction in the whole process of vibration in the standing wave, and oscillator is different at the amplitude of diverse location particle, so the axis of the certain altitude of the upper surface setting of bar shaped vibrating body and the moving tooth of width can be attended by the variation at angle of inclination in motion process, and the variation at this inclination angle combines with the vibration of vertical direction and just obtained the velocity component of horizontal direction, so the fricting movement of the present invention by moving tooth and friction material layer passes to material carrier platform with the velocity component of horizontal direction.Its axis changed especially obviously when moving tooth was arranged in 1/8th, 3/8ths, 5/8ths and 7/8ths places of standing wave wavelength at the inclination angle of vibration processes, and therefore moving tooth is arranged on this position can increase frictional force.As Fig. 8 and shown in Figure 9, by the standing wave waveform as can be seen, when moving tooth is positioned at 1/8th and 5/8ths places of standing wave wavelength, forward strip oscillator B1 provides the frictional force of edge-directions X, and moving tooth is when being positioned at 3/8ths and 7/8ths places of standing wave wavelength, and oppositely strip oscillator B2 provides the frictional force of edge+directions X.In summary, among Fig. 1, when the forward strip oscillator B1 that is positioned at south, two orientation, north in the piezoelectric vibrator array worked simultaneously, material carrier platform 7 was done horizontal rectilinear motion westwards in the micromotion platform; When the reverse strip oscillator B2 that is positioned at south, two orientation, north in the piezoelectric vibrator array worked simultaneously, material carrier platform 7 was done horizontal rectilinear motion eastwards in the micromotion platform; When the forward strip oscillator B1 that is positioned at east, two orientation, west in the piezoelectric vibrator array worked simultaneously, material carrier platform 7 was done rectilinear motion longitudinally northwards in the micromotion platform; When the reverse strip oscillator B2 that is positioned at east, two orientation, west in the piezoelectric vibrator array worked simultaneously, material carrier platform 7 was done rectilinear motion longitudinally southwards in the micromotion platform; As the reverse strip oscillator B2 that is positioned at two orientation in north and east in the piezoelectric vibrator array, the forward strip oscillator B1 when working simultaneously that is positioned at two orientation in west and south, material carrier platform 7 is done clockwise rotatablely moving in the micromotion platform; As the forward strip oscillator B1 that is positioned at two orientation in north and east in the piezoelectric vibrator array, the reverse strip oscillator B2 when working simultaneously that is positioned at two orientation in west and south, material carrier platform 7 is done counterclockwise rotatablely moving in the micromotion platform.

The invention effect: 1) the invention provides that a kind of brand-new drive pattern-piezoelectric ceramic array drives and the new structure micropositioner that adapts of drive pattern therewith, it in same plane, realized accurate laterally, vertically and the motion of rotation Three Degree Of Freedom.2) array Piezoelectric Ceramic pattern provided by the invention combines the advantage of orthoscopic ultrasonic motor and rotary type ultraphonic motor, can realize simultaneously that the power of three-degree-of-freedom motion provides in the plane, and owing to be directly to drive micropositioner, make platform response speed further improve, it is more accurate to move.3) micropositioner provided by the invention is simple in structure, and is easy to operate.4) the invention enables the piezoelectric ceramic good characteristic that the application of brand-new mode has been arranged, wide application prospect is arranged at aspects such as Aero-Space, medicine equipment, intelligent robot, science and techniques of defence.

Description of drawings

Fig. 1 is the arrangement schematic diagram of the piezoelectric ceramic piece 1 of piezoelectric vibrator array 10 lower surfaces of the present invention; Fig. 2 is the structural representation of single strip oscillator in the piezoelectric vibrator array 10 of the present invention; Fig. 3 is that the A of Fig. 2 is to view; Fig. 4 is the structural representation of micromotion platform of the present invention; Fig. 5 is the vertical view of micromotion platform of the present invention; Fig. 6 is the structural representation of bottom supporting platform 11 among the present invention; Fig. 7 is the assembling schematic diagram of bottom supporting platform 11 and array piezoelectric vibrator 10; Fig. 8 is the structure of forward strip oscillator B1 and the schematic diagram of operation principle thereof; Fig. 9 is the structure of reverse strip oscillator B2 and the schematic diagram of operation principle thereof.

Embodiment

Embodiment one: referring to Fig. 1 to Fig. 3, Fig. 8 and Fig. 9, the piezoelectric vibrator array of this embodiment is made of the oscillator group in the east in the same plane, south, west, four orientation, north, east, south, west, four oscillator groups in north are made of a forward strip oscillator B1 and a reverse strip oscillator B2 respectively, the horizontal placement of each strip oscillator that constitutes south, north orientation oscillator group is arranged into row, and formation east, west are vertically placed to each strip oscillator of oscillator group and be arranged into delegation.Described forward strip oscillator B1 and oppositely strip oscillator B2 all form by a bar shaped vibrating body 2, four piezoelectric ceramic pieces 1 and four groups of moving tooth groups 3; In each strip oscillator, four adjacent successively arrangements of piezoelectric ceramic piece 1 also are affixed on the lower surface of bar shaped vibrating body 2, and described piezoelectric ceramic piece 1 and bar shaped vibrating body 2 be with wide, the length of described piezoelectric ceramic piece 1 equal bar shaped vibrating body 2 natural frequency definite wavelength 1/2nd; The two adjacent groups moving tooth group 3 of bar shaped vibrating body 2 upper surfaces is separately positioned on 1/8th and 5/8ths places of these bar shaped vibrating body 2 vibration wavelengths among the described forward strip oscillator B1, and the upper surface two adjacent groups moving tooth group 3 of bar shaped vibrating body 2 is separately positioned on 3/8ths and 7/8ths places of these bar shaped vibrating body 2 vibration wavelengths among the described reverse strip oscillator B2; As shown in Figure 3, each group moving tooth group 3 contains three moving teeth, and in each group moving tooth group 3 of each strip oscillator, and three moving teeth form a line along the Width of bar shaped vibrating body 2.The height of described moving tooth is 3.5～4.5 millimeters.When applying the sinusoidal voltage of 180 ° of phasic differences mutually on adjacent two piezoelectric ceramic pieces 1 to forward strip oscillator B1 and reverse strip oscillator B2 lower surface, each strip oscillator provides the power of direction shown in the solid arrow among Fig. 1.

Embodiment two: referring to Fig. 1 to Fig. 3, Fig. 8 and Fig. 9, the micromotion platform of the planar three freedom of employing embodiment one described piezoelectric vibrator array is by support 13, fixed mount, the rolling frame, supporter 6, material carrier platform 7, stressed plate 8, friction material layer 9, piezoelectric vibrator array 10, bottom supporting platform 11 and precompression device 12 are formed, two relative on fixed mount sidewalls are fixedlyed connected with support 13 respectively, and be provided with guide rail between relative two sidewalls on described two sidewalls and the rolling frame, in addition be provided with guide rail between relative two sidewalls on the inboard of two sidewalls and the supporter 6 on the rolling frame, described guide rail is arranged in the same plane.Described material carrier platform 7 is divided into top disk and bottom rotation axis two parts, the top disk of described material carrier platform 7 embeds in the upper surface of described supporter 6, the center of described supporter 6 has a manhole, fixedly connected with the upper surface of described stressed plate 8 by the manhole of supporter 6 in the lower end of the bottom rotation axis of described material carrier platform 7, the lower surface of described stressed plate 8 is coated with friction material layer 9, the lower surface of described friction material layer 9 contacts with the upper surface of each moving tooth of piezoelectric vibrator array 10, piezoelectric ceramic piece one side of piezoelectric vibrator array 10 contacts with the upper surface of described bottom supporting platform 11, and described precompression device 12 is the mechanisms that can apply precompression to the lower surface of described bottom supporting platform 11.Described guide rail can adopt two v type spherical guides, as shown in Figure 3.Can use bearing or other parts, the no gap of structure realization between the supporter 6 of described micromotion platform and the material carrier platform 7, rotate freely cooperation, the top disk of described material carrier platform 7 can move, also can rotate freely by relative its with supporter 6 no gap level of synchronization.Each strip oscillator in the above-mentioned piezoelectric vibrator array 10 adopts the standing wave type of drive, it is the elastomeric material that bar shaped vibrating body 2 adopts conduction, draw a lead and with its ground connection from the upper surface of bar shaped vibrating body 2, respectively draw a lead from the lower surface of each piezoelectric ceramic piece 1 then, make the sinusoidal voltage that passes to 180 ° of phase phasic differences on adjacent two piezoelectric ceramic pieces 1 of each strip oscillator lower surface at last.

Embodiment three: referring to Fig. 4 to Fig. 7, this embodiment is with the difference of embodiment two: described bottom supporting platform 11 is a cross plate, the upper surface of four overhanging ends of described cross plate has elongated slot 11-2, the degree of depth of described elongated slot 11-2 is 1.5～2.5 millimeters, the upper surface of described cross plate core has a rectangular channel 11-1, and the lower surface of the core of described cross plate has an axle 11-3 who protrudes.The upper surface groove of four overhanging ends of described cross plate is along four oscillator groups in east, south, west, north that supporting described piezoelectric vibrator array 10 respectively, as shown in Figure 7, the upper surface groove of four overhanging ends of described cross plate contacts along potsherd one side with forward strip oscillator B1 or reverse strip oscillator B2, and two grooves of the upper surface of described cross plate are along in the gap between adjacent two potsherds 1 that are inserted into each strip oscillator lower surface respectively.The width of above-mentioned elongated slot 11-2 is by the subregion decision of row formula piezoelectric vibrator 10.Other compositions are identical with embodiment two with annexation.The bottom supporting platform is made into the cross plate of trough of belt, has made things convenient for and given piezoelectric ceramic piece 1 energising, and produce standing wave for piezoelectric ceramic piece 1 certain space is provided.

Embodiment four: referring to Fig. 4 to Fig. 7, this embodiment is with the difference of embodiment three: described precompression device 12 is made up of base plate 12-1 and the adjustment screw 12-2 that the center is threaded through hole, described base plate 12-1 and described support 13 are fixedlyed connected by securing member, described adjustment screw 12-2 is threaded with the center tapped through hole of described base plate 12-1, and the center of described adjustment screw 12-2 has a blind hole, the axle 11-3 of described cross plate lower surface is inserted in this blind hole, is provided with a spring 12-3 between the lower surface of axle 11-3 is bottom blind hole.Axle 11-3 inserts in the blind hole of adjustment screw 12-2 and its matched in clearance, and compression spring 12-3, and in rotation adjustment screw 12-2, the pressure that spring 12-3 is applied to a 11-3 will strengthen like this, thereby strengthens precompression.Other compositions are identical with embodiment three with annexation.When the rotation adjustment screw moves upward it, will increase the pressure of 12 pairs of bottom supporting platforms 11 of precompression device, increase the pressure between oscillator moving tooth and the friction material layer then.

Embodiment five: referring to Fig. 4 and Fig. 5, this embodiment is with the difference of embodiment two: support 13 is divided into left side and right side support two parts, left side and right side support are the flat board that is converted into the right angle, vertical a placement of right-angle side of left side and right side support.Other compositions are identical with embodiment two with annexation.The perpendicularity of keeping support helps guaranteeing the levelness of micromotion platform.

Embodiment six: referring to Fig. 4 and Fig. 5, this embodiment is with the difference of embodiment five: described fixed mount is made up of the first semi-closure rectangle rack 4-1 and longitudinal rail bar 4-2 two parts, the described first semi-closure rectangle rack 4-1 has only three limits and horizontal positioned, and the described first semi-closure rectangle rack 4-1 is fixedlyed connected with the straight vertical arm of angle of left side brackets on last one side relative with open side and this limit is provided with V-way; The two ends of longitudinal rail bar 4-2 are separately fixed on the both sides of the first semi-closure rectangle rack 4-1 open side, V-way and this madial wall of the interior sidewall surface of longitudinal rail bar 4-2 on the first semi-closure rectangle rack 4-1 is provided with V-way, and the lateral wall of longitudinal rail bar 4-2 is fixedlyed connected with the straight vertical arm of angle of right side support.Other compositions are identical with embodiment five with annexation.When the lateral wall of longitudinal rail bar 4-2 is connected by adjustment screw with the straight vertical arm of angle of right side support, can regulate two distances between the V-arrangement longitudinal rail by adjustment screw, make material carrier platform 7 to move with supporter 6 no gap level of synchronization.

Embodiment seven: referring to Fig. 4 and Fig. 5, this embodiment is with the difference of embodiment six: described rolling frame is made up of the second semi-closure rectangle rack 5-1 and cross slide way bar 5-2 two parts, the described second semi-closure rectangle rack 5-1 also has only three limits and horizontal positioned, the inwall that the described second semi-closure rectangle rack 5-1 goes up one side relative with open side is provided with V-way, and the V-way that the outer wall on both sides in addition of the described second semi-closure rectangle rack 5-1 is provided with V-way and this outer wall is slidingly connected by the V-way of rolling element 14 and the first semi-closure rectangle rack 4-1 and longitudinal rail bar 4-2 respectively; The two ends of described cross slide way bar 5-2 are separately fixed on the both sides of the described second semi-closure rectangle rack 5-1 open side, and the interior sidewall surface of cross slide way bar 5-2 is provided with V-way to V-way and this madial wall of the second semi-closure rectangle rack 5; Described supporter 6 is that cross section is the quadrangular of rectangle, be respectively equipped with V-way on two relative side surfaces of supporter 6, the V-way of described supporter 6 is slidingly connected by the V-way of rolling element 14 and the second semi-closure rectangle rack 5-1 and cross slide way bar 5-2 respectively.Other compositions are identical with embodiment six with annexation.The rolling frame is not only as the rolling part of longitudinal rail, also as the standing part of cross slide way, so the horizontal and vertical motion of level has focused in the horizontal plane.The rolling frame also is made up of two parts, makes things convenient for installation and removal, is convenient to regulate the distance between the cross slide way, makes material carrier platform 7 to move with supporter 6 no gap level of synchronization.

Claims (10)

1, piezoelectric vibrator array, it is characterized in that described piezoelectric vibrator array is made of the oscillator group in the east in the same plane, south, west, four orientation, north, east, south, west, four oscillator groups in north are made of at least one forward strip oscillator (B1) and at least one reverse strip oscillator (B2) respectively, the horizontal placement of each strip oscillator that constitutes south, north orientation oscillator group is arranged into row, and formation east, west are vertically placed to each strip oscillator of oscillator group and be arranged into delegation; Described forward strip oscillator (B1) and reverse strip oscillator (B2) all are made up of a bar shaped vibrating body (2), two piezoelectric ceramic pieces (1) and two group moving tooth groups (3) at least at least; In each strip oscillator, the adjacent successively arrangement of at least two piezoelectric ceramic pieces (1) also is affixed on the lower surface of bar shaped vibrating body (2), and described piezoelectric ceramic piece (1) and bar shaped vibrating body (2) be with wide, the length of described piezoelectric ceramic piece (1) equal bar shaped vibrating body (2) natural frequency definite wavelength 1/2nd; The two adjacent groups moving tooth group (3) of bar shaped vibrating body (2) upper surface is separately positioned on 1/8th and 5/8ths places of this bar shaped vibrating body (2) vibration wavelength in the described forward strip oscillator (B1), and the upper surface two adjacent groups moving tooth group (3) of bar shaped vibrating body (2) is separately positioned on 3/8ths and 7/8ths places of this bar shaped vibrating body (2) vibration wavelength in the described reverse strip oscillator (B2); Each group moving tooth group (3) contains at least one moving tooth, and in each group moving tooth group (3) of each strip oscillator, at least one moving tooth forms a line along the Width of bar shaped vibrating body (2).

2, piezoelectric vibrator array according to claim 1, it is characterized in that in forward strip oscillator (B1) or reverse strip oscillator (B2), the number of the piezoelectric ceramic piece (1) of each strip oscillator lower surface is two or two integral multiple, and the group number of the moving tooth group (3) of each strip oscillator upper surface equates with the number of piezoelectric ceramic piece (1).

3, piezoelectric vibrator array according to claim 1 is characterized in that described moving tooth height is 3.5～4.5 millimeters.

4, adopt the micromotion platform of the planar three freedom of the described piezoelectric vibrator array of claim 1, it is characterized in that described micromotion platform is by support (13), fixed mount, the rolling frame, supporter (6), material carrier platform (7), stressed plate (8), friction material layer (9), piezoelectric vibrator array (10), bottom supporting platform (11) and precompression device (12) are formed, two relative on fixed mount sidewalls are fixedlyed connected with support (13) respectively, and be provided with guide rail between relative two sidewalls on described two sidewalls and the rolling frame, the inboard of other two sidewalls is gone up between two relative sidewalls with supporter (6) and is provided with guide rail on the rolling frame, and described guide rail is arranged in the same plane; Described material carrier platform (7) is divided into top disk and bottom rotation axis two parts, the top disk of described material carrier platform (7) embeds in the upper surface of described supporter (6), the center of described supporter (6) has a manhole, fixedly connected with the upper surface of described stressed plate (8) by the manhole of supporter (6) in the lower end of the bottom rotation axis of described material carrier platform (7), the lower surface of described stressed plate (8) is coated with friction material layer (9), the lower surface of described friction material layer (9) contacts with the upper surface of each moving tooth of piezoelectric vibrator array (10), piezoelectric ceramic piece one side of piezoelectric vibrator array (10) contacts with the upper surface of described bottom supporting platform (11), and described precompression device (12) is the mechanism that can apply precompression to the lower surface of described bottom supporting platform (11).

5, the micromotion platform of the planar three freedom of the described piezoelectric vibrator array of employing claim 1 according to claim 4 is characterized in that described guide rail adopts two v type spherical guides.

6, the micromotion platform of the planar three freedom of the described piezoelectric vibrator array of employing claim 1 according to claim 4, it is characterized in that described bottom supporting platform (11) is a cross plate, the upper surface of four overhanging ends of described cross plate has elongated slot (11-2), the upper surface of the core of described cross plate has a rectangular channel (11-1), and the lower surface of the core of described cross plate has an axle (11-3) that protrudes.

7, the micromotion platform of the planar three freedom of the described piezoelectric vibrator array of employing claim 1 according to claim 6, the degree of depth that it is characterized in that described elongated slot (11-2) is 1.5～2.5 millimeters.

8, according to the micromotion platform of the planar three freedom of claim 4 or the described piezoelectric vibrator array of 5 described employing claims 1, it is characterized in that described support (13) is divided into left side and right side support two parts, left side and right side support are the flat board that is converted into the right angle, vertical a placement of right-angle side of left side and right side support; Described fixed mount is made up of the first semi-closure rectangle rack (4-1) and longitudinal rail bar (4-2) two parts, the described first semi-closure rectangle rack (4-1) has only three limits and horizontal positioned, and fixedly connected with the straight vertical arm of angle of left side brackets in the last one side relative with open side of the described first semi-closure rectangle rack (4-1) and this limit is provided with V-way; The two ends of longitudinal rail bar (4-2) are separately fixed on the both sides of first semi-closure rectangle rack (4-1) open side, V-way and this madial wall of the interior sidewall surface of longitudinal rail bar (4-2) on the first semi-closure rectangle rack (4-1) is provided with V-way, and the lateral wall of longitudinal rail bar (4-2) is fixedlyed connected with the straight vertical arm of angle of right side support; Described rolling frame is made up of the second semi-closure rectangle rack (5-1) and cross slide way bar (5-2) two parts, the described second semi-closure rectangle rack (5-1) also has only three limits and horizontal positioned, the inwall that the described second semi-closure rectangle rack (5-1) is gone up one side relative with open side is provided with V-way, and the V-way that the outer wall on both sides in addition of the described second semi-closure rectangle rack (5-1) is provided with V-way and this outer wall is slidingly connected by the V-way of rolling element (14) with the first semi-closure rectangle rack (4-1) and longitudinal rail bar (4-2) respectively; The two ends of described cross slide way bar (5-2) are separately fixed on the both sides of described second semi-closure rectangle rack (5-1) open side, and the interior sidewall surface of cross slide way bar (5-2) is provided with V-way to V-way and this madial wall of the second semi-closure rectangle rack (5); Described supporter (6) is that cross section is the quadrangular of rectangle, be respectively equipped with V-way on two relative side surfaces of supporter (6), the V-way of described supporter (6) is slidingly connected by the V-way of rolling element (14) with the second semi-closure rectangle rack (5-1) and cross slide way bar (5-2) respectively.

9, the micromotion platform of the planar three freedom of the described piezoelectric vibrator array of employing claim 1 according to claim 6, it is characterized in that described precompression device (12) is made up of base plate (12-1) and adjustment screw (12-2) that the center is threaded through hole, described base plate (12-1) is fixedlyed connected by securing member with described support (13), described adjustment screw (12-2) is threaded with the center tapped through hole of described base plate (12-1), and the center of described adjustment screw (12-2) has a blind hole, the axle of described cross plate lower surface (11-3) is inserted in this blind hole, is provided with a spring (12-3) between the lower surface of axle (11-3) and blind hole bottom.

10, the micromotion platform of the planar three freedom of the described piezoelectric vibrator array of employing claim 1 according to claim 6 is characterized in that each the strip oscillator in the described piezoelectric vibrator array (10) adopts the standing wave type of drive.

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