CN211720490U - SMD rotary-type dual drive piezoelectric actuator - Google Patents

Abstract

The utility model discloses a patch type rotary dual-drive piezoelectric actuator, which comprises a U-shaped beam, two driving rings, two connecting rods, two torsional vibration piezoelectric element groups, a bending vibration piezoelectric element group and two mounting frames; the U-shaped beam comprises a bottom beam and two side beams; the two driving circular rings are respectively connected with two ends of the U-shaped beam through two connecting rods, and m driving teeth are uniformly arranged on one end face of each driving circular ring in the circumferential direction; the two torsional vibration piezoelectric element groups are respectively and symmetrically arranged on the two side beams, and the bending vibration piezoelectric element group is arranged on the bottom beam. The two mounting frames are respectively arranged on the two side beams. The utility model discloses utilize piezoelectric material's inverse piezoelectric effect to convert the electric energy into mechanical energy, rely on the friction direct drive rotor rotatory, do not need complicated transmission and reduction gears, simple structure is compact, easily realizes the miniaturization, and can work under strong magnetic field and the vacuum environment.

Description

SMD rotary-type dual drive piezoelectric actuator

Technical Field

The utility model relates to a piezoelectric drive technique and two degree of freedom joint module technical field especially relate to a SMD rotary-type dual drive piezoelectric actuator.

Background

The robot joint module is usually driven by a motor and a hydraulic pressure to realize the movement of the joint module and the whole robot. With the continuous expansion of the application range of the mechanical arm in the scientific research field, some special working occasions have higher requirements on the driving technology of the joint module, such as no interference of a strong magnetic field, vacuum environment operation, a micro structure and the like. Electromagnetic motor can't normally work in the strong magnetic field environment, and hydraulic drive can't effectively work under the vacuum environment, and these two kinds of modes of actuating all have the mechanism redundancy to be unfavorable for the miniaturization.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the technical problem that to the defect that involves in the background art, provide a SMD rotary-type dual drive piezoelectric actuator.

The utility model adopts the following technical scheme to solve the technical problems

A surface mount type rotary dual-drive piezoelectric actuator comprises a U-shaped beam, a first drive ring, a second drive ring, a first connecting rod, a second connecting rod, a first torsional vibration piezoelectric element group, a second torsional vibration piezoelectric element group, a bending vibration piezoelectric element group, a first mounting frame and a second mounting frame;

the U-shaped beam comprises a bottom beam, a first side beam and a second side beam which are symmetrical, and two ends of the bottom beam are respectively and vertically fixedly connected with one end of the first side beam and one end of the second side beam; the bottom beam, the first side beam and the second side beam are all cuboids and respectively comprise first to fourth side faces and two end faces, the first to fourth side faces are sequentially connected, the first side face is parallel to the third side face, and the second side face is parallel to the fourth side face; the third side surface of the first side beam and the first side surface of the second side beam are positioned at the inner side of the U-shaped beam, the first side surface of the first side beam and the third side surface of the second side beam are positioned at the outer side of the U-shaped beam, and the first side surface of the bottom beam is respectively connected with the first side surface of the first side beam and the third side surface of the second side beam;

the first connecting rod and the second connecting rod are both cylinders, one end face is a plane, and the other end face is an arc face; the plane end of the first connecting rod is fixedly connected with the other end of the first side beam, and the cambered surface end of the first connecting rod is fixedly connected with the side surface of the first driving ring; the plane end of the second connecting rod is fixedly connected with the other end of the second side beam, and the cambered surface end of the second connecting rod is fixedly connected with the side surface of the second driving ring;

the first connecting rod and the first side beam are coaxial, the axis of the first connecting rod passes through the center of the first driving circular ring, the second connecting rod and the second side beam are coaxial, the axis of the second connecting rod passes through the center of the second driving circular ring, and two end faces of the first driving circular ring and the second driving circular ring are parallel to the first side face of the first side beam;

the first mounting frame and the second mounting frame both comprise two mounting pieces, wherein the two mounting pieces of the first mounting frame are symmetrically arranged on the second side surface and the fourth side surface of the first side beam, and the two mounting pieces of the second mounting frame are symmetrically arranged on the second side surface and the fourth side surface of the second side beam; through holes are formed in the two mounting pieces of the first mounting frame and the second mounting frame and used for fixing the surface-mounted rotary type dual-drive piezoelectric actuator;

the bending vibration piezoelectric element group comprises two bending vibration piezoelectric elements, and the bending vibration piezoelectric elements adopt single-partition piezoelectric elements and are polarized along the thickness direction; the two bending vibration piezoelectric elements have the same polarization direction and are symmetrically arranged at the centers of the first side surface and the third side surface of the bottom beam;

the first torsional vibration piezoelectric element group and the second torsional vibration piezoelectric element group respectively comprise a first torsional vibration piezoelectric unit and a second torsional vibration piezoelectric unit, the first torsional vibration piezoelectric unit and the second torsional vibration piezoelectric unit respectively comprise first torsional vibration piezoelectric elements, second torsional vibration piezoelectric elements, third torsional vibration piezoelectric elements, fourth torsional vibration piezoelectric elements and U-shaped beams, the first torsional vibration piezoelectric elements, the second torsional vibration piezoelectric elements and the third torsional vibration piezoelectric elements are bonded to form a grid square, the first torsional vibration piezoelectric elements, the second torsional vibration piezoelectric elements and the third torsional vibration piezoelectric elements are polarized along the thickness direction, and the polarization directions of the adjacent torsional vibration piezoelectric elements are opposite;

the first torsional vibration piezoelectric unit and the second torsional vibration piezoelectric unit of the first torsional vibration piezoelectric element group are symmetrically arranged at the centers of the first side surface and the third side surface of the first side beam, and the first torsional vibration piezoelectric unit and the second torsional vibration piezoelectric unit of the second torsional vibration piezoelectric element group are symmetrically arranged at the centers of the first side surface and the third side surface of the second side beam; the polarization directions of the torsional vibration piezoelectric elements at the corresponding positions of the first torsional vibration piezoelectric unit and the second torsional vibration piezoelectric unit in the first torsional vibration piezoelectric element group are opposite; the polarization directions of the torsional vibration piezoelectric elements at the corresponding positions of the first torsional vibration piezoelectric unit of the first torsional vibration piezoelectric element group and the first torsional vibration piezoelectric unit of the second torsional vibration piezoelectric element group are the same;

m driving teeth are uniformly arranged on the end face, far away from the second driving ring, of the first driving ring in the circumferential direction, m driving teeth are uniformly arranged on the end face, far away from the first driving ring, of the second driving ring in the circumferential direction, and m is a natural number larger than or equal to 3;

in the first driving circular ring, an included angle between a connecting line between the center of the driving tooth closest to the driving beam and the center of the driving circular ring and the axis of the driving beam is 3 pi/4 m; in the second driving circular ring, an included angle between a connecting line between the center of the driving tooth closest to the driving beam and the center of the driving circular ring and the axis of the driving beam is 9 pi/4 m.

As a further optimization scheme of the patch-type rotary dual-drive piezoelectric actuator of the present invention, the side length of the square formed by the first torsional vibration piezoelectric unit and the second torsional vibration piezoelectric unit in the first torsional vibration piezoelectric unit group and the second torsional vibration piezoelectric unit group is equal to the width of the first side beam, and two sides of the square are aligned with two long sides of the first side;

two edges of two bending vibration piezoelectric elements in the bending vibration piezoelectric element group are aligned with two long edges of the first side surface of the bottom beam.

The utility model discloses a single mode driving method of this SMD rotary-type dual drive piezoelectric actuator, including following step:

step A.1), applying a first simple harmonic voltage signal to the first torsional vibration piezoelectric element group and the second torsional vibration piezoelectric element group to excite 2n +1 order torsional vibration modes of the first side beam and the second side beam, wherein n is an integer greater than or equal to 0, the torsional vibration modes can induce m order out-of-plane bending vibration modes of the first driving ring and the second driving ring, the motion trail of each driving tooth is an ellipse under simple harmonic vibration, the elliptical motion trail directions of the driving teeth of the first driving ring and the second driving ring are opposite, and an external rotor in contact with the driving teeth is driven to rotate along one direction under the friction action;

step A.2), if the external rotor needs to be driven to rotate reversely, the first simple harmonic voltage signal is applied to the first torsional vibration piezoelectric element group and the second torsional vibration piezoelectric element group, the second simple harmonic voltage signal is applied to the bending vibration piezoelectric element group, a 2n +1 order bending vibration mode of the bottom beam is excited, a 2n +2 order bending vibration mode of the first side beam and the second side beam is induced, the bending vibration mode can excite the first driving ring and the second driving ring to generate another m order out-of-plane bending vibration mode, the motion locus of the driving teeth of the first driving ring and the second driving ring is an ellipse opposite to that of the torsional vibration mode, and the external rotor in contact with the driving teeth is driven to rotate reversely under the friction action.

The utility model also discloses a compound mode driving method of this SMD rotary-type dual drive piezoelectric actuator, including following step:

step B.1), two-phase simple harmonic voltage signals are applied to the first torsional vibration piezoelectric element group, the second torsional vibration piezoelectric element group, the first bending vibration piezoelectric element group and the second bending vibration piezoelectric element group at the same time, so that the first driving ring and the second driving ring generate two standing waves with a pi/2 space phase difference, the phase difference of the first simple harmonic voltage signal and the second simple harmonic voltage signal in time is adjusted to be pi/2, the two standing waves of the first driving ring and the second driving ring are superposed to form a traveling wave, the driving teeth perform elliptic motion under the traveling wave, the driving teeth of the first driving ring and the second driving ring have opposite elliptic motion trail directions, and an external rotor in contact with the driving teeth is driven to rotate along one direction under the friction action;

and B.2), if the external rotor needs to be driven to rotate reversely, adjusting the first simple harmonic voltage signal and the second simple harmonic voltage signal to have a phase difference of-pi/2 in time.

The utility model adopts the above technical scheme to compare with prior art, have following technological effect:

the piezoelectric driving mode based on the inverse piezoelectric effect can realize the characteristics of compact structure, direct driving, no electromagnetic interference, easy miniaturization and the like of a driving structure under the condition that the preparation and processing technology of the piezoelectric ceramic material is further developed, and has wide application prospect in an extreme working environment. The utility model provides a based on reverse piezoelectric effect and friction driven SMD rotary-type dual drive piezoelectric actuator can realize characteristics such as the just reversal of rotor and mechanism are simple, miniaturized, can work under the extreme environment such as vacuum high-intensity magnetic field.

Drawings

FIG. 1 is a schematic structural diagram of a patch-type rotary-type dual-drive piezoelectric actuator;

FIG. 2 is a schematic diagram comparing the polarization direction and the electric signal application manner of the first torsional vibration piezoelectric element group;

FIG. 3 is a schematic diagram showing the polarization direction of the bending piezoelectric element group and the application manner of the electric signal;

FIG. 4 is a schematic view of the first side rail torsional vibration mode;

FIG. 5 is a schematic view of the mode of operation of the bottom beam;

FIG. 6 is a schematic illustration of a bottom rail induced bending mode of the first side rail;

FIG. 7 is a schematic diagram of a fourth order out-of-plane bending mode of operation of the first and second drive rings (expanded) under torsional excitation;

FIG. 8 is a schematic diagram comparing the fourth-order out-of-plane bending vibration modes of the first and second driving rings (expanded) under bending vibration excitation;

fig. 9 is a schematic diagram comparing the motion traces of the driving teeth of the first and second driving rings under two four-step out-of-plane bending vibration working modes.

In the figure, 1-a first driving ring, 2-a U-shaped beam, 3-a driving tooth, 4-a first torsional vibration piezoelectric element group, 5-a bending vibration piezoelectric element group and 6-a mounting piece of a second mounting frame.

Detailed Description

The technical scheme of the utility model is further explained in detail with the attached drawings as follows:

the present invention may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. In the drawings, components are exaggerated for clarity.

As shown in fig. 1, the utility model discloses a patch-type rotary dual-drive piezoelectric actuator, which comprises a U-shaped beam, a first drive ring, a second drive ring, a first to a second connecting rod, a first to a second torsional vibration piezoelectric element group, a bending vibration piezoelectric element group, a first mounting frame and a second mounting frame;

the U-shaped beam comprises a bottom beam, a first side beam and a second side beam which are symmetrical, and two ends of the bottom beam are respectively and vertically fixedly connected with one end of the first side beam and one end of the second side beam; the bottom beam, the first side beam and the second side beam are all cuboids and respectively comprise first to fourth side faces and two end faces, the first to fourth side faces are sequentially connected, the first side face is parallel to the third side face, and the second side face is parallel to the fourth side face; the third side surface of the first side beam and the first side surface of the second side beam are positioned at the inner side of the U-shaped beam, the first side surface of the first side beam and the third side surface of the second side beam are positioned at the outer side of the U-shaped beam, and the first side surface of the bottom beam is respectively connected with the first side surface of the first side beam and the third side surface of the second side beam;

the first connecting rod and the second connecting rod are both cylinders, one end face is a plane, and the other end face is an arc face; the plane end of the first connecting rod is fixedly connected with the other end of the first side beam, and the cambered surface end of the first connecting rod is fixedly connected with the side surface of the first driving ring; the plane end of the second connecting rod is fixedly connected with the other end of the second side beam, and the cambered surface end of the second connecting rod is fixedly connected with the side surface of the second driving ring;

the first connecting rod and the first side beam are coaxial, the axis of the first connecting rod passes through the center of the first driving circular ring, the second connecting rod and the second side beam are coaxial, the axis of the second connecting rod passes through the center of the second driving circular ring, and two end faces of the first driving circular ring and the second driving circular ring are parallel to the first side face of the first side beam;

the first mounting frame and the second mounting frame both comprise two mounting pieces, wherein the two mounting pieces of the first mounting frame are symmetrically arranged on the second side surface and the fourth side surface of the first side beam, and the two mounting pieces of the second mounting frame are symmetrically arranged on the second side surface and the fourth side surface of the second side beam; through holes are formed in the two mounting pieces of the first mounting frame and the second mounting frame and used for fixing the surface-mounted rotary type dual-drive piezoelectric actuator;

as shown in fig. 3, the group of bending vibration piezoelectric elements includes two bending vibration piezoelectric elements, and the bending vibration piezoelectric elements are single-partition piezoelectric elements and polarized along the thickness direction; the two bending vibration piezoelectric elements have the same polarization direction and are symmetrically arranged at the centers of the first side surface and the third side surface of the bottom beam;

as shown in fig. 2, each of the first torsional vibration piezoelectric element group and the second torsional vibration piezoelectric element group includes a first torsional vibration piezoelectric unit and a second torsional vibration piezoelectric unit, each of the first torsional vibration piezoelectric unit and the second torsional vibration piezoelectric unit includes first to fourth torsional vibration piezoelectric elements, each of the first to fourth torsional vibration piezoelectric elements is bonded to a U-shaped beam to form a grid square, each of the first to fourth torsional vibration piezoelectric elements is polarized along a thickness direction, and polarization directions of adjacent torsional vibration piezoelectric elements are opposite;

the first torsional vibration piezoelectric unit and the second torsional vibration piezoelectric unit of the first torsional vibration piezoelectric element group are symmetrically arranged at the centers of the first side surface and the third side surface of the first side beam, and the first torsional vibration piezoelectric unit and the second torsional vibration piezoelectric unit of the second torsional vibration piezoelectric element group are symmetrically arranged at the centers of the first side surface and the third side surface of the second side beam; the polarization directions of the torsional vibration piezoelectric elements at the corresponding positions of the first torsional vibration piezoelectric unit and the second torsional vibration piezoelectric unit in the first torsional vibration piezoelectric element group are opposite; the polarization directions of the torsional vibration piezoelectric elements at the corresponding positions of the first torsional vibration piezoelectric unit of the first torsional vibration piezoelectric element group and the first torsional vibration piezoelectric unit of the second torsional vibration piezoelectric element group are the same;

m driving teeth are uniformly arranged on the end face, far away from the second driving ring, of the first driving ring in the circumferential direction, m driving teeth are uniformly arranged on the end face, far away from the first driving ring, of the second driving ring in the circumferential direction, and m is a natural number larger than or equal to 3;

in the first driving circular ring, an included angle between a connecting line between the center of the driving tooth closest to the driving beam and the center of the driving circular ring and the axis of the driving beam is 3 pi/4 m; in the second driving circular ring, an included angle between a connecting line between the center of the driving tooth closest to the driving beam and the center of the driving circular ring and the axis of the driving beam is 9 pi/4 m.

As a further optimization scheme of the patch-type rotary dual-drive piezoelectric actuator of the present invention, the side length of the square formed by the first torsional vibration piezoelectric unit and the second torsional vibration piezoelectric unit in the first torsional vibration piezoelectric unit group and the second torsional vibration piezoelectric unit group is equal to the width of the first side beam, and two sides of the square are aligned with two long sides of the first side;

two edges of two bending vibration piezoelectric elements in the bending vibration piezoelectric element group are aligned with two long edges of the first side surface of the bottom beam.

The utility model discloses a single mode driving method of this SMD rotary-type dual drive piezoelectric actuator, including following step:

step A.1), applying a first simple harmonic voltage signal to the first torsional piezoelectric element group and the second torsional piezoelectric element group, as shown in FIG. 2, exciting 2n +1 order torsional vibration modes of the first side beam and the second side beam, as shown in FIG. 4, wherein n is an integer greater than or equal to 0, the torsional vibration modes can induce m order out-of-plane bending vibration modes of the first driving ring and the second driving ring, as shown in FIG. 7, the motion trajectory of each driving tooth under the simple harmonic vibration is an ellipse, the elliptical motion trajectories of the driving teeth of the first driving ring and the second driving ring are opposite in direction, and as shown in FIG. 9, an external rotor in contact with the driving teeth is driven to rotate along one direction under the friction action;

step A.2), if the external rotor needs to be driven to rotate reversely, the application of a first simple harmonic voltage signal to the first torsional vibration piezoelectric element group and the second torsional vibration piezoelectric element group is stopped, a second simple harmonic voltage signal is applied to the bending vibration piezoelectric element group, as shown in fig. 3, a 2n +1 order bending vibration mode of the bottom beam is excited, as shown in fig. 5, a 2n +2 order bending vibration mode of the first side beam and the second side beam is induced, as shown in fig. 6, the bending vibration mode can excite the first driving ring and the second driving ring to generate another m order of out-of-plane bending vibration mode, as shown in fig. 8, at the moment, the motion locus of the driving teeth of the first driving ring and the second driving ring is an ellipse opposite to that of the torsional vibration mode, and the external rotor in contact with the driving teeth is driven to rotate reversely under the friction action.

The utility model also discloses a compound mode driving method of this SMD rotary-type dual drive piezoelectric actuator, including following step:

step B.1), two-phase simple harmonic voltage signals are applied to the first torsional vibration piezoelectric element group, the second torsional vibration piezoelectric element group, the first bending vibration piezoelectric element group and the second bending vibration piezoelectric element group at the same time, so that the first driving ring and the second driving ring generate two standing waves with a pi/2 space phase difference, the phase difference of the first simple harmonic voltage signal and the second simple harmonic voltage signal in time is adjusted to be pi/2, the two standing waves of the first driving ring and the second driving ring are superposed to form a traveling wave, the driving teeth perform elliptic motion under the traveling wave, the driving teeth of the first driving ring and the second driving ring have opposite elliptic motion trail directions, and an external rotor in contact with the driving teeth is driven to rotate along one direction under the friction action;

and B.2), if the external rotor needs to be driven to rotate reversely, adjusting the first simple harmonic voltage signal and the second simple harmonic voltage signal to have a phase difference of-pi/2 in time.

It will be understood by those skilled in the art that, unless otherwise defined, all terms (including technical and scientific terms) used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. It will be further understood that terms, such as those defined in commonly used dictionaries, should be interpreted as having a meaning that is consistent with their meaning in the context of the prior art and will not be interpreted in an idealized or overly formal sense unless expressly so defined herein.

The above-mentioned embodiments further describe the objects, technical solutions and advantages of the present invention in detail, it should be understood that the above description is only the embodiments of the present invention, and is not intended to limit the present invention, and any modifications, equivalent substitutions, improvements and the like made within the spirit and principle of the present invention should be included in the scope of the present invention.

Claims (2)

1. A surface mount type rotary dual-drive piezoelectric actuator is characterized by comprising a U-shaped beam, a first drive ring, a second drive ring, a first connecting rod, a second connecting rod, a first torsional vibration piezoelectric element group, a second torsional vibration piezoelectric element group, a bending vibration piezoelectric element group, a first mounting frame and a second mounting frame;

the U-shaped beam comprises a bottom beam, a first side beam and a second side beam which are symmetrical, and two ends of the bottom beam are respectively and vertically fixedly connected with one end of the first side beam and one end of the second side beam; the bottom beam, the first side beam and the second side beam are all cuboids and respectively comprise first to fourth side faces and two end faces, the first to fourth side faces are sequentially connected, the first side face is parallel to the third side face, and the second side face is parallel to the fourth side face; the third side surface of the first side beam and the first side surface of the second side beam are positioned at the inner side of the U-shaped beam, the first side surface of the first side beam and the third side surface of the second side beam are positioned at the outer side of the U-shaped beam, and the first side surface of the bottom beam is respectively connected with the first side surface of the first side beam and the third side surface of the second side beam;

the first connecting rod and the second connecting rod are both cylinders, one end face is a plane, and the other end face is an arc face; the plane end of the first connecting rod is fixedly connected with the other end of the first side beam, and the cambered surface end of the first connecting rod is fixedly connected with the side surface of the first driving ring; the plane end of the second connecting rod is fixedly connected with the other end of the second side beam, and the cambered surface end of the second connecting rod is fixedly connected with the side surface of the second driving ring;

the first connecting rod and the first side beam are coaxial, the axis of the first connecting rod passes through the center of the first driving circular ring, the second connecting rod and the second side beam are coaxial, the axis of the second connecting rod passes through the center of the second driving circular ring, and two end faces of the first driving circular ring and the second driving circular ring are parallel to the first side face of the first side beam;

the first mounting frame and the second mounting frame both comprise two mounting pieces, wherein the two mounting pieces of the first mounting frame are symmetrically arranged on the second side surface and the fourth side surface of the first side beam, and the two mounting pieces of the second mounting frame are symmetrically arranged on the second side surface and the fourth side surface of the second side beam; through holes are formed in the two mounting pieces of the first mounting frame and the second mounting frame and used for fixing the surface-mounted rotary type dual-drive piezoelectric actuator;

the bending vibration piezoelectric element group comprises two bending vibration piezoelectric elements, and the bending vibration piezoelectric elements adopt single-partition piezoelectric elements and are polarized along the thickness direction; the two bending vibration piezoelectric elements have the same polarization direction and are symmetrically arranged at the centers of the first side surface and the third side surface of the bottom beam;

the first torsional vibration piezoelectric element group and the second torsional vibration piezoelectric element group respectively comprise a first torsional vibration piezoelectric unit and a second torsional vibration piezoelectric unit, the first torsional vibration piezoelectric unit and the second torsional vibration piezoelectric unit respectively comprise first torsional vibration piezoelectric elements, second torsional vibration piezoelectric elements, third torsional vibration piezoelectric elements, fourth torsional vibration piezoelectric elements and U-shaped beams, the first torsional vibration piezoelectric elements, the second torsional vibration piezoelectric elements and the third torsional vibration piezoelectric elements are bonded to form a grid square, the first torsional vibration piezoelectric elements, the second torsional vibration piezoelectric elements and the third torsional vibration piezoelectric elements are polarized along the thickness direction, and the polarization directions of the adjacent torsional vibration piezoelectric elements are opposite;

the first torsional vibration piezoelectric unit and the second torsional vibration piezoelectric unit of the first torsional vibration piezoelectric element group are symmetrically arranged at the centers of the first side surface and the third side surface of the first side beam, and the first torsional vibration piezoelectric unit and the second torsional vibration piezoelectric unit of the second torsional vibration piezoelectric element group are symmetrically arranged at the centers of the first side surface and the third side surface of the second side beam; the polarization directions of the torsional vibration piezoelectric elements at the corresponding positions of the first torsional vibration piezoelectric unit and the second torsional vibration piezoelectric unit in the first torsional vibration piezoelectric element group are opposite; the polarization directions of the torsional vibration piezoelectric elements at the corresponding positions of the first torsional vibration piezoelectric unit of the first torsional vibration piezoelectric element group and the first torsional vibration piezoelectric unit of the second torsional vibration piezoelectric element group are the same;

m driving teeth are uniformly arranged on the end face, far away from the second driving ring, of the first driving ring in the circumferential direction, m driving teeth are uniformly arranged on the end face, far away from the first driving ring, of the second driving ring in the circumferential direction, and m is a natural number larger than or equal to 3;

in the first driving circular ring, an included angle between a connecting line between the center of the driving tooth closest to the driving beam and the center of the driving circular ring and the axis of the driving beam is 3 pi/4 m; in the second driving circular ring, an included angle between a connecting line between the center of the driving tooth closest to the driving beam and the center of the driving circular ring and the axis of the driving beam is 9 pi/4 m.

2. The patch-type rotary-type dual-drive piezoelectric actuator according to claim 1, wherein a side length of a square formed by the first torsional vibration piezoelectric unit and the second torsional vibration piezoelectric unit in the first torsional vibration piezoelectric unit group and the second torsional vibration piezoelectric unit group is equal to a width of the first side face of the first side beam, and two sides of the square are aligned with two long sides of the first side face;

two edges of two bending vibration piezoelectric elements in the bending vibration piezoelectric element group are aligned with two long edges of the first side surface of the bottom beam.

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