JP2018207779A - Vibration actuator, lens barrel and camera - Google Patents

Abstract

To provide a vibration actuator with large driving torque and improved actuation characteristics.SOLUTION: A vibration actuator 10 of the present invention comprises: an electromechanical conversion element 13 which is in an annular shape, and has a plurality of first divided region 13A and a plurality of second divided region 13B which are divided in a radial direction; an elastic body 12 which generates driving force by vibration of the electromechanical conversion element 13; and a relative movement member 15 which pressure-contacts the elastic body 12, and relatively moves with respect to the elastic body 12 by the driving force. The first divided region 13A and the second divided region 13B are polarized in directions opposite to each other and alternately arranged, and a central angle formed by two edge sides along a radial direction, of the first divided region 13A and a central angle formed by two edge sides along a radial direction, of the second divided region 13B are different from each other.SELECTED DRAWING: Figure 6

Description

  The present invention relates to a vibration actuator, a lens barrel, and a camera.

In the conventional electromechanical transducer of a traveling wave type vibration actuator, a positive region polarized by applying a positive voltage and a negative region polarized by applying a negative voltage are provided at an equal angle (area) (patent) Reference 1).
Further, when it is desired to increase the driving torque of the actuator or to improve the starting characteristics, the driving voltage is increased.

JP 2006-347257 A

  An object of the present invention is to provide a vibration actuator, a lens barrel, and a camera that can obtain a large driving torque without increasing the driving voltage.

  The present invention solves the above problems by the following means.

The vibration actuator according to the present invention includes an electromechanical transducer having a plurality of first divided regions and a plurality of second divided regions divided in a predetermined direction, and an elasticity that generates a driving force by vibration of the electromechanical transducer. And a moving member that moves relative to the elastic body by a driving force of the elastic body, wherein the first divided area and the second divided area are polarized in different directions, and a plurality of the first divided areas are provided. At least a part of the two divided regions is disposed between the two first divided regions along the predetermined direction, and the area of the first divided region is larger than the area of the second divided region. .
In addition, the vibration actuator of the present invention generates an electromechanical transducer having a plurality of first divided regions and a plurality of second divided regions divided in a predetermined direction, and generates a driving force by vibration of the electromechanical transducer. And a moving member that moves relative to the elastic body by a driving force of the elastic body, wherein the first divided region and the second divided region are polarized in different directions, At least a part of the second divided area is disposed between the two first divided areas along the predetermined direction, and the length of the first divided area in the predetermined direction is the predetermined direction. The length is longer than the length of the second divided region.
The lens barrel of the present invention is configured to include the vibration actuator.
The camera of the present invention is configured to include the vibration actuator.
In addition, said structure may be improved suitably, and at least one part may substitute for another structure.

  According to the present invention, it is possible to provide a vibration actuator, a lens barrel, and a camera that can obtain a large driving torque.

It is a figure explaining the electronic camera of one Embodiment of this invention. It is a figure explaining a lens-barrel, and is a figure of the state which incorporated the ring-shaped vibration wave motor in the lens-barrel. It is a partially broken perspective view of a vibrator and a mover. It is a block diagram explaining the drive apparatus of a vibration wave motor and a vibration wave motor. It is the graph which showed the relationship between the phase difference of the two drive signals divided by the phase shift part, and the rotational speed of a vibration wave motor. It is a figure which shows the polarization ratio of the piezoelectric material of this embodiment. It is a figure which shows the polarization ratio of the piezoelectric material in a comparison form. It is the figure which showed the displacement which generate | occur | produces when a drive signal is applied to a piezoelectric material, A figure (a) shows a comparison form, (b) shows this embodiment. It is a figure which shows the polarization ratio of the piezoelectric material in the deformation | transformation form of this embodiment.

FIG. 1 is a diagram illustrating an electronic camera 1 according to an embodiment of the present invention.
The electronic camera 1 of the present embodiment includes an imaging optical system (lens barrel 20), an imaging element 30, an AFE (Analog front end) circuit 60, an image processing unit 70, an audio detection unit 80, and a buffer memory 110. The recording interface 120, the monitor 140, the operation member 90, the memory 130, and the CPU 100, and can be connected to the PC 100 as an external device.

  The lens barrel 20 includes a plurality of optical lenses, and forms a subject image on the light receiving surface of the image sensor 30. In FIG. 1, the optical lens system is simplified and illustrated as a single lens L. In addition, the optical lens L for AF in the optical lens group is driven by driving the vibration wave motor 10.

  The image sensor 30 is configured by a CMOS image sensor or the like in which light receiving elements are two-dimensionally arranged on a light receiving surface. The image sensor 30 photoelectrically converts the subject increase caused by the light beam that has passed through the imaging optical system 20 to generate an analog image signal. The analog image signal is input to the AFE circuit 60.

  The AFE circuit 60 performs gain adjustment (signal amplification according to ISO sensitivity) for the analog image signal. Specifically, the imaging sensitivity is changed within a predetermined range in accordance with a sensitivity setting instruction from the CPU 100. The AFE circuit 60 further converts the image signal after analog processing into digital data by a built-in A / D conversion circuit. The digital data is input to the image processing unit 70.

The image processing unit 70 performs various types of image processing on the digital image data.
The buffer memory 110 temporarily records image data in the pre-process and post-process of image processing by the image processing unit 70.
The sound detection unit 80 includes a microphone and a signal amplification unit 44, and mainly detects and captures sound from the subject direction during moving image shooting, and transmits the data to the CPU 100.

The recording interface 120 has a connector (not shown). A memory card 121 is connected to the connector, and data is written to the connected memory card 121 and data is read from a recording medium.
The monitor 140 is composed of a liquid crystal panel, and displays an image, an operation menu, and the like according to an instruction from the CPU 100.
The operation member 90 indicates a mode dial, a cross key, an enter button, and a release button, and sends an operation signal corresponding to each operation to the CPU 100. Settings for still image shooting and moving image shooting are set by the operation member 90.

The CPU 100 comprehensively controls operations performed by the electronic camera 1 by executing a program stored in a ROM (not shown). For example, AF (autofocus) operation control, AE (automatic exposure) operation control, auto white balance control, and the like are performed.
The memory 130 records a series of image data subjected to image processing.

  FIG. 2 is a diagram for explaining the lens barrel 20 and is a view showing a state in which the ring-shaped vibration wave motor 10 is incorporated in the lens barrel 20. FIG. 3 is a partially broken perspective view of the vibrator 11 and the moving element 15.

  The vibrator 11 includes an electro-mechanical conversion element (hereinafter referred to as a piezoelectric body) 13 such as a piezoelectric element or an electrostrictive element that converts electrical energy into mechanical energy, and an elastic body 12 that is joined to the piezoelectric body 13. It is composed of Although a traveling wave is generated in the vibrator 11, this embodiment will be described as nine traveling waves as an example.

  The elastic body 12 is made of a metal material having a high resonance sharpness and has an annular shape. A groove 12c is cut on the opposite side of the elastic body 12 to the bonding surface 12d to which the piezoelectric body 13 is bonded. Then, the tip surface of the protruding portion 12b (a portion where the groove 12c is not provided) becomes the driving surface 12a and is brought into pressure contact with the moving element 15. The reason for cutting the groove 12c is to make the neutral surface of the traveling wave as close to the piezoelectric body 13 as possible, thereby amplifying the amplitude of the traveling wave on the drive surface 12a.

  Although described in detail later, the piezoelectric body 13 is divided into two phases (A phase and B phase) along the circumferential direction. In each phase, the first divided region 13A divided in the radial direction, and the first divided region and the second divided region 13B whose polarization directions are opposite to each other, one for each half wavelength. They are arranged alternately (see FIG. 6 described later).

Under the piezoelectric body 13, a non-woven fabric 16, a pressure plate 17, and a pressure member 18 are disposed.
The nonwoven fabric 16 is made of, for example, a felt material, and is placed under the piezoelectric body 13 so as not to transmit the vibration of the vibrator 11 to the pressure plate 17 or the pressure member 18.
The pressure plate 17 is pressurized by the pressure member 18.
The pressure member 18 is disposed under the pressure plate 17 and generates a pressurizing force. In this embodiment, the pressure member 18 is a disc spring, but it may be a coil spring or a wave spring instead of a disc spring. The pressure member 18 is held by being fixed to a pressing ring 19 fixed to the fixing member 14.

The mover 15 is made of a light metal such as aluminum, and a sliding material for improving wear resistance is provided on the surface of the sliding surface 15a.
On the side opposite to the sliding surface 15a of the mover 15 (Z plus direction in FIG. 3, the optical axis direction subject side), rubber is absorbed in order to absorb vibration in the vertical direction (Z direction in FIG. 3) of the mover 15. Such a vibration absorbing member 23 is disposed, and an output transmission member 24 is disposed in the Z plus direction.

The output transmission member 24 regulates the pressurizing direction (Z direction) and the radial direction by a bearing 25 provided on the fixed member 14. Thereby, the moving element 15 is regulated in the pressurizing direction and the radial direction.
The output transmission member 24 has a protrusion 24 a from which a fork 35 connected to the cam ring 36 is engaged, and the cam ring 36 is rotated as the output transmission member 24 rotates.

A key groove 37 is obliquely cut in the cam ring 36, and a fixing pin 38 provided in the AF ring 34 is engaged with the key groove 37. The AF ring 34 is driven in the straight direction in the axial direction so that it can stop at a desired position.
The fixing member 14 has a holding ring 19 attached thereto by screws, and by attaching this, the output transmission member 24 to the moving element 15, the vibrator 11, and the pressing member 18 can be configured as one motor unit.

FIG. 4 is a block diagram illustrating the vibration wave motor 10 and the drive device 40 </ b> A of the vibration wave motor 10.
First, the drive / control unit 41 of the vibration wave motor 10 will be described.

The oscillating unit 42 generates a drive signal having a desired frequency according to a command from the control unit 41.
The phase shift unit 43 divides the drive signal generated by the oscillating unit 42 into two drive signals having different phases in response to a command from the control unit 41.
The amplification unit 44 boosts the two drive signals divided by the phase shift unit 43 to desired voltages, respectively.
A drive signal from the amplifying unit 44 is transmitted to the vibration wave motor 10, and by applying this drive signal, a traveling wave is generated in the vibrator 11 of the vibration wave motor 10 described later, and the movable element 15 is driven.

  The rotation detection unit 46 is configured by an optical encoder, a magnetic encoder, or the like, detects the position and speed of a driven object driven by driving the moving element 15, and transmits the detected value to the control unit 41 as an electric signal.

  The control unit 41 controls driving of the vibration wave motor 10 and operation of the vibration wave motor 10 based on a drive command from the CPU 100 of the lens barrel 20 or the camera 1 main body. The control unit 41 receives the detection signal from the rotation detection unit 46, obtains position information and speed information based on the value, and controls the frequency, phase difference, etc. of the oscillation unit 42 so as to be positioned at the target position. To do.

  FIG. 5 is a graph showing the relationship between the phase difference between the two drive signals divided by the phase shift unit 43 and the rotational speed of the vibration wave motor 10. The vibration wave motor 10 is driven with a phase difference of 90 degrees at which the rotational speed is fastest during normal driving. When the phase difference is close to 0, the wave generated on the drive surface 12a of the elastic body 12 is not a traveling wave but a standing wave, and the rotation of the moving element 15 is stopped.

FIG. 6 is a diagram showing the polarization ratio of the piezoelectric body 13 of the present embodiment. FIG. 7 is a diagram showing the polarization ratio of the piezoelectric body 113 in the comparative embodiment.
The piezoelectric body 13 of the present embodiment and the piezoelectric body 113 of the comparative embodiment are divided into two phases (A phase and B phase) along the circumferential direction.

First, in order to facilitate the description, the comparison form in FIG. 7 will be described.
In the comparative form, in each of the A phase and the B phase, the first divided region 113A and the second divided region 113B divided along the radial direction are divided every ½ wavelength (center angle 22.50 °). They are alternately arranged one by one. The first divided region 113A and the second divided region have opposite polarization directions.
The central angle is an angle between two radii passing through both ends in the circumferential direction of the divided region, and is an angle formed by a radius including two edges along the radial direction of the divided region.

The first divided region 113A is a region where the surface shown in FIG. 6 (the surface opposite to the surface to which the elastic body 12 is bonded) is a surface to which a positive voltage is applied during polarization (in the figure, “+”). Is attached). Further, the second divided region 113B is a region where the surface shown in FIG. 6 (the surface opposite to the surface to which the elastic body 12 is bonded) is a surface to which a negative voltage is applied during polarization (in the figure, “ -").
A first ground region 113G1 provided so as to have an interval of 3/4 wavelength (16.875 ° × 2 = 33.75 °) between the A phase and the B phase, and the first ground region 113G1 and a second ground region 113G2 provided in a region facing the center with a quarter wavelength (11.25 °) therebetween.

On the other hand, the piezoelectric body 13 of the present embodiment in FIG. 6 also has a first divided region 13A divided along the radial direction in each of the A phase and the B phase, and the first divided region 13A having a polarization direction opposite to that of the first divided region 13A. The two divided regions 13B are alternately arranged one by one.
However, unlike the comparative example, the first divided region 13A and the second divided region 13B of the present embodiment have a central angle that is not an angle corresponding to ½ wavelength.

In the present embodiment, the central angles of the first divided regions 13A are all equal to the first angle of 24.50 °. In addition, the central angles of the second divided regions 13B are all equal second angles of 20.50 °.
That is, the central angle of the first divided region 13A is increased by 2 ° from 22.50 ° in the comparative example, and the central angle of the second divided region 13B is decreased by 2 ° from 22.50 ° in the comparative example. ing. In terms of percentage, the central angle of the first divided region 13A is 19.5% greater than the central angle of the second divided region 13B.

  However, the present invention is not limited to this, and it is sufficient that one of the central angle of the first divided region 13A or the central angle of the second divided region 13B is an area increase of 1% to 30% from the other. Further, the ratio of enlargement / reduction may be reversed, that is, the central angle of the first divided region 13A may be smaller than the central angle of the second divided region 13B.

  Thus, the amount of decrease in the second divided region 13B is equal to the amount of increase in the first divided region 13A. In each of the A phase and the B phase, the number of the first divided regions 13A is four and the number of the second divided regions is three, as illustrated. That is, it starts from the first divided area 13A and ends at the first divided area 13B. For this reason, in each of the A phase and the B phase, the area is increased as a whole by one angle increase (2 °) of the first divided area 13A compared to the comparative form.

Therefore, in the present embodiment, the angle of the second ground region 13G2 is decreased by 4 ° in total, that is, the A phase angle increase (2 °) and the B phase angle increase (2 °).
That is, the angle of the second ground region 13G2 is 7.25 °, which is 4 ° less than the 11.25 ° of the comparative example.
Note that the first ground region 13G1 is also provided in this embodiment so as to have an interval of 3/4 wavelengths (33.75 °).

8A and 8B are diagrams showing displacements that occur when a drive signal is applied to the piezoelectric bodies 13 and 113. FIG. 8A shows a comparative example, and FIG. 8B shows this embodiment.
In the comparative example shown in FIG. 8A, the central angle, the length in the circumferential direction, and the area of the first divided region 113A and the second divided region 113B are equal (the polarization ratio is equal).
Therefore, for example, when a drive signal such as a sine wave is input, the displacement in the Z direction (thickness direction of the piezoelectric body 113) in the figure becomes equal in the Z plus direction and the Z minus direction.

  On the other hand, in the case of the present embodiment shown in FIG. 8B, the central angle, the circumferential length, and the area of the first divided region 13A and the second divided region 13B are different (polarization ratios are different).

For this reason, as shown in FIG. 8B, the displacement amounts of the first divided region 13A and the second divided region 13B are different. That is, the region displacement of the first divided region 13A having a large angle increases. Therefore, the force with which the piezoelectric body 13 lifts the moving element 15 increases, and the drive torque of the vibration actuator 10 increases.
As described above, according to this embodiment, the drive torque of the actuator 10 can be increased only by changing the angular distribution of the polarization of the piezoelectric body 13. Further, since the driving torque is large, it is possible to provide a vibration actuator, a lens barrel, and a camera with improved startability characteristics.

(Deformation)
The present invention is not limited to the described embodiments, and various modifications and changes as shown below are possible, and these are also within the scope of the present invention.
(1) In the above-described embodiment, the A phase angle increase (2 °) and the B phase angle increase (2 °), a total of 4 °, are decreased from the angle of the second ground region 13G2.
However, the present invention is not limited to this. For example, as shown in FIG. 9, the sum (4 °) of the angle increase (2 °) of the A phase and the angle increase (2 °) of the B phase is the first ground region 13G1. It may be reduced equally from both 'and the second ground region 13G2'.
(2) The total of the angle increase (2 °) of the A phase (2 °) and the angle increase (2 °) of the B phase (2 °) may be reduced from the first ground region.
(3) The areas of the first divided region and the second divided region may be adjusted so that the areas of the first ground region 13G1 and the second ground region 13G2 do not change.
(4) Furthermore, the area of the second ground region may be increased and the area of the first ground region may be decreased.
(5) The increase / decrease in the area of the first ground region and the second ground region may be changed between the A phase and the B phase.
In addition, although embodiment and a deformation | transformation form can also be used in combination suitably, detailed description is abbreviate | omitted. Further, the present invention is not limited to the embodiment described above.

  1: camera, 10: vibration wave motor, 11: vibrator, 12: elastic body, 12a: driving surface, 12d: bonding surface, 13: piezoelectric body, 13A: first divided region, 13B: second divided region, 13G1 : First ground region, 13G2: Second ground region, 15: Mover, 15a: Sliding surface, 20: Lens barrel

Claims (7)

An electromechanical transducer having a plurality of first divided regions and a plurality of second divided regions divided in a predetermined direction;
An elastic body that generates a driving force by vibration of the electromechanical transducer;
A moving member that moves relative to the elastic body by the driving force of the elastic body,
The first divided region and the second divided region are polarized in different directions, and at least a part of the plurality of second divided regions is between the two first divided regions along the predetermined direction. The vibration actuator is arranged, and an area of the first divided region is larger than an area of the second divided region. The vibration actuator according to claim 1,
A vibration actuator in which a length of the first divided region in the predetermined direction is longer than a length of the second divided region in the predetermined direction. The vibration actuator according to claim 1 or 2,
The electromechanical transducer has a ring shape, and the plurality of first divided regions and the plurality of second divided regions are divided in a circumferential direction. The vibration actuator according to claim 3,
Each of the plurality of second divided regions is disposed between the two first divided regions along the circumferential direction,
A vibration actuator in which a central angle formed by two edges along the radial direction of the first divided region is larger than a central angle formed by two edges along the radial direction of the second divided region. An electromechanical transducer having a plurality of first divided regions and a plurality of second divided regions divided in a predetermined direction;
An elastic body that generates a driving force by vibration of the electromechanical transducer;
A moving member that moves relative to the elastic body by the driving force of the elastic body,
The first divided region and the second divided region are polarized in different directions, and at least a part of the plurality of second divided regions is between the two first divided regions along the predetermined direction. The vibration actuator is arranged and the length of the first divided region in the predetermined direction is longer than the length of the second divided region in the predetermined direction.   A lens barrel comprising the vibration actuator according to any one of claims 1 to 5.   A camera comprising the vibration actuator according to claim 1.

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