JP7372563B2 - Lens drive device, camera module, and camera mounting device - Google Patents

Description

The present invention relates to a lens driving device, a camera module, and a camera mounting device.

Generally, mobile terminals such as smartphones are equipped with a small camera module. Such camera modules have an autofocus function (hereinafter referred to as "AF function") that automatically adjusts the focus when photographing a subject, and an optical system that reduces shake (vibration) that occurs during shooting. A lens driving device having an optical image stabilization (OIS) function (hereinafter referred to as "OIS function") that corrects and reduces image disturbance is applied (for example, Patent Document 1).

A lens drive device having an AF function and an OIS function includes an autofocus drive unit (hereinafter referred to as “AF drive unit”) for moving the lens unit in the optical axis direction, and an autofocus drive unit (hereinafter referred to as “AF drive unit”) for moving the lens unit in the optical axis direction, and an autofocus drive unit for moving the lens unit in the optical axis direction. and an shake correction drive section (hereinafter referred to as "OIS drive section") for swinging the camera. In Patent Document 1, a voice coil motor (VCM) is applied to the AF drive section and the OIS drive section.

Furthermore, in recent years, camera modules having multiple (typically two) lens driving devices have been put into practical use (so-called dual cameras). Dual cameras have various possibilities depending on the usage scene, such as being able to simultaneously capture two images with different focal lengths, or capturing a still image and a moving image simultaneously.

Japanese Patent Application Publication No. 2013-210550 International Publication No. 2015/123787

However, as in Patent Document 1, a lens driving device using VCM is affected by external magnetism, so there is a risk that high-precision operation may be impaired. In particular, in a dual camera in which lens drive devices are arranged side by side, there is a high possibility that magnetic interference will occur between the lens drive devices.

On the other hand, Patent Document 2 discloses a lens drive device in which an ultrasonic motor is applied to an AF drive section and an OIS drive section. The lens driving device disclosed in Patent Document 2 is magnetless and can reduce the influence of external magnetism, but the structure is complicated and it is difficult to reduce the size and height of the device.

An object of the present invention is to provide a lens driving device, a camera module, and a camera mounting device that can be made smaller and lower in height, and can improve driving performance.

One aspect of the lens driving device according to the present invention is
A lens accommodating portion is provided on the inner side, and a ball holding portion having a shape protruding outward in the radial direction is provided on a part of the outer circumferential surface along a predetermined direction perpendicular to the optical axis direction, and the ball holding portion includes: A lens holder, wherein ball accommodating portions are formed at respective positions of both ends in the predetermined direction, and a driving portion is disposed on the outside of a side surface between the ball accommodating portions;
The lens holder is housed in an opening in which a cutout corresponding to the protruding shape of the ball holding part is formed, and the ball holding part and the driving part are housed in the cutout, and the predetermined shape is formed in the cutout. A fixing part, in which a ball fixing part is provided at each end in the direction;
a plurality of rows of balls parallel to the optical axis, each row being rotatably interposed between the ball accommodating part and the ball fixing part in the predetermined direction and respectively accommodated in the ball accommodating part; a supporting part that supports the lens holder driven by the driving part so as to be movable in the optical axis direction with respect to the fixed part;
Stoppers for regulating downward movement of the lens holder are provided on the lower surface of the ball holding part at a plurality of locations corresponding to the positions of the ball accommodating part.

One aspect of the camera module according to the present invention is
The above lens driving device,
a lens accommodated in the lens accommodating section ;
and an imaging section that captures a subject image formed by the lens section.

One aspect of the camera-mounted device according to the present invention is
A camera-equipped device that is an information device or a transportation device,
The above camera module,
An image processing unit that processes image information obtained by the camera module.

According to the present invention, it is possible to reduce the size and height of a lens drive device, a camera module, and a camera mounting device, and it is also possible to improve drive performance.

FIG. 1A and FIG. 1B are diagrams showing a smartphone equipped with a camera module according to an embodiment of the present invention. FIG. 2 is an external perspective view of the camera module. 3A and 3B are external perspective views of the lens driving device according to the embodiment. FIG. 4 is an exploded perspective view of the lens driving device. FIG. 5 is an exploded perspective view of the lens driving device. FIG. 6 is a plan view showing the wiring structure of the base. 7A and 7B are perspective views of the OIS drive section. FIG. 8 is an exploded perspective view of the OIS movable part. FIG. 9 is an exploded perspective view of the OIS movable part. FIG. 10 is an exploded perspective view of the OIS movable part. 11A and 11B are perspective views of the AF drive section. FIG. 12 is a plan view showing the wiring structure and support structure in the AF unit. FIG. 13 is a diagram showing the support structure in the AF unit. FIG. 14 is a side view showing how the AF drive section is attached. 15A and 15B are diagrams showing an automobile as a camera mounting device equipped with an on-vehicle camera module.

Hereinafter, embodiments of the present invention will be described in detail based on the drawings.

1A and 1B are diagrams showing a smartphone M (an example of a camera-equipped device) equipped with a camera module A according to an embodiment of the present invention. FIG. 1A is a front view of the smartphone M, and FIG. 1B is a rear view of the smartphone M.

Smartphone M has a dual camera consisting of two rear cameras OC1 and OC2. In this embodiment, camera module A is applied to rear cameras OC1 and OC2.
Camera module A is equipped with an AF function and an OIS function, and not only automatically focuses when photographing a subject, but also optically corrects shake (vibration) that occurs during photographing to photograph images without image blur. be able to.

FIG. 2 is an external perspective view of the camera module A. 3A and 3B are external perspective views of the lens driving device 1 according to the embodiment. FIG. 3B shows a state in which FIG. 3A is rotated by 180 degrees around the Z axis. As shown in FIGS. 2, 3A, and 3B, the embodiment will be described using an orthogonal coordinate system (X, Y, Z). The figures to be described later are also shown using a common orthogonal coordinate system (X, Y, Z).

For example, the camera module A is configured such that when actually taking a picture with the smartphone M, the X direction is the up-down direction (or left-right direction), the Y direction is the left-right direction (or up-down direction), and the Z direction is the front-back direction. It will be installed. That is, the Z direction is the optical axis direction, the upper side (+Z side) in the figure is the light receiving side in the optical axis direction, and the lower side (−Z side) is the imaging side in the optical axis direction. Further, the X direction and the Y direction orthogonal to the Z axis are referred to as "optical axis orthogonal directions", and the XY plane is referred to as "optical axis orthogonal plane".

As shown in FIGS. 2, 3A, and 3B, the camera module A includes a lens driving device 1 that realizes an AF function and an OIS function, a lens section 2 in which a lens is housed in a cylindrical lens barrel, and a lens section. The camera includes an imaging unit (not shown) that captures a subject image formed by 2.

An imaging section (not shown) is arranged on the imaging side of the lens driving device 1 in the optical axis direction. The imaging unit (not shown) includes, for example, an image sensor board and an image sensor mounted on the image sensor board. The image sensor is configured by, for example, a CCD (charge-coupled device) type image sensor, a CMOS (complementary metal oxide semiconductor) type image sensor, or the like. The image sensor captures a subject image formed by the lens unit 2. The lens driving device 1 is mounted on an image sensor substrate (not shown) and mechanically and electrically connected to it. A control unit that controls the drive of the lens drive device 1 may be provided on the image sensor board, or may be provided on a camera-equipped device (in the embodiment, the smartphone M) on which the camera module A is mounted.

The lens driving device 1 is covered with a cover 24 on the outside. The cover 24 is a rectangular lidded square cylinder when viewed from above in the optical axis direction. In the embodiment, the cover 24 has a square shape in plan view. The cover 24 has a generally circular opening 241 on the top surface. The lens portion 2 faces the outside through the opening 241 of the cover 24, and is configured to protrude from the opening surface of the cover 24 toward the light receiving side as it moves in the optical axis direction. The cover 24 is fixed to the base 21 (see FIG. 4) of the OIS fixing section 20 of the lens driving device 1, for example, by adhesive.

4 and 5 are exploded perspective views of the lens driving device 1. FIG. FIG. 5 shows a state in which FIG. 4 is rotated by 180 degrees around the Z axis. FIG. 4 shows a state in which the OIS drive unit 30 and sensor board 22 are attached, and FIG. 5 shows a state in which the OIS drive unit 30 and sensor board 22 are removed.
As shown in FIGS. 4 and 5, in this embodiment, the lens driving device 1 includes an OIS movable section 10 (second movable section), an OIS fixed section 20 (second fixed section), an OIS drive section 30 (XY direction drive unit) and an OIS support unit 40 (second support unit).

The OIS movable part 10 is a part that swings in a plane perpendicular to the optical axis during shake correction. The OIS movable unit 10 includes an AF unit, a second stage 13, and a ball 42 (see FIG. 8, etc.). The AF unit includes an AF movable section 11 (first movable section), a first stage 12 (first fixed section), an AF drive section 14 (Z-direction drive section), and an AF support section 15 (first support section). (See Figures 7 to 9).
The OIS fixed part 20 is a part to which the OIS movable part 10 is connected via the OIS support part 40. The OIS fixing part 20 includes a base 21.
The OIS movable section 10 is arranged apart from the OIS fixed section 20 in the optical axis direction, and is connected to the OIS fixed section 20 via the OIS support section 40 . Further, the OIS movable portion 10 and the OIS fixed portion 20 are urged in a direction toward each other by an OIS urging member 50. In this embodiment, the OIS biasing members 50 are arranged at the four corners of the lens driving device 1 in a plan view.

Note that in this embodiment, regarding movement in the Y direction, the entire OIS movable section 10 including the AF unit moves as a movable body. On the other hand, regarding movement in the X direction, only the AF unit moves as a movable body. That is, regarding movement in the X direction, the second stage 13 constitutes the OIS fixing section 20 together with the base 21, and the ball 42 functions as the OIS supporting section 40.

The base 21 is formed of, for example, a molding material made of polyarylate (PAR), a PAR alloy (for example, PAR/PC) that is a mixture of a plurality of resin materials containing PAR, or a liquid crystal polymer. The base 21 is a rectangular member in plan view, and has a circular opening 211 in the center.

The base 21 has a first base part 212 forming the main surface of the base 21 and a second base part 213 on which the sensor substrate 22 is placed. The second base portion 213 is recessed relative to the first base portion 212 . The sensor substrate 22 is placed on the second base portion 213, and the first base portion 212 and the sensor substrate 22 form a flush base surface.

In the present embodiment, the second base section 213 corresponds to an area where the AF drive section 14 and the OIS drive section 30 are not arranged, that is, one side (fourth side) of the rectangle that is the planar shape of the base 21. located in the area. By arranging the sensor board 22 on the second base portion 213, the power supply lines and signal lines for the magnetic sensors 25X, 25Y, and 25Z can be consolidated, and the wiring structure in the base 21 can be simplified ( (See Figure 6).

Further, the base 21 has a third base portion 214 on the periphery of the opening 211 that restricts movement of the AF movable portion 11 toward the imaging side in the optical axis direction. The third base portion 214 is formed to be recessed with respect to the first base portion 212, thereby ensuring a movement stroke of the AF movable portion 11 toward the imaging side in the optical axis direction.

The base 21 has an OIS motor fixing part 215 in which the second OIS driving part 30Y is arranged. The OIS motor fixing part 215 is provided at a corner of the base 21, for example, is formed to protrude from the first base part 212 toward the light receiving side in the optical axis direction, and has a shape capable of holding the second OIS driving part 30Y. have.

Terminal fittings 23A to 23C are arranged on the base 21 by, for example, insert molding. The terminal fitting 23A includes a power supply line to the AF drive section 14 and the first OIS drive section 30X. The terminal fittings 23A are exposed from, for example, openings 216 formed at the four corners of the base 21, and are electrically connected to the OIS biasing member 50. Power is supplied to the AF drive section 14 and the first OIS drive section 30X via the OIS biasing member 50. The terminal fitting 23B includes power supply lines (eg, 4 lines) and signal lines (eg, 6 lines) to the magnetic sensors 25X, 25Y, and 25Z. The terminal fitting 23B is electrically connected to wiring (not shown) formed on the sensor board 22. The terminal fitting 23C includes a power supply line to the second OIS drive section 30Y.

Further, the base 21 has a ball accommodating portion 217 in which the ball 41 that constitutes the OIS support portion 40 is arranged. The ball accommodating portion 217 is provided near the four corners of the base 21, for example. The ball accommodating portion 217 is recessed into a rectangular shape extending in the Y direction. The side surface of the ball accommodating portion 217 is formed into a tapered shape, for example, so that the groove width becomes narrower toward the bottom surface.

The sensor board 22 has wiring (not shown) including power supply lines and signal lines for the magnetic sensors 25X, 25Y, and 25Z. Magnetic sensors 25X, 25Y, and 25Z are mounted on the sensor board 22. The magnetic sensors 25X, 25Y, and 25Z are composed of, for example, Hall elements or TMR (Tunnel Magneto Resistance) sensors, and are electrically connected to the terminal fittings 23B via wiring (not shown) formed on the sensor board 22. be done.

In the first stage 12 of the OIS movable section 10, magnets 16X and 16Y are arranged at positions facing the magnetic sensors 25X and 25Y (see FIG. 10). The position of the OIS movable section 10 in the X direction and the Y direction is detected by a position detection section consisting of magnetic sensors 25X, 25Y and magnets 16X, 16Y.
Further, in the AF movable section 11 of the OIS movable section 10, a magnet 16Z is arranged at a position facing the magnetic sensor 25Z (see FIG. 10). The position of the AF movable section 11 in the Z direction is detected by a position detection section consisting of a magnetic sensor 25Z and a magnet 16Z. Note that instead of the magnets 16X, 16Y, and 16Z and the magnetic sensors 25X, 25Y, and 25Z, optical sensors such as photoreflectors are used to determine the position of the OIS movable part 10 in the X and Y directions and the position of the AF movable part 11 in the Z direction. It may also be detected.

The OIS biasing member 50 is composed of, for example, a tension coil spring, and connects the OIS movable part 10 and the OIS fixed part 20. In this embodiment, one end of the OIS biasing member 50 is connected to the terminal fitting 23A of the base 21, and the other end is connected to the wirings 17A and 17B of the first stage 12. The OIS biasing member 50 receives a tensile load when the OIS movable part 10 and the OIS fixed part 20 are connected, and acts so that the OIS movable part 10 and the OIS fixed part 20 approach each other. That is, the OIS movable part 10 is held so as to be swingable within the XY plane while being biased in the optical axis direction (pressed against the base 21) by the OIS biasing member 50. Thereby, the OIS movable part 10 can be held in a stable state without wobbling.
Further, in this embodiment, the OIS biasing member 50 functions as a power supply line to the AF drive section 14 and the first OIS drive section 30X.

The OIS support section 40 supports the OIS movable section 10 with respect to the OIS fixed section 20 while being spaced apart in the optical axis direction. In this embodiment, OIS support section 40 includes four balls 41 interposed between OIS movable section 10 (first stage 12 and second stage 13) and base 21. Four balls 41 are interposed between the base 21 and the second stage 13.
Further, the OIS support section 40 includes four balls 42 interposed between the first stage 12 and the second stage 13 in the OIS movable section 10 (see FIG. 8, etc.).
In this embodiment, by restricting the directions in which the balls 41 and 42 (total of 8 balls) constituting the OIS support section 40 can roll, the OIS movable section 10 can be swung with high accuracy within the XY plane. It has become. Note that the number of balls 41 and 42 that constitute the OIS support section 40 can be changed as appropriate.

The OIS drive section 30 is an actuator that moves the OIS movable section 10 in the X direction and the Y direction. Specifically, the OIS drive section 30 includes a first OIS drive section 30X (first XY direction drive section) that moves the OIS movable section 10 (AF unit only) in the X direction, and a first OIS drive section 30X (first XY direction drive section) that moves the OIS movable section 10 (AF unit only) in the It is configured with a second OIS drive section 30Y (second XY direction drive section) that moves in the Y direction.
The first and second OIS drive units 30X and 30Y are configured with ultrasonic motors. The first OIS drive section 30X is fixed to a notch 122 (OIS motor fixing section) of the first stage 12 along the X direction. The second OIS drive section 30Y is fixed to the OIS motor fixing section 215 of the base 21 so as to extend along the Y direction. That is, the first OIS drive section 30X and the second OIS drive section 30Y are arranged along sides that are perpendicular to each other.

The configuration of the OIS drive unit 30 is shown in FIGS. 7A and 7B. 7A shows a state in which each member of the OIS drive unit 30 is assembled, and FIG. 7B shows a state in which each member of the OIS drive unit 30 is disassembled. Although FIGS. 7A and 7B show the second OIS drive section 30Y, the main structure of the first OIS drive section 30X, specifically the structure except for the shape of the OIS electrode 33, is the same. , will be treated as a diagram showing the OIS drive section 30.

As shown in FIGS. 7A and 7B, the OIS driving section 30 includes an OIS resonating section 31, an OIS piezoelectric element 32, and an OIS electrode 33. The driving force of the OIS drive unit 30 is transmitted to the second stage 13 via the OIS power transmission unit 34. Specifically, the first OIS drive unit 30X is connected to the second stage 13 via the first OIS power transmission unit 34X, and the second OIS drive unit 30Y is connected to the second stage 13 via the second OIS power transmission unit 34Y. and is connected to the second stage 13.

The OIS piezoelectric element 32 is, for example, a plate-shaped element made of a ceramic material, and generates vibration by applying a high frequency voltage. Two OIS piezoelectric elements 32 are arranged so as to sandwich the body 311 of the OIS resonator 31 .
The OIS electrode 33 sandwiches the OIS resonator 31 and the OIS piezoelectric element 32, and applies a voltage to the OIS piezoelectric element 32. The OIS electrode 33 of the first OIS drive unit 30X is electrically connected to the wiring 17A of the first stage 12, and the OIS electrode 33 of the second OIS drive unit 30Y is electrically connected to the wiring 23C of the base 21. be done.

The OIS resonator 31 is formed of a conductive material, resonates with the vibration of the OIS piezoelectric element 32, and converts the vibration motion into linear motion. In this embodiment, the OIS resonator 31 includes a substantially rectangular body 311 sandwiched between the OIS piezoelectric elements 32 and two arm portions 312 extending from the upper and lower parts of the body 311 in the X direction or the Y direction. , a protrusion 313 extending from the center of the body 311 in the X direction or the Y direction, and a current-carrying portion 314 extending from the center of the body 311 on the side opposite to the protrusion 313 . The two arm parts 312 have a symmetrical shape, each free end part abuts the OIS power transmission part 34, resonates with the vibration of the OIS piezoelectric element 32, and deforms symmetrically. The energizing section 314 of the first OIS drive section 30X is electrically connected to the wiring 17A of the first stage 12, and the energizing section 31d of the second OIS driving section 30Y is electrically connected to the wiring 23C of the base 21. be done.

The OIS piezoelectric element 32 is bonded to the body 311 of the OIS resonator 31 from the thickness direction, and is sandwiched between the OIS electrodes 33, thereby electrically connecting them to each other. For example, by connecting one of the power supply paths to the OIS electrode 33 and the other to the current-carrying section 314 of the OIS resonant section 31, a voltage is applied to the OIS piezoelectric element 32, and vibration is generated.

The OIS resonator 31 has at least two resonant frequencies, and deforms with different behavior for each resonant frequency. In other words, the overall shape of the OIS resonant section 31 is set so that it deforms in different behaviors for two resonant frequencies. The different behaviors are a behavior in which the OIS power transmission unit 34 is moved forward in the X direction or the Y direction, and a behavior in which it is moved backward.

The OIS power transmission section 34 is a chucking guide that extends in one direction, and one end is connected to the OIS drive section 30 and the other end is connected to the second stage 13. The OIS power transmission section 34 includes an OIS motor contact section 341, a stage fixing section 343, and a connecting section 342. The OIS motor contact portion 341 contacts the free end of the arm portion 312 of the OIS resonator 31 . The stage fixing part 343 is arranged at the end of the OIS power transmission part 34, and is fixed to the OIS chucking guide fixing part 135 (see FIG. 8, etc.) of the second stage 13. The connecting portion 342 is a portion that connects the OIS motor contact portion 341 and the stage fixing portion 343, and is bifurcated from the stage fixing portion 343 into two parts that are formed parallel to each other.

The width between the OIS motor contact parts 341 is set wider than the width between the free ends of the arm parts 312 of the OIS resonant part 31. For example, in the connecting part between the connecting part 342 and the stage fixing part 343, by interposing a separating member 344 that is larger than the width of the connecting end between the two connecting parts 342, it is possible to You can expand the width. As a result, when the OIS power transmission section 34 is attached to the OIS drive section 30, the OIS power transmission section 34 functions as a leaf spring, and a biasing force acts in a direction to spread the arm section 312 of the OIS resonance section 31. This urging force holds the OIS power transmission section 34 between the free ends of the arm section 312 of the OIS resonance section 31, and the driving force from the OIS resonance section 31 is efficiently transmitted to the OIS power transmission section 34.

Since the OIS drive section 30 and the OIS power transmission section 34 are only in contact with each other in an energized state, the outer size of the lens drive device 1 can be increased simply by enlarging the contact portion in the X direction or the Y direction. Therefore, the moving distance (stroke) of the OIS movable portion 10 can be increased.

The first OIS drive unit 30X is fixed to the OIS movable unit 10 (first stage 12), is connected to the second stage 13 via the OIS power transmission unit 34X, and is driven by the second OIS drive unit 30Y. When correcting directional shake, it moves together with the OIS movable section 10. On the other hand, the second OIS drive section 30Y is fixed to the OIS fixing section 20 (base 21) and connected to the second stage 13 via the OIS power transmission section 34Y. Not affected by directional shake correction. That is, movement of the OIS movable part 10 by one OIS drive part 30 is not hindered by the structure of the other OIS drive part 30. Therefore, rotation of the OIS movable section 10 around the Z axis can be prevented, and the OIS movable section 10 can be accurately swung within the XY plane.

8 to 10 are exploded perspective views of the OIS movable section 10. FIG. 9 shows a state in which FIG. 8 is rotated by 180 degrees around the Z axis. FIG. 10 is a downward perspective view showing a state in which FIG. 8 is rotated by 180 degrees around the Z-axis. Note that in FIG. 9, the AF drive section 14 and the first OIS drive section 30X are in a state of being removed from the first stage 12.
In the following, in a rectangular planar shape of the lens drive device 1, the side where the AF drive section 14 is arranged is referred to as a "first side", and the side where the first OIS drive section 30X is arranged is referred to as a "second side". '', the side on which the second OIS drive unit 30X is arranged will be referred to as the "third side", and the remaining side will be referred to as the "fourth side".

As shown in FIGS. 8 to 10, in this embodiment, the OIS movable section 10 includes an AF movable section 11, a first stage 12, a second stage 13, an AF drive section 14, an AF support section 15, and the like. Regarding movement in the Y direction, the entire OIS movable part 10 including the first stage 12 and second stage 13 becomes a movable body, whereas with respect to movement in the X direction, the second stage 13 acts as an OIS fixed part 20. Only the AF unit functions as the OIS movable part 10. Further, the first stage 12 functions as an AF fixing section.

The AF movable section 11 is a section that moves in the optical axis direction during focusing. The AF movable section 11 is arranged radially inwardly and spaced apart from the first stage 12 (AF fixed section), and is supported while being biased by the first stage 12 via the AF support section 15 .

The AF movable section 11 is a lens holder that holds the lens section 2 (see FIG. 2) (hereinafter referred to as "lens holder 11"). The lens holder 11 is formed of, for example, polyarylate (PAR), a PAR alloy that is a mixture of a plurality of resin materials including PAR, a liquid crystal polymer, or the like. The lens holder 11 has a cylindrical lens accommodating portion 111. The lens portion 2 (see FIG. 2) is fixed to the lens housing portion 111a by, for example, adhesive.

The lens holder 11 has ball holding parts 112 at two locations along the X direction, that is, along the first side and the second side, on the peripheral surface of the lens accommodating part 111. The lens holder 11 has, for example, a rectangular parallelepiped shape. In each ball holding section 112, ball accommodating sections 113 for accommodating the AF support section 15 (ball) are provided at both ends in the X direction. The side surface of the ball accommodating portion 113 is formed into a tapered shape, for example, so that the groove width becomes narrower toward the bottom surface. Further, on the lower surface of the ball holding portion 112, a stopper portion that protrudes toward the imaging side in the optical axis direction than the lower surface of the lens accommodating portion 111 and restricts movement of the lens holder 11 toward the imaging side (lower side) in the optical axis direction. 114 are provided. In the present embodiment, the stopper section 114 comes into contact with the third base section 214 of the base 21 in the reference state in which the AF drive section 14 is not driven.

Further, a magnet accommodating portion 115 is provided on the circumferential surface of the lens accommodating portion 111 to accommodate a magnet 16Z for Z position detection. A magnet 16Z is arranged in the magnet accommodating part 115. On the sensor board 22, a magnetic sensor 25Z for Z position detection is arranged at a position facing the magnet 16Z in the optical axis direction (see FIG. 4).

Furthermore, an AF power transmission section 144 is disposed at the bottom of one of the ball holding sections 112 so as to protrude in the Y direction (-side). The AF power transmission section 144 is a chucking guide having a predetermined length in the Z direction, and the arm section 141b of the resonance section 141 of the AF drive section 14 comes into contact with the AF power transmission section 144 so as to sandwich the AF power transmission section 144. The power of the section 14 is transmitted (see FIG. 14). Since the AF power transmission section 144 is held between the two arm sections 141b, the driving force generated by the deformation of the resonance section 141 is efficiently transmitted.

In this embodiment, the AF power transmission section 144 is configured as a separate member from the lens holder 11. The AF power transmission section 144 has, for example, a U-shape in plan view, and has a bottom surface fixed to the circumferential surface of the ball holding section 112 with side surfaces facing in the X direction. The AF power transmission section 144 is made of, for example, a metal material such as titanium copper, nickel copper, or stainless steel. Thereby, the driving force of the AF drive unit 14 is transmitted more efficiently than when the arm portion 141b of the AF drive unit 30 comes into contact with the lens holder 11, which is a resin molded product. Note that the AF power transmission section 144 may be integrally molded with the lens holder 11.

The first stage 12 is a part that supports the AF movable part 11 via the AF support part 15. The second stage 13 is arranged on the imaging side of the first stage 12 in the optical axis direction with a ball 42 in between. The first stage 12 moves in the X direction and the Y direction during shake correction, and the second stage 13 moves only in the Y direction during shake correction.

The first stage 12 is a cylindrical member having a substantially rectangular shape when viewed in plan from the optical axis direction, and is made of, for example, a liquid crystal polymer. The first stage 12 has a substantially circular opening 121 in a portion corresponding to the lens holder 11 . In the first stage 12, a notch 122 is provided in a portion corresponding to the OIS drive unit 30 (the outer surface of the side wall along the second side and the third side), and a notch 122 is provided so as not to protrude outward in the radial direction. The OIS drive section 30 can be placed in the.

The first stage 12 has four ball accommodating sections 123 for accommodating the balls 42 on the lower surface. In addition, in FIG. 10, one of the ball accommodating parts 123 is not shown. The ball accommodating portion 123 is recessed into a rectangular shape extending in the X direction. Further, the side surface of the ball accommodating portion 123 is formed into a tapered shape so that the groove width becomes narrower toward the bottom surface. The ball accommodating part 123 faces the ball accommodating part 133 of the second stage 13 in the Z direction.

In the first stage 12, the inner surfaces of two side walls (side walls along the first side and second side) along the ) is formed. Furthermore, ball fixing parts 124 for fixing the AF support part 15 are provided at both ends of the notch. The ball fixing portion 124 is formed to protrude from the lower surface of the first stage 12 toward the imaging side in the optical axis direction.

In the first stage 12, an AF motor fixing section 125 in which the AF drive section 14 is disposed is formed on one side wall along the X direction (the side wall along the first side). The AF drive section 14 is fixed to the AF motor fixing section 125 by, for example, adhesive.

In the first stage 12, one side wall along the Y direction (the side wall along the fourth side) is provided with a magnet housing section 126 that stores magnets 16X and 16Y for XY position detection. Magnets 16X and 16Y are arranged in the magnet accommodating portion 126. For example, the magnet 16X is magnetized in the X direction, and the magnet 16Y is magnetized in the Y direction. On the sensor board 22, magnetic sensors 25X and 25Y for XY position detection are arranged at positions facing the magnets 16X and 16Y in the optical axis direction (see FIG. 4).

Furthermore, wiring lines 17A and 17B are embedded in the first stage 12 by, for example, insert molding (see FIG. 12). The wirings 17A and 17B are arranged, for example, along the first side and the second side. The wirings 17A and 17B are exposed from the four corners of the first stage 12, and one end of the OIS biasing member 50 is connected to these parts. Power is supplied to the first OIS drive unit 30X through the wiring 17A, and power is supplied to the AF drive unit 14 through the wiring 17B.

The second stage 13 is a cylindrical member having a substantially rectangular shape when viewed in plan from the optical axis direction, and is made of, for example, a liquid crystal polymer. The inner peripheral surface 131 of the second stage 13 is formed to correspond to the outer shape of the lens holder 11. In the second stage 13, a notch 132 is provided in a portion corresponding to the OIS drive unit 30 (the outer surface of the side wall along the second side and the third side), as in the first stage 12. , the OIS drive section 30 can be arranged so as not to protrude outward in the radial direction.

The second stage 13 has four ball accommodating portions 134 for accommodating the balls 41 on the lower surface. The ball accommodating portion 134 faces the ball accommodating portion 217 of the base 21 in the Z direction. The ball accommodating portion 134 is recessed into a rectangular shape extending in the Y direction. Further, the side surface of the ball accommodating portion 134 is formed into a tapered shape so that the groove width becomes narrower toward the bottom surface.
Further, the second stage 13 has four ball accommodating portions 133 for accommodating the balls 42 on the upper surface. The ball accommodating part 133 faces the ball accommodating part 123 of the first stage 12 in the Z direction. The ball accommodating portion 133 is recessed into a rectangular shape extending in the X direction. The side surface of the ball accommodating portion 133 is formed into a tapered shape so that the groove width becomes narrower toward the bottom surface.

The four balls 41 constituting the OIS support section 40 are held between the ball accommodating section 217 of the base 21 and the ball accommodating section 134 of the second stage 13 in multi-point contact. Therefore, the ball 41 stably rolls in the X direction.
Further, the four balls 42 are held between the ball accommodating portion 133 of the second stage 13 and the ball accommodating portion 123 of the first stage 12 with multi-point contact. Therefore, the ball 42 stably rolls in the X direction.

The AF support part 15 is a part that supports the lens holder 11 (AF movable part) with respect to the first stage 12 (AF fixed part). In this embodiment, the AF support section 15 is composed of a plurality of balls (here, two balls) arranged in line in the Z direction. The AF support part 15 is rotatably interposed between the ball accommodating part 113 of the lens holder 11 and the ball fixing part 124 of the first stage 12.

In this embodiment, as shown in FIG. 12, the AF support portions 15 are arranged at four locations on the outer peripheral surface of the lens holder 11. Specifically, a set of AF support parts 15A are arranged on a first straight line L1 (see FIG. 12) along the X direction, and a set of AF support parts 15A are arranged on a second straight line L2 (see FIG. 12) along the X direction. A set of second AF support parts 15B. The first straight line L1 and the second straight line L2 are in a symmetrical positional relationship with respect to a straight line L3 passing through the optical axis and parallel to the X direction.
Further, as shown in FIG. 13, an urging section 18 for urging the lens holder 11 is disposed between one of the set of AF support sections 15A and the ball fixing section 124 of the first stage 12. Ru. FIG. 13 is a sectional view taken along the straight line L1 in FIG. 12. Similarly, in the other set of AF support parts 15B, the biasing part 18 is arranged between the ball fixing part 124 of the first stage 12 and the AF support part 15B.
Therefore, the lens holder 11 is supported by the first stage 12 while being biased in the X direction via the two sets of AF support parts 15A and 15B. Thereby, the lens holder 11 is held in a stable posture.

As shown in FIG. 13, the biasing portion 18 includes, for example, a plate spring 181 (biasing member) made of a metal material and a spacer 182 (interference member) made of a ceramic material with a small coefficient of friction. have A leaf spring 181 is arranged on the first stage 12 side, and a spacer 182 is arranged on the lens holder 11 side. By interposing the ceramic spacer 182 between the leaf spring 181 and the AF support portion 15 (ball), the ball can be rolled smoothly and durability is improved. Note that the material of the spacer 182 may be any material as long as it allows the balls to roll smoothly, and is not limited to a ceramic material with a small coefficient of friction, but may also be a material with an appropriate coefficient of friction, such as a copper alloy or stainless steel. .

The AF drive section 14 is an actuator that moves the AF movable section 11 in the Z direction. The AF drive unit 14, like the OIS drive unit 30, is composed of an ultrasonic motor. The AF drive section 14 is fixed to the side wall of the first stage 12 along the X direction (the side wall along the first side) so that the arm section 141b extends in the Z direction.

The configuration of the AF drive section 14 is shown in FIGS. 11A and 11B. FIG. 11A shows a state where each member of the AF drive section 14 is assembled, and FIG. 11B shows a state where each member of the AF drive section 14 is disassembled. The configuration of the AF drive section 14 is almost the same as that of the OIS drive section 30.

As shown in FIGS. 11A and 11B, the AF drive section 14 includes an AF resonant section 141, an AF piezoelectric element 142, and an AF electrode 143. The driving force of the AF drive section 14 is transmitted to the lens holder 11 via the AF power transmission section 144.

The AF piezoelectric element 142 is, for example, a plate-shaped element made of a ceramic material, and generates vibration by applying a high frequency voltage. Two AF piezoelectric elements 142 are arranged so as to sandwich the body 141a of the AF resonator 141.
The AF electrode 143 sandwiches the AF resonance part 141 and the AF piezoelectric element 142 and applies a voltage to the AF piezoelectric element 142.

The AF resonator 141 is formed of a conductive material, resonates with the vibration of the AF piezoelectric element 142, and converts the vibration motion into linear motion. In the present embodiment, the AF resonator 141 includes a substantially rectangular body 141a held between the AF piezoelectric elements 142, two arm portions 141b extending in the Z direction from the body 141a, and a central portion of the body 141a. A protruding portion 141c extending in the Z direction from the central portion of the body portion 141a, and an energizing member extending from the center of the body portion 141a to the side opposite to the protruding portion 141c and electrically connected to the power feeding path (wiring 17B of the first stage 12). It has a section 141d. The two arm portions 141b have a symmetrical shape and are symmetrically deformed in resonance with the vibration of the AF piezoelectric element 142. The AF drive section 14 is arranged such that two arm sections 141b extend in the Z direction and sandwich the AF power transmission section 144 at their free ends.

An AF piezoelectric element 142 is bonded to the body 141a of the AF resonator 141 from the thickness direction, and is sandwiched between the AF electrodes 143, thereby electrically connecting them to each other. By connecting the current-carrying part 141d of the AF resonance part 141 and the AF electrode 143 to the wiring 17B of the first stage 12, a voltage is applied to the AF piezoelectric element 142, and vibration is generated.

Like the OIS resonance section 31, the AF resonance section 141 has at least two resonance frequencies, and deforms with different behavior for each resonance frequency. In other words, the overall shape of the AF resonance section 141 is set so that it deforms with different behaviors for two resonance frequencies.

In the lens driving device 1, when a voltage is applied to the AF driving section 14, the AF piezoelectric element 142 vibrates, and the AF resonating section 141 deforms in a manner that corresponds to the frequency. The AF power transmission section 144 is slid in the Z direction by the driving force of the AF drive section 14. Along with this, the AF movable section 11 moves in the Z direction, and focusing is performed. Since the AF support section 15 is composed of a ball, the AF movable section 11 can move smoothly in the Z direction. Furthermore, since the AF drive section 14 and the AF power transmission section 144 are only in contact with each other in a biased state, simply increasing the size of the contact portion in the Z direction will not impede the ability to reduce the height of the lens drive device 1. Therefore, the moving distance (stroke) of the AF movable section 11 can be easily lengthened.

In the lens driving device 1, when a voltage is applied to the OIS driving section 30, the OIS piezoelectric element 32 vibrates, and the OIS resonating section 31 deforms in a manner that corresponds to the frequency. The driving force of the OIS drive unit 30 causes the OIS power transmission unit 34 to slide in the X direction or the Y direction. Along with this, the OIS movable section 10 moves in the X direction or the Y direction, and shake correction is performed. Since the OIS support part 40 is composed of a ball, the OIS movable part 10 can move smoothly in the X direction or the Y direction.

Specifically, when the first OIS drive unit 30X is driven and the OIS power transmission unit 34 moves in the Power is transmitted to. At this time, the balls 41 held between the second stage 13 and the base 21 (the four balls accommodated in the ball accommodating portion 217) cannot roll in the X direction. The directional position is maintained. On the other hand, since the ball 42 held between the first stage 12 and the second stage 13 can roll in the X direction, the first stage 12 moves in the X direction with respect to the second stage 13. That is, the second stage 13 constitutes the OIS fixed part 20, and the first stage 12 constitutes the OIS movable part 10.

Further, when the second OIS drive unit 30Y is driven and the OIS power transmission unit 34 moves in the Y direction, power is transmitted from the base 21 where the second OIS drive unit 30Y is disposed to the second stage 13. Ru. At this time, since the ball 42 held between the first stage 12 and the second stage 13 cannot roll in the Y direction, the position of the first stage 12 in the Y direction with respect to the second stage is maintained. On the other hand, since the balls 41 held between the second stage 13 and the base 21 (the four balls accommodated in the ball accommodating section 217) can roll in the Y direction, the second stage 13 is Move in the Y direction. The first stage 12 also moves in the Y direction following the second stage 13. That is, the base 21 constitutes the OIS fixed part 20, and the AF unit including the first stage 12 and the second stage 13 constitutes the OIS movable part 10.

In this way, the OIS movable section 10 swings within the XY plane, and shake correction is performed. Specifically, the OIS drive units 30X and 30Y are energized based on a detection signal indicating angular shake from a shake detection unit (for example, a gyro sensor, not shown) so that the angular shake of camera module A is offset. Voltage is controlled. At this time, the translational movement of the OIS movable section 10 can be accurately controlled by feeding back the detection results of the XY position detection section composed of the magnets 16X, 16Y and the magnetic sensors 25X, 25Y.

As described above, the lens driving device 1 according to the embodiment includes the first stage 12 (first fixed part), the lens holder 11 (first movable part) disposed inside the first stage 12 in the radial direction, An AF support part 15 (first support part) that supports the lens holder 11 with respect to the first stage 12, and an AF support part 15 (first support part) that is arranged on the first stage 12 and moves the lens holder 11 in the optical axis direction with respect to the first stage 12. AF drive unit 14 (Z-direction drive unit), and has a rectangular shape in plan view when viewed from the optical axis direction.
The lens holder 11 has an AF power transmission section 144 provided to protrude outward in the radial direction, and the AF drive section 14 has a piezoelectric element 142 and a resonance section 141, and has an ultrasonic wave converting vibration motion into linear motion. The two arm parts 141b of the resonance part 141 extend in the optical axis direction and are arranged on the first side of the rectangle so as to sandwich the AF power transmission part 144.
The lens holder 11 is supported by the first stage 12 via the AF support part 15 in a biased direction perpendicular to the optical axis direction.

According to the lens driving device 1, since the AF driving section 14 is constituted by an ultrasonic motor, the influence of external magnetism can be reduced, and the size and height can be reduced.
Further, the arm portion 141b of the AF drive section 14 extends in the optical axis direction and holds the AF power transmission section 144, and the driving force of the AF drive section 14 is transmitted to the lens holder 11 to the maximum extent. The driving force for moving the lens holder 11 can be efficiently obtained. Moreover, since the lens holder 11 is biased by the first stage (AF fixing part) via the AF support part 15, its posture when moving in the optical axis direction is stabilized. Therefore, the driving performance of the lens driving device 1 is significantly improved.
Even if the camera module A having the lens drive device 1 is placed close to each other like the smartphone M, there is no magnetic influence, so it is extremely suitable for use with a dual camera.

Further, in the lens driving device 1, the biasing direction is parallel to the first side on which the AF driving section 14 is arranged.
Specifically, two AF support parts 15A (first support parts) are arranged on the first straight line L1 parallel to the urging direction on the outer peripheral surface of the lens holder 11 (first movable part).
Further, a leaf spring 181 (biasing member) is interposed between one of the set of AF support parts 15A (first support part) and the first stage 12 (first fixing part).
Further, the AF support part 15B (first support part) has two parts on the outer peripheral surface of the lens holder 11 (first movable part) on a second straight line L2 that is parallel to the urging direction and different from the first straight line L1. It is located.
Further, the two sets of AF support parts 15A and 15B (first support parts) are arranged at symmetrical positions with respect to a straight line L3 that is parallel to the biasing direction and passes through the optical axis.
Further, the AF support section 15 (first support section) is composed of balls arranged in line in the optical axis direction.
With the above configuration, the attitude of the lens holder 11 when moving in the optical axis direction can be made more stable.

As above, the invention made by the present inventor has been specifically explained based on the embodiments, but the present invention is not limited to the above embodiments, and can be modified without departing from the gist thereof.

For example, in the embodiment, the smartphone M, which is a camera-equipped mobile terminal, was described as an example of a camera-equipped device equipped with a camera module A. However, the present invention provides a camera module and image information obtained by the camera module. It can be applied to a camera-equipped device having an image processing section for processing. Camera-equipped devices include information equipment and transportation equipment. Information devices include, for example, a camera-equipped mobile phone, a notebook computer, a tablet terminal, a portable game machine, a web camera, and a camera-equipped vehicle-mounted device (for example, a back monitor device, a drive recorder device). Furthermore, transportation equipment includes, for example, automobiles.

FIG. 15A and FIG. 15B are diagrams showing an automobile V as a camera mounting device on which a vehicle camera module VC (Vehicle Camera) is mounted. 15A is a front view of the automobile V, and FIG. 15B is a rear perspective view of the automobile V. The automobile V is equipped with the camera module A described in the embodiment as the in-vehicle camera module VC. As shown in FIGS. 15A and 15B, the in-vehicle camera module VC is attached, for example, to a windshield facing forward, or to a rear gate facing rearward. This in-vehicle camera module VC is used for back monitors, drive recorders, collision avoidance control, automatic driving control, and the like.

In the embodiment, the lens holder 11 is urged in the X direction, but the direction in which the lens holder 11 is urged does not have to be in the X direction, as long as the lens holder 11 can be held in a stable posture. For example, in the embodiment, the two sets of AF support parts 15A and 15B are arranged on straight lines L1 and L2 that are parallel to the X direction, which is the urging direction, respectively, but the extending direction of the straight lines L1 and L2 is It may be in the Y direction or in a direction tilted from the X and Y directions. Furthermore, the straight lines L1 and L2 may intersect with each other or may not be arranged symmetrically with respect to the straight line passing through the optical axis.

Further, the present invention can be applied not only to autofocus but also to zooming and the like, where a movable part is moved in the optical axis direction.
Furthermore, the support structure of the AF unit is not limited to the case where the drive source is an ultrasonic motor like the AF drive section 14, but can also be used with a drive source other than the ultrasonic motor (for example, a voice coil motor (VCM)). The present invention can also be applied to a lens driving device provided with the present invention.

The embodiments disclosed this time should be considered to be illustrative in all respects and not restrictive. The scope of the present invention is indicated by the claims rather than the above description, and it is intended that all changes within the meaning and range equivalent to the claims are included.

1 Lens drive device 10 OIS movable part (second movable part)
11 AF movable part (first movable part)
12 First stage (first fixed part)
13 Second stage 14 AF drive section (Z direction drive section)
141 AF resonance part 142 AF piezoelectric element 143 AF electrode 144 AF power transmission part 15 AF support part (first support part)
20 OIS fixing part (second fixing part)
21 Base 30 OIS drive section (XY direction drive section)
31 OIS resonance part 32 OIS piezoelectric element 33 OIS electrode 34 OIS power transmission part 40 OIS support part (second support part)
50 OIS biasing member A Camera module M Smartphone (camera mounted device)

Claims (6)

A lens accommodating portion is provided on the inner side, and a ball holding portion having a shape protruding outward in the radial direction is provided on a part of the outer circumferential surface along a predetermined direction perpendicular to the optical axis direction, and the ball holding portion includes: A lens holder, wherein ball accommodating portions are formed at respective positions of both ends in the predetermined direction, and a driving portion is disposed on the outside of a side surface between the ball accommodating portions;
The lens holder is housed in an opening in which a cutout corresponding to the protruding shape of the ball holding part is formed, and the ball holding part and the driving part are housed in the cutout, and the predetermined shape is formed in the cutout. A fixing part, in which a ball fixing part is provided at each end in the direction;
a plurality of rows of balls parallel to the optical axis, each row being rotatably interposed between the ball accommodating part and the ball fixing part in the predetermined direction and respectively accommodated in the ball accommodating part; a supporting part that supports the lens holder driven by the driving part so as to be movable in the optical axis direction with respect to the fixed part;
stoppers for regulating downward movement of the lens holder are provided on the lower surface of the ball holding part at a plurality of locations corresponding to the positions of the ball accommodating part;
Lens drive device. comprising a biasing section that biases the ball row in the predetermined direction;
The lens driving device according to claim 1. The drive unit is an ultrasonic motor disposed opposite to a side surface of the ball holding unit,
A power transmission part that transmits the driving force of the ultrasonic motor is arranged between the ball accommodating parts in the predetermined direction on the side surface.
The lens driving device according to claim 1 or 2. The fixed part is arranged on the base so as to be movable in a direction perpendicular to the optical axis,
the stopper abuts on the base in a reference state when the drive unit is not driven;
The lens driving device according to any one of claims 1 to 3. A lens driving device according to any one of claims 1 to 4,
a lens accommodated in the lens accommodating section;
an imaging unit that captures a subject image formed by the lens;
The camera module. A camera-equipped device that is an information device or a transportation device,
A camera module according to claim 5;
an image processing unit that processes image information obtained by the camera module;
Camera-equipped device.

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