JP7506325B2 - Optical actuator, camera module, and camera-mounted device - Google Patents

Description

The present invention relates to an optical actuator, a camera module, and a camera-mounted device.

Thin camera-equipped devices equipped with a camera module, such as smartphones and digital cameras, are known in the art. The camera module includes a lens unit having one or more lenses, and an image sensor that captures the subject image formed by the lens unit.

A camera module has also been proposed that includes a bending optical system that uses a prism provided before the lens section to bend light from a subject along a first optical axis in the direction of a second optical axis and guide the light to the lens section (for example, Patent Document 1).

The camera module disclosed in Patent Document 1 includes a shake correction device that corrects camera shake that occurs in the camera, and an autofocus device that performs autofocus. Such a camera module has a shake correction actuator and an autofocus actuator as optical actuators. Of these, the shake correction actuator includes an actuator that oscillates a prism.

JP 2020-126231 A

In the case of the optical actuator described above, if the lens guide (movable part) that holds the lens collides with the base (fixed part) that holds the lens guide during autofocus or when an external impact is applied, the actuator does not have the function of absorbing the impact applied to the lens guide and base due to the collision.

The object of the present invention is to provide an optical actuator, a camera module, and a camera-mounted device that have the ability to absorb impact when a movable part and a fixed part collide.

One aspect of the optical actuator according to the present invention is
A movable part on which a lens part can be mounted;
A fixed part that houses a movable part;
A drive unit that moves the movable unit relative to the fixed unit;
and a shock absorbing section that absorbs shock when the movable section and the fixed section collide with each other.
The impact absorbing part has a soft part fixed to one of the movable part and the fixed part, and a hard part covering the surface of the soft part and abutting the other of the movable part and the fixed part upon collision.
When implementing the above-mentioned optical actuator, the soft portion may preferably be made of a damper material.
Moreover, the hard portion may be a leaf spring made of a material harder than the damper material.
In this case, the leaf spring is
A fixed region that is fixed to one member and does not come into contact with the other member during a collision;
The flexible portion may have a shock absorbing region that covers a surface of the flexible portion and elastically deforms upon contact with another member upon collision.

One aspect of the camera module according to the present invention includes the optical actuator described above and an imaging element arranged downstream of the lens unit.

One aspect of the camera-equipped device according to the present invention has the above-mentioned camera module and a control unit that controls the camera module.

The present invention provides an optical actuator, a camera module, and a camera-mounted device that can reduce the product size.

FIG. 1 is a perspective view illustrating a camera module according to an embodiment of the present invention. FIG. 2 is a perspective view of the camera module with the cover omitted. FIG. 3 is a perspective view for explaining the first base and the second base. FIG. 4 is a perspective view for explaining the first base and the second base. FIG. 5 is a perspective view of the holder. FIG. 6 is a perspective view of the holder. FIG. 7 is a perspective view of the support wall portion of the first base. FIG. 8A is a cross-sectional view of the light path bending module. FIG. 8B is a schematic cross-sectional view of the optical bending module. FIG. 9 is a perspective view of the FPC. FIG. 10 is a perspective view of the FPC. FIG. 11 is a perspective view of the first drive unit, the second drive unit, and the third drive unit. FIG. 12 is a perspective view of the lens guide. FIG. 13 is a perspective view of the lens guide. FIG. 14 is a bottom view of the lens guide. FIG. 15 is a perspective view of the lens guide to which the shock absorbing portion is attached. FIG. 16 is a perspective view of the lens guide to which the shock absorbing portion is attached. FIG. 17 is a partial cross-sectional view of the lens module taken along line XX in FIG. 18 is a partial cross-sectional view of the lens module taken along line YY in FIG. FIG. 19 is a partial cross-sectional view of the lens module taken along line ZZ in FIG. FIG. 20 is a perspective view of the shock absorbing portion. FIG. 21 is a perspective view of the shock absorbing portion. FIG. 22A is a partial cross-sectional view of a lens module for explaining the function of a shock absorbing portion. FIG. 22B is a partial cross-sectional view of the lens module for explaining the function of the shock absorbing portion. FIG. 23A is a diagram showing an example of a camera-mounted device equipped with a camera module. FIG. 23B is a diagram showing an example of a camera-mounted device equipped with a camera module. FIG. 24A is a diagram showing an automobile as a camera-mounted device equipped with an in-vehicle camera module. FIG. 24B is a diagram showing an automobile as a camera-mounted device equipped with an in-vehicle camera module.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the drawings. Note that the optical actuator, camera module, and camera-mounted device according to the embodiments described below are examples of the optical actuator, camera module, and camera-mounted device according to the present invention, and the present invention is not limited to the embodiments.

[Embodiment]
A camera module 1 according to an embodiment of the present invention will be described with reference to Figures 1 to 24B. Below, an overview of the camera module 1 will be described, and then structures of the light path bending module 2, lens module 4, and image sensor module 9 included in the camera module 1 will be described. Note that the optical actuator, camera module, and camera-mounted device according to the present invention may include all of the configurations described below, or may not include some of the configurations.

The camera module 1 is mounted, for example, on a smartphone M (see Figs. 23A and 23B), a mobile phone, a digital camera, a notebook computer, a tablet terminal, a portable game machine, and a thin camera-mounted device (such as an in-vehicle camera). The smartphone M has a dual camera consisting of two rear cameras OC1 and OC2. In this embodiment, the camera module 1 is applied to the rear camera OC2.

The following describes each part of the camera module 1 of this embodiment based on the state in which it is incorporated into the camera module 1. In addition, the Cartesian coordinate system (X, Y, Z) shown in each figure is used to explain the structure of the camera module 1 of this embodiment.

When an image is actually captured by the camera-mounted device, the camera module 1 is mounted so that, for example, the X direction is the left-right direction of the camera-mounted device, the Y direction is the up-down direction of the camera-mounted device, and the Z direction is the front-back direction of the camera-mounted device. Light from a subject (incident light) enters the prism 22 of the light path bending module 2 from the Z direction + side (plus side) of the camera module 1, as shown by the dashed dotted line α (also called the first optical axis) in Figure 1. The prism 22 is an example of a light path bending member.

The light (outgoing light) incident on the prism 22 is bent at the optical path bending surface of the prism 22 as shown by the dashed line β (also called the second optical axis) in Figure 1, and is guided to the lens section 6 of the lens module 4, which is arranged in front of the prism 22 (on the + side in the X direction).

The subject image formed by the lens unit 6 is then captured by the image sensor module 9 (see FIG. 2), which is arranged in front of the lens module 4.

The camera module 1 of this embodiment performs shake correction (OIS: Optical Image Stabilization) using the shake correction device 3 built into the light path bending module 2. In other words, the light path bending module 2 has a hand shake correction function.

In addition, the camera module 1 of this embodiment performs autofocus by displacing the lens unit in the X direction using the AF (Auto Focus) device 7 built into the lens module 4. In other words, the lens module 4 has an autofocus function.

(Light path bending module)
The light path bending module 2 will be described with reference to Figures 1 to 11. The light path bending module 2 includes a cover 93, a first base 21, a prism 22, and a shake correction device 3.

The first base 21 has a support portion 214b inserted into the recess 314 of the holder 31 so as to define the center of oscillation of the holder 31 at a position near the center of the mounting surface 310 of the holder 31.

Specifically, the first base 21 has a first base body 210 and a support wall portion 214. The first base 21 is combined with the cover 93 to form a storage space in which the prism 22 and the shake correction device 3 can be placed.

The first base body 210 is an example of a fixing part body, and is a U-shaped member with openings at the front end, rear end, and top end. The first base body 210 has a bottom wall portion 211, a left wall portion 212, and a right wall portion 213. The first base body 210 is connected at its front end portion to the second base 5, which will be described later. In other words, the first base body 210 and the second base 5 are integral.

The bottom wall portion 211 is a plate parallel to the XY plane. The bottom wall portion 211 has a second coil arrangement portion 211a for arranging the second coil 371 of the second drive portion 37. The second coil arrangement portion 211a is a through hole.

The left wall portion 212 is a plate-like member parallel to the XZ plane, with its lower end connected to the left end of the bottom wall portion 211. The left wall portion 212 has a left first coil arrangement portion 212a for arranging the left first coil 341 of the first drive portion 33. The left first coil arrangement portion 212a is a through hole.

The right wall portion 213 is a plate-like member parallel to the XZ plane, with its lower end connected to the right end of the bottom wall portion 211. The right wall portion 213 has a right first coil arrangement portion 213a for arranging the right first coil 351 of the first drive portion 33. The right first coil arrangement portion 213a is a through hole.

The support wall portion 214 is a separate member from the first base body 210, and has a rear wall portion 214a and a support portion 214b. The rear wall portion 214a is a plate-like member parallel to the YZ plane. The rear wall portion 214a closes the rear end of the first base body 210. The rear wall portion 214a is supported by the first base body 210 via a biasing spring 322, which will be described later.

The support portion 214b is provided on the front side surface of the rear wall portion 214a to support the holder 31 (described later) so that it can swing. The support portion 214b is composed of a protrusion extending forward (positive side in the X direction) from the rear wall portion 214a. At the tip of the support portion 214b, there is a cone-shaped protrusion-side tapered surface 214c whose inner diameter becomes smaller as it advances rearward.

When inserted into the recess 314 of the holder 31 (described below), the support portion 214b supports the holder 31 via the ball 321 so that the holder 31 can swing. The manner in which the support portion 214b supports the holder 31 will be described later.

In this embodiment, the support portion 214b is provided on the rear wall portion 214a of the first base 21. However, the configuration of the support portion is not limited to this embodiment. For example, the support portion may be provided on the bottom wall portion of the first base. In this case, the support portion may extend upward from the bottom wall portion of the first base. In this case, the recess of the holder may be provided on the lower side surface of the holder.

Next, the shake correction device 3 will be described. The shake correction device 3 performs shake correction in the rotational direction about the first axis A1 and shake correction in the rotational direction about the second axis A2 by swinging the prism 22 about a first axis A1 parallel to the Z direction and a second axis A2 parallel to the Y direction. Such a shake correction device 3 is disposed in a storage space surrounded by the cover 93 and the first base 21. In this embodiment, the first axis A1 and the second axis A2 are straight lines passing through the ball 321.

The shake correction device 3 includes a holder 31, a swing support unit 32, a first drive unit 33, and a second drive unit 37.

In the shake correction device 3, the holder 31 is supported on the first base 21 via the swing support part 32. The holder 31 can swing relative to the first base 21 around the first axis A1 and around the second axis A2. In this state, the holder 31 swings around the first axis A1 based on the driving force generated by the first drive part 33, and swings around the second axis A2 based on the driving force generated by the second drive part 37.

When the first drive unit 33 is driven under the control of the control unit 92 (see FIG. 1), the holder 31 and the prism 22 oscillate around the first axis A1. This corrects the vibration in the rotational direction around the first axis A1. When the second drive unit 37 is driven under the control of the control unit 92 (see FIG. 1), the holder 31 and the prism 22 oscillate around the second axis A2. This corrects the vibration in the rotational direction around the second axis A2. The specific structure of each component of the vibration correction device 3 is described below.

The holder 31 supports the prism 22 (see FIG. 1) so that it can swing relative to the first base 21. The holder 31 has a mounting surface 310 on which the prism 22 is mounted, and a recess 314 that extends toward the center of the mounting surface on the back side of the mounting surface 310, and swings when driven by the first drive unit 33 and the second drive unit 37.

Specifically, the holder 31 is disposed in a space surrounded by the bottom wall portion 211, the left wall portion 212, the right wall portion 213, and the rear wall portion 214a of the first base 21. The holder 31 is swingable about the first axis A1 and about the second axis A2 relative to the first base 21. Therefore, the prism 22 is also swingable about the first axis A1 and about the second axis A2 relative to the first base 21.

The holder 31 is made of, for example, synthetic resin. The holder 31 has a mounting surface 310 on which the prism 22 can be mounted. The mounting surface 310 is provided between the left side and right side of the holder 31, and is an inclined surface that is inclined so that it is positioned lower (negative side in the Z direction) as it moves forward (positive side in the X direction).

The holder 31 has a left side first magnet arrangement portion 311 on the left side surface for arranging the left side first magnet 340 of the first drive unit 33 described below. The left side first magnet arrangement portion 311 is configured as a recess. The left side first magnet arrangement portion 311 faces the left side first coil arrangement portion 212a of the first base body 210.

The holder 31 has a right-side first magnet arrangement portion 312 on its right side surface for arranging a right-side first magnet 350 of the first drive unit 33 described below. The right-side first magnet arrangement portion 312 is configured as a recess. The right-side first magnet arrangement portion 312 faces the right-side first coil arrangement portion 213a of the first base body 210 in the left-right direction.

The holder 31 has a second magnet arrangement section 313 on its lower surface for arranging the second magnet 370 of the second drive section 37 described below. The second magnet arrangement section 313 is configured as a recess. The second magnet arrangement section 313 faces the second coil arrangement section 211a of the first base body 210 in the vertical direction.

The holder 31 has a recess 314 on the rear side. The recess 314 extends forward from the rear side of the holder 31. In other words, the recess 314 extends from the rear side of the holder 31 toward the center of the mounting surface 310. The central axis of the recess 314 is parallel to the front-rear direction. The holder 31 also has a spring fixing portion 314b around the recess 314 on the rear side (see FIG. 6). The spring fixing portion 314b also has multiple (four in this embodiment) locking protrusions 314c. The inner fixing portion 324 of the biasing spring 322 described below is fixed to the spring fixing portion 314b by a fixing means such as adhesive. In this state, the locking protrusions 314c are each inserted into the locking holes 324b in the inner fixing portion 324.

The recess 314 has a conical recess-side tapered surface 314a at its inner end, the inner diameter of which decreases toward the front. The taper angle θ ₁ (see FIG. 8A ) of the recess-side tapered surface 314a is smaller than the taper angle θ ₂ of the protrusion-side tapered surface 214c of the first base 21. By adopting such a configuration, it becomes easier to ensure the thickness around the recess 314 (near the center of the mounting surface 310), thereby suppressing a decrease in the strength of the holder 31.

The support portion 214b of the first base 21 is inserted into the recess 314. The outer diameter of the support portion 214b is smaller than the inner diameter of the recess 314. Therefore, the outer peripheral surface of the support portion 214b does not abut against the inner peripheral surface of the recess 314.

The holder 31 having the above-described configuration is housed in the first base 21. In this state, the holder 31 is supported by the swing support part 32 on the first base 21 in a swingable state relative to the first base 21.

Next, the swing support part 32 will be described. The swing support part 32 is composed of the support part 214b of the first base 21, the ball 321, the recess 314 of the holder 31, and the biasing spring 322.

As shown in FIG. 8A, the support portion 214b is inserted into the recess 314. In addition, a ball 321 is disposed between the convex side tapered surface 214c of the support portion 214b and the recess side tapered surface 314a of the recess 314. The center of the ball 321 (i.e., the swing center of the holder 31) and the second drive portion 37 described below are disposed on the same straight line parallel to the Z direction.

The biasing spring 322 biases the holder 31 backward. In other words, the biasing spring 322 biases the recess 314 toward the support portion 214b. Therefore, the ball 321 is sandwiched between the convex side tapered surface 214c and the concave side tapered surface 314a.

Specifically, the biasing spring 322 is an example of a biasing member, and as shown in FIG. 7, has an outer fixing portion 323, an inner fixing portion 324, and a connecting portion 325.

The outer fixing part 323 is an example of a first fixing part, has a plate shape parallel to the YZ plane, and is fixed to the first base body 210 of the first base 21. Specifically, the outer fixing part 323 has a left fixing part 323a and a right fixing part 323b. The left fixing part 323a is fixed to the rear end part of the left wall part 212 of the first base body 210. The right fixing part 323b is fixed to the rear end part of the right wall part 213 of the first base body 210.

The inner fixing part 324 is an example of a second fixing part and is a plate parallel to the YZ plane. The inner fixing part 324 has a central hole 324a and multiple (four in this embodiment) locking holes 324b. The locking holes 324b are provided around the central hole 324a. The inner fixing part 324 is fixed to the holder 31. Specifically, the inner fixing part 324 is fixed to the spring fixing part 314b provided on the rear side of the holder 31 by a fixing means such as adhesive. In this state, the support part 214b is inserted into the central hole 324a of the inner fixing part 324, and the locking protrusions 314c provided on the spring fixing part 314b are inserted into each of the locking holes 324b of the inner fixing part 324.

The connection portion 325 is an elastically deformable line that connects the outer fixing portion 323 and the inner fixing portion 324. Specifically, the connection portion 325 has a pair of left connecting portions 325a, 325b and a pair of right connecting portions 325c, 325d.

The pair of left-side connecting portions 325a, 325b and the pair of right-side connecting portions 325c, 325d each have a serpentine portion.

In the assembled state, the connection portion 325 elastically deforms so as to bias the inner fixing portion 324 rearward. Therefore, the biasing spring 322 biases the holder 31 rearward toward the support wall portion 214 based on the restoring force of the connection portion 325. As a result, the recess 314 of the holder 31 is biased rearward toward the support portion 214b by the biasing spring 322.

The first drive unit 33 swings the holder 31 around the first axis A1. The first axis A1 is an axis parallel to the Z direction. Specifically, the first axis A1 is an axis that passes through the center of the ball 321 of the swing support unit 32 and is parallel to the Z direction. The center of the ball 321 may be considered to be the swing center of the swing of the holder 31 based on the drive of the first drive unit 33.

The first drive unit 33 has a left first drive unit 34, a right first drive unit 35, and a first position detection element 36.

The left first drive unit 34 is provided between the left side surface of the holder 31 and the left FPC 81 of the FPC (Flexible Printed Circuit) 8 fixed to the left wall portion 212 of the first base 21.

Now, the FPC 8 will be described with reference to Figures 9 and 10. The FPC 8 has a left FPC 81, a right FPC 82, and a lower FPC 83.

The left FPC 81 is a plate parallel to the XZ plane and extends in the front-rear direction from the light path bending module 2 to the lens module 4. The left FPC 81 is fixed to the left side surfaces of the light path bending module 2 and the lens module 4.

The left FPC 81 has a left terminal section 810 consisting of multiple terminals arranged vertically at the front end. The left terminal section 810 is, for example, a terminal connected to the positive side of a power source. The left terminal section 810 is connected to the left first coil 341 and the first position detection element 36 of the first driving section 33, the second coil 371 and the second position detection element 372 of the second driving section 37, and the left third coil 731 and the third position detection element 75 of the third driving section 72 via wiring provided on the FPC 8.

The right-side FPC 82 is a plate parallel to the XZ plane and extends in the front-rear direction from the light path bending module 2 to the lens module 4. The right-side FPC 82 is fixed to the right side surfaces of the light path bending module 2 and the lens module 4.

The right-side FPC 82 has a right-side terminal portion 820 composed of multiple terminals arranged vertically at the front end. The right-side terminal portion 820 is, for example, a terminal connected to the negative side of a power source. The right-side terminal portion 820 is connected to the right-side first coil 351 and the first position detection element 36 of the first driving unit 33, the second coil 371 and the second position detection element 372 of the second driving unit 37, and the right-side third coil 741 and the third position detection element 75 of the third driving unit 72 via wiring provided on the FPC 8.

The lower FPC 83 is a plate parallel to the XY plane, and connects the lower end of the left FPC 81 and the lower end of the right FPC 82 in the left-right direction below the light path bending module 2. The lower FPC 83 is fixed to the lower surface of the light path bending module 2.

Returning to the description of the left first drive unit 34, the left first drive unit 34 is a voice coil motor and has a left first magnet 340 and a left first coil 341.

The left first magnet 340 is disposed in the left first magnet arrangement portion 311 of the holder 31. The left first magnet 340 is fixed to the left first magnet arrangement portion 311 of the holder 31 by a fixing means such as adhesive.

The left first magnet 340 consists of two magnet elements adjacent to each other in the front-to-rear direction. Each of these magnet elements is arranged so that its longitudinal direction coincides with the vertical direction. Each of these magnet elements is magnetized in the left-to-right direction and has one magnetic pole on one side. The magnetic poles of each magnet element are oriented in the opposite direction.

The left first coil 341 is an elliptical, so-called air-core coil that is supplied with power during shake correction. The long axis of the left first coil 341 coincides with the up-down direction. The left first coil 341 is arranged in the left first coil arrangement portion 212a of the first base body 210 and is fixed to the left FPC 81 by a fixing means such as adhesive.

The left first coil 341 is provided to the left (outside in the width direction) of the left first magnet 340. The left first coil 341 faces the left first magnet 340 with a predetermined gap in the left-right direction.

In this embodiment, the left first magnet 340 is provided in the movable part, and the left first coil 341 is provided in the fixed part. However, the left first magnet 340 may be provided in the fixed part, and the left first coil 341 may be provided in the movable part.

The right-side first drive unit 35 is provided between the right side surface of the holder 31 and the right-side FPC 82 of the FPC 8 fixed to the right wall portion 213 of the first base 21.

The right-side first drive unit 35 is also a voice coil motor and has a right-side first magnet 350 and a right-side first coil 351.

The right-side first magnet 350 is disposed in the right-side first magnet arrangement portion 312 of the holder 31. The right-side first magnet 350 is fixed to the right-side first magnet arrangement portion 312 of the holder 31 by a fixing means such as adhesive.

The right-side first magnet 350 consists of two magnet elements adjacent to each other in the front-to-rear direction. Each of these magnet elements is arranged so that its longitudinal direction coincides with the up-to-down direction. Each of these magnet elements is magnetized in the left-to-right direction and has one magnetic pole on one side. The magnetic poles of each magnet element are oriented in the opposite directions.

The right-side first coil 351 is an elliptical, so-called air-core coil that is supplied with power during shake correction. The long axis of the right-side first coil 351 coincides with the up-down direction. The right-side first coil 351 is fixed to the right-side FPC 82 by a fixing means such as adhesive while being disposed in the right-side first coil arrangement portion 213a of the first base body 210. The right-side first coil 351 is electrically connected to the left-side first coil 341 via the FPC 8.

The right-side first coil 351 is provided to the right (outside in the width direction) of the right-side first magnet 350. The right-side first coil 351 faces the right-side first magnet 350 with a predetermined gap in between in the left-right direction.

In this embodiment, the right-side first magnet 350 is provided in the movable part, and the right-side first coil 351 is provided in the fixed part. However, the right-side first magnet 350 may be provided in the fixed part, and the right-side first coil 351 may be provided in the movable part.

As shown in FIG. 10, the first position detection element 36 is fixed to the left FPC 81 while being disposed in the center of the left first coil 341. The first position detection element 36 faces the left first magnet 340 in the left-right direction. The first position detection element 36 detects the magnetic flux of the left first magnet 340 and sends the detection value to a control unit 92 mounted on a sensor board 91. The control unit 92 determines the position of the holder 31 around the first axis A1 based on the detection value received from the first position detection element 36.

In the case of the first drive unit 33 having the above-mentioned configuration, when a current flows through the left first coil 341 and the right first coil 351 via the FPC 8 under the control of the control unit 92, a Lorentz force is generated that displaces the left first magnet 340 and the right first magnet 350 in the front-rear direction.

Specifically, the above Lorentz force acts on the left first magnet 340 in one direction in the front-to-rear direction. On the other hand, the above Lorentz force acts on the right first magnet 350 in the other direction in the front-to-rear direction. In this way, forces acting in opposite directions in the front-to-rear direction act on the left first magnet 340 and the right first magnet 350.

The left first magnet 340 and the right first magnet 350 are each fixed to the holder 31, so that the holder 31 oscillates about the first axis A1 based on the Lorentz force. The direction of movement (rotation direction) of the holder 31 can be switched by controlling the direction of the current flowing through the left first coil 341 and the right first coil 351.

The second drive unit 37 swings the holder 31 around the second axis A2. The second axis A2 passes through the center of the ball 321 of the swing support unit 32 and is parallel to the Y direction. The center of the ball 321 may be considered as the swing center of the swing of the holder 31 based on the drive of the second drive unit 37.

The second drive unit 37 has a second magnet 370, a second coil 371, and a second position detection element 372. The second drive unit 37 is provided between the lower surface of the holder 31 and the bottom wall portion 211 of the first base 21.

The second magnet 370 is arranged in the second magnet arrangement portion 313 of the holder 31. The second magnet 370 is fixed to the second magnet arrangement portion 313 by a fixing means such as adhesive.

The second magnet 370 consists of two magnet elements adjacent to each other in the front-to-rear direction. Each of these magnet elements is arranged so that its longitudinal direction coincides with the left-to-right direction. Each of these magnet elements is magnetized in the up-down direction and has one magnetic pole on one side. The magnetic poles of each magnet element are oriented in the opposite directions.

The second coil 371 is an oval-shaped, so-called air-core coil that is supplied with power during shake correction. The second coil 371 is arranged so that its major axis coincides with the left-right direction. The second coil 371 is fixed to the lower FPC 83 of the FPC 8 while being arranged in the second coil arrangement portion 211a of the first base 21.

The second coil 371 is disposed below the second magnet 370. The second coil 371 faces the second magnet 370 at a predetermined distance in the vertical direction.

The second position detection element 372 (see Figures 8A and 9) is fixed to the lower FPC 83 while being disposed in the center of the second coil 371. The second position detection element 372 faces the second magnet 370 in the vertical direction. The second position detection element 372 detects the magnetic flux of the second magnet 370 and sends the detection value to the control unit 92 mounted on the sensor board 91. The control unit 92 determines the position of the holder 31 around the second axis A2 based on the detection value received from the second position detection element 372.

In the case of the second drive unit 37 having the above-mentioned configuration, when a current flows through the second coil 371 via the FPC 8 under the control of the control unit 92, a Lorentz force is generated that moves the second magnet 370 in one direction in the forward/rearward direction.

Since the second magnet 370 is fixed to the holder 31, the holder 31 swings about the second axis A2 based on the Lorentz force. The direction of movement (rotation) of the holder 31 can be changed by controlling the direction of the current flowing through the second coil 371.

(Lens module)
Next, the lens module 4 will be described with reference to Figures 1 to 4 and Figures 11 to 21. The lens module 4 has a cover 93, a second base 5, a lens unit 6, an AF device 7, and a shock absorbing unit 76.

The second base 5 is an example of a fixed part, and when combined with the cover 93, forms a storage space in which the lens unit 6 and the AF device 7 can be placed. The second base 5 supports the lens guide 70 of the lens unit 6 via a support mechanism 71, which will be described later.

The second base 5 has a bottom wall portion 50, a left wall portion 51, a right wall portion 52, and a front wall portion 53. The rear end portion of the second base 5 is connected to the front end portion of the first base 21. Thus, the first base 21 and the second base 5 are integral.

The bottom wall portion 50 is a rectangular plate parallel to the XY plane. The bottom wall portion 50 constitutes the bottom of the second base 5. The rear end portion of the bottom wall portion 50 is connected to the bottom wall portion 211 of the first base body 210.

The bottom wall portion 50 has a left groove portion 500 (see FIG. 4) and a right groove portion 501 (see FIG. 3) on the upper surface. The left groove portion 500 and the right groove portion 501 are spaced apart in the left-right direction and are parallel to each other. The left groove portion 500 and the right groove portion 501 each extend in the front-rear direction.

The left side groove portion 500 has two left side first support portions 500a, 500b (see FIG. 4) in the front-rear direction. The left side first support portion 500a is provided at the front end portion of the left side groove portion 500. As shown in FIG. 17, the left side first support portion 500a has a pair of tapered support surfaces 500c, 500d that are V-shaped.

The left first support portion 500b is provided at the rear end of the left groove portion 500. As shown in FIG. 19, the left first support portion 500b has a pair of tapered support surfaces 500c, 500d that are V-shaped.

As shown in Figures 17 to 19, the lower half of the left shaft 710 is disposed in the left groove 500. The left shaft 710 is cylindrical and disposed with its central axis aligned in the front-to-rear direction. The left shaft 710 is supported from below by the first left support parts 500a, 500b in the left groove 500. The left shaft 710 is supported by the second base 5 at two points in the axial direction.

The left shaft 710 also contacts the pair of tapered support surfaces 500c, 500d of the left first support parts 500a, 500b at two locations in the axial direction (front-to-back direction). Therefore, the left shaft 710 contacts the second base 5 at two locations in the width direction at two locations in the axial direction (front-to-back direction). The contact between the left shaft 710 and the pair of tapered support surfaces 500c, 500d is line contact.

The front end surface of the left shaft 710 abuts against the front end of the left groove portion 500. The rear end surface of the left shaft 710 abuts against the rear end of the left groove portion 500. With this configuration, the left shaft 710 is positioned in the front-rear direction relative to the second base 5.

The right side groove portion 501 has right side first support portions 501a, 501b (see FIG. 3) at two locations in the front-rear direction. The right side first support portion 501a is provided at the front end portion of the right side groove portion 501. As shown in FIG. 17, the right side first support portion 501a has a pair of tapered support surfaces 501c, 501d that are V-shaped.

The right-side first support portion 501b is provided at the rear end of the right-side groove portion 501. As shown in FIG. 19, the right-side first support portion 501b has a pair of tapered support surfaces 501c, 501d that are V-shaped.

As shown in Figures 17 to 19, the lower half of the right shaft 711 is disposed in the right groove 501. The right shaft 711 is cylindrical and disposed with its central axis aligned in the front-to-rear direction. The right shaft 711 is supported from below by the right first support parts 501a, 501b in the right groove 501. The right shaft 711 is supported by the second base 5 at two points in the axial direction.

The right shaft 711 also abuts against a pair of tapered support surfaces 501c, 501d of the right first support parts 501a, 501b at two locations in the axial direction (front-to-back direction). Therefore, the right shaft 711 contacts the second base 5 at two locations in the width direction, at two locations in the axial direction (front-to-back direction). The contact between the right shaft 711 and the pair of tapered support surfaces 501c, 501d is line contact.

The front end surface of the right shaft 711 abuts against the front end of the right groove portion 501. The rear end surface of the right shaft 711 abuts against the rear end of the right groove portion 501. With this configuration, the right shaft 711 is positioned in the front-rear direction relative to the second base 5.

A left yoke 502 (see FIG. 11) is provided in the bottom wall 50 at a position vertically facing the left third magnet 730 described below. A right yoke 503 (see FIG. 11) is provided in the bottom wall 50 at a position vertically facing the right third magnet 740 described below. Based on the attractive force between the left yoke 502 and the left third magnet 730, and the attractive force between the right yoke 503 and the right third magnet 740, the lens guide 70 described below is biased downward toward the bottom wall 50 of the second base 5.

The left wall portion 51 is a plate-like member parallel to the XZ plane, with its lower end connected to the left end of the bottom wall portion 50. The left wall portion 51 has a left-side third coil arrangement portion 510 (see FIG. 4) for arranging the left-side third coil 731 of the third drive portion 72. The left-side third coil arrangement portion 510 is a through hole.

The left wall 51 has a front stopper portion 511 (see FIG. 4) at the front end of the inner surface (right side surface). The front stopper portion 511 is a rectangular plate extending from the inner surface of the left wall 51 to the right (inner side in the width direction). The rear end surface of the front stopper portion 511 faces the front end surface of the left wall portion 703 of the lens guide 70 (described below) in the front-rear direction. The rear end surface of the front stopper portion 511 functions as a stopper surface that restricts the forward movement of the lens guide 70 within a predetermined range.

The left wall 51 has a rear stopper portion 512 (see FIG. 4) at the rear end of the inner surface (right side surface). The rear stopper portion 512 is a rectangular plate extending from the inner surface of the left wall 51 to the right (inner side in the width direction). The front end surface of the rear stopper portion 512 faces the rear end surface of the left wall portion 703 of the lens guide 70 (described below) in the front-rear direction. The front end surface of the rear stopper portion 512 functions as a stopper surface that restricts the rearward movement of the lens guide 70 within a predetermined range.

The right wall portion 52 is a plate-like member parallel to the XZ plane, with its lower end connected to the right end of the bottom wall portion 50. The right wall portion 52 has a right-side third coil arrangement portion 520 (see FIG. 3) for arranging the right-side third coil 741 of the third drive portion 72. The right-side third coil arrangement portion 520 is a through hole.

The right wall portion 52 has a front stopper portion 521 (see FIG. 3) at the front end portion of the inner surface (left side surface). The front stopper portion 521 is a rectangular plate extending from the inner surface of the right wall portion 52 to the left (inside in the width direction). The rear end surface of the front stopper portion 521 faces the front end surface of the right wall portion 704 of the lens guide 70 (described below) in the front-rear direction. The rear end surface of the front stopper portion 521 functions as a stopper surface that restricts the forward movement of the lens guide 70 within a predetermined range.

The right wall portion 52 has a rear stopper portion 522 (see FIG. 3) at the rear end of the inner surface (left side surface). The rear stopper portion 522 is a rectangular plate extending from the inner surface of the right wall portion 52 to the right side (inner side in the width direction). The front end surface of the rear stopper portion 522 faces the rear end surface of the right wall portion 704 of the lens guide 70 (described below) in the front-rear direction. The front end surface of the rear stopper portion 522 functions as a stopper surface that restricts the rearward movement of the lens guide 70 within a predetermined range.

The front wall portion 53 has a rectangular frame shape parallel to the YZ plane. In the second base 5, the imaging element 90 of the imaging element module 9 is disposed at a position adjacent to the rear side surface of the front wall portion 53. The imaging element 90 is, for example, an imaging element such as a CCD (charge-coupled device) type image sensor or a CMOS (complementary metal oxide semiconductor) type image sensor.

The lens unit 6 (see FIG. 1) is held by a lens guide 70, which will be described later. The lens unit 6 has a cylindrical lens barrel and one or more lenses held by the lens barrel. For example, the lens unit 6 has a telephoto lens group, for example with an optical magnification of 3x or more, fixed between the end of the lens barrel on the negative side in the X direction and the end of the lens barrel on the positive side in the X direction.

The AF device 7 moves the lens unit 6 in a direction parallel to the second optical axis (X direction) for the purpose of autofocus. Specifically, the AF device 7 has a lens guide 70, a support mechanism 71, and a third drive unit 72.

The lens guide 70 is an example of a movable part, and holds the lens barrel of the lens unit 6. The lens guide 70 is supported by the second base 5 via a support mechanism 71 in a state in which it can move at least in the direction of the second optical axis (X direction).

The lens guide 70 is U-shaped and open at the front, rear, and top. Specifically, the lens guide 70 has a bottom wall portion 700, a left wall portion 703, and a right wall portion 704.

The bottom wall portion 700 faces the bottom wall portion 50 of the second base 5 with a gap therebetween in the up-down direction. As shown in Figures 13 and 14, the bottom wall portion 700 has a left groove portion 701 and a right groove portion 702 on the lower surface. The left groove portion 701 and the right groove portion 702 are spaced apart in the left-right direction and are parallel to each other.

The left side groove portion 701 and the right side groove portion 702 are examples of a first groove portion and a second groove portion, respectively, and extend in the front-rear direction. The left side groove portion 701 and the right side groove portion 702 face the left side groove portion 500 and the right side groove portion 501 of the second base 5 in the up-down direction.

The left side groove 701 has left side second support portions 701a and 701b at two locations in the front-to-rear direction. The left side second support portion 701a is an example of a support surface and is provided at the front end portion of the left side groove 701. The left side second support portion 701b is an example of a support surface and is provided at the rear end portion of the left side groove 701.

The left second support parts 701a and 701b face the left first support parts 500a and 500b of the second base 5 in the up-down direction. The left second support part 701a has a pair of tapered support surfaces 701c and 701d arranged in a V-shape (see FIG. 17). The left second support part 701b has a pair of tapered support surfaces 701c and 701d arranged in a V-shape.

As shown in Figures 17 to 19, the upper half of the left shaft 710 is disposed in the left groove 701. The left shaft 710 abuts against the left second support parts 701a and 701b from below in the left groove 701. The left shaft 710 supports the lens guide 70 from below at two points in the axial direction.

Specifically, the left shaft 710 abuts against a pair of tapered support surfaces 701c, 701d of the left second support parts 701a, 701b at two locations in the axial direction (front-rear direction). Therefore, the left shaft 710 contacts the lens guide 70 at two locations in the axial direction (front-rear direction).

The contact between the left shaft 710 and the pair of tapered support surfaces 701c, 701d is a line contact. The front and rear end faces of the left shaft 710 do not abut against the lens guide 70.

In this embodiment, the left groove 701 has a constricted shape so that the space inside the groove is narrowed (shallowed and/or narrowed) by the tapered support surfaces 701c, 701d of the left second support parts 701a, 701b. Therefore, in the normal state, the left shaft 710 and the left groove 701 are not in contact with each other in any part other than the left second support parts 701a, 701b.

The right side groove 702 has a right side second support portion 702a at one location in the front-rear direction. The right side second support portion 702a is provided in the center of the right side groove portion 702 in the front-rear direction. The right side second support portion 702a has a curved support surface 702b that is convex downward. The support surface 702b is a curved surface centered on a central axis parallel to the Y direction. The support surface 702b is also provided in a flat shape in a cross section viewed from the X direction. The cross section viewed from the X direction means a cross section when the support surface 702b is cut by a plane parallel to the YZ plane. The flat shape in a cross section viewed from the X direction means that there are no or almost no corners, irregularities, or curvatures in the cross section.

The position of the right second support part 702a in the front-rear direction is between the left second support part 701a and the left second support part 701b. In addition, a straight line parallel to the Z direction passing through the center of gravity G of the lens guide 70 carrying the lens part 6 passes through a triangular area (see FIG. 14) formed by straight lines connecting the positions of the right second support part 702a, the left second support part 701a, and the left second support part 701b. This configuration allows the lens guide 70 to be stably supported on the second base 5.

As shown in Figures 17 to 19, the upper half of the right shaft 711 is disposed in the right groove 702. As shown in Figure 18, the right shaft 711 abuts against the right second support portion 702a from below in the right groove 702. The right shaft 711 supports the lens guide 70 from below at one point in the axial direction.

Specifically, the right shaft 711 abuts against the support surface 702b of the right second support portion 702a at one point in the axial direction (front-rear direction). The contact between the support surface 702b and the right shaft 711 is point contact. This configuration allows the lens guide 70 to move stably. The front end surface and the rear end surface of the right shaft 711 do not abut against the lens guide 70.

In this embodiment, the right groove 702 has a constricted shape so that the space inside the groove is narrowed (shallowed and/or narrowed) by the support surface 702b of the right second support part 702a. Therefore, in the normal state, the right shaft 711 and the right groove 702 are not in contact with each other except at the right second support part 702a. When the lens guide 70 is tilted at a predetermined angle or more with respect to the front-to-rear direction, the upper end of the right shaft 711 abuts against the front stopper part 702c or the rear stopper part 702d described below.

As shown in FIG. 14, the right groove portion 702 has a front stopper portion 702c and a rear stopper portion 702d. The front stopper portion 702c is provided forward of the right second support portion 702a in the front-rear direction. The rear stopper portion 702d is provided rearward of the right second support portion 702a in the front-rear direction.

The front stopper portion 702c and the rear stopper portion 702d are each a convex portion that protrudes downward from the bottom of the right groove portion 702. The positions of the front stopper portion 702c and the rear stopper portion 702d in the up-down direction are above the lower end portion (tip portion) of the support surface 702b of the right second support portion 702a.

When the lens guide 70 is parallel to the front-to-rear direction, the front stopper portion 702c and the rear stopper portion 702d do not come into contact with the right shaft 711. On the other hand, when the lens guide 70 is tilted relative to the front-to-rear direction (in other words, when the lens guide 70 rotates around an axis parallel to the Y direction), the front stopper portion 702c or the rear stopper portion 702d comes into contact with the upper end of the right shaft 711. In this way, the front stopper portion 702c and the rear stopper portion 702d prevent the lens guide 70 from being significantly tilted relative to the front-to-rear direction.

The left wall portion 703 is a plate-like member parallel to the XZ plane, with its lower end connected to the left end of the bottom wall portion 700. The left wall portion 703 has a left third magnet arrangement portion 703a on its left side surface (the outer surface in the width direction) for arranging the left third magnet 730 of the third drive portion 72. The left third magnet arrangement portion 703a is a recess.

The left wall 703 has multiple (three in this embodiment) front damper holders 703b, 703c, and 703d on the left half of the front end surface (see FIG. 13). The front damper holders 703b, 703c, and 703d are portions for holding the damper member 77 of the shock absorbing section 76, which will be described later. The front damper holders 703b, 703c, and 703d are each annular convex portions, and are arranged in a line in the vertical direction.

The left wall portion 703 has a front leaf spring fixing portion 703h in the right half of the front end surface (see FIG. 13). As shown in FIG. 16, a fixing portion 780 of a leaf spring 78 in the left first shock absorbing portion 76a (described below) is fixed to the front leaf spring fixing portion 703h. The front leaf spring fixing portion 703h is a portion that does not come into contact with the second base 5 during AF.

The left wall 703 has multiple (three in this embodiment) rear damper holders 703e, 703f, and 703g on the left half of the rear end surface (see FIG. 12). The rear damper holders 703e, 703f, and 703g are portions for holding the damper member 77 of the shock absorbing section 76, which will be described later. The rear damper holders 703e, 703f, and 703g are annular convex portions, and are arranged in a line in the vertical direction.

The left wall 703 has a rear leaf spring fixing portion 703i in the right half of the rear end surface (see FIG. 12). As shown in FIG. 15, a fixing portion 780 of the leaf spring 78 in the left second shock absorbing portion 76b (described later) is fixed to the rear leaf spring fixing portion 703i. The rear leaf spring fixing portion 703i is a portion that does not come into contact with the second base 5 during AF.

The right wall portion 704 is a plate-like member parallel to the XZ plane, with its lower end connected to the right end of the bottom wall portion 700. The right wall portion 704 has a right third magnet arrangement portion 704a on its outer surface (left side surface) for arranging the right third magnet 740 of the third drive portion 72. The right third magnet arrangement portion 704a is a recess.

The right wall 704 has multiple (three in this embodiment) front damper holders 704b, 704c, and 704d on the right half of the front end surface (see FIG. 13). The front damper holders 704b, 704c, and 704d are portions for holding the damper member 77 of the shock absorbing section 76, which will be described later. The front damper holders 704b, 704c, and 704d are annular convex portions, and are arranged in a line in the vertical direction.

The right wall portion 704 has a front leaf spring fixing portion 704h in the left half of the front end surface (see FIG. 13). As shown in FIG. 16, a fixing portion 780 of the leaf spring 78 in the right first shock absorbing portion 76c (described later) is fixed to the front leaf spring fixing portion 704h. The front leaf spring fixing portion 704h is a portion that does not come into contact with the second base 5 during AF.

The right wall portion 704 has multiple (three in this embodiment) rear damper holding portions 704e, 704f, and 704g on the right half of the rear end surface (see FIG. 12). The rear damper holding portions 704e, 704f, and 704g are portions for holding the damper member 77 of the shock absorbing portion 76 described below. The rear damper holding portions 704e, 704f, and 704g are annular convex portions, and are arranged in a line in the vertical direction.

The right wall portion 704 has a rear leaf spring fixing portion 704i in the left half of the rear end surface (see FIG. 12). As shown in FIG. 15, a fixing portion 780 of the leaf spring 78 in the right second shock absorbing portion 76d (described later) is fixed to the rear leaf spring fixing portion 704i. The rear leaf spring fixing portion 704i is a portion that does not come into contact with the second base 5 during AF.

The lens guide 70 having the above configuration holds the lens portion 6 (see FIG. 1) in a space defined by the bottom wall portion 700, the left wall portion 703, and the right wall portion 704. The lens guide 70 is supported on the second base 5 via a support mechanism 71. The lens guide 70 is movable in the axial direction relative to the second base 5. When the lens guide 70 moves, it slides on the left shaft 710 and right shaft 711 of the support mechanism 71, which will be described later.

The support mechanism 71 is a mechanism for supporting the lens guide 70 on the second base 5. The support mechanism 71 is composed of the left shaft 710 and the right shaft 711 described above. The left shaft 710 and the right shaft 711 correspond to an example of the first shaft and the second shaft. The lower half of the left shaft 710 and the right shaft 711 are arranged in the left groove portion 500 and the right groove portion 501 of the bottom wall portion 50 of the second base 5, as shown in Figures 17 to 19. The upper half of the left shaft 710 and the right shaft 711 are arranged in the left groove portion 701 and the right groove portion 702 of the bottom wall portion 700 of the lens guide 70, as shown in Figures 17 to 19. In other words, the lens guide 70 is placed on the left shaft 710 and the right shaft 711.

The third drive unit 72 is an actuator for moving the lens guide 70 in the direction of the second optical axis (X direction). The third drive unit 72 has a left third drive unit 73, a right third drive unit 74, and a third position detection element 75.

The left third drive unit 73 is provided between the left wall portion 703 of the lens guide 70 and the left FPC 81 fixed to the left side surface (outer surface in the width direction) of the left wall portion 51 of the second base 5. The left third drive unit 73 is a voice coil motor, and has a left third magnet 730 and a left third coil 731.

The left third magnet 730 is disposed in the left third magnet arrangement portion 703a of the lens guide 70. The left third magnet 730 is fixed to the left third magnet arrangement portion 703a of the lens guide 70 by a fixing means such as adhesive.

The left third magnet 730 consists of two magnet elements adjacent to each other in the front-to-rear direction. Each of these magnet elements is arranged so that its longitudinal direction coincides with the up-to-down direction. Each of these magnet elements is magnetized in the left-to-right direction, with one magnetic pole on one side. The magnetic poles of each magnet element are oriented in the opposite direction.

The left third coil 731 is an oval-shaped, so-called air-core coil that is supplied with power during AF. The long axis of the left third coil 731 coincides with the up-down direction. The left third coil 731 is arranged in the left third coil arrangement section 510 of the second base 5 and is fixed to the left FPC 81 by a fixing means such as adhesive.

The left third coil 731 is provided to the left (outside in the width direction) of the left third magnet 730. The left third coil 731 faces the left third magnet 730 at a predetermined interval in the left-right direction. The left third coil 731 is connected to the right third coil 741 and the left terminal portion 810 of the FPC 8.

In this embodiment, the left third magnet 730 is provided in the movable part, and the left third coil 731 is provided in the fixed part. However, the left third magnet 730 may be provided in the fixed part, and the left third coil 731 may be provided in the movable part.

The right-side third drive unit 74 is provided between the right wall portion 704 of the lens guide 70 and the right-side FPC 82 fixed to the right side surface (the outer surface in the width direction) of the right wall portion 52 of the second base 5. The right-side third drive unit 74 is also a voice coil motor, and has a right-side third magnet 740 and a right-side third coil 741.

The right-side third magnet 740 is arranged in the right-side third magnet arrangement portion 704a of the lens guide 70. The right-side third magnet 740 is fixed to the right-side third magnet arrangement portion 704a of the lens guide 70 by a fixing means such as adhesive.

The right-side third magnet 740 consists of two magnet elements adjacent to each other in the front-to-rear direction. Each of these magnet elements is arranged so that its longitudinal direction coincides with the up-to-down direction. Each of these magnet elements is also magnetized in the left-to-right direction, with one magnetic pole on one side. The magnetic poles of each magnet element are oriented in the opposite direction to each other.

The right third coil 741 is an elliptical, so-called air-core coil that is supplied with power during AF. The long axis of the right third coil 741 coincides with the up-down direction. The right third coil 741 is arranged in the right third coil arrangement section 520 of the second base 5 and is fixed to the right FPC 82 by a fixing means such as adhesive.

The right third coil 741 is provided to the right (outside in the width direction) of the right third magnet 740. The right third coil 741 faces the right third magnet 740 at a predetermined interval in the left-right direction. The right third coil 741 is connected to the left third coil 731 and the right terminal portion 820 of the FPC 8.

In this embodiment, the right-side third magnet 740 is provided in the movable part, and the right-side third coil 741 is provided in the fixed part. However, the right-side third magnet 740 may be provided in the fixed part, and the right-side third coil 741 may be provided in the movable part.

As shown in Figs. 4 and 11, the third position detection element 75 is fixed to the left FPC 81 while being disposed at the center of the left third coil 731. The third position detection element 75 faces the left third magnet 730 in the left-right direction. The third position detection element 75 detects the magnetic flux of the left third magnet 730 and sends the detection value to a control unit 92 mounted on a sensor board 91. The control unit 92 determines the position of the holder 31 in a direction parallel to the second optical axis (front-back direction) based on the detection value received from the third position detection element 75.

In the case of the third drive unit 72 having the above-mentioned configuration, when a current flows through the left third coil 731 and the right third coil 741 via the FPC 8 under the control of the control unit 92, a Lorentz force is generated that displaces the left third magnet 730 and the right third magnet 740 in the front-rear direction. As a result, the lens guide 70 to which the left third magnet 730 and the right third magnet 730 are fixed moves in the X direction. At this time, the lens guide 70 moves in the X direction while sliding on the left shaft 710 and the right shaft 711 of the support mechanism 71. In this manner, autofocus is performed.

The lens module 4 according to this embodiment also has a shock absorbing section 76 for absorbing the shock when the lens guide 70 moves in the front-rear direction and collides with the second base 5. The shock absorbing section 76 will be described below.

As shown in Figures 15, 16, 20, and 21, the shock absorbing section 76 is composed of a left first shock absorbing section 76a, a left second shock absorbing section 76b, a right first shock absorbing section 76c, and a right second shock absorbing section 76d, which are provided at the four corners of the lens guide 70.

The left first shock absorbing portion 76a is provided on the front end surface of the left wall portion 703 of the lens guide 70. The left second shock absorbing portion 76b is provided on the rear end surface of the left wall portion 703 of the lens guide 70. The right first shock absorbing portion 76c is provided on the front end surface of the right wall portion 704 of the lens guide 70. The right second shock absorbing portion 76d is provided on the rear end surface of the right wall portion 704 of the lens guide 70.

As shown in Figures 20 and 21, the left first shock absorbing portion 76a, the left second shock absorbing portion 76b, the right first shock absorbing portion 76c, and the right second shock absorbing portion 76d each have a damper member 77 and a leaf spring 78.

The damper members 77 are an example of a soft part. In this embodiment, the number of damper members 77 in each of the left first shock absorbing part 76a, the left second shock absorbing part 76b, the right first shock absorbing part 76c, and the right second shock absorbing part 76d is three. However, the number of damper members 77 is not limited to this embodiment. The material of the damper members 77 is preferably an elastic material such as adhesive, rubber, and molding material (elastomer).

The damper members 77 of the left first shock absorbing portion 76a are fixed to the front damper holders 703b, 703c, and 703d of the left wall portion 703 of the lens guide 70.

The damper members 77 of the left second shock absorbing portion 76b are fixed to the rear damper holders 703e, 703f, and 703g of the left wall portion 703 of the lens guide 70.

The damper members 77 of the right-side first shock absorbing portion 76c are fixed to the front damper holding portions 704b, 704c, and 704d of the right wall portion 704 of the lens guide 70.

The damper members 77 of the right second shock absorbing portion 76d are fixed to the rear damper retaining portions 704e, 704f, and 704g of the right wall portion 704 of the lens guide 70.

The leaf spring 78 is made of, for example, metal, and has a fixed portion 780 and an absorbing portion 781. The fixed portion 780 is fixed to a portion of the lens guide 70 that does not abut against the second base 5. The absorbing portion 781 covers the surface of the damper member 77. The absorbing portion 781 abuts against the surface of the damper member 77.

The absorbing portion 781 may be attached to the surface of the damper member 77 by suction, or may be fixed to the surface of the damper member 77 by a fixing means such as an adhesive. The absorbing portion 781 may come into contact with the second base 5 during AF. The absorbing portion 781 may also come into contact with the second base 5 due to an impact applied to the lens guide 70 due to, for example, being dropped. When the absorbing portion 781 comes into contact with the second base 5, it elastically deforms to absorb the impact.

Specifically, the leaf spring 78 of the left first shock absorbing portion 76a is fixed to the front end surface of the left wall portion 703 of the lens guide 70. More specifically, the fixing portion 780 of the leaf spring 78 of the left first shock absorbing portion 76a is fixed to the front leaf spring fixing portion 703h of the left wall portion 703 of the lens guide 70. In addition, the absorbing portion 781 of the leaf spring 78 of the left first shock absorbing portion 76a covers the surface (front side surface) of the damper member 77 of the left first shock absorbing portion 76a. The absorbing portion 781 of the leaf spring 78 of the left first shock absorbing portion 76a faces the front stopper portion 511 (see FIG. 4) of the left wall portion 51 of the second base 5 in the front-rear direction.

The leaf spring 78 of the left second shock absorbing portion 76b is fixed to the rear end surface of the left wall portion 703 of the lens guide 70. Specifically, the fixing portion 780 of the leaf spring 78 of the left second shock absorbing portion 76b is fixed to the rear leaf spring fixing portion 703i of the left wall portion 703 of the lens guide 70. In addition, the absorbing portion 781 of the leaf spring 78 of the left second shock absorbing portion 76b covers the surface (rear side surface) of the damper member 77 of the left second shock absorbing portion 76b. The absorbing portion 781 of the leaf spring 78 of the left second shock absorbing portion 76b faces the rear stopper portion 512 (see FIG. 4) of the left wall portion 51 of the second base 5 in the front-rear direction.

The leaf spring 78 of the right-side first shock absorbing portion 76c is fixed to the front end surface of the right wall portion 704 of the lens guide 70. Specifically, the fixing portion 780 of the leaf spring 78 of the right-side first shock absorbing portion 76c is fixed to the front leaf spring fixing portion 704h of the right wall portion 704 of the lens guide 70. In addition, the absorbing portion 781 of the leaf spring 78 of the right-side first shock absorbing portion 76c covers the surface (front side surface) of the damper member 77 of the right-side first shock absorbing portion 76c. The absorbing portion 781 of the leaf spring 78 of the right-side first shock absorbing portion 76c faces the front stopper portion 521 (see FIG. 3) of the right wall portion 52 of the second base 5 in the front-rear direction.

The leaf spring 78 of the right-side second shock absorbing portion 76d is fixed to the rear end surface of the right wall portion 704 of the lens guide 70. Specifically, the fixing portion 780 of the leaf spring 78 of the right-side second shock absorbing portion 76d is fixed to the rear leaf spring fixing portion 704i of the right wall portion 704 of the lens guide 70. In addition, the absorbing portion 781 of the leaf spring 78 of the right-side second shock absorbing portion 76d covers the surface (rear side surface) of the damper member 77 of the right-side second shock absorbing portion 76d. The absorbing portion 781 of the leaf spring 78 of the right-side second shock absorbing portion 76d faces the rear stopper portion 522 (see FIG. 3) of the right wall portion 52 of the second base 5 in the front-rear direction.

The shock absorbing section 76 configured as described above absorbs the shock when the lens guide 70 moves in the front-rear direction and collides with the second base 5. Figures 22A and 22B are cross-sectional views of the portions corresponding to the left first shock absorbing section 76a and the right first shock absorbing section 76c.

Figure 22A is a diagram corresponding to a state in which the lens guide 70 has not moved in the forward or backward direction (hereinafter referred to as the reference state of the lens guide 70). Figure 22B is a diagram corresponding to a state in which the lens guide 70 has moved a predetermined distance forward from the reference state.

When the lens guide 70 is in the standard state, there is a gap in the front-to-rear direction between the absorbing portion 781 of the leaf spring 78 in the left first shock absorbing portion 76a and the front stopper portion 511 of the left wall portion 51 in the second base 5, as shown in FIG. 22A.

When the lens guide 70 is in the reference state, there is a gap in the front-to-rear direction between the absorbing portion 781 of the leaf spring 78 in the right-side first shock absorbing portion 76c and the front stopper portion 521 of the right wall portion 52 in the second base 5, as shown in FIG. 22A.

When the lens guide 70 moves a predetermined distance forward from the reference state, as shown in FIG. 22B, the absorbing portion 781 of the leaf spring 78 in the left first shock absorbing portion 76a abuts against the front stopper portion 511 of the left wall portion 51 of the second base 5, and the absorbing portion 781 of the leaf spring 78 in the right first shock absorbing portion 76c collides with the front stopper portion 521 of the right wall portion 52 of the second base 5.

In the event of such a collision, the absorbing portion 781 of the leaf spring 78 in the left first shock absorbing portion 76a and the absorbing portion 781 of the leaf spring 78 in the right first shock absorbing portion 76c elastically deform, and the damper member 77 of the left first shock absorbing portion 76a and the damper member 77 of the right first shock absorbing portion 76c elastically deform, thereby absorbing the impact associated with the collision.

On the other hand, although not shown, when the lens guide 70 moves rearward a predetermined distance, the absorbing portion 781 of the leaf spring 78 in the left second shock absorbing portion 76b abuts against the rear stopper portion 512 of the left wall portion 51 of the second base 5, and the absorbing portion 781 of the leaf spring 78 in the right second shock absorbing portion 76d collides with the rear stopper portion 522 of the right wall portion 52 of the second base 5.

In the event of such a collision, the absorbing portion 781 of the leaf spring 78 in the left second shock absorbing portion 76b and the absorbing portion 781 of the leaf spring 78 in the right second shock absorbing portion 76d elastically deform, and the damper member 77 of the left second shock absorbing portion 76b and the damper member 77 of the right second shock absorbing portion 76d elastically deform, thereby absorbing the impact associated with the collision.

In the case of the lens module 4 described above, when a current flows through the left third coil 731 and the right third coil 741 of the AF device 7 via the FPC 8, a Lorentz force is generated that displaces the left third coil 731 and the right third coil 741 in the direction of the optical axis (X direction).

Then, because the left third coil 731 and the right third coil 741 are fixed to the lens guide 70, the lens guide 70 moves in the direction of the optical axis (X direction) based on the Lorentz force. Note that the direction of movement of the lens guide 70 can be switched by controlling the direction of the current flowing through the left third coil 731 and the right third coil 741. In this way, autofocusing is performed.

In the case of the camera module 1 according to this embodiment having the above-mentioned configuration, the product size can be reduced. The reason for this will be explained with reference to FIG. 8B. First, when the swing center C1 of the prism 22 is located on the underside of the holder 31 as in the conventional structure, the distance from the swing center C1 to the corner P1, which is the position on the upper surface of the prism 22 that is the furthest from the swing center C1, is R1. Therefore, when the prism 22 swings around an axis that passes through the swing center C1 and is parallel to the left-right direction (Y direction), the radius of rotation of the corner P1 is R1.

On the other hand, in the present embodiment, the swing center C2 of the prism 22 is the center of the ball 321. When the swing center C2 is located near the center of the mounting surface 310 of the holder 31, the distance from the swing center C2 to the corner P1 is R2. Therefore, when the prism 22 swings around an axis that passes through the swing center C2 and is parallel to the left-right direction (Y direction), the rotation radius of the corner P1 is R2. As shown in FIG. 8B, the rotation radius R2 is smaller than the rotation radius R1. Therefore, when the swing angle of the prism 22 is the same, the movement distance of the corner P1 of the camera module 1 of this embodiment is shorter than the movement distance of the corner P1 of the camera module of the conventional structure. If the movement distance of the corner P1 is large, the members arranged around the corner P1 are arranged to avoid the movement trajectory of the corner P1, which may increase the product size. On the other hand, in the present embodiment, the movement distance of the corner P1 is small, so the components arranged around the corner P1 can be arranged relatively close to the corner P1. As a result, the product size can be reduced.

Furthermore, in the case of the camera module 1 according to this embodiment, the lens module 4 includes the shock absorbing portion 76 described above. As described above, the shock absorbing portion 76 absorbs the shock when the lens guide 70 collides with the second base 5. In particular, in the case of this embodiment, during the above-mentioned collision, as shown in FIG. 22B, the absorbing portion 781 of the leaf spring 78 in the shock absorbing portion 76 collides with the second base 5. The leaf spring 78 is made of a metal material that has a relatively high hardness. Therefore, the durability of the shock absorbing portion 76 can be improved compared to the case where the damper member 77 directly contacts the second base 5. As a result, damage to the shock absorbing portion 76 can be suppressed.

Furthermore, in the case of the camera module 1 according to this embodiment, the lens guide 70 is supported on the second base 5 by the left shaft 710 and the right shaft 711. This type of support mechanism is more durable than a configuration in which the lens guide is supported by balls. Furthermore, this type of configuration can support the lens guide more stably than a configuration in which the lens guide is supported by balls.

The left shaft 710 contacts the left second support portions 701a, 701b of the lens guide 70 at two locations in the axial direction (front-to-back direction) and two locations in the width direction. On the other hand, the right shaft 711 contacts the right second support portion 702a of the lens guide 70 at one location in the axial direction (front-to-back direction) and one location in the width direction. This configuration can prevent the lens guide 70 from tilting in the assembled state due to the influence of dimensional variations in the lens guide 70. As a result, the position of the lens guide 70 relative to the second base 5 is stabilized.

(Additional Note)
Although the present invention has been specifically described based on the embodiment, the present invention is not limited to the above-described embodiment and can be modified without departing from the gist of the present invention.

In the above-described embodiments, a smartphone M (see Figures 23A and 23B), which is a mobile terminal with a camera, has been described as an example of a camera-mounted device equipped with a camera module 1, but the present invention can be applied to a camera-mounted device having a camera module and an image processing unit that processes image information obtained by the camera module. Camera-mounted devices include information devices and transportation equipment. Information devices include, for example, mobile phones with cameras, notebook computers, tablet terminals, portable game consoles, web cameras, and in-vehicle devices with cameras (for example, rear monitor devices and drive recorder devices). Furthermore, transportation equipment includes, for example, automobiles.

24A and 24B are diagrams showing an automobile V as a camera-mounted device equipped with an in-vehicle camera module VC (Vehicle Camera). FIG. 24A is a front view of the automobile V, and FIG. 24B is a rear perspective view of the automobile V. The automobile V is equipped with the camera module 1 described in the embodiment as the in-vehicle camera module VC. As shown in FIG. 24A and FIG. 24B, the in-vehicle camera module VC is attached, for example, to the windshield facing forward or to the rear gate facing backward. This in-vehicle camera module VC is used for a backup monitor, a drive recorder, collision avoidance control, automatic driving control, etc.

The optical actuator and camera module of the present invention can be mounted in thin camera-equipped devices such as smartphones, mobile phones, digital cameras, notebook computers, tablet terminals, portable game consoles, and vehicle-mounted cameras.

REFERENCE SIGNS LIST 1 camera module 2 light path bending module 21 first base 210 first base body 211 bottom wall 211a second coil arrangement section 212 left wall 212a left first coil arrangement section 213 right wall 213a right first coil arrangement section 214 support wall section 214a rear wall section 214b support section 214c convex side tapered surface 22 prism 3 shake correction device 31 holder 310 mounting surface 311 left first magnet arrangement section 312 right first magnet arrangement section 313 second magnet arrangement section 314 concave section 314a concave side tapered surface 314b spring fixing section 314c locking convex section 32 swing support section 321 ball 322 biasing spring 323 outer fixing section 323a Left fixing portion 323b Right fixing portion 324 Inner fixing portion 324a Central hole 324b Locking hole 325 Connection portion 325a, 325b Left connecting portion 325c, 325d Right connecting portion 33 First driving portion 34 Left first driving portion 340 Left first magnet 341 Left first coil 35 Right first driving portion 350 Right first magnet 351 Right first coil 36 First position detection element 37 Second driving portion 370 Second magnet 371 Second coil 372 Second position detection element 4 Lens module 5 Second base 50 Bottom wall portion 500 Left groove portion 500a, 500b Left first support portion 500c, 500d Tapered support surface 501 Right groove portion 501a, 501b Right side first support portion 501c, 501d tapered support surface 502 left side yoke 503 right side yoke 51 left wall portion 510 left side third coil arrangement portion
511 Front stopper portion 512 Rear stopper portion 52 Right wall portion 520 Right side third coil arrangement portion 521 Front stopper portion 522 Rear stopper portion 53 Front wall portion 6 Lens portion 7 AF device 70 Lens guide 700 Bottom side wall 701 Left side groove portion 701a, 701b Left side second support portion 701c, 701d Tapered support surface 702 Right side groove portion 702a Right side second support portion 702b Support surface 702c Front stopper portion 702d Rear stopper portion 703 Left wall portion 703a Left side third magnet arrangement portion 703b, 703c, 703d Front damper holding portion 703e, 703f, 703g Rear damper holding portion 703h Front leaf spring fixing portion 703i Rear leaf spring fixing portion 704 Right wall portion 704a Right side third magnet arrangement portion 704b, 704c, 704d Front damper holding portion 704e, 704f, 704g Rear damper holding portion 704h Front leaf spring fixing portion 704i Rear leaf spring fixing portion 71 Support mechanism 710 Left side shaft 711 Right side shaft 72 Third driving portion 73 Left side third driving portion 730 Left side third magnet 731 Left side third coil 74 Right side third driving portion 740 Right side third magnet 741 Right side third coil 75 Third position detection element 76 Shock absorbing portion 76a Left side first shock absorbing portion 76b Left side second shock absorbing portion 76c Right side first shock absorbing portion 76d Right side second shock absorbing portion 77 Damper member 78 Leaf spring 780 Fixing portion 781 Absorption portion 8 FPC
81 Left side FPC
810 Left side terminal portion 82 Right side FPC
820 Right side terminal portion 83 Lower FPC
9 Image pickup element module 90 Image pickup element 91 Sensor board 92 Control unit 93 Cover

Claims (6)

A movable part on which a lens part can be mounted;
A fixed part that accommodates the movable part;
A drive unit that moves the movable unit relative to the fixed unit;
a shock absorbing part that absorbs shock when the movable part and the fixed part collide with each other,
the impact absorbing section has a soft section fixed to one of the movable section and the fixed section, and a hard section covering a surface of the soft section and coming into contact with the other of the movable section and the fixed section upon the collision;
The soft portion is made of a damper material,
The hard portion is a leaf spring made of a material harder than the damper material,
The leaf spring is
a fixed region that is fixed to the one member and does not come into contact with the other member during the collision;
an impact absorbing region covering a surface of the soft portion and elastically deforming upon contact with the other member upon the collision;
Optical actuator. The number of the soft portions is plural,
The optical actuator according to claim 1 , wherein the soft portions are arranged in a line. The driving unit moves the movable unit in a first direction parallel to a direction of the incident light to the lens unit,
The optical actuator according to claim 1 , wherein the soft portion is fixed to a surface of the one member that is perpendicular to the first direction. The surface is at least one surface of the movable portion in the first direction,
The optical actuator according to claim 3 , wherein the shock absorbing portions are provided at both a left end and a right end of the surface. An optical actuator according to any one of claims 1 to 4 ;
an imaging element disposed behind the lens unit;
A camera module comprising: A camera module according to claim 5 ;
A control unit that controls the camera module;
A camera-equipped device having the above configuration.

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