JP2022174311A - Optical actuator, camera module, and camera mounting device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an optical actuator capable of improving productivity.

SOLUTION: An optical actuator comprises: a fixed side member; a movable side member capable of holding an optical member; and a drive unit including a magnet and configured to oscillate the movable side member with respect to the fixed side member. One member of the fixed side member and the movable side member has a magnet placement part that holds a magnet. The magnet placement part has at least one recess part on an inner peripheral surface that forms a cavity between itself and the held magnet.

SELECTED DRAWING: Figure 6

COPYRIGHT: (C)2023,JPO&INPIT

Description

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

2. Description of the Related Art Conventionally, thin camera-equipped devices, such as smartphones and digital cameras, which are equipped with camera modules are known. A camera module includes a lens unit having one or more lenses, and an imaging element that captures a subject image formed by the lens unit.

Also, a bending optical system that bends light from a subject along the first optical axis in the direction of the second optical axis by a prism, which is an optical path bending member provided in the front stage of the lens section, and guides the light to the rear lens section. A camera module has also been proposed (for example, Patent Document 1).

A camera module disclosed in Japanese Patent Application Laid-Open No. 2002-200000 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 actuators, the shake correction actuator has a first actuator and a second actuator for swinging the prism about two different axes. Specifically, the first actuator swings the prism about a first swing axis orthogonal to a plane including the first optical axis and the second optical axis. Also, the second actuator swings the prism around a second swing axis that coincides with the second optical axis.

When the camera shakes, the shake correction actuator swings the prism under the control of the control unit to correct the shake. This corrects camera shake.

JP 2015-92285 A

By the way, in the case of the camera module disclosed in Patent Document 1 as described above, the first swing support for supporting the prism swingably around the first swing shaft with respect to the base (fixed side member) Since the mechanism and the second swing support mechanism for supporting the prism so as to swing about the second swing shaft with respect to the base (fixed member) are separately provided, the optical actuator is There is a possibility that the structure will become complicated and the optical module will become large. Further, there is a demand for an improvement in productivity of such optical actuators.

SUMMARY OF THE INVENTION An object of the present invention is to provide an optical actuator, a camera module, and a camera-mounted device capable of improving productivity.

One aspect of the optical actuator according to the present invention is
a fixed side member;
a movable member capable of holding an optical member;
a drive unit that includes a magnet and causes the movable member to swing with respect to the fixed member;
one of the fixed-side member and the movable-side member has a magnet placement portion that holds a magnet;
The magnet placement portion has at least one recess on the inner peripheral surface that forms a gap with the held magnet.

One aspect of the camera module according to the present invention is
an optical actuator as described above;
an optical path bending member held by the movable side member of the optical actuator and bending incident light along the first direction so as to travel in one direction in the second direction;
an imaging element arranged on one side in the second direction with respect to the optical actuator;
Prepare.

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

According to the present invention, it is possible to provide an optical actuator, a camera module, and a camera mounting device capable of improving productivity.

FIG. 1 is a perspective view of a camera module according to Embodiment 1 of the present invention. FIG. 2 is an exploded perspective view of an optical path bending module. FIG. 3 is a perspective view of a base and members supported by the base. FIG. 4 is a perspective view of a base and members supported by the base. FIG. 5 is a perspective view of a holder and members supported by the holder. FIG. 6 is a perspective view of a holder and members supported by the holder. FIG. 7 is a perspective view of a holder and members supported by the holder. FIG. 8 is a perspective view of an insert plate. FIG. 9 is a perspective view of an insert plate. FIG. 10 is an exploded perspective view of the swing support. 11 is a cross-sectional view taken along the line XX of FIG. 1. FIG. FIG. 12 is a perspective view of a first drive section and a second drive section; FIG. 13 is a side view of the second drive section; FIG. 14A is a diagram showing an example of a camera-equipped device equipped with a camera module. FIG. 14B is a diagram showing an example of a camera-equipped device equipped with a camera module. FIG. 15A is a diagram showing an automobile as a camera-equipped device on which an in-vehicle camera module is installed. FIG. 15B is a diagram showing an automobile as a camera-equipped device equipped with an in-vehicle camera module.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described in detail based on the drawings. An optical actuator, a camera module, and a camera-mounted device according to embodiments to be described later are examples of the optical actuator, camera module, and camera-mounted device according to the present invention, and the present invention is not limited by the embodiments.

[Embodiment]
A camera module according to an embodiment of the present invention will be described with reference to FIGS. 1 to 15B. Hereinafter, after explaining the outline of the camera module 1, the structures of the optical path bending module 2, the lens module 80, and the imaging element module 81 included in the camera module 1 will be explained. The optical actuator, camera module, and camera-mounted device according to the present invention may have all of the configurations described later, or may not have some of the configurations.

(The camera module)
The camera module 1 is mounted on, for example, a smart phone M (see FIGS. 14A and 14B), a mobile phone, a digital camera, a notebook computer, a tablet terminal, a portable game machine, and a thin camera-equipped device (vehicle camera, etc.). be. The smart phone 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.

Each part constituting the camera module 1 of the present embodiment will be described below based on the state in which it is incorporated in the camera module 1 . Further, in describing the structure of the camera module 1 of the present embodiment, an orthogonal coordinate system (X, Y, Z) shown in each drawing is used.

The camera module 1 is mounted so that, for example, the X direction is the left-right direction, the Y direction is the up-down direction, and the Z direction is the front-rear direction when the camera-mounted device actually takes a picture. Light (incident light) from a subject enters the prism 5 of the optical path bending module 2 from the + side (plus side) in the Z direction, as indicated by the dashed line α (also referred to as the first optical axis) in FIG. . The prism 5 corresponds to an example of an optical path bending member.

The light that has entered the prism 5 (output light) is bent at the optical path bending surface of the prism 5, as indicated by the dashed line β (also referred to as the second optical axis) in FIG. In other words, the light is guided to the lens portion 801 of the lens module 80 arranged on the positive side in the X direction.

Then, the subject image formed by the lens unit 801 is captured by the imaging device module 81 (see FIG. 1) arranged in the rear stage of the lens module 80 .

In this embodiment, the Z direction corresponds to an example of the first direction. Also, the X direction corresponds to an example of the second direction. The direction from the negative side (minus side) in the X direction to the positive side in the X direction corresponds to one side in the first direction. The direction from the + side in the X direction to the - side in the X direction corresponds to the other side in the first direction. The Y direction corresponds to an example of the third direction. Also, the direction from the negative side in the Y direction to the positive side in the Y direction corresponds to one side in the third direction. The direction from the Y direction + side to the Y direction − side corresponds to the other side in the third direction. However, the first direction and the second direction are not limited to the case of this embodiment. The first direction and the second direction may be directions orthogonal to each other.

Also, the XY plane is a plane perpendicular to the first direction. The YZ plane is a plane perpendicular to the second direction, and the XZ plane is a plane perpendicular to the third direction.

The camera module 1 of the present embodiment performs shake correction (OIS: Optical Image Stabilization) by the shake correction device 6 incorporated in the optical path bending module 2 . In other words, the optical path bending module 2 has a camera shake correction function.

Further, the camera module 1 of the present embodiment performs autofocus by displacing the lens portion in the X direction with an AF device (not shown) incorporated in the lens module 80 . That is, the lens module 80 has an autofocus function.

Also, the lens unit 801 of the lens module 80 is a so-called zoom lens that can handle wide-angle photography (focal length: short) to telephoto photography (focal length: long). The camera module 1 of this embodiment uses a zoom device (not shown) incorporated in the lens module 80 to move the lens unit 801 to a position in the X direction corresponding to wide-angle shooting or telephoto shooting. That is, the lens module 80 has a zoom function.

<Optical path bending module>
The optical path bending module 2 will be described with reference to FIGS. 1 to 13. FIG. The optical path bending module 2 includes a cover 3, a base 4, a prism 5, a shake correction device 6, and an FPC7.

(cover)
As shown in FIG. 1, the cover 3 is made of synthetic resin or non-magnetic metal, for example, and is a box-shaped member that is open on both sides in the Z direction and on the + side in the X direction. Light from the subject side can enter the inner space of the cover 3 through the opening on the positive side in the Z direction of the cover 3 . The cover 3 as described above is combined with the base 4 (to be described later) from the + side in the Z direction.

(base)
The base 4 will be described with reference to FIGS. 2 to 4. FIG. The base 4 corresponds to an example of a stationary member. The base 4 has a bottom wall portion 40 , a left wall portion 41 , a right wall portion 42 , a rear wall portion 43 and a base plate 44 .

(bottom wall)
The bottom wall portion 40 has a rectangular plate shape parallel to the XY plane and the longitudinal direction of which coincides with the Y direction. The bottom wall portion 40 constitutes the bottom portion of the base 4 . The bottom wall portion 40 has a first end that is the end on the + side in the Y direction and a second end that is the end on the − side (minus side) in the Y direction. In addition, the bottom wall portion 40 has a third end that is the end on the negative side in the X direction and a fourth end that is the end on the positive side in the X direction. In addition, the bottom wall portion 40 has a first surface (lower side surface) that is a surface on the negative side in the Z direction and a second surface (upper side surface) that is a surface on the positive side in the Z direction.

For the sake of convenience, the left-right direction means the left-right direction when the optical path bending module 2 is viewed from the + side in the X direction with the + side in the Z direction facing up. Therefore, the positive side in the Y direction corresponds to the left side, and the negative side in the Y direction corresponds to the right side. In the optical path bending module 2, the positive side in the X direction corresponds to the front side, and the negative side in the X direction corresponds to the rear side. Furthermore, in the optical path bending module 2, the positive side in the Z direction corresponds to the upper side, and the negative side in the Z direction corresponds to the lower side.

Such a bottom wall portion 40 has a fixed side magnet holding portion 401 and a first coil arrangement portion 402 .

The fixed-side magnet holding portion 401 is for holding a fixed-side magnet 631 and a fixed-side holding member 632 of the swing support portion 63, which will be described later. The fixed-side magnet holding portion 401 is configured by a concave portion provided on the upper side surface (second surface) of the bottom wall portion 40 .

Such a fixed-side magnet holding portion 401 is provided at the central portion of the bottom wall portion 40 in the left-right direction. Specifically, the fixed-side magnet holding portion 401 is provided at an intermediate portion in the front-rear direction and a center portion in the left-right direction of the bottom wall portion 40 .

The first coil arrangement portion 402 is a space for arranging a left first coil 642a, a right first coil 642b, and a first position detection element 643 in the first drive portion 64, which will be described later.

Specifically, the first coil placement section 402 has a left first coil placement section 403 and a right first coil placement section 404 .

The left first coil arrangement portion 403 is a space for arranging a left first coil 642a and a first position detection element 643 in the first driving portion 64, which will be described later. The bottom wall portion 40 is configured by a through hole provided on the left side of the fixed magnet holding portion 401 .

The right first coil arrangement portion 404 is a space for arranging a right first coil 642b in the first driving portion 64, which will be described later. The right first coil arrangement portion 404 is configured by a through hole provided on the right side of the fixed magnet holding portion 401 in the bottom wall portion 40 .

Here, a straight line passing through the center of the ball 633 of the rocking support portion 63 described later and parallel to the vertical direction (Z direction) is defined as the first axis A1 (see FIG. 11). A straight line passing through the center of the ball 633 of the rocking support portion 63 described later and parallel to the left-right direction (Y direction) is defined as a second axis A2 (see FIG. 11).

The first axis A1 is also the center of swing when the holder 60 (to be described later) swings. The second axis A2 is also the center of swing when the holder 60 swings.

A virtual plane passing through the second axis A1 and parallel to the XZ plane is defined as a first virtual plane. A virtual plane passing through the second axis A2 and parallel to the YZ plane is defined as a second virtual plane.

The left first coil placement portion 403, the right first coil placement portion 404, and the fixed magnet holding portion 401 are provided on the bottom wall portion 40 on the same straight line parallel to the left-right direction (Y direction). In other words, the left first coil placement portion 403, the right first coil placement portion 404, and the fixed magnet holding portion 401 are provided on the line of intersection between the second virtual plane and the bottom wall portion 40 in the bottom wall portion 40. It is

(left wall)
The left wall portion 41 corresponds to an example of the first wall portion of the base and has a plate shape. The left wall portion 41 is provided along the left end portion of the bottom wall portion 40 . The left wall portion 41 extends upward from the left end portion of the bottom wall portion 40 .

The left wall portion 41 has a pair of left locking portions 411 and 412 and a pair of left damper placement portions 413 and 414 .

The pair of left locking portions 411 and 412 are provided on the left wall portion 41 at symmetrical or substantially symmetrical positions with respect to the second imaginary plane. The left locking portion 411 is provided on the front side (X direction + side) of the left locking portion 412 .

A second locking portion 66 b of a left spring 661 of a return mechanism 66 , which will be described later, is locked to the left locking portion 411 . The second locking portion 66 b of the left spring 662 of the return mechanism 66 is locked to the left locking portion 412 .

The pair of left damper placement portions 413 and 414 are provided on the left wall portion 41 at symmetrical or substantially symmetrical positions with respect to the second imaginary plane. The left damper placement portion 413 is provided on the front side (X direction + side) of the left damper placement portion 414 .

In the case of this embodiment, the pair of left locking portions 411 and 412 are arranged between the left damper placement portion 413 and the left damper placement portion 414 in the left wall portion 41 .

The left damper arrangement portions 413 and 414 are each configured by a concave portion formed in the upper surface of the left wall portion 41 . Left damper members 73 and 74 are arranged in the left damper arrangement portions 413 and 414, respectively.

(right wall)
The right wall portion 42 corresponds to an example of the second wall portion of the base and has a plate shape. The right wall portion 42 is provided along the right end portion of the bottom wall portion 40 . The right wall portion 42 extends upward from the right end portion of the bottom wall portion 40 .

The right wall portion 42 has a pair of right engaging portions 421 and 422 and a pair of right damper placement portions 423 and 424 .

The pair of right engaging portions 421 and 422 are provided on the right wall portion 42 at symmetrical or substantially symmetrical positions with respect to the second imaginary plane. The right locking portion 421 is provided on the front side (X direction + side) of the right locking portion 422 . The pair of right locking portions 421 and 422 face the pair of left locking portions 411 and 412 in the Y direction.

A second locking portion 66 b of a right spring 663 of a return mechanism 66 described later is locked to the right locking portion 421 . A second locking portion 66b of a right spring 664 of a return mechanism 66, which will be described later, is locked to the right locking portion 422. As shown in FIG.

The pair of right damper placement portions 423 and 424 are provided on the right wall portion 42 at symmetrical or substantially symmetrical positions with respect to the second imaginary plane. The right damper placement portion 423 is provided on the front side (X direction + side) of the right damper placement portion 424 .

In the case of this embodiment, the pair of right engaging portions 421 and 422 are arranged between the right damper placement portion 423 and the right damper placement portion 424 on the right wall portion 42 .

The right damper arrangement portions 423 and 424 are each configured by a concave portion formed in the upper surface of the right wall portion 42 . Right damper members 75 and 76 are arranged in the right damper arrangement portions 423 and 424, respectively.

(rear wall)
The rear wall portion 43 corresponds to an example of the third wall portion of the base and has a plate shape. The rear wall portion 43 is provided along the rear end portion of the bottom wall portion 40 . The rear wall portion 43 extends upward from the rear end portion of the bottom wall portion 40 .

The rear wall portion 43 has a second coil placement portion 431 . The second coil arrangement portion 431 is formed by a rectangular cutout that is provided at a central position in the left-right direction of the rear wall portion 43 and is open in the front-rear direction and upward. A second coil 652 of a second driving section 65 to be described later is arranged in the second coil arrangement section 431 .

(base plate)
The base plate 44 has a plate shape parallel to the XY plane. The base plate 44 has a first surface (upper side surface) that is a surface on the positive side in the Z direction and a second surface (lower side surface) that is a surface on the negative side in the Z direction.

The base plate 44 is fixed to the lower surface of the bottom wall portion 40 . A first FPC element 71 of the FPC 7 described later is provided on the upper surface of the base plate 44 .

(FPC)
The FPC 7 will be described with reference to FIG. The FPC 7 has a substantially L-shaped plate shape when the FPC 7 is viewed from the left-right direction, and has a first FPC element 71 and a second FPC element 72 .

(First FPC element)
The first FPC element 71 is in the shape of a rectangular plate parallel to the XY plane and whose longitudinal direction coincides with the Y direction. The first FPC element 71 is fixed to the bottom surface of the bottom wall portion 40 of the base 4 .

The first FPC element 71 has a first end that is the end on the + side in the Y direction and a second end that is the end on the − side in the Y direction. In addition, the first FPC element 71 has a third end that is the end on the negative side in the X direction and a fourth end that is the end on the positive side in the X direction. In addition, the first FPC element 71 has a first surface (lower side surface) that is a surface on the Z direction - side and a second surface (upper surface) that is a surface on the Z direction + side.

The first FPC element 71 has a first terminal portion 711 , a first coil fixing portion 712 and a first element fixing portion 715 .

The first terminal portion 711 is composed of a plurality of terminals connected to the sensor substrate 91 (see FIG. 1) on which the imaging element module 81 is mounted. The first terminal portion 711 is provided at the second end (right end) of the first FPC element 71 .

The first coil fixing portion 712 is a portion for fixing a left first coil 642a and a right first coil 642b of the first driving portion 64, which will be described later. The first coil fixing portion 712 has a left first coil fixing portion 713 and a right first coil fixing portion 714 .

The left first coil fixing portion 713 is provided on the upper side surface of the first FPC element 71 at a portion facing the left first magnet placement portion 614c of the holder 60, which will be described later, in the vertical direction (Z direction).

The right first coil fixing portion 714 is provided on the upper side surface of the first FPC element 71 at a portion facing the right first magnet placement portion 614d of the holder 60, which will be described later, in the vertical direction (Z direction).

The first element fixing portion 715 is a portion for fixing the first position detecting element 643 of the first driving portion 64 which will be described later. The first element fixing portion 715 is provided on the upper side surface of the first FPC element 71 at a position vertically facing the left end portion (first end portion) of the left first magnet placement portion 614c of the holder 60, which will be described later. there is

(Second FPC element)
The second FPC element 72 has a rectangular plate shape parallel to the YZ plane and the longitudinal direction of which is aligned with the Y direction. The second FPC element 72 extends upward (Z direction + side) from the rear end of the first FPC element 71 .

The second FPC element 72 has a first end that is the end on the + side in the Y direction and a second end that is the end on the - side in the Y direction. In addition, the second FPC element 72 has a third end that is the end on the negative side in the Z direction and a fourth end that is the end on the positive side in the Z direction. In addition, the second FPC element 72 has a first surface (front side surface) on the positive side in the X direction and a second surface (rear side surface) on the negative side in the Z direction.

The second FPC element 72 has a second coil fixing portion 721 and a second element fixing portion 722 (see FIG. 13).

The second coil fixing portion 721 is a portion for fixing a second coil 652 of the second drive portion 65, which will be described later. The second coil fixing portion 721 is provided on the front side surface of the second FPC element 72 at a portion facing a second magnet placement portion 610a of the holder 60 described later in the front-rear direction (X direction).

The second element fixing portion 722 is a portion for fixing the second position detecting element 654 of the second driving portion 65 which will be described later. The second element fixing portion 722 is provided on the front side surface of the second FPC element 72 at a position vertically facing a position detection magnet placement portion 610b of the holder 60 described later.

<Shake correction device>
Next, the shake correction device 6 will be described. The shake correcting device 6 is a driving unit that swings the prism 5 around a first axis A1 parallel to the Z direction (see FIG. 11) and a second axis A2 parallel to the Y direction (see FIG. 11). As a result, shake correction in the rotation direction about the first axis A1 and shake correction in the rotation direction about the second axis A2 are performed. Such a shake correcting device 6 is arranged in a housing space covered with the cover 3 and the base 4 .

The shake correction device 6 includes a holder 60 , a swing support portion 63 , a first drive portion 64 , a second drive portion 65 and a return mechanism 66 .

In the shake correction device 6 , the holder 60 is supported by the base 4 via the swing support portion 63 . The holder 60 is swingable about the first axis A1 and swingable about the second axis A2 with respect to the base 4 . In this state, the holder 60 swings about the first axis A1 based on the driving force (also referred to as the first driving force) generated by the first driving portion 64, and the driving force generated by the second driving portion 65 (Also referred to as a second driving force), it swings around the second axis A2.

When the first driving section 64 is driven under the control of the control section 92 (see FIG. 1), the holder 60 and the prism 5 swing about the first axis A1. As a result, shake in the direction of rotation about the first axis A1 is corrected. Further, when the second driving section 65 is driven under the control of the control section 92 (see FIG. 1), the holder 60 and the prism 5 swing about the second axis A2. As a result, shake in the rotational direction about the second axis A2 is corrected. A specific structure of each member included in the shake correction device 6 will be described below.

(holder)
The holder 60 will be described with reference to FIGS. 2 and 5 to 9. FIG. The holder 60 corresponds to an example of the movable side member and holds the prism 5 (see FIG. 1). The holder 60 is also an example of a holding member for swingably supporting the prism 5 with respect to the base 4 .

The holder 60 is swingable about the first axis A1 and swingable about the second axis A2 with respect to the base 4 . Therefore, the prism 5 is also swingable about the first axis A1 and swingable about the second axis A2 with respect to the base 4 .

The holder 60 has a holder body 61 and an insert plate 62 .

(Holder body)
The holder main body 61 is made of synthetic resin, for example, and includes a rear wall portion 610 , a left wall portion 611 , a right wall portion 612 , a mounting portion 613 and a bottom wall portion 614 .

(rear wall)
The rear wall portion 610 is parallel to the YZ plane and has a plate shape whose longitudinal direction coincides with the Y direction. The rear wall portion 610 has a first end (left end) that is the end on the + side in the Y direction, a second end (right end) that is the end on the − side in the Y direction, and an end on the − side in the Z direction. It has a certain third end (lower end) and a fourth end (upper end) which is the end on the Z direction + side. In addition, the rear wall portion 610 has a first surface (rear side surface) that is the surface on the X direction - side.

The rear wall portion 610 has a second magnet placement portion 610a on the rear side surface. The second magnet arrangement portion 610a is for arranging a second magnet 651 of the second drive portion 65, which will be described later.

Specifically, the second magnet arrangement portion 610a is provided in the center portion in the left-right direction on the rear side surface of the rear wall portion 610. As shown in FIG. The second magnet placement portion 610a is configured by, for example, a space defined by a rectangular recess or a through hole.

The second magnet placement portion 610a has at least one (two in the present embodiment) recesses 610a1 on its inner peripheral surface. The concave portion 610 a 1 serves as an adhesive supply port when supplying adhesive between the inner peripheral surface of the second magnet placement portion 610 a and the outer peripheral surface of the second magnet 651 .

The rear wall portion 610 is arranged on the front side of the rear wall portion 43 of the base 4 . The rear wall portion 610 faces the rear wall portion 43 in the front-rear direction (X direction). The second magnet arrangement portion 610 a is arranged on the front side of the second coil arrangement portion 431 of the rear wall portion 610 . The second magnet placement portion 610a faces the second coil placement portion 431 of the rear wall portion 610 in the front-rear direction.

The rear wall portion 610 has a position detection magnet placement portion 610b on the rear side surface. Specifically, the position detection magnet placement portion 610b is provided on the rear side surface of the rear wall portion 610, at the center in the left-right direction and below the second magnet placement portion 610a.

The position detection magnet placement portion 610b and the second magnet placement portion 610a are configured by continuous concave portions. The position detection magnet arrangement portion 610b is for arranging a second position detection magnet 653 of the second driving portion 65, which will be described later.

(left wall)
The left wall portion 611 corresponds to an example of the first wall portion of the holder and has a plate shape parallel to the XZ plane. The left wall portion 611 has a first end (rear end) that is the end on the negative side in the X direction and a second end (front end) that is the end on the positive side in the X direction. A rear end portion of the left wall portion 611 is connected to a left end portion of the rear wall portion 610 . The left wall portion 611 extends forward from the left end portion of the rear wall portion 610 .

The left wall portion 611 has a pair of left locking portions 611a and 611b and a pair of left convex portions 611c and 611d. The pair of left engaging portions 611a and 611b are provided on the left wall portion 611 at symmetrical or substantially symmetrical positions with respect to the second imaginary plane. The left locking portion 611a is provided on the front side (X direction + side) of the left locking portion 611b.

The left engaging portion 611a and the left engaging portion 411 of the base 4 are positioned on the same YZ plane. The left locking portion 611b and the left locking portion 412 of the base 4 are positioned on the same YZ plane.

A first engaging portion 66a of a left spring 661 of a return mechanism 66, which will be described later, is engaged with the left engaging portion 611a. A first locking portion 66a of a left spring 662 of the return mechanism 66 is locked to the left locking portion 611b.

The pair of left convex portions 611c and 611d are provided on the left wall portion 611 at positions facing the pair of left damper placement portions 413 and 414 of the base 4 in the vertical direction (Z direction). Each of the pair of left convex portions 611c and 611d has a shaft shape extending in the vertical direction. The tip surfaces (lower end surfaces) of the pair of left convex portions 611c and 611d respectively face the bottom surfaces of the pair of left damper placement portions 413 and 414 in the vertical direction (Z direction) with a gap therebetween.

In the case of the present embodiment, left damper members 73 and 74 (see FIG. 2) are provided so as to bridge between the tip end surfaces of the pair of left convex portions 611c and 611d and the bottom surfaces of the pair of left damper placement portions 413 and 414. is provided. The left damper members 73 and 74 are applied between the tip surfaces of the pair of left convex portions 611c and 611d and the bottom surfaces of the pair of left damper placement portions 413 and 414 using a dispenser. The left damper members 73 and 74 are, for example, ultraviolet curable silicone gel.

(right wall)
The right wall portion 612 corresponds to an example of the second wall portion of the holder and has a plate shape parallel to the XZ plane. The right wall portion 612 has a first end (rear end) that is the end on the negative side in the X direction and a second end (front end) that is the end on the positive side in the X direction. A rear end portion of the right wall portion 612 is connected to a right end portion of the rear wall portion 610 . The right wall portion 612 extends forward from the right end portion of the rear wall portion 610 .

The right wall portion 612 has a pair of right engaging portions 612a, 612b and a pair of right convex portions 612c, 612d. The pair of right engaging portions 612a and 612b are provided on the right wall portion 612 at symmetrical or substantially symmetrical positions with respect to the second imaginary plane. The right locking portion 612a is provided on the front side (X direction + side) of the right locking portion 612b.

The right engaging portion 612a and the right engaging portion 421 of the base 4 are located on the same YZ plane. The right locking portion 612b and the right locking portion 422 of the base 4 are located on the same YZ plane.

A first locking portion 66a of a right spring 663 of a return mechanism 66, which will be described later, is locked to the right locking portion 612a. A first locking portion 66a of a right spring 664 of the return mechanism 66 is locked to the right locking portion 612b.

The pair of right convex portions 612c and 612d are provided on the right wall portion 612 at positions facing the pair of right damper placement portions 423 and 424 of the base 4 in the vertical direction (Z direction). Each of the pair of right protrusions 612c and 612d has a shaft shape extending in the vertical direction. The tip surfaces (lower end surfaces) of the pair of right convex portions 612c and 612d respectively face the bottom surfaces of the pair of right damper placement portions 423 and 424 in the vertical direction (Z direction) with a gap therebetween.

In the case of this embodiment, right damper members 75 and 76 (see FIG. 2) are provided so as to bridge between the tip end surfaces of the pair of right convex portions 612c and 612d and the bottom surfaces of the pair of right damper placement portions 423 and 424. It is The right damper members 75 and 76 are each applied between the tip surfaces of the pair of right convex portions 612c and 612d and the bottom surfaces of the pair of right damper placement portions 423 and 424 using a dispenser. The right damper members 75 and 76 are, for example, ultraviolet curable silicone gel.

(Placement part)
The mounting portion 613 has a plate shape whose longitudinal direction coincides with the Y direction. The mounting portion 613 has a first end (front end) that is the end on the + side in the X direction, a second end (rear end) that is the end on the - side in the X direction, and an end on the + side in the Y direction. and a fourth end (right end) that is the Y-direction - side end.

A rear end portion of the mounting portion 613 is connected to an upper end portion of the front side surface of the rear wall portion 610 . A front end portion of the mounting portion 613 is connected to a front end portion of a bottom wall portion 614 which will be described later. A left end portion of the mounting portion 613 is connected to a right side surface (inner side surface) of the left wall portion 611 . A right end portion of the mounting portion 613 is connected to a left side surface of the right wall portion 612 .

The first end of the mounting portion 613 is positioned below the second end of the mounting portion 613 . That is, the mounting portion 613 is inclined downward with distance from the rear wall portion 610 . The upper side surface of the mounting portion 613 is a mounting surface for placing the prism 5 thereon.

The mounting surface faces the back surface of the prism 5 (surface on the −Z direction side). The mounting surface is, for example, a surface parallel to the rear surface of the prism 5 . The mounting portion is not limited to the structure of this embodiment, and may be a boss or the like capable of positioning the prism 5, for example.

(bottom wall)
The bottom wall portion 614 constitutes the bottom portion of the holder main body 61 . The bottom wall portion 614 has a first end (left end) that is the end on the + side in the Y direction, a second end (right end) that is the end on the − side in the Y direction, and an end on the + side in the X direction. It has a certain third end (front end) and a fourth end (rear end) which is the X direction - side end. The bottom wall portion 614 has a first side surface (lower side surface) that is the Z-direction-side surface.

A left end portion of the bottom wall portion 614 is connected to a lower end portion of the left wall portion 611 . A right end portion of the bottom wall portion 614 is connected to a lower end portion of the right wall portion 612 . A front end portion of the bottom wall portion 614 is connected to a front end portion of the mounting portion 613 . A rear end portion of the bottom wall portion 614 is connected to a lower end portion of the rear wall portion 610 .

The bottom wall portion 614 has a movable side magnet placement portion 614a and a first magnet placement portion 614b on its lower side.

The movable-side magnet placement portion 614a is for holding a movable-side magnet 635 and a movable-side holding member 634 of the swing support portion 63, which will be described later. The movable-side magnet placement portion 614 a is configured by a recess provided on the lower side surface (first side surface) of the bottom wall portion 614 .

Such a movable side magnet placement portion 614a is provided in the center portion of the bottom wall portion 614 in the left-right direction. Specifically, the movable-side magnet placement portion 614 a is provided at the middle portion in the front-rear direction and the center portion in the left-right direction of the bottom wall portion 614 . The movable-side magnet arrangement portion 614a faces the fixed-side magnet holding portion 401 of the base 4 in the vertical direction.

The first magnet arrangement portion 614b is for arranging a left first magnet 641a and a right first magnet 641b of the first drive portion 64, which will be described later.

Specifically, the first magnet placement portion 614b has a left first magnet placement portion 614c and a right first magnet placement portion 614d. The left first magnet placement portion 614 c and the right first magnet placement portion 614 d are each configured by a space defined by a recess provided on the lower surface of the bottom wall portion 614 .

The left first magnet placement portion 614c has at least one (two in the present embodiment) recesses 614c1 on its inner peripheral surface. The concave portion 614c1 serves as an adhesive supply port when supplying adhesive between the inner peripheral surface of the left first magnet placement portion 614c and the outer peripheral surface of the left first magnet 641a.

The right first magnet placement portion 614d has at least one (two in the present embodiment) recesses 614d1 on its inner peripheral surface. The concave portion 614d1 serves as an adhesive supply port when supplying adhesive between the inner peripheral surface of the right first magnet placement portion 614d and the outer peripheral surface of the right first magnet 641b.

The left first magnet placement portion 614c and the right first magnet placement portion 614d face the left first coil placement portion 403 and the right first coil placement portion 404 of the base 4 in the vertical direction (Z direction).

The left first magnet placement portion 614c and the right first magnet placement portion 614d face the left first coil fixing portion 713 and the right first coil fixing portion 714 of the FPC 7 in the vertical direction (Z direction).

A first left magnet 641a of the first driving section 64, which will be described later, is arranged in the first left magnet arrangement section 614c. The first right magnet 641b of the first driving section 64 is arranged in the first right magnet arrangement section 614d.

(insert plate)
The insert plate 62 is insert-molded in the holder body 61 . The insert plate 62 is formed by bending a single plate. The insert plate 62 is made of magnetic metal. The insert plate 62 may be made of non-magnetic metal.

The insert plate 62 has a rear plate portion 620, a left plate portion 621, a right plate portion 622, a center plate portion 623, and a bottom plate portion 624, as shown in FIGS.

(Rear plate)
The rear plate portion 620 has a substantially rectangular plate shape parallel to the YZ plane. The rear plate portion 620 has a first end (left end) that is the end on the + side in the Y direction, a second end (right end) that is the end on the − side in the Y direction, and an end on the − side in the Z direction. It has a certain third end (lower end) and a fourth end (upper end) which is the end on the Z direction + side. In addition, the rear plate portion 620 has a first surface (rear side surface) that is the surface on the X direction - side.

The rear plate portion 620 is embedded in the rear wall portion 610 of the holder main body 61 . A portion of the rear side surface of the rear plate portion 620 that faces the second magnet arrangement portion 610 a of the holder body 61 in the front-rear direction (hereinafter referred to as an exposed portion of the rear plate portion 620 ) is not covered with the rear wall portion 610 . exposed to the outside. A second magnet 651 of the second driving portion 65, which will be described later, is fixed to the exposed portion of the rear plate portion 620 by fixing means such as adhesion. Such an exposed portion of the rear plate portion 620 functions as a yoke.

(left plate)
The left plate portion 621 has a plate shape parallel to the XZ plane. The left plate portion 621 has a first end (rear end) that is the end on the negative side in the X direction and a second end (front end) that is the end on the positive side in the X direction. A rear end portion of the left plate portion 621 is connected to a left end portion of a center plate portion 623 which will be described later. The left plate portion 621 extends forward from the left end portion of the center plate portion 623 .

The left plate portion 621 is embedded in the left wall portion 611 of the holder body 61 . The left plate portion 621 has a first side surface (right side surface) that is the side surface on the Y direction - side. A left exposed portion 621a that is part of the right side surface of the left plate portion 621 is not covered with the left wall portion 611 and is exposed to the outside. The left side surface of the prism 5 is fixed to the left exposed portion 621a via fixing means such as an adhesive.

(Right plate)
The right plate portion 622 has a plate shape parallel to the XZ plane. The right plate portion 622 has a first end (rear end) that is the end on the negative side in the X direction and a second end (front end) that is the end on the positive side in the X direction. A rear end portion of the right plate portion 622 is connected to a right end portion of a center plate portion 623 which will be described later. The right plate portion 622 extends forward from the right end portion of the central plate portion 623 .

The right plate portion 622 is embedded in the right wall portion 612 of the holder body 61 . The right plate portion 622 has a first side surface (left side surface) that is the side surface on the + side in the Y direction. A right exposed portion 622a that is part of the left side surface of the right plate portion 622 is not covered with the right wall portion 612 and is exposed to the outside. The right side surface of the prism 5 is fixed to the right exposed portion 622a via fixing means such as an adhesive.

(Central plate)
The center plate portion 623 has a first end (front end) that is the end on the + side in the X direction, a second end (rear end) that is the end on the - side in the X direction, and an end on the + side in the Y direction. and a fourth end (right end) that is the Y-direction - side end.

A rear end portion of the central plate portion 623 is connected to an upper end portion of the rear plate portion 620 . A front end portion of the central plate portion 623 is connected to a front end portion of a bottom plate portion 624 which will be described later. A left end portion of the center plate portion 623 is connected to a rear end portion of the left plate portion 621 . A right end portion of the central plate portion 623 is connected to a rear end portion of the right plate portion 622 .

The first end of the central plate portion 623 is positioned below the second end of the central plate portion 623 . That is, the central plate portion 623 is inclined downward as it is separated from the rear plate portion 620 .

The central plate portion 623 is embedded in the mounting portion 613 of the holder body 61 . A central exposed portion 623 a that is part of the upper surface of the central plate portion 623 is exposed to the outside without being covered with the mounting portion 613 . The lower surface of the prism 5 is fixed to the central exposed portion 623a via fixing means such as an adhesive.

(bottom plate)
The bottom plate portion 624 has a plate shape parallel to the XY plane. The bottom plate portion 624 has a first end (front end) that is the end on the + side in the X direction and a second end (rear end) that is the end on the - side in the X direction. The bottom plate portion 624 has a first side surface (lower side surface) that is the Z-direction-side surface.

A front end portion of the bottom plate portion 624 is connected to a front end portion of the central plate portion 623 . The bottom plate portion 624 is embedded in the bottom wall portion 614 of the holder main body 61 . On the lower surface of the bottom plate portion 624, the bottom exposed portion 624a, which faces the left first magnet placement portion 614c and the right first magnet placement portion 614d of the holder body 61 in the vertical direction, is covered with the bottom wall portion 614. exposed to the outside.

A left first magnet 641a and a right first magnet 641b of the first driving portion 64, which will be described later, are fixed to the bottom side exposed portion 624a by fixing means such as adhesion. Such an exposed portion of the bottom plate portion 624 functions as a yoke. A rear exposed portion 624b, which is the rear end portion of the bottom plate portion 624, protrudes rearward from the rear side surface of the bottom wall portion 614 of the holder main body 61. As shown in FIG. Such a rear end side exposed portion 624b contributes to improvement in the bonding strength between the holder main body 61 and the insert plate 62. As shown in FIG.

(Swing support part)
The rocking support portion 63 will be described with reference to FIGS. 2, 10, and 11. FIG. The rocking support portion 63 is for supporting the holder 60 in a rockable state with respect to the base 4 about the first axis A1 and the second axis A2 (see FIG. 11).

The swing support portion 63 is provided between the bottom wall portion 614 of the holder 60 (specifically, the holder main body 61 ) and the bottom wall portion 40 of the base 4 . Specifically, the swing support portion 63 has a stationary magnet 631 , a stationary holding member 632 , a ball 633 , a movable holding member 634 , and a movable magnet 635 in order from the side closer to the base 4 .

(Fixed side magnet)
The fixed-side magnet 631 corresponds to one example of the fixed-side magnetic acting portion and the magnetic acting portion, and is a disc-shaped magnet that is magnetized in the vertical direction. The fixed-side magnet 631 is magnetized so that the upper surface is the first pole (for example, N pole) and the lower surface is the second pole (for example, S pole).

The fixed-side magnet 631 is fixed to the fixed-side magnet holding portion 401 of the base 4 by fixing means such as adhesion.

(Fixed side holding member)
The fixed-side holding member 632 is disk-shaped and made of a material (for example, synthetic resin or metal) harder than the material forming the base 4 .

The fixed-side holding member 632 has a fixed-side holding surface 632a on its upper surface. The fixed-side holding surface 632 a has a conical shape that opens to the upper surface of the fixed-side holding member 632 . The inner diameter of the fixed-side holding surface 632a becomes smaller toward the bottom.

The fixed-side holding member 632 restricts rotation with respect to the base 4, for example, based on engagement between an engaging portion provided on the outer peripheral surface of the fixed-side holding member 632 and the inner peripheral surface of the fixed-side magnet holding portion 401. It is The fixed-side holding member 632 is fixed above the portion of the fixed-side holding member 632 to which the fixed-side magnet 631 is fixed by a fixing means such as adhesion.

Although illustration is omitted, the fixed-side holding member may be integrally formed with the base 4 . In this case, the fixed-side holding surface may be directly formed on the upper surface of the bottom wall portion 40 of the base 4 . In this case, the stationary magnet 631 may be arranged below the stationary holding surface on the bottom wall portion 40 of the base 4 . Therefore, even when the fixed-side holding member is integrally formed with the base 4, the positional relationship between the fixed-side magnet and the fixed-side holding surface is the same as in the present embodiment.

(ball)
The ball 633 corresponds to an example of the support member and is made of magnetic metal. The ball 633 is provided between a fixed side holding member 632 and a movable side holding member 634 which will be described later. The ball 633 has a central portion and a pair of contact surfaces that contact a fixed-side holding surface 632a and a movable-side holding surface 634a, which will be described later. The pair of contact surfaces are spherical around the center of ball 633 . In addition, the supporting member is not limited to the ball. The shape of the support member may be various shapes in which a pair of abutment surfaces of the support member that abut against the fixed-side holding surface 632a and the movable-side holding surface 634a, which will be described later, are spherical.

Incidentally, in the case of this embodiment, the ball 633, which is the supporting member, is made of magnetic metal but is not magnetized. However, the support member may be magnetized in a specific direction so that it can be attracted to the fixed magnet 63 and movable magnet 635 . When the support member is magnetized, it is preferable that the support member have a structure in which the magnetization directions of the support member and the fixed magnet 63 and the movable magnet 635 do not change.

(Movable side holding member)
The movable-side holding member 634 is disk-shaped and made of a material (for example, synthetic resin or metal) harder than the material forming the holder body 61 of the holder 60 .

The movable-side holding member 634 has a movable-side holding surface 634a on its lower surface. The movable-side holding surface 634 a has a conical shape that opens to the lower surface of the movable-side holding member 634 . The inner diameter of the movable side holding surface 634a becomes smaller toward the upper side.

The movable-side holding member 634 is fixed to the movable-side magnet placement portion 614a of the holder 60 (specifically, the holder main body 61) by fixing means such as adhesion. The movable-side holding member 634 restricts rotation with respect to the holder 60, for example, based on engagement between an engaging portion provided on the outer peripheral surface of the movable-side holding member 634 and the inner peripheral surface of the movable-side magnet placement portion 614a. It is

Although illustration is omitted, the movable-side holding member may be integrally formed with the holder 60 (specifically, the holder main body 61). In this case, the movable-side holding surface may be formed directly on the lower surface of the bottom wall portion 614 of the holder 60 (specifically, the holder main body 61).

Also, in this case, a movable-side magnet 635, which will be described later, may be arranged above the movable-side holding surface on the bottom wall portion 614 of the holder 60 (specifically, the holder main body 61). Therefore, even when the movable-side holding member is integrally formed with the holder 60 (specifically, the holder main body 61), the positional relationship between the movable-side magnet and the movable-side holding surface is the same as in the present embodiment. .

(Moving side magnet)
The movable-side magnet 635 corresponds to an example of the movable-side magnetic acting portion and the magnetic acting portion, and is a disc-shaped magnet that is magnetized in the vertical direction. The movable-side magnet 635 is magnetized so that the upper surface is the first pole (for example, N pole) and the lower surface is the second pole (for example, S pole). The magnetization direction of the movable-side magnet 635 and the magnetization direction of the fixed-side magnet 631 are the same.

The movable-side magnet 635 is fixed above the portion to which the movable-side holding member 634 is fixed in the movable-side magnet arrangement portion 614a by fixing means such as adhesion.

(Summary of rocking support)
A part of the outer peripheral surface of the ball 633 is in contact with the fixed side holding surface 632 a of the fixed side holding member 632 . The ball 633 is attracted to the fixed side holding surface 632a based on the attractive force between the ball 633 and the fixed side magnet 631 (that is, the magnetic force of the fixed side magnet 631).

A part of the outer peripheral surface of the ball 633 is in contact with the movable side holding surface 634 a of the movable side holding member 634 . The ball 633 is attracted to the movable side holding surface 634a based on the attractive force between the ball 633 and the movable side magnet 635 (that is, the magnetic force of the movable side magnet 635).

Therefore, the ball 633 and the movable-side holding surface 634a are configured to keep the distance between the center of the ball 633 and the movable-side magnet 635 constant while the holder 60 is rocking. In other words, the movable-side magnet 635 swings on an arc around the center of the ball 633 when the holder 60 swings. That is, the ball 633 has a central portion and supports the holder 60 so as to be able to swing about this central portion. Such a configuration can stabilize the oscillation of the holder 60, and thus can stabilize the drive characteristics and improve the reliability of the optical path bending module 2. FIG.

The centers of the fixed magnet 631, fixed holding member 632, ball 633, movable holding member 634, and movable magneto 635 are located on the first axis A1.

The rocking support portion 63 configured as described above supports the holder 60 in a rockable state about the first axis A1 and the second axis A2 (see FIG. 11) with respect to the base 4. . In addition, since the ball 633 is pressed against the fixed side holding surface 632a and the movable side holding surface 634a based on the magnetic forces of the fixed side magnet 631 and the movable side magnet 635, the ball 633, the fixed side holding surface 632a and the movable side holding surface 632a are pressed against each other. There is no gap with the surface 634a. As a result, the holder 60 is positioned with respect to the base 4 by the swing support portion 63 .

Incidentally, in the case of this embodiment, the ball 633, which is the support member, is not a magnet but a magnetic metal. However, the support member (ball 633) may be a magnet. When the support member (ball 633) is a magnet, a magnet may be employed as the magnetic acting portion, like the fixed magnet 631 and the movable magnet 635 of this embodiment. Also, when the support member (ball 633) is a magnet, the magnetic acting portion may be made of magnetic metal instead of a magnet. Specifically, when the support member (ball 633) is a magnet, instead of the fixed side magnet 631, a fixed side magnetic acting portion made of magnetic metal is adopted instead of a magnet, and instead of the movable side magnet 635, a magnet is used. It is also possible to employ a movable side magnetically acting portion made of non-magnetic metal.

(first drive unit)
The first driving portion 64 swings the holder 60 about the first axis A1 (see FIG. 11). The first axis A1 is an axis parallel to the Z direction. Specifically, the first axis A1 is an axis passing through the center of the ball 633 of the swing support portion 63 and parallel to the Z direction.

The first drive section 64 has a left first drive section 64 a , a right first drive section 64 b and a first position detection element 643 .

(left first drive unit)
The left first driving portion 64 a is provided between the bottom wall portion 614 of the holder 60 and the FPC 7 fixed to the base 4 . The FPC 7 may be regarded as part of the stationary member.

The left first drive unit 64a is a voice coil motor and includes a left first magnet 641a and a left first coil 642a.

The left first magnet 641 a is arranged in the left first magnet placement portion 614 c of the bottom wall portion 614 of the holder 60 . The upper side surface of the first left magnet 641 a is attracted to the bottom plate portion 624 of the insert plate 62 . The left first magnet 641a is fixed to the bottom plate portion 624 of the insert plate 62 and the left first magnet placement portion 614c of the holder main body 61 by fixing means such as adhesion.

The first left magnet 641a is composed of two magnet elements adjacent to each other in the front-rear direction. Each of these magnet elements is magnetized in the vertical direction and has one magnetic pole on one side. The orientation of the magnetic poles of each magnet element is opposite to each other.

The left first coil 642a is an oval so-called air-core coil to which power is supplied during shake correction. The left first coil 642a is fixed to the left first coil fixing portion 713 of the FPC 7 by a fixing means such as adhesion, with the long axis aligned in the left-right direction.

The left first coil 642a is provided below the left first magnet 641a. The left first coil 642a faces the left first magnet 641a with a predetermined gap in the vertical direction.

In this embodiment, the first left magnet 641a is provided on the movable member, and the first left coil 642a is provided on the fixed member. However, the left first magnet 641a may be provided on the fixed member and the left first coil 642a may be provided on the movable member.

(Right side first drive unit)
The right first driving section 64b is a voice coil motor and includes a right first magnet 641b and a right first coil 642b.

The right first magnet 641 b is arranged in the right first magnet placement portion 614 d of the bottom wall portion 614 of the holder 60 . The first right magnet 641 b is attracted to the bottom plate portion 624 of the insert plate 62 . The right first magnet 641b is fixed to the bottom plate portion 624 of the insert plate 62 and the right first magnet arrangement portion 614d of the holder main body 61 by fixing means such as adhesion.

The first right magnet 641b is composed of two magnet elements adjacent to each other in the front-rear direction. Each of these magnet elements is magnetized in the vertical direction and has one magnetic pole on one side. The orientation of the magnetic poles of each magnet element is opposite to each other.

The right first coil 642b is an oval so-called air-core coil to which power is supplied during shake correction. The right first coil 642b is fixed to the right first coil fixing portion 714 of the FPC 7 by a fixing means such as adhesion, with the long axis aligned in the left-right direction.

The right first coil 642b is provided below the right first magnet 641b. The right first coil 642b faces the right first magnet 641b with a predetermined gap in the vertical direction. The left first coil 642a and the right first coil 642b are electrically connected via wiring (not shown) of the FPC 7 .

In this embodiment, the first right magnet 641b is provided on the movable member, and the first right coil 642b is provided on the fixed member. However, the right first magnet 641b may be provided on the fixed member, and the right first coil 642b may be provided on the movable member.

In the case of the present embodiment, the left first driving portion 64a and the right first driving portion 64b pass through the third axis (the axis parallel to the front-rear direction) orthogonal to the first axis A1 and the second axis A2, and extend along the XZ plane. has a symmetrical structure with respect to a plane parallel to The left first driving portion 64a and the right first driving portion 64b are provided parallel to a plane (XY plane) orthogonal to the Z direction (first direction).

(first position detection element)
The first position detection element 643 is fixed to the first element fixing portion 715 of the FPC7. The first position detection element 643 is provided below the first left magnet 641a. The first position detection element 643 faces the end (specifically, the left end) of the left first magnet 641a in the vertical direction.

Specifically, the first position detection element 643 is arranged such that the center of the detection surface of the first position detection element 643 coincides with the contact surface between the front side magnet element and the rear side magnet element that constitute the left first magnet 641a. , are provided so as to face each other in the vertical direction.

The first position detection element 643 is connected to the power supply through the FPC7. The first position detection element 643 detects the magnetic flux (also referred to as position information) of the first left magnet 641 a and sends the detected value to the controller 92 mounted on the sensor substrate 91 . Based on the detection value received from the first position detection element 643, the control section 92 obtains the position of the first left magnet 641a (holder 60) around the first axis A1.

In the case of this embodiment, the first position detection element 643 detects a change in magnetic flux passing vertically through the detection surface of the first position detection element 643 . In a state where the holder 60 does not swing about the first axis A1 (also referred to as a reference state of the holder), the magnetic flux passing vertically through the detection surface of the first position detection element 643 is zero. The arrangement of the first left magnet 641a and the first position detection element 643 is set.

When the holder 60 swings about the first axis A1 from the reference state, the left first magnet 641a swings (moves in the front-rear direction) together with the holder 60, and the detection surface of the first position detection element 643 moves. The magnetic flux passing through in the vertical direction changes.

(Operation of first drive unit)
In the case of the first drive unit 64 having the configuration as described above, under the control of the control unit 92, when current flows through the left first coil 642a and the right first coil 642b via the FPC 7, the left first magnet 641a and the A Lorentz force is generated that displaces the right first magnet 641b in the front-rear direction.

Specifically, the Lorentz force acting in one direction in the front-rear direction acts on the first left magnet 641a. On the other hand, the Lorentz force acting in the other direction in the front-rear direction acts on the first right magnet 641b. In this manner, forces directed in opposite directions in the front-rear direction act on the first left magnet 641a and the first right magnet 641b.

Since the first left magnet 641a and the first right magnet 641b are fixed to the holder 60, the holder 60 swings about the first axis A1 based on the Lorentz force. By controlling the directions of the currents flowing through the left first coil 642a and the right first coil 642b, the moving direction (rotating direction) of the holder 60 is switched.

Although illustration is omitted, the swing stroke of the holder 60 about the first axis A1 is defined by a gap in the left-right direction or the front-rear direction between a part of the holder 60 and a part of the base 4. there is

For example, when the holder 60 swings about the first axis A1 in the first rotation direction, the holder 60 is moved from the left wall portion 611 of the holder 60 in the reference state (also referred to as the first movable side restricting portion). ) and a portion of the left wall portion 41 of the base 4 (also referred to as the first fixed side restricting portion). is movable.

When the holder 60 swings about the first axis A1 in the first rotation direction, the holder 60 swings in the first rotation direction when the first movable side regulating portion and the first fixed side regulating portion come into contact with each other. stops.

Further, when the holder 60 swings about the first axis A1 in the second rotation direction, the holder 60 in the reference state of the holder 60 is a part of the right wall portion 612 of the holder 60 (also referred to as the second movable side restricting portion). ) and a portion of the right wall portion 42 of the base 4 (also referred to as a second fixed side restricting portion). is movable.

When the holder 60 swings about the first axis A1 in the second rotation direction, when the second movable side regulating portion and the second fixed side regulating portion come into contact with each other, the holder 60 swings in the second rotation direction. stops.

(Second drive unit)
The second driving portion 65 swings the holder 60 around the second axis A2 (see FIG. 11). The second axis A2 is an axis passing through the center of the ball 633 of the swing support portion 63 and parallel to the Y direction.

The second drive section 65 has a second magnet 651 , a second coil 652 , a second position detection magnet 653 and a second position detection element 654 . The second driving portion 65 has a symmetrical structure with respect to a plane parallel to the XZ plane. Also, the second driving portion 65 is provided in a state parallel to a plane (YZ plane) perpendicular to the X direction, which is the second direction.

(second magnet)
The second magnet 651 is arranged in the second magnet placement portion 610 a of the rear wall portion 610 of the holder 60 . The front side surface of the second magnet 651 is attracted to the rear plate portion 620 of the insert plate 62 . The second magnet 651 is fixed to the rear plate portion 620 of the insert plate 62 and the second magnet arrangement portion 610a of the holder main body 61 by fixing means such as adhesion.

The second magnet 651 is composed of two vertically adjacent magnet elements. Each of these magnet elements is magnetized in the front-rear direction and has one magnetic pole on one side. The orientation of the magnetic poles of each magnet element is opposite to each other.

(Second coil)
The second coil 652 is an oval so-called air-core coil to which power is supplied during shake correction. The second coil 652 is arranged in the second coil arrangement portion 431 of the base 4 with the longitudinal axis aligned in the left-right direction. The second coil 652 is fixed to the portion of the second FPC element 72 of the FPC 7 that is arranged in the second coil arrangement portion 431 .

The second coil 652 is provided behind the second magnet 651 . The second coil 652 faces the second magnet 651 with a predetermined gap in the front-rear direction.

The second coil 652 has a first end and a second end. A first end of the second coil 652 is connected to a first terminal (not shown) of the FPC 7 . This first terminal is, for example, the terminal connected to the positive side of the power supply. A second end of the second coil 652 is connected to a second terminal (not shown) of the FPC 7 . This second terminal is, for example, the terminal connected to the negative side of the power supply.

(Second position detection magnet)
The second position detection magnet 653 is arranged in the position detection magnet placement portion 610 b of the rear wall portion 610 of the holder 60 . The front side surface of the second position detection magnet 653 is attracted to the rear plate portion 620 of the insert plate 62 . The second position detection magnet 653 is fixed to the rear plate portion 620 of the insert plate 62 and the position detection magnet arrangement portion 610b of the holder main body 61 by fixing means such as adhesion.

The second position detection magnet 653 is magnetized in the front-rear direction and has one magnetic pole on one side. In the case of this embodiment, the magnetization direction of the second position detection magnet 653 is opposite to the magnetization direction of the lower magnet element among the two magnet elements that constitute the second magnet 651 . Such a configuration contributes to improvement in position detection accuracy by the second position detection element 654, which will be described later.

(Second position detection element)
The second position detection element 654 is fixed to the front side surface of the second FPC element 72 of the FPC 7 . The second position detection element 654 is connected to the power supply through the FPC7. The second position detection element 654 is provided behind the second position detection magnet 653 . The second position detection element 654 faces the second position detection magnet 653 in the front-rear direction.

The second position detection element 654 detects the magnetic flux (also referred to as position information) of the second position detection magnet 653 passing through the detection surface of the second position detection element 654, and outputs the detected value to the sensor substrate 91. sent to the control unit 92. Note that the detection surface of the second position detection element 654 is a surface parallel to the YZ plane.

Specifically, the second position detection element 654 is arranged such that the center of the detection surface of the second position detection element 654 is positioned between the lower magnet element and the second magnet element of the two magnet elements that constitute the second magnet 651 . It is provided so as to face the contact surface with the two-position detection magnet 653 in the front-rear direction.

In the case of this embodiment, the second position detection element 654 detects changes in magnetic flux passing through the detection surface of the second position detection element 654 in the front-rear direction. In a state where the holder 60 does not swing about the second axis A2 (also referred to as a reference state of the holder), the second position is set so that the magnetic flux passing through the second position detection element 654 in the front-rear direction becomes zero. The arrangement of the detection magnet 653 and the second position detection element 654 is set.

When the holder 60 swings about the second axis A2 from the reference state, the second position detection magnet 653 swings together with the holder 60, and the magnetic flux passing through the second position detection element 654 in the vertical direction changes. .

Based on the detection value received from the second position detection element 654, the control section 92 obtains the position of the second position detection magnet 653 (holder 60) around the second axis A2.

(Operation of second drive unit)
In the case of the second drive unit 65 having the configuration as described above, when a current flows through the second coil 652 via the FPC 7 under the control of the control unit 92, the second magnet 651 is displaced to one side in the vertical direction. power is generated.

Since the second magnet 651 is fixed to the holder 60, the holder 60 swings about the second axis A2 based on the Lorentz force. By controlling the direction of the current flowing through the second coil 652, the direction of movement (direction of rotation) of the holder 60 is switched.

Although illustration is omitted, the swing stroke of the holder 60 about the second axis A2 is defined by a gap in the vertical direction or the front-rear direction between a part of the holder 60 and a part of the base 4. there is

For example, when the holder 60 swings about the second axis A2 in the first rotation direction, the holder 60 is moved to a part of the front end portion of the holder 60 (also referred to as a third movable side regulating portion) in the reference state of the holder 60 . ) and a portion of the front end of the base 4 (also referred to as a third fixed side restricting portion). .

When the holder 60 swings about the second axis A2 in the first rotation direction, when the third movable side regulating portion and the third fixed side regulating portion come into contact with each other, the holder 60 swings in the second rotation direction. stops.

Further, when the holder 60 swings about the second axis A2 in the second rotation direction, the holder 60 is moved to a portion of the rear end portion of the holder 60 (also referred to as a fourth movable side regulating portion) in the reference state of the holder 60. ) and a portion of the rear end portion of the base 4 (also referred to as a fourth fixed side restricting portion). is.

When the holder 60 swings about the second axis A2 in the second rotation direction, when the fourth movable side regulating portion and the fourth fixed side regulating portion come into contact with each other, the holder 60 swings in the second rotation direction. stops.

(return mechanism)
The return mechanism 66 is a mechanism for returning the holder 60 to its initial position about the first axis when the first driving portion 64 stops while the holder 60 is swinging about the first axis A1. The return mechanism 66 is also a mechanism for returning the holder 60 to its initial position about the second axis when the second drive unit 65 stops while the holder 60 is swinging about the second axis A2. be.

Furthermore, the return mechanism 66 is also a mechanism for positioning the holder 60 with respect to the base 4 in a state where the holder 60 is positioned at the initial position about the first axis and the initial position about the second axis. Note that the initial position of the holder 60 about the first axis is regarded as the position of the holder 60 about the first axis in a state in which the first driving section 64 is not driven (also referred to as a non-driving state of the first driving section). you can Further, the initial position of the holder 60 about the second axis is regarded as the position of the holder 60 about the second axis in a state in which the second driving section 65 is not driven (also referred to as a non-driving state of the second driving section). you can

Specifically, the return mechanism 66 has a pair of left springs 661, 662 and a pair of right springs 663, 664, as shown in FIGS. The pair of left springs 661, 662 and the pair of right springs 663, 664 are examples of elastic members.

A pair of left springs 661, 662 and a pair of right springs 663, 664 respectively have a first locking portion 66a, a second locking portion 66b, and an elastic deformation portion 66c.

The first locking portion 66a constitutes upper ends of the pair of left springs 661, 662 and the pair of right springs 663, 664, respectively. The first locking portion 66 a is locked to the holder 60 .

Specifically, the first engaging portion 66 a of the left spring 661 is engaged with the left engaging portion 611 a of the holder 60 . The first engaging portion 66a of the left spring 662 is engaged with the left engaging portion 611b of the holder 60. As shown in FIG.

Also, the first engaging portion 66 a of the right spring 663 is engaged with the right engaging portion 612 a of the holder 60 . Also, the first engaging portion 66 a of the right spring 664 is engaged with the right engaging portion 612 b of the holder 60 .

The second locking portion 66b constitutes the lower ends of the pair of left springs 661, 662 and the pair of right springs 663, 664, respectively. The second locking portion 66b is locked to the base 4. As shown in FIG.

Specifically, the second locking portion 66 b of the left spring 661 is locked to the left locking portion 411 of the base 4 . The second engaging portion 66b of the left spring 662 is engaged with the left engaging portion 412 of the base 4. As shown in FIG.

The second engaging portion 66b of the right spring 663 is engaged with the right engaging portion 421 of the base 4. As shown in FIG. The second engaging portion 66b of the right spring 663 is engaged with the right engaging portion 422 of the base 4. As shown in FIG.

The elastic deformation portion 66c vertically connects the first locking portion 66a and the second locking portion 66b. The elastically deformable portion 66c is a wire having a meandering shape that is folded back several times in the horizontal direction. The elastic deformation portion 66c is elastically deformed when the holder 60 swings about the first axis A1. The restoring force of the elastically deforming portion 66c acts on the holder 60 as a force (hereinafter referred to as a first restoring force) directed to return the holder 60 to the initial position around the first axis.

The elastic deformation portion 66c also elastically deforms when the holder 60 swings about the second axis A2. The restoring force of the elastically deforming portion 66c acts on the holder 60 as a force (hereinafter referred to as a second restoring force) directed to return the holder 60 to the initial position about the second axis.

The return mechanism 66 configured as described above is configured such that when the holder 60 is positioned at the initial position about the first axis A1 and the initial position about the second axis A2, the pair of left springs 661 and 662 and the pair of right springs The elastic deformation portions 66c of 663 and 664 are in a neutral state in which they are not deformed.

A first restoring force acts on the holder 60 when the holder 60 swings about the first axis A1. A second restoring force acts on the holder 60 when the holder 60 swings about the second axis A2. In a state in which the holder 60 swings about the first axis A1 and swings about the second axis A2, the first restoring force and the second restoring force act on the holder 60 at the same time.

In the state where the first driving portion 64 is driven (driving state of the first driving portion), the driving force of the first driving portion 64 is applied to the return mechanism 66 (specifically, the pair of left springs 661 and 662). and a pair of right springs 663, 664).

Therefore, the holder 60 swings around the first axis A<b>1 based on the driving force of the first driving portion 64 . On the other hand, when the first driving portion 64 is not driven (non-driving state of the first driving portion), the holder 60 returns to the initial position about the first axis based on the first restoring force received from the return mechanism 66. return. In the non-driving state of the first driving portion 64 , the holder 60 is positioned at the initial position around the first axis by the return mechanism 66 . Therefore, swinging of the holder 60 about the first axis is suppressed when the first driving portion 64 is in a non-driving state.

Further, in the state where the second driving portion 65 is driven (driving state of the second driving portion), the driving force of the second driving portion 65 is applied to the return mechanism 66 (specifically, the pair of left springs 661). , 662 and the pair of right springs 663, 664).

Therefore, the holder 60 swings about the second axis A<b>2 based on the driving force of the second driving portion 65 . On the other hand, when the second driving portion 65 is not driven (non-driving state of the second driving portion), the holder 60 returns to the initial position about the first axis based on the second restoring force received from the return mechanism 66. return. In the non-driving state of the second driving portion 65 , the holder 60 is positioned at the initial position around the second axis by the return mechanism 66 . Therefore, swinging of the holder 60 about the second axis is suppressed when the second driving portion 65 is in a non-driving state.

[Lens module]
The lens module 80 is arranged on the + side in the X direction compared to the optical path bending module 2 . The light from the subject enters the prism 5 of the optical path bending module 2 from the + side in the Z direction, as indicated by the dashed line α (also referred to as the first optical axis) in FIG.

The light incident on the prism 5 is bent at the optical path bending surface of the prism 5, as indicated by the dashed line β (also referred to as the second optical axis) in FIG. The light is guided to the lens portion 801 of the lens module 80 arranged in the positive direction).

The lens module 80 includes a cover 800, a base (not shown), a lens section 801, and an AF device (not shown). The cover 800 may be integrated with the cover 3 of the optical path bending module 2 or may be separate.

The lens unit 801 is arranged in a housing space existing between the cover and the base while being held by a lens guide (not shown). The lens unit 801 has a lens barrel 801a and one or more lenses 801b held by the lens barrel 801a. The lens unit 801 is supported by the base so as to be displaceable in the X direction via a lens guide.

The AF device is a drive unit that displaces the lens unit 801 in the X direction for the purpose of autofocus. Incidentally, the structure of the AF device is not particularly limited. For example, the AF apparatus may be a motor (not shown) and a conversion mechanism that converts the rotary motion of the motor into linear motion in the X direction to move the lens unit 801 in the X direction.

[Image sensor module]
The imaging element module 81 is arranged on the + side in the X direction compared to the lens unit 801 . The imaging element module 81 includes an imaging element such as a CCD (charge-coupled device) type image sensor, a CMOS (complementary metal oxide semiconductor) type image sensor, or the like. The imaging device of the imaging device module 81 captures the subject image formed by the lens unit 801 and outputs an electrical signal corresponding to the subject image. A sensor substrate 91 is electrically connected to the image pickup device module 81, and power is supplied to the image pickup device module 81 via the sensor substrate 91, and an electrical signal of a subject image picked up by the image pickup device module 81 is output. Such an image sensor module 81 can adopt a conventionally known structure.

(Action and effect of the present embodiment)
According to this embodiment having the configuration as described above, the size of the camera module 1 can be reduced.

That is, in the case of the present embodiment, a mechanism that supports the holder 60 so as to swing the first shaft 1A with respect to the base 4 and a mechanism that supports the holder 60 with respect to the base 4 so that the second shaft 2A can swing. are configured by a common swing support portion 63 .

Therefore, in the case of this embodiment, there is a mechanism for supporting the holder 60 with respect to the base 4 so as to swing the first shaft 1A, and a mechanism for supporting the holder 60 with respect to the base 4 so as to swing the second shaft 2A. , and , can be miniaturized in the optical path bending module 2, and by extension, in the camera module 1, as compared with a structure in which these are provided separately.

Also, based on the magnetic force of the fixed-side magnet 631 and the movable-side magnet 635 that constitute the swing support portion 63, the ball 633 that constitutes the swing support portion 63 is attracted to the fixed-side holding surface 632a and the movable-side holding surface 634a. ing. Therefore, no gap exists between the ball 633 and the fixed side holding surface 632a and the movable side holding surface 634a. As a result, the holder 60 can be positioned with respect to the base 4 by the swing support portion 63 . As described above, according to this embodiment, the ball 633 , the fixed magnet 631 and the movable magnet 635 can position the holder 60 with respect to the base 4 with a simple structure.

Both the fixed magnet 631 and the movable magnet 635 magnetically attract the ball 633 . In other words, a magnetic attraction force acts between the stationary magnet 631 and the ball 633 and between the movable magnet 635 and the ball 63 . Such a configuration can reduce the height of the optical path bending module 2 while positioning the holder 60 with respect to the base 4 .

The ball 633 is attracted to the fixed side holding surface 632 a of the fixed side holding member 632 and the movable side holding surface 634 a of the movable side holding member 634 by the magnetic forces of the fixed side magnet 631 and the movable side magnet 635 . That is, the ball 633 is held by the fixed-side holding surface 632a and the movable-side holding surface 634a, which are surfaces. Such a configuration can stably hold the ball 633 with respect to the fixed side holding member 632 (in other words, the base 4) and the movable side holding surface 634a (in other words, the holder 60).

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

In each of the above-described embodiments, the smartphone M (see FIGS. 14A and 14B), which is a mobile terminal with a camera, was described as an example of a camera-equipped device equipped with the camera module 1. However, the present invention includes a camera module and a camera. It can be applied to a camera-equipped device having an image processing section that processes image information obtained by a module. Camera-equipped devices include information equipment and transportation equipment. Information devices include, for example, camera-equipped mobile phones, laptop computers, tablet terminals, portable game machines, web cameras, and camera-equipped in-vehicle devices (eg, back monitor devices, drive recorder devices). Transportation equipment also includes, for example, automobiles.

15A and 15B are diagrams showing an automobile V as a camera-equipped device equipped with an in-vehicle camera module VC (Vehicle Camera). 15A is a front view of automobile V, and FIG. 15B is a rear perspective view of automobile V. FIG. An automobile V is equipped with the camera module 1 described in the embodiment as an in-vehicle camera module VC. As shown in FIGS. 15A and 15B, the in-vehicle camera module VC is attached to the windshield facing forward, or attached to the rear gate facing rearward, for example. This in-vehicle camera module VC is used for a back monitor, a drive recorder, collision avoidance control, automatic driving control, and the like.

The optical actuator and camera module according to the present invention can be mounted on thin camera-equipped devices such as smartphones, mobile phones, digital cameras, laptop computers, tablet terminals, portable game machines, and vehicle-mounted cameras.

1 camera module 2 optical path bending module 3 cover 4 base 40 bottom wall portion 401 fixed side magnet holding portion 402 first coil placement portion 403 left first coil placement portion 404 right first coil placement portion 41 left wall portion 411, 412 left side engagement Stopping portion 413, 414 Left damper placement portion 42 Right wall portion 421, 422 Right locking portion 423, 424 Right damper placement portion 43 Rear wall portion 431 Second coil placement portion 44 Base plate 5 Prism 6 Shake correction device 60 Holder 61 Holder body 610 rear wall portion 610a second magnet arrangement portion 610a1 recess 610b position detection magnet arrangement portion 611 left wall portion 611a, 611b left locking portion 611c, 611d left convex portion 612 right wall portion 612a, 612b right locking portion 612c, 612d right side Protruding portion 613 Mounting portion 614 Bottom wall portion 614a Movable side magnet placement portion 614b First magnet placement portion 614c Left first magnet placement portion 614c1 Recess 614d Right first magnet placement portion 614d1 Recess 62 Insert plate 620 Rear plate portion 621 Left plate Part 621a Left exposed part 622 Right plate part 622a Right exposed part 623 Center plate part 623a Center side exposed part 624 Bottom plate part 624a Bottom side exposed part 624b Rear end side exposed part 63 Swing support part 631 Fixed side magnet 632 Fixed side holding member 632a Fixed-side holding surface 633 Ball 634 Movable-side holding member 634a Movable-side holding surface 635 Movable-side magnet 64 First drive unit 64a Left first drive unit 64b Right first drive unit 641a Left first magnet 641b Right first magnet 642a Left side First coil 642b Right first coil 643 First position detection element 65 Second drive unit 651 Second magnet 652 Second coil 653 Second position detection magnet 654 Second position detection element 66 Return mechanism 661, 662 Left spring 663, 664 Right Spring 66a First Locking Part 66b Second Locking Part 66c Elastic Deformation Part 7 FPC
71 first FPC element 711 first terminal portion 712 first coil fixing portion 713 left first coil fixing portion 714 right first coil fixing portion 715 first element fixing portion 72 second FPC element 721 second coil fixing portion 722 second Element fixing part 73, 74 Left damper member 75, 76 Right damper member 80 Lens module 800 Cover 801 Lens part 801a Lens barrel 801b Lens 81 Imaging element module 91 Sensor board 92 Control part A1 First axis A2 Second axis V Automobile VC Vehicle Camera module for M Smartphone

Claims (7)

a fixed side member;
a movable member capable of holding an optical member;
a drive unit that includes a magnet and causes the movable member to swing with respect to the fixed member;
one of the fixed-side member and the movable-side member has a magnet placement portion that holds the magnet;
The magnet placement portion has at least one concave portion on the inner peripheral surface that forms a gap between the held magnet and the magnet placement portion.
optical actuator. The magnet is fixed to the inner peripheral surface with an adhesive,
2. The optical actuator according to claim 1, wherein the recess is a supply port for the adhesive when supplying the adhesive between the inner peripheral surface and the outer peripheral surface of the magnet. The inner peripheral surface has a rectangular frame shape provided so as to surround the outer peripheral surface of the magnet,
2. The optical actuator according to claim 1, wherein the concave portion is provided on each of two sides facing each other on the inner peripheral surface. The inner peripheral surface has a rectangular frame shape provided so as to surround the outer peripheral surface of the magnet,
2. The optical actuator according to claim 1, wherein two of said recesses are provided on one side of said inner peripheral surface so as to be adjacent to each other. The one member has a right magnet arrangement portion and a left magnet arrangement portion provided so as to be laterally adjacent to each other,
the inner peripheral surfaces of the right magnet placement portion and the left magnet placement portion each have a rectangular frame shape surrounding the outer peripheral surface of the magnet;
The recess is provided on an inner peripheral surface of the right magnet placement portion on a side near the left magnet placement portion,
2. The optical actuator according to claim 1, wherein the concave portion is provided on a side of the inner peripheral surface of the left magnet placement portion near the right magnet placement portion. An optical actuator according to claim 1;
an optical path bending member held by the movable side member of the optical actuator and bending incident light along the first direction so as to travel in one direction in the second direction;
an imaging element arranged on one side in the second direction with respect to the optical actuator;
A camera module with a camera module according to claim 6;
a control unit that controls the camera module;
A camera-mounted device having a

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