CN210742593U - Optical member driving device, camera device, and electronic apparatus - Google Patents

Abstract

The utility model provides an optical component drive arrangement, camera device and electronic equipment that can fix SMA cable with abundant intensity. The OIS lens driving device (2) is provided with a base (3), an FPC (7) fixed on the base (3), a lower curling plate (4) fixed on the FPC (7), an upper curling plate (5) sliding on the lower curling plate (4), and a plurality of SMA cables (6) with two ends fixed on the lower curling plate (4) and the upper curling plate (5). Thus, the lower crimp plate (4) includes a 1 st plate (40A) and a 2 nd plate (40B) which are a plurality of plates having one crimp portion, and the plates are fixed to the FPC (7) in a state of being separated from each other and are electrically connected.

Description

Optical member driving device, camera device, and electronic apparatus

Technical Field

The present invention relates to an optical component drive device, a camera device, and an electronic apparatus used in an electronic apparatus such as a smartphone.

Background

Some camera apparatuses having an OIS (Optical Image Stabilizer) function include a camera apparatus in which an SMA (memory Alloy) cable is disposed between a movable member holding an Optical member and a support member supporting the movable member, and the movable member and the support member are relatively moved by expansion and contraction of the SMA cable. As a document disclosing a technique related to such a camera device, there is patent document 1. The suspension unit described in patent document 1 includes: the movable part as the plate body is made of stainless steel; and a support member as a plate body, in which a wiring portion formed of an FPC (Flexible Printed Circuits) is provided on the base. The movable member and the support member are disposed to face each other with the bearing interposed therebetween, and each of corners of the support member in the diagonal direction and corners of the movable member in the diagonal direction intersecting the corner have a curled portion. An SMA wire is laid between the crimps of the movable member and the crimps of the support member.

[ Prior art documents ]

[ patent document ]

[ patent document 1 ] International publication No. WO2018/129185A

SUMMERY OF THE UTILITY MODEL

[ problem to be solved by the utility model ]

However, in the technique of patent document 1, the wiring portions on the base of the support member are brought into contact with the crimping portions at the corners, and the SMA wires are crimped to the respective wiring portions at the crimping portions to fix the SMA wires. Therefore, there is a problem in that the fixing strength of the SMA cable is weak.

The present invention has been made in view of the above problems, and an object of the present invention is to provide an optical component driving device, a camera device, and an electronic apparatus capable of fixing an SMA cable with sufficient strength.

[ MEANS FOR SOLVING PROBLEMS ] to solve the problems

In order to solve the above problem, according to a preferred aspect of the present invention, there is provided an optical component driving device including: a base; an FPC fixed on the base; a lower crimping plate fixed to the FPC; an upper curl plate that slides on the lower curl plate; and a plurality of SMA cables having both ends fixed to the lower crimp plate and the upper crimp plate, the lower crimp plate including a plurality of plate pieces having one crimp portion, the plate pieces being fixed to the FPC in a state of being separated from each other and being electrically connected.

In this aspect, the lower curl plate may have a plate piece that does not have the curl portion, and a wrist portion extending from a main body portion of the upper curl plate may be electrically connected to the plate piece.

Further, the respective plates may be directly soldered to pads provided on the surface of the FPC.

In another preferred aspect of the present invention, the camera device includes the optical member driving device.

An electronic device according to another preferred embodiment of the present invention is characterized by including the camera device.

[ Utility model effect ] is provided

The utility model discloses an optical component drive arrangement possesses: a base; an FPC fixed on the base; a lower crimping plate fixed to the FPC; an upper curl plate that slides on the lower curl plate; and a plurality of SMA cables having both ends fixed to the lower crimping plate and the upper crimping plate, the lower crimping plate including a plurality of plate pieces having one crimping portion, the plate pieces being fixed to the FPC in a state of being separated from each other and being electrically connected. Thus, even if a separate wiring connected to a terminal connected from each sheet to an external power source is provided in advance on the FPC, it is not necessary to provide a wiring to each sheet itself. Therefore, the SMA cable is directly crimped to the curl portion without crimping the SMA cable to each wiring portion, and the optical component drive device, the camera device, and the electronic apparatus that can fix the SMA cable with sufficient strength can be provided.

Drawings

Fig. 1 is a front view of a smartphone 99, and the smartphone 99 is an electronic device on which a camera apparatus 1 including an OIS lens driving apparatus 2 as an optical component driving apparatus according to an embodiment of the present invention is mounted.

Fig. 2 is a perspective view of the camera device 1 of fig. 1.

Fig. 3 is a perspective view of the OIS lens driving apparatus 2 of fig. 2.

Fig. 4 is a perspective view of the OIS lens driving apparatus 2 of fig. 2 exploded.

Fig. 5 (a) is a view of a part of the upper curl plate 5 of the OIS lens driving apparatus 2 of fig. 2 viewed obliquely from below, (B) is a cross-sectional view showing a contact portion between the convex portion 50 of the upper curl plate 5 and the 3 rd plate piece 40C of the lower curl plate 4, and (C) is a view of parts of the upper curl plate 5 and the lower curl plate 4 viewed obliquely from above.

[ notation ] to show

1 a camera device; 2 OIS lens drive; 3, a base; 4 lower curl plate; 5 an upper curl plate; 6 SMA wires; 7 FPC; 8 lens bodies; 36 a support sheet; 37 a through hole; 38. 88 a terminal block; 39 terminal; 40A No. 1 sheet; 40B a 2 nd plate; 40C No. 3 sheet; 41. 43, 51 cuts; 42A, 42B, 52A, 52B curl portions; 50 convex parts; 54 a body portion; 55 a wrist portion; 56 a connecting part; 57 a through hole; 71 bonding pads; an 80 AF actuator; 90 an image sensor; 98 a housing; 99 smart phones.

Detailed Description

Hereinafter, embodiments of the present invention will be described with reference to the drawings. As shown in fig. 1, the camera device 1 is housed in a housing of a smartphone 99. The camera apparatus 1 has: a lens body 8 as an optical member; an image sensor 90 that photoelectrically converts light incident from a subject via the lens body 8; an AF (Auto focus) actuator 80 that drives the lens body 8 in the optical axis direction; an OIS lens driving device 2 that drives the AF actuator 80 in a plane orthogonal to the optical axis; and a housing 98 covering these components. The lens body 8 as an optical member is driven by the OIS lens driving device 2 in an in-plane direction orthogonal to the optical axis.

Hereinafter, the optical axis direction along the optical axis of the lens body 8 is appropriately referred to as the Z direction, one direction orthogonal to the Z direction is appropriately referred to as the X direction, and a direction orthogonal to both the Z direction and the X direction is appropriately referred to as the Y direction. In addition, the + Z side of the optical axis of the lens body 8 on the side of the object may be referred to as the upper side, and the Z side opposite to the object on which the image sensor 90 is provided may be referred to as the lower side.

As shown in fig. 4, the OIS lens driving apparatus 2 includes: a base 3; a lower curl plate 4 fixed to the base 3; an upper curl plate 5 sliding on the lower curl plate 4; and 4 SMA cables 6 fixed at both ends to the lower curl plate 4 and the upper curl plate 5. The details of the structure of each part will be described below.

The base 3 is in the shape of a thin quadrilateral. A through hole 37 having a perfect circular shape is provided in the center of the base 3. A support piece 36 and a terminal block 38 are provided on the X-side edge of the base 3. The support piece 36 is used to support the terminal stand 88 of the AF actuator 80 from the back side. The AF actuator 80 and the terminal block 88 are connected by an FPC. Five terminals 39 are provided on the terminal block 38 of the base 3. One of the five terminals 39 is a ground terminal. The remaining 4 are current input terminals.

An FPC7 is fixed to the upper surface of the base 3. The pads 71 are provided at six positions on the periphery of the through hole 37 of the FPC 7. The FPC7 is a circuit board and has wirings from the pads 71 to the terminals 39.

The lower curl plate 4 is disposed so that the pair of the 1 st plate piece 40A, the pair of the 2 nd plate piece 40B, and the pair of the 3 rd plate piece 40C having the arcuately curved sides face inward with the curved sides, and has a substantially square outer shape as a whole. The 1 st plate 40A, the 2 nd plate 40B, and the 3 rd plate 40C are made of a conductive material such as SUS, for example. The 1 st sheet 40A, the 2 nd sheet 40B, and the 3 rd sheet 40C are fixed to the FPC7 in a state of being separated from each other.

Each pair of the 1 st plate 40A, the 2 nd plate 40B, and the 3 rd plate 40C is disposed at a point-symmetrical position with respect to the center of the through-hole 37. Thus, the 1 st plate 40A and the 2 nd plate 40B are located at both sides of one diagonal line of the lower curl plate 4 having a substantially square shape, and the 3 rd plate 40C is located at a position facing the other diagonal line of the substantially square shape, which is sandwiched by the 1 st plate 40A and the 2 nd plate 40B.

The 1 st plate 40A has a notch 41 at its bent side and a curled portion 42A at the corner of the substantially square shape. The curled portion 42A is formed by bending a rectangular piece protruding outward in the Y direction with the corner portion as a base end upward and then folding back toward the base end side. Between the curled portion 42A and the bent edge, a step is provided by bending the 1 st sheet 40A so that the height is equal to a height of a curled portion 52A of an upper curled plate 5 to be described later.

A notch 41 is provided at the bent side of the 2 nd plate 40B, and a curled portion 42B is provided at the corner position of the substantially square shape. The curled portion 42B is formed by folding a rectangular piece protruding outward in the X direction with the corner portion as a base end upward and then folding back toward the base end. Between the curled portion 42B and the bent edge, a step is provided by bending the 2 nd sheet piece 40B so that the height is equal to a height of a curled portion 52B of an upper curled plate 5 to be described later.

The 3 rd plate 40C has a notch 41 at the curved side and a notch 43 at the corner where the 2 nd side opposite to the curved side intersects.

The 1 st, 2 nd, and 3 rd sheets 40A, 40B, and 40C are positioned so that each cutout 41 becomes directly above the pad 71 of the FPC7, and is soldered directly to the pad 71 of the FPC 7. The two 1 st plate pieces 40A and the two 2 nd plate pieces 40B are electrically connected to the respective current input terminals of the five terminals 39 of the terminal block 38 via the wirings of the FPC 7. The two 3 rd sheet pieces 40C are electrically connected to one ground terminal of the five terminals 39 of the terminal block 38 via the wiring of the FPC 7.

The upper curl plate 5 is made of a conductive material such as SUS, for example, and has a substantially square main body 54 and 2 arm portions 55 extending outward from both end edges of the main body 54 parallel to the Y direction in point symmetry. A through hole 57 is provided in the center of the body portion 54. The body 54 has cutouts 51 at six locations around the periphery of the through-hole 57. The main body 54 is provided with protrusions 50 protruding downward at four locations around the periphery of the through-hole 57. As shown in fig. 5 (a), the projection 50 projects smoothly from the main body 54, and its lower surface portion has a circular flat plate shape. The convex portion 50 can be formed integrally with the upper curl plate 5 by punching or the like, and therefore is superior to shock resistance such as drop.

The upper curl plate 5 has its corners facing one diagonal direction chamfered to be rounded, and two curl portions 52A and 52B are provided at the corners facing the other diagonal direction, respectively. The curled portion 52A is formed by folding a rectangular piece, which protrudes outward in the Y direction with the corner portion as a base end, upward and then folding back to the base end side. The curled portion 52B is formed by folding a rectangular piece, which protrudes outward in the X direction with the corner portion as a base end, upward and then folding back to the base end side.

The arm portions 55 project in the Y direction from the base end of the position close to the corner where the curled portion 52B of the end side parallel to the Y direction of the main body portion 54 is located, extend to the corner where the curled portion 52B is not present along the end side in the Y direction, and extend to the front of the curled portion 52A along the end side in the X direction around the outside of the corner. A connection portion 56 is provided at the tip of the wrist portion 55. Two of the projections 50 are provided in the body portion 54 near the connection portion 56.

The lower curl plate 4 and the upper curl plate 5 are sequentially placed on the base 3 so that the corners of the square shape overlap with the corners of the square shape of the base 3. The curled portions 42A and 42B of the lower curled plate 4 are arranged at one diagonal corner of the substantially square shape, and the curled portions 52A and 52B of the upper curled plate 5 are arranged at the other diagonal corner of the substantially square shape. At this time, curled portion 42A and curled portion 52A are juxtaposed in the X direction, and curled portion 42B and curled portion 52B are juxtaposed in the Y direction. The arm 55 is disposed between the chamfered corner of the main body 54 and the step formed between the 1 st plate 40A and the 2 nd plate 40B. The notch 51 of the upper curl plate 5 is located right above the notch 41 of the lower curl plate 4, and the solder does not contact the upper curl plate 5.

As shown in fig. 5 (B), two of the four protrusions 50 of the upper curl plate 5 abut against the abutted portions of the 3 rd sheet 40C of the lower curl plate 4. The remaining two of the projections 50 abut against the abutted portions of the 2 nd plate 40B. A low friction layer is formed on the surface of the projection 50, and an insulating layer is formed on the contacted surface of the 3 rd plate 40C and the 2 nd plate 40B contacted with the projection 50. A low friction layer may be formed on the surface of the 3 rd plate 40C and the 2 nd plate 40B to be contacted, and an insulating layer may be formed on the surface of the convex portion 50. Alternatively, the lower curl plate 4 may be provided with a convex portion, and the upper curl plate 5 may be provided with a contacted portion.

The description is made in detail. When one of the convex portions 50 and the abutted portions is provided on the upper curl plate 5 and the other of the convex portions and the abutted portions is provided on the 1 st plate piece 40A or the 2 nd plate piece 40B of the lower curl plate 4, as will be described later, a potential difference is generated between the upper curl plate 5 and the lower curl plate 4. Therefore, an insulating layer is provided on at least one of the surface of the convex portion and the surface of the abutted portion, and the both are insulated from each other. Therefore, the low friction layer having a small friction coefficient is preferably provided on the surface thereof, that is, on the surface of the projection not provided with the insulating layer, or on the surface of the abutted part or on the surface of the insulating layer.

When one of the convex portion 50 and the abutted portion is provided on the upper curl plate 5 and the other is provided on the 3 rd sheet piece 40C of the lower curl plate 4, the upper curl plate 5 and the lower curl plate 4 are at the same potential as described later. Therefore, the convex portion and the abutted portion can be directly abutted without providing an insulating layer. Further, the layer described in the preceding paragraph may be provided, or only the low friction layer may be provided without providing the insulating layer.

As shown in fig. 5 (C), the connecting portion 56 of the upper curl plate 5 is joined to the upper surface of the 3 rd sheet 40C and electrically connected to the 3 rd sheet 40C. Further, two ends 2 of the SMA cable 6 extending in the X direction are respectively fixed to the curled portion 42A and the curled portion 52A by caulking, and two ends 2 of the SMA cable 6 extending in the Y direction are respectively fixed to the curled portion 42B and the curled portion 52B by caulking.

The five terminals 39 of the terminal block 38 are connected to an external power supply. Thus, a current path of the external power supply → the current input terminal → the wiring of the FPC7 → the 1 st or 2 nd sheet 40A or 40B of the lower curl plate 4 → the SMA cable 6 → the upper curl plate 5 → the 3 rd sheet 40C of the lower curl plate 4 → the wiring of the FPC7 → the ground terminal → the external power supply is formed, and the current is supplied to the SMA cable 6. When electric current is supplied to the SMA wires 6, the SMA wires 6 contract due to heat generation by the energization. By contraction of the SMA wire 6, the upper curl plate 5 and the AF actuator 80 supported by the same move in the XY in-plane direction while sliding on the lower curl plate 4.

The above is the structural details of the present embodiment. The OIS lens driving apparatus 2 as the optical component driving apparatus of the present embodiment includes a base 3, an FPC7 fixed to the base 3, a lower curl plate 4 fixed to an FPC7, an upper curl plate 5 sliding on the lower curl plate 4, and a plurality of SMA cables 6 having both ends fixed to the lower curl plate 4 and the upper curl plate 5. Thus, the lower curl plate 4 includes a plurality of plate pieces having one curl portion, i.e., a 1 st plate piece 40A and a 2 nd plate piece 40B, which are fixed to the FPC7 in a state of being separated from each other and are electrically connected. Thus, even if a separate wiring connected to the terminal 39 connected from each sheet to the external power source is provided in advance in the FPC7, it is not necessary to provide a wiring to each sheet itself. Therefore, the SMA cable 6 can be directly crimped to the crimp portion without crimping the SMA cable 6 to each wiring portion. Therefore, according to the present embodiment, it is possible to provide an optical component driving device, a camera device, and an electronic apparatus capable of fixing the SMA cable 6 with sufficient strength.

In the OIS lens driving apparatus 2 as the optical component driving apparatus of the present embodiment, the lower curl plate 4 has the 3 rd plate piece 40C, the 3 rd plate piece 40C is a plate piece having no curl portion, and the arm portion 55 extending from the main body portion 54 of the upper curl plate 5 is electrically connected to the 3 rd plate piece 40C. Thus, even if a separate wiring connected from the 3 rd sheet 40C to the terminal 39 for grounding is provided in advance on the FPC7, it is not necessary to provide the wiring to the 3 rd sheet 40C itself. Therefore, according to the present embodiment, the electrical connections are all realized with the same structure, and the manufacturing is easy.

In addition, in the above embodiment, each sheet of the lower curl plate 4 is not required to be manufactured by a separate press working. A member in which all the sheet pieces forming the lower curl plate 4 are integrated may be manufactured by press working, and after fixing the member to the FPC7, the connecting portion of each sheet piece may be cut.

Claims (5)

1. An optical component driving device is characterized by comprising:

a base;

an FPC fixed on the base;

a lower crimping plate fixed to the FPC;

an upper curl plate that slides on the lower curl plate; and

a plurality of SMA wires having both ends fixed to the lower crimping plate and the upper crimping plate,

the lower crimp plate includes a plurality of plate pieces having one crimp portion, and the plate pieces are fixed to the FPC in a state of being separated from each other and are electrically connected.

2. Optical component driving device according to claim 1,

the lower curl plate has a plate piece that does not have the curl portion, and a wrist portion extending from a body portion of the upper curl plate is electrically connected to the plate piece.

3. Optical component driving device according to claim 2,

the sheets are directly soldered to pads provided on the surface of the FPC.

4. A camera device comprising the optical member driving device according to any one of claims 1 to 3.

5. An electronic device comprising the camera device according to claim 4.

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