CN214896139U - Camera device and electronic apparatus - Google Patents

Abstract

The utility model provides a be difficult to bring harmful effects's camera device to the optical characteristic of lens. A camera device (8) is provided with a lens carrier (70) for holding a lens body (7) and a blade drive device (1) for driving a blade (11) arranged on the front side of the lens body (7), wherein the lens carrier (70) is provided with a metal carrier side receiving part (701) extending forward from the front end of the lens carrier (70), the blade drive device (1) is provided with a metal blade side receiving part (953) protruding sideward from the side surface of the blade drive device (1) and a blade side receiving part (963), and the carrier side receiving part (701), the blade side receiving part (953) and the blade side receiving part (963) are fixed and electrically connected. The utility model also provides an electronic equipment.

Description

Camera device and electronic apparatus

Technical Field

The utility model relates to a used camera device of electronic equipment such as smart mobile phone and electronic equipment.

Background

Various techniques have been proposed for adjusting the amount of light entering a lens body by sliding a blade of a camera device. The optical device (camera device) disclosed in patent document 1 includes a blade drive device provided on the front side of all lens barrels of the lens drive device, and the blade drive device includes 2 blades, 2 plate members sandwiching the blades from front to back, a coil, and a drive magnet on a base member. The blade driving device adjusts the amount of light incident on the lens module by rotating one of the 2 plate members relative to the other by the electromagnetic force of the blade coil and the driving magnet to move the blade.

Documents of the prior art

Patent document

[ patent document 1 ] Japanese patent laid-open No. 2020 and 122915A

SUMMERY OF THE UTILITY MODEL

Problem to be solved by utility model

However, the optical device of patent document 1 has a structure in which a power feeding terminal having spring elasticity is drawn from the rear surface of the base member, the rear end of the power feeding terminal is connected to a portion of the lens driving device that supports the lens barrel, and a current is supplied from the lens driving device to the blade coil via the power feeding terminal. Therefore, the optical characteristics of the lens held by the lens driving device may be adversely affected.

The present invention has been made in view of the above problems, and an object of the present invention is to provide a camera device which is less likely to adversely affect the optical characteristics of a lens.

Means for solving the problems

In order to solve the above problem, a camera device according to a preferred embodiment of the present invention includes: a lens carrier; which holds the lens body; and a blade driving device that drives a blade disposed on a front side of the lens body, wherein the lens carrier has a metal carrier-side receiving portion extending forward from a front end of the lens carrier, the blade driving device has a metal blade-side receiving portion protruding laterally or rearward from a side surface or a bottom surface of the blade driving device, and the carrier-side receiving portion and the blade-side receiving portion are fixed and electrically connected.

In this aspect, the carrier-side receiving portion may be formed integrally with the lens carrier by insert molding.

The blade-side receiving portion may be formed integrally with the blade drive device by insert molding.

Further, a 1 st surface facing forward may be formed at a front end of the carrier-side receiving portion, a 2 nd surface facing rearward may be formed at a front end of the blade-side receiving portion, and the 2 nd surface may be placed on the 1 st surface.

The two plate-like members of the carrier-side receiving portion may be slightly separated from each other and opposed to each other, and the 1 st surface may be formed to extend in a direction of being separated from each other.

Further, the tip end portion of the 1 st surface may extend forward.

Further, a resin constituting the lens carrier body may be filled between the two plate-like members.

Further, the lens drive device may further include a front plate spring that supports the lens carrier, and the front plate spring may be disposed in contact with a base portion of the carrier-side receiving portion, fixed to the lens carrier, and electrically connected to the carrier-side receiving portion.

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

Effect of the utility model

The camera device of the present invention includes a lens carrier for holding a lens body and a blade driving device for driving a blade arranged on the front side of the lens body, wherein the lens carrier has a metal-made carrier side receiving portion extending from the front end of the lens carrier toward the front side, the blade driving device has a metal-made blade side receiving portion protruding from the side or bottom surface of the blade driving device toward the side or rear side, and the carrier side receiving portion is fixed to and electrically connected to the blade side receiving portion. Thus, the blade drive device is not fixed to the lens body but to the lens carrier, and thus a camera device in which the optical characteristics of the lens are not adversely affected can be provided.

Drawings

Fig. 1 is a front view of a smartphone 9 on which a camera device 8 including a blade drive device 1 and a lens drive device 5 according to an embodiment of the present invention is mounted.

Fig. 2 is a perspective view of the blade drive device 1 and the lens drive device 5 of fig. 1.

Fig. 3 is an exploded perspective view of the blade drive device 1 of fig. 2.

Fig. 4 is a perspective view of FPC60 of fig. 3.

Fig. 5 is a view of fig. 2 with the 1 st cover 50 removed.

Fig. 6 is a view of fig. 5 with the spacer 51 removed.

Fig. 7 is a view of fig. 6 with the front plate-like spring 52 removed.

Fig. 8 is an enlarged view of the periphery of the joint portion between the carrier-side receptor 701 and the blade- side receptors 953 and 963 in fig. 5.

Fig. 9 is a perspective view of the blade drive device 1 of fig. 2.

Fig. 10 is an exploded perspective view of the blade drive device 1 of fig. 10.

Fig. 11 is a view showing the 2 nd base 43 of fig. 10.

Detailed Description

Hereinafter, embodiments of the present invention will be described with reference to the drawings. As shown in fig. 1, a camera device 8 according to an embodiment of the present invention is housed in a smartphone 9.

The camera device 8 has: a lens body 7; a blade 11 disposed on the front side of the lens body 7; an image sensor 6 that converts light from the lens body 7 into an electric signal; a lens driving device 5 for driving the lens body 7; and a blade driving device 1 for driving the blade 11.

Hereinafter, a direction in which light from an object enters is referred to as a Z direction, one direction orthogonal to the Z direction is referred to as an X direction, and a direction orthogonal to both the Z direction and the X direction is referred to as a Y direction. The + Z side of the optical axis of the lens body 7, which is the side of the subject, is sometimes referred to as the front side, and the-Z side, which is the side opposite to the subject where the image sensor 6 is provided, is sometimes referred to as the rear side. The + X side is sometimes referred to as the upper side, the-X side as the lower side, the + Y side as the left side, and the-Y side as the right side.

As shown in fig. 3, the lens driving device 5 includes a 1 st cover 50, a spacer 51, four front plate-shaped springs 52, an fpc (flexible printed circuits)60, a lens carrier 70, a holder 71, a 1 st hall IC72, a position detection magnet 73, a weight 74, a 1 st coil 75, two rear plate-shaped springs 82, a 1 st magnet 85, and a 1 st base 87. In the present embodiment, the lens carrier 70 as the movable portion moves in the Z direction with respect to the 1 st base 87 as the fixed portion. The 1 st base 87 is attached with the 1 st magnet 85, the FPC60, the 1 st hall IC72, and the 1 st cover 50, and forms a large fixed portion. The lens carrier 70 is provided with a 1 st coil 75, a position detection magnet 73, and a weight 74, and forms a large movable body. The lens body 7 and the blade drive device 1 are also mounted on the lens carrier 70. They move in the Z direction together with the lens carrier 70.

As shown in fig. 4, the FPC60 has an external terminal connection portion 64 connected to the outside of the lens drive device 5 at one end, a flat plate portion 62 at the other end, and an internal path portion 61 at one other end. The flat plate portion 62 has a part thereof at one end and a part thereof at the other end. A belt-shaped portion 63 extending along the outer periphery of the lens drive device 5 is connected between the external terminal connecting portion 64 and the flat plate portion 62. The lens driving device 5 and the blade driving device 1 are electrically connected to the outside via the FPC 60.

A connection terminal connected to the outside is provided at the rear end of the external terminal connection portion 64. The belt-like portion 63 extends in the-X direction from the front side of the external terminal connecting portion 64, changes its direction to extend in the + Y direction at the corner of the lens driving device 5 on the-X-Y side, and reaches the flat plate portion 62. The flat plate portion 62 is fixed to a side wall portion 872 of the 1 st base 87 described later. The inner path portion 61 protrudes from the + Z side portion of the flat plate portion 62. The inner path portion 61 is formed in a rectangular frame shape, and the wiring portions 660 are formed at four corners. the-Z side portion of the flat plate portion 62 projects to the-Y side as a projection 65 belonging to the other end. At the-Z-side end edge of the flat plate portion 62, 3 notches 670 are provided. The 3 cutouts 670 on the + Y side and the-Y side are provided with wiring portions 680. Further, a 1 st hall IC72 described later is fixed to the inner surface of the flat plate portion 62 located at the other end.

The 1 st base 87 and the 1 st cover 50 are combined into a frame body. The image sensor 6 is fixed to the rear surface of the 1 st base 87.

In the frame body, a lens carrier 70 is housed. The blade drive device 1 is mounted on the front side of the lens carrier 70. The blade drive device 1 is exposed forward from the through hole of the 1 st cover 50.

The lens carrier 70 holds the lens body 7 and moves at least in the optical axis direction of the lens body 7. As shown in fig. 5, metal carrier-side receiving portions 701 are provided in respective pairs at respective positions on the + Y side and the-Y side of the lens body 7 on the front surface of the lens carrier 70.

As shown in fig. 8, the carrier-side receiving portion 701 is formed integrally with the lens carrier 70 by insert molding. The two plate-like members are slightly separated and opposed to the + X side and the-X side with respect to the pair of carriage-side receiving portions 701. Between the pair of carrier-side receiving portions 701, a resin constituting the main body of the lens carrier 70 is filled. The pair of carriage-side receiving portions 701 extend forward from the front surface of the lens carriage 70, and the front end portions are folded and spread at right angles in directions away from each other, forming the 1 st surface 702 on the front side. The front end portion of the 1 st surface 702 extends forward.

The 1 st base 87 is a plate-like member having a rectangular outer shape and has a through hole at the center. The 1 st base 87 is formed by insert molding the body of the 1 st base 87 with a 1 st metal member 91, a 2 nd metal member 92, and a 3 rd metal member (not shown) embedded in a resin, which is formed of a resin. The 3 metal members are formed in an overall rectangular shape extending along four sides of the 1 st base 87. The 1 st metal member 91 and the 2 nd metal member 92 have side surface exposed portions exposed to the outside of the side surface on the-X side of the 1 st base 87. The 1 st metal member 91 and the 2 nd metal member 92 have front surface exposed portions exposed to the front surface.

As shown in fig. 3, 5, 6, and 7, the pillar portion 871 is present at the four corners of the 1 st base 87. At the end edges of the 1 st base 87 on the-X side and the + X side, there are side wall portions 872. As shown in fig. 3, a rectangular opening 873 is provided in the side wall 872 on the-X side.

As shown in fig. 3 and 7, the 1 st coil 75 is wound around the protrusion portions on the + Y side and the-Y side of the lens carrier 70 with the Y direction as the axis. The 1 st magnet 85 is fixed to the 1 st coil 75 so as to face the front surface of the + Y side and-Y side edge portions of the 1 st base 87. In the 1 st magnet 85, two magnet pieces are arranged in parallel in the Z direction, and a magnetic pole on one side facing the 1 st coil 75 and a magnetic pole on the opposite side are magnetized to have opposite magnetic poles. In addition, the magnetizing directions of the two magnet sheets are opposite.

The front plate spring 52 is divided into four plate spring pieces of + X + Y side, + X-Y side, -X + Y side and-X-Y side, electrically separated, and has a rectangular shape as a whole. As shown in fig. 5, each plate-shaped spring piece of the front plate-shaped spring 52 has an inner portion 521, an outer portion 522, and an arm portion 523 that elastically couples these portions. The rear plate spring 82 is divided into two plate spring pieces of + X side and-X side, electrically separated from each other, and has a rectangular shape as a whole. Each plate-shaped spring piece of the rear plate-shaped spring 82 has an inner portion 821, two outer portions 822, and two arm portions 823 elastically connecting these portions.

The lens carrier 70 is supported in the air by the front plate-like springs 52 and the rear plate-like springs 82. The four inner sides 521 of the front plate-like spring 52 are fixed to the front peripheral edge of the lens carrier 70. As shown in fig. 8, the inner portion 521 on the + X-Y side and the inner portion 521 on the-X-Y side are disposed so as to contact the base portions of the two carrier-side receiving portions 701 on the-Y side of the lens carrier 70, respectively, and are electrically connected by means of solder bonding or the like. Similarly, the inner portion 521 on the + X + Y side and the inner portion 521 on the-X + Y side are also arranged so as to contact the base portions of the two carrier-side receiving portions 701 on the + Y side of the lens carrier 70, and are electrically connected by means of solder bonding or the like.

The rear plate spring 82 has two inner portions 821 fixed to a rear peripheral edge of the lens carrier 70. As shown in fig. 3, 5, 6, and 7, four outer side portions 822 of the rear plate-like spring 82 are fixed to inner portions of the column portions 871 on the front surface of the 1 st base 87.

The inner path portion 61 of the FPC60 is disposed behind the four outer portions 522 of the front plate-like spring 52, and the outer portions 522 and the wire portions 660 are electrically connected to each other by solder bonding or the like. A rectangular frame-shaped spacer 51 is fixed to the front side of the outer portion 522, and the spacer 51 is fixed to the rear surface of the front side wall of the 1 st cover 50. The four outer portions 522 of the front plate spring 52 extend in the X direction and the Y direction with the same width as the inner path portion 61 and the spacer 51, respectively, and these three portions closely extend along the outer shape of the 1 st cover 50.

As shown in fig. 3, the 1 st hall IC72 is fixed to the inner surface of the flat plate portion 62. The 1 st hall IC72 is a magnetic field position sensor. At the position where the 1 st hall IC72 is fixed in the FPC60, 6 wiring portions are provided. The 6 wiring portions of the FPC60 and the 6 contact points of the 1 st hall IC72 are electrically connected by solder or the like. Four of the 6 wiring portions of the FPC60 are connected to the external terminal connecting portion 64. The remaining two wiring portions are connected to the wiring portions 680, respectively.

The 1 st hall IC72 is housed in the opening 873 of the side wall portion 872 on the-X side of the 1 st base 87. The position detection magnet 73 is fixed at a position facing the 1 st hall IC72 on the-X side surface of the lens carrier 70. A weight 74 is fixed to the + X side of the lens carrier 70. The weight 74 is used to obtain a weight balance with the position detection magnet 73.

As shown in fig. 2, the side surface exposed portions of the 1 st metal member 91 and the 2 nd metal member 92 are exposed from the portion of the cutout 670 of the FPC60 to the outside of the-X side surface of the 1 st base 87. Of the two side surface exposed portions of the 1 st metal member 91, the + Y side surface exposed portion is joined to the + Y side wire connecting portion 680 by solder, and the 2 nd metal member 92 has the side surface exposed portion joined to the-Y side wire connecting portion 680 by solder.

The front surface exposed portion of the 1 st metal member 91 is exposed to the inside of the pillar portion 871 on the-X + Y side in the front surface of the 1 st base 87, and is soldered to the outside portion 822 of the rear plate spring 82 on the-X side. One end of the 1 st coil 75 on the + Y side and one end of the-Y side are electrically connected to the inner side 821 of the rear plate-like spring 82 on the-X side, respectively.

The front surface exposed portion of the 2 nd metal member 92 is exposed to the inside of the column portion 871 on the + X-Y side in the front surface of the 1 st base 87, and is solder-bonded to the outside portion 822 of the rear plate-like spring 82 on the + X side. The other end portions of the + Y-side and-Y-side 1 st coils 75 are electrically connected to the inner portions 821 of the + X-side rear plate-like springs 82, respectively.

When a current is supplied to the 1 st coil 75, an electromagnetic force is generated in the 1 st coil 75 by the magnetic field of the 1 st magnet 85, and a thrust in the Z direction is generated. By this thrust force, the lens carrier 70 holding the lens body 7 and the blade drive device 1 supported on the front side thereof move in the Z direction against the elastic forces of the front plate-shaped spring 52 and the rear plate-shaped spring 82. When the current supply to the 1 st coil 75 is stopped, the lens body 7, the lens carrier 70, and the blade drive device 1 return to the original positions.

The 1 st hall IC72 detects the magnetic field of the opposing position detection magnet 73, and outputs a current for driving the 1 st coil 75 based on the detection result. The magnetic field corresponds to the position of the position detection magnet 73 in the Z direction with respect to the 1 st hall IC 72.

As shown in fig. 9 and 10, the blade drive device 1 includes a 2 nd cover 10, four blades 11, a fixed plate 12, a front side coil substrate 20, four 2 nd magnets 21, a movable ring 22, four plate springs 30, a rear side coil substrate 40, a circuit substrate 41, a 2 nd hall IC42, and a 2 nd base 43.

In the blade drive device 1, the circuit board 41 is fixed to the front side of the 2 nd base 43, and the rear coil board 40 is fixed to the front side. Further, the 2 nd magnet 21 is fixed inside the movable ring 22. The movable ring 22 is rotatably supported via a plate spring 30 at a column portion erected on the inner peripheral side of the 2 nd base 43. The front coil substrate 20 is fixed to the fixed plate 12 on the rear side, and the fixed plate 12 is fixed to the 2 nd base 43 so as to cover the 2 nd base 43. The 4 blades 11 are attached to the front side of the fixed plate 12 so as to be connected to the movable ring 22, and an opening is formed in the center of the 4 blades 11. Thus, the driving blade 11 is moved by the rotation of the movable ring 22 to change the opening size. Further, the 2 nd shroud 10 is provided in such a manner as to cover an outer portion of the blade 11.

The circuit board 41 is provided with a 2 nd hall IC42 for detecting the position of the 2 nd magnet 21. Further, the 2 nd coil 121 is embedded in the front side coil substrate 20 and the rear side coil substrate 40, and the 2 nd coil 121 sandwiches the 2 nd magnet 21 from the front and the rear. When a current flows through the 2 nd coil 121, an electromagnetic force is generated in the 2 nd coil 121 by the magnetic field of the 2 nd magnet 21, and the movable ring 22 on which the 2 nd magnet 21 is mounted is rotated by the reaction thereof.

The 2 nd base 43 is formed by insert molding in a state where the main body of the 2 nd base 43 is made of resin and two 4 th metal members 94, two 5 th metal members 95, and two 6 th metal members 96 are embedded in the resin.

The 2 nd base 43 has a ring shape. In the 2 nd base 43, there is a pillar portion 431 rising toward the + Z side, surrounding the + X + Y side, the + X-Y side, the-X + Y side, and the-X-Y side of the inner peripheral edge of the center through hole. On the + Y side and the-Y side of the 2 nd base 43, three holes 434 are provided, respectively. The 3 holes 434 are juxtaposed along the X direction.

Each of the 4 th metal members 94 has: an exposed portion 941 where the hole 434 on the + X side is exposed along the front and rear hook; an embedded portion 942 that protrudes from the exposed portion 941 to the + X side in an embedded state and extends to the nearest column portion 431 while being bent; and a rising portion 943 rising from the column portion 431 and extending to the front side along the column portion 431. The front end of the standing portion 943 protrudes to the front of the front edge of the column portion 431.

Each 5 th metal member 95 has: an exposure portion 951 exposed along a front-rear hook in the central hole 434; an embedded portion 952 extending from the exposed portion 951 toward the outer peripheral side in an embedded state; and a blade-side receiving portion 953 which is raised in a stepped manner at the front end of the embedded portion 952 and protrudes outward from the outer edge of the 2 nd base 43.

Each 6 th metal member 96 has: an exposed portion 961 where the hole 434 on the-X side is exposed along the front and rear hook shapes; an embedded portion 962 extending from the exposed portion 961 toward the outer peripheral side in an embedded state; and a blade-side receiving portion 963 that protrudes outward from the outer edge of the 2 nd base 43 after the tip end of the embedded portion 962 rises in a stepped manner.

The rising portions of the blade side receivers 953 and 963 are covered with a thin plate portion 439 that is laterally long in the X direction, and the blade side receivers 953 and 963 protrude outward from the side surface of the thin plate portion 439.

The four exposed portions 951 and 961 are electrically connected to the 2 nd hall IC42 via the circuit board 41. One of the output currents of the 2 nd hall IC42 is supplied from the circuit board 41 to the 2 nd coil 121 of the rear coil board 40. The other output current of the 2 nd hall IC42 flows from the circuit board 41 to the 4 th metal member 94 through the exposed portion 941, and is electrically connected to the 2 nd coil 121 of the front coil substrate 20 at the distal end portion of the standing portion 943.

As shown in fig. 8, the blade-side receiving portion 953 and the blade-side receiving portion 963 protruding from the notches 120 on the + Y side and the-Y side of the blade drive device 1 have a shape in which the surfaces facing the front-rear direction are plate surfaces, and the 2 nd surfaces 970 which are the rear surfaces are placed on the 1 st surfaces 702 of the two carrier-side receiving portions 701 on the + Y side and the-Y side of the lens carrier 70, respectively. The carrier-side receiving portion 701, the blade-side receiving portion 953, and the blade-side receiving portion 963 are fixed and electrically connected by welding or soldering. By providing the 1 st surface 702 and the 2 nd surface 970, the carrier-side receiving portion 701 can stably receive the blade- side receiving portions 953 and 963.

The above is the details of the present embodiment. The camera device 8 according to the present embodiment includes a lens carrier 70 that holds a lens body 7, and a blade drive device 1 that drives a blade 11 disposed in front of the lens body 7, the lens carrier 70 includes a carrier-side receiving portion 701 made of metal and extending forward from a front end of the lens carrier 70, the blade drive device 1 includes a blade-side receiving portion 953 made of metal and a blade-side receiving portion 963 made of metal and protruding laterally from a side surface of the blade drive device 1, and the carrier-side receiving portion 701, the blade-side receiving portion 953, and the blade-side receiving portion 963 are fixed and electrically connected. Thus, the blade drive device 1 is not fixed to the lens body 7 but fixed to the lens carrier 70, and therefore the camera device 8 which hardly adversely affects the optical characteristics of the lens can be provided.

In the above embodiment, the blade side receivers 953 and 963 may protrude rearward from the bottom surface of the blade drive device 1. In this case, the 2 nd surface 970 may be provided.

The 2 nd coil 121 may be fixed to the movable ring 22, and the 2 nd magnet 21 may be fixed to the fixed plate 12 or the 2 nd base 43. In this case, power may be supplied to the 2 nd coil 121 from the rising portion 943 of the 4 th metal member 94 through the plate spring 30.

For example, when the 2 nd hall IC42 is not provided and the 2 nd coil 121 is fed from the outside of the blade drive device 1, the four blade- side receivers 953 and 963 can be set to 2, and the number of the carriage-side receivers 701 can also be set to 2. In this case, the number of divisions of the front plate-like spring 52 may be 2, 2 inner portions of the front plate-like spring 52 may be electrically connected to 2 carriage-side receiving portions 701, and 2 outer portions of the rear plate-like spring 82 may be electrically connected to the outside via the FPC 60.

Description of the symbols:

1 a blade driving device; 5a lens driving device; 6 an image sensor; 7 a lens body; 8 a camera device; 9 a smart phone; 10, a 2 nd cover; 11 blades; 12 fixing the plate; 20 a front side coil substrate; 21 a 2 nd magnet; 22 a movable ring; 30 plate-shaped springs; 40 a rear side coil substrate; 41 a circuit board; 42 nd Hall IC; 43 a 2 nd base; 50, cover 1; a 51 shim; 52 a front plate spring; 60 FPC; 61 an inner path part; 62 a flat plate portion; 63 a band-shaped portion; 64 an external terminal connection portion; 65 a projection; 70 a lens carrier; 72 1 st Hall IC; 73 position detection magnet; 74 a counterweight; 75, 1 st coil; 82 rear plate springs; 85 the 1 st magnet; 87 base No. 1; 91 a 1 st metal part; 92 a 2 nd metal part; 94, a 4 th metal part; 95 th metal part; 96 th metal part; 120. 670 cutting; 121, coil 2; 431. 871 column parts; 434 holes; 439 a thin plate portion; 521821 inner side; 522822 outer side portions; 523. 823 wrist part; 660. 680 a wiring portion; 701 a carrier side receiving part; 702, side 1; 872 side wall portions; 873 an opening; 941. 951 and 961 exposed parts; 942. 952, 962 embedded parts; 943 a standing part; 953. 963 a blade-side receptor; 970 on side 2.

Claims (9)

1. A camera device is characterized by comprising:

a lens carrier that holds a lens body; and

a blade driving device for driving the blade disposed on the front side of the lens body,

the lens carrier has a metal carrier side receiving part extending from the front end of the lens carrier to the front,

the blade driving device has a metal blade receiving part protruding from a side surface or a bottom surface of the blade driving device to a side or a rear side,

the carrier-side receiving portion and the blade-side receiving portion are fixed and electrically connected.

2. The camera device according to claim 1,

the carrier-side receiving portion is formed integrally with the lens carrier by insert molding.

3. The camera device according to claim 1,

the blade-side receiving portion is formed integrally with the blade drive device by insert molding.

4. The camera device according to claim 1,

a forward 1 st surface is formed at a front end of the carrier-side receiving portion, a rearward 2 nd surface is formed at a front end of the blade-side receiving portion, and the 2 nd surface is placed on the 1 st surface.

5. The camera device according to claim 4,

the two plate-like members are slightly separated and opposed to each other in the carrier-side receiving portion, and the 1 st surfaces are formed to extend in directions away from each other.

6. The camera device according to claim 5,

the front end portion of the 1 st surface extends further forward.

7. The camera device according to claim 5,

between the two plate-like members, a resin constituting the lens carrier body is filled.

8. The camera device according to claim 1,

a front plate spring for supporting the lens carrier,

the front plate spring is disposed so as to contact the base of the carrier-side receiving portion, fixed to the lens carrier, and electrically connected to the carrier-side receiving portion.

9. An electronic device comprising the camera device according to any one of claims 1 to 8.

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