KR20130020414A - Wirespring combination structure of compensation hand vibration device for camera - Google Patents

Abstract

PURPOSE: A wire spring coupling structure of a camera shake compensating device is provided to improve the durability of a wire spring by preventing stress being focused on a portion where a connection unit and a coupling unit are connected as the diameter of the coupling unit becomes smaller toward the connection unit. CONSTITUTION: A wire spring coupling structure of a camera shake compensating device comprises a lens holder(100), a fixed body(200), and a wire spring(300). A lens unit is mounted inside the lens holder. The fixed body is arranged on the top of the lens holder. One end of the wire spring is fixed to the fixed body, and the other end of the wire spring is fixed to the lens holder so that the wire spring fixes the lens holder to the fixed body to be movable in a horizontal direction. The wire spring is composed of a connection unit and a coupling unit.

Description

WIRESPRING COMBINATION STRUCTURE OF COMPENSATION HAND VIBRATION DEVICE FOR CAMERA}

The present invention is a wire spring coupling structure of the camera shake correction device for the camera, to combine the lens unit to move horizontally to prevent the camera shake of the camera shake image to prevent the camera shake by the camera shake to the wire spring coupling structure of the camera It is about.

1 is a perspective view showing a conventional camera shake correction device, Figure 2 is an exploded perspective view showing a conventional camera shake correction device, Figure 3 is a partially exploded perspective view showing an enlarged portion A of FIG.

As shown in FIGS. 1 to 3, a conventional camera shake correction apparatus includes a lens holder 610 including a lens unit 510, a coil 640 outside the lens holder 610, and The magnet 650 disposed adjacent to the outer side of the coil 640, the iron piece 660 whose one end is in contact with the magnet 650 and the other end is inserted into the coil, and the power supplied to the coil 640 are controlled. It comprises a control unit 700.

The iron piece 660 causes the magnetic field generated in the magnet 650 and the magnetic field generated in the coil 640 to be horizontal to each other when power is applied to the coil 640 to move the coil 640 to the lens unit ( It flows in the direction crossing the optical axis direction of 510.

The magnet 650 is mounted on the upper and lower ends of the iron piece 660, respectively, the polarity of the surface in contact with the iron piece 660 is the same.

In addition, the anti-shake device is a fixed body 630 disposed below the lens holder 610, the lower end is connected to the fixed body 630 and the upper end is connected to the lens holder 610 is the lens holder ( It further comprises a wire spring 620 that elastically supports the 610 in a direction crossing the optical axis of the lens unit 510.

The wire spring 620 is bent in a direction crossing the optical axis of the lens unit 510 as the lens holder 610 moves, and has a force of restoring to its original state by an elastic force.

However, since the wire spring 620 is formed in a simple straight shape and the coupling force between the fixed body 630 and the lens holder 610 is weak, the wire spring 620 when the lens holder 610 moves for a long time. There was a problem that the fixed body 630 and the lens holder 610 is separated.

In addition, when the lens holder 610 is moved, the wire spring 620 is deformed in a specific portion adjacent to the fixed body 630 and the lens holder 610 and the stress is concentrated in this portion when used for a long time There is a problem that the wire spring 620 is cut.

The present invention is to solve the above problems, to increase the coupling area of the wire spring coupled to the lens holder and the fixed body to increase the coupling force between the lens holder and the fixed body and to generate stress concentration on a specific portion of the wire spring It is an object of the present invention to provide a coupling structure of the wire spring of the camera shake correction device that can increase the durability by preventing.

In the camera shake correction device for camera shake compensation device of the present invention for moving the lens unit horizontally to correct the image shake due to the user's hand shake when shooting the subject to achieve the above object, A lens holder to which the lens unit is mounted; A fixed body disposed above the lens holder; A wire spring having one end mounted on the fixed body and the other end mounted on the lens holder to couple the lens holder horizontally to the fixed body; Consists of, the wire spring, the connection portion disposed between the lens holder and the fixed body; A coupling part formed at one or more ends of the connection part in a coil shape and coupled to the fixed body or the lens holder; .

The joining portion becomes smaller in diameter toward the joining portion.

The lens holder and the fixing body are formed with coupling holes penetrating up and down, respectively, the coupling part is inserted into the coupling hole, and the end of the connection part where the coupling part is formed is disposed to coincide with the center of the coupling hole.

The connecting portion is formed in a coil shape.

A soldering layer for fixing the wire springs to the fixed body and the lens holder is formed on the fixed body and the lens holder, to which both ends of the wire spring are coupled, and a bonding layer on the opposite side of the surface where the connection part is disposed in the solder layer. Is formed.

Wire spring coupling structure of the camera shake correction device according to the present invention has the following effects.

Coil-shaped couplings are formed on the wire springs that engage the fixed body or lens holder, thereby increasing the coupling area of the coupling parts that are coupled to the fixed body or lens holder, thereby increasing the coupling force of the wire springs, and stresses on specific portions of the wire springs It can prevent concentration and increase durability.

In addition, the coupling portion is formed to become smaller as the diameter toward the connecting portion, thereby preventing the concentration of stress in the connection portion between the connecting portion and the coupling portion can increase the durability of the wire spring.

In addition, since the coupling portion is formed in a coil shape and its diameter is larger than that of the coupling portion and the difference with the inner diameter of the coupling hole is not large, it is easy to arrange the end of the coupling portion in the center of the coupling hole.

In addition, since the connection portion is formed in a coil shape, the elastic deformation and restoration of the wire spring can be more easily performed when the lens holder is horizontally moved.

In addition, the coupling part is fixed to the lens holder and the fixed body by the solder layer and the bonding layer, thereby further increasing the coupling force of the wire spring.

1 is a perspective view showing a conventional camera shake correction device,
2 is an exploded perspective view showing a conventional camera shake correction device,
3 is a partially exploded perspective view illustrating an enlarged portion A of FIG. 2;
Figure 4 is a vertical cross-sectional view of the wire spring coupling structure of the camera shake correction device according to an embodiment of the present invention,
5 is an enlarged view illustrating an enlarged portion B of FIG. 4;
6 is a view showing various shapes of a wire spring according to an embodiment of the present invention,
7 is a view showing a state in which the webbing spring coupling structure of the camera shake correction device according to an embodiment of the present invention is moved horizontally,

5 is an enlarged view illustrating part B of FIG. 4, FIG. 6 is a view illustrating various shapes of a wire spring according to an embodiment of the present invention, and FIG. 7 is a camera shake correction device according to an embodiment of the present invention. Figure is a view showing a state in which the Y spring coupling structure of the horizontal movement.

Wire spring 300 coupling structure of the camera shake correction device according to an embodiment of the present invention as shown in Figures 4 to 7, the lens holder 100, the fixed body 200 and the wire spring 300 Is done.

Such a camera shake correction device is described in the patent application No. 10-0952620 filed by the applicant of the present invention, the detailed structure is well referred to it.

In FIGS. 4 to 7, the lens holder 100 and the fixed body 200 are simplified and briefly illustrated. The lens unit, coil member, magnet, and iron member, which will be described later, are not separately illustrated in the drawings.

A lens unit is mounted to the lens holder 100 and is horizontally coupled to the fixed body 200 by the wire spring 300.

A coil member is mounted on the side of the lens holder 100, and circuit boards 110 and 210 are mounted on the lower side of the lens holder 100.

In addition, as shown in FIG. 4, a coupling hole 101 penetrating the lens holder 100 and the circuit board 110 up and down is formed under the lens holder 100.

The lower end of the wire spring 300 is inserted into the coupling hole 101.

The fixed body 200 is disposed above the lens holder 100 to support the lens holder 100 in the vertical direction by the wire spring 300 to move horizontally.

In addition, the upper and lower through the upper portion of the fixed body 200 is formed through the lens sphere is passed through the lens unit mounted on the lens holder 100 and projected by the image sensor of the camera.

In addition, the magnet and the iron piece member is mounted on the side of the fixed body 200 to correspond to the coil member.

The magnet generates a magnetic field and induces a flow of the magnetic field through the iron piece member so that the lens holder 100 mounted with the lens unit is horizontally moved by the coil member through which current flows as the user shakes the hand.

4 and 5, the circuit board 210 is mounted on the fixed body 200, and the coupling hole 201 penetrates the fixed body 200 and the circuit board 210 up and down. Is formed.

An upper end of the wire spring 300 is inserted into the coupling hole 201.

The wire spring 300 has one end mounted to the fixed body 200 and the other end mounted to the lens holder 100 to couple the lens holder 100 to the fixed body 200 in a horizontal movement.

Usually, four or more wire springs 300 are mounted to balance the lens holder 100 to the fixed body 200.

The wire spring 300 is composed of a connection portion 310 and the coupling portion (320).

The connection part 310 is made of a straight metal wire, and is disposed between the lens holder 100 and the fixed body 200.

The coupling part 320 is formed in a coil shape at one end and / or the other end of the connection part 310 to be coupled to the fixed body 200 and the lens holder 100.

That is, the coupling part 320 is inserted into the coupling holes 101 and 201 formed in the fixed body 200 and the lens holder 100, respectively, so that the lens holder 100 is fixed by the wire spring 300. It is coupled to the horizontal movement to the body 200.

And the coupling portion 320 is formed so as to decrease in diameter toward the connecting portion 310 as shown in Figure 5 (a).

Accordingly, the degree of bending of the connection part 310 and the connection part 310 of the coupling part 320 may be minimized to prevent concentration of stress.

In addition, the coupling part 320 is formed in a coil shape as described above, when the lens holder 100 vibrates in the vertical direction by an external impact, absorbs the shock received by the lens holder 100 and the vertical vibration It acts as a offsetting buffer.

Solder layer 410 for fixing the wire spring 300 to the fixed body 200 and the lens holder 100 in the fixed body 200 and the lens holder 100 is coupled to both ends of the wire spring 300 ) Is formed.

As shown in FIG. 5, the solder layer 410 is formed between the coupling part 320 and the coupling hole 201 and covers the upper portion of the coupling part 320 to fix the coupling part 320. It is fixed to the body 200.

That is, the coupling part 320 is fixed to the fixed body 200 by the soldering layer 410 and is electrically connected to the circuit board 210.

On the other hand, since the diameter of the connection portion 310 is very small compared to the inner diameter of the coupling hole 201, the coupling hole 201 without forming the coil-shaped coupling portion 320 at the end of the connection portion 310. When inserted into and fixed to), the gap between the coupling hole 201 and the connection portion 310 is large and the area where the connection portion 310 is coupled to the fixed body 200 by the soldering layer 410 is small. The coupling force of the wire spring 300 and the fixed body 200 is dropped.

Accordingly, as described above, the coupling part 320 of the coil shape is formed at the end of the connection part 310.

When the coupling part 320 is formed in a coil shape and is fixed to the fixed body 200, the wire spring 300 and the fixed body 200 are large because the coupling area coupled by the solder layer 410 is large. Can increase the binding force.

In addition, since the diameter of the coupling part 320 is larger than the diameter of the connection part 310 and the difference with the inner diameter of the coupling hole 201 is not large, the coupling hole 201 is formed at the upper end of the connection part 310. It is easy to place in the center of.

In addition, a bonding layer 420 is formed on a surface opposite to a surface on which the connection part 310 is disposed in the solder layer 410.

That is, the bonding layer 420 is formed by applying a bond on the solder layer 410.

The bonding layer 420 may be a thermosetting bond, an ultraviolet curing bond, an instant adhesive, or the like.

As such, by forming the bonding layer 420 on the solder layer 410, the bonding force between the wire spring 300 and the fixed body 200 may be further increased.

In some cases, the soldering layer 410 may be formed by one soldering without forming the bonding layer 420 to couple the wire spring 300 to the fixed body 200.

In addition, instead of the bonding layer 420, the solder layer 410 may be formed by double soldering on the initial solder layer 410 once more, but the solder layer 410 formed by the initial solder is generated during the second soldering. There is a problem that melts by heat.

Accordingly, in the present embodiment, after the initial primary soldering, a bond is applied on the soldering layer 410 to form the bonding layer 420.

When the bonding layer 420 is hardened, the solder layer 410 is not melted because it is lower than the temperature generated during soldering.

The coupling structure of the coupling part 320 and the lens holder 100 formed at the lower end of the connection part 310 is also the same as the coupling structure of the coupling part 320 and the fixed body 200 described above.

Accordingly, when power is supplied to the circuit board 210 mounted on the fixed body 200, the circuit board 110 mounted to the wire spring 300 and the lens holder 100 by the solder layer 410. Power is supplied to the coil member connected to the circuit board 110, and a vibration occurs in the camera, the lens holder 100 mounted with the lens unit is horizontal as shown in FIG. It is possible to prevent the image of the subject photographed by the camera from being shaken.

As described above, the wire spring 300 may be formed at any one of both ends of the connection part 310, as shown in FIG. 6 (a). It may be formed.

As described above, the coupling part 320 formed at either end of the connection part 310 is coupled to the lens holder 100 or the fixed body 200, and the connection part 310 in which the coupling part 320 is not formed. ) Is mounted directly on the fixed body 200 or the lens holder 100.

In addition, as shown in Figure 6 (b), the diameter of the coupling portion 320 may be formed to be constant.

However, as described above, the diameter of the coupling part 320 is gradually reduced to the connection part 310 to prevent concentration of stress on the connection part between the connection part 310 and the coupling part 320. have.

As shown in FIG. 6C, the wire spring 300 may form the connection part 310 in a coil shape.

By forming the connection part 310 in a coil shape, the elastic deformation and restoration of the wire spring 300 may be more easily performed when the lens holder 100 is horizontally moved.

The coupling structure of the wire spring of the camera shake prevention device for the present invention is not limited to the above-described embodiment, and can be modified in various ways within the range to which the technical idea of the present invention is permitted.

100: lens holder, 101: coupling hole, 110: circuit board, 200: fixed body, 201: coupling hole, 210: circuit board, 300: wire spring, 310: connection part, 320: coupling part, 410: solder layer, 420 : Bonding layer,

Claims (5)

In the camera shake correction device for correcting the shaking of the image due to the user's hand shake when shooting the subject by horizontally moving the lens unit,
A lens holder to which the lens unit is mounted;
A fixed body disposed above the lens holder;
A wire spring having one end mounted on the fixed body and the other end mounted on the lens holder to couple the lens holder horizontally to the fixed body; Lt; / RTI >
The wire spring is,
A connection part disposed between the lens holder and the fixed body;
A coupling part formed at one or more ends of the connection part in a coil shape and coupled to the fixed body or the lens holder; Wire spring coupling structure of the camera shake correction device, characterized in that consisting of. The method according to claim 1,
The coupling portion is a wire spring coupling structure of the camera shake correction device, characterized in that the diameter is gradually smaller toward the connecting portion direction. The method according to claim 1 or 2,
The lens holder and the fixing body is formed with coupling holes penetrating up and down, respectively,
The coupling part is inserted into the coupling hole,
The end portion of the connection portion formed with the coupling portion is a wire spring coupling structure of the camera shake correction device for the camera, characterized in that arranged to match the center of the coupling hole. The method according to claim 1 or 2,
The connection portion of the wire spring coupling device for a camera shake correction device, characterized in that the connecting portion is formed in a coil shape. The method according to claim 1 or 2,
A soldering layer for fixing the wire springs to the fixed body and the lens holder is formed in the fixed body and the lens holder coupled to both ends of the wire spring,
Bonding layer is formed on the opposite side of the surface of the soldering layer in which the connecting portion is disposed, the wire spring coupling structure of the camera shake correction device for the camera.

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