KR100952620B1 - Compensation hand vibration device for camera - Google Patents

Abstract

PURPOSE: A hand shaking stabilizer for camera is provided to prevent the bending of a wire spring in a lens insertion process and to minimize external force of a driving unit in horizontal movement of a lens holder by electrically connecting the wire spring with the driving unit. CONSTITUTION: The upper end of a wire spring(140) is installed on a cover(130). The lower end of the wire spring is installed in the bottom of a lens holder(120). The wire spring supports the lens holder in up and down directions. A driving unit is connected with the bottom of the wire spring and a first substrate(150). The driving unit is electrically connected with the wire spring. If power source is applied, the driving unit transfers the lens holder in a horizontal direction.

Description

Camera shake stabilizer {COMPENSATION HAND VIBRATION DEVICE FOR CAMERA}

The present invention relates to a camera shake correction apparatus, and in particular, a camera shake correction apparatus for compensating for shake by moving a lens holder in which a lens is mounted in a horizontal direction to correct an image shake due to a shake of a user when a subject is photographed. 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 an enlarged partial exploded perspective view of 'A' of FIG.

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

The iron piece 660 has the magnetic field generated from the magnet 650 and the magnetic field generated from the coil 640 when the power is applied to the coil 640 so that the coil 640 is horizontal to the lens ( 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 support member 630 disposed below the lens unit 610, the lower end is connected to the support member 630 and the upper end is connected to the lens unit 610 is the lens unit ( It further comprises a wire spring 620 to elastically support the 610 to flow in the direction crossing the optical axis of the lens 510.

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

However, in the assembling process of inserting the lens 510 into the lens unit 610, a force is applied downward to the lens unit 610. In this case, the wire spring 620 is excessively bent and damaged.

In addition, the wire spring 620 is connected to the control unit 700 and the coil 640 to transfer power applied from the control unit 700 to the coil 640.

That is, disconnection of the coil 640 and the wire spring 620 are electrically connected to each other.

However, since the disconnection of the coil 640 is very small, it is difficult to fix the wire spring to the wire spring, and the coil 640 is repeatedly moved due to the repeated movement of the wire spring 620 when the lens unit 610 moves horizontally. The breakage of disconnection often occurs.

The present invention has been made to solve the above-described problems, the camera shake correction device to prevent the wire spring is bent during the lens insertion process, and minimize the external force added to the disconnection of the coil connected to the wire spring when the lens holder is moved. The purpose is to provide.

Camera shake correction apparatus of the present invention to achieve the above object; A lens holder disposed above the base and horizontally mounted and having a lens therein; A cover mounted on an upper portion of the base to surround the lens holder; A wire spring having an upper end mounted on the cover and a lower end mounted on the lower end of the lens holder to elastically support the lens holder in a vertical direction; A first substrate mounted on a lower end of the lens holder and having a first copper plate portion fixed through the lower end of the wire spring; A driving unit connected to a lower end of the wire spring or the first substrate and moving the lens holder in a horizontal direction when power is applied through the wire spring; It is made, including.

The driving unit may include a coil member mounted to a side of the lens holder and configured to horizontally move the lens holder by forming a magnetic field when power is applied; An upper magnet and a lower magnet mounted between the base and the cover and disposed adjacent to the coil member; An iron piece member having one end mounted between the upper magnet and the lower magnet and the other end inserted into the center of the coil; It is made, including, the disconnection of the coil member is fixed to the first copper plate with the wire spring.

The first substrate is formed with a avoidance groove in which the disconnection of the coil member is disposed, the size of the avoidance groove is formed larger than the diameter of the coil member disconnection.

An upper fixing part is formed at the side of the cover to insert the upper magnet, and a lower fixing part is formed at the side of the base to insert the lower magnet, and the upper fixing part and the lower fixing part are formed at the upper magnet or the lower fixing part. A locking jaw is formed to prevent the magnet from moving in the direction of the lens holder.

The image stabilization apparatus includes a control unit mounted on the lower portion of the base to control power supplied to the driving unit; A second substrate mounted on an upper side of the cover and having a second copper plate portion fixed to penetrate an upper end of the wire spring; It further comprises, wherein the second substrate is formed with a flexible circuit portion for electrically connecting the second substrate and the control unit, the side of the cover and the base is formed with a seating groove in which the flexible circuit portion is inserted and seated. .

A locking groove is formed in an upper portion of the lens holder, and a locking protrusion inserted into the locking groove is protruded downward in the cover, and rotation and rise of the lens holder are prevented by the locking protrusion and the locking groove.

According to the camera shake correction apparatus of the present invention as described above has the following advantages.

The driving unit is connected to the lower end of the wire spring to be in electrical communication with the wire spring, thereby receiving power through the wire spring, thereby minimizing external force applied to the driving unit during horizontal movement of the lens holder.

In addition, by connecting the lower end of the wire spring and the drive unit to the first substrate formed with the first copper plate portion through which the lower end of the wire spring is fixed, the wire spring and the drive unit can be fixed It has the effect of enlarging the position and facilitating the connection.

In addition, by attaching an upper end of the wire spring to the cover, and a lower end to the lower end of the lens holder to elastically support the lens holder relative to the cover, the force added to the wire spring when the lens is assembled to the lens holder The direction of may be generated in the direction in which the wire spring is stretched to prevent the wire spring from being excessively bent and damaged.

By fixing the disconnection of the coil member together with the wire spring to the first copper plate portion through which the wire spring is fixed, there is an effect of simplifying the assembly process of connecting the disconnection of the wire spring and the coil member.

By forming a avoidance groove in which the disconnection of the coil member is disposed in the first substrate, and the size of the avoidance groove is larger than the diameter of the coil member disconnection, disconnection of the coil member disposed below the first substrate. It is inserted into the avoidance groove has the effect of preventing the interference with the base when the lens holder is moved.

By forming the engaging jaw to prevent the upper magnet or the lower magnet from moving in the direction of the lens holder in the upper fixing portion and the lower fixing portion, to guide the position when the upper magnet and the lower magnet assembly, There is an effect to improve the assembly by preventing the upper fixing portion and the lower fixing portion is separated.

By forming a seating groove into which the flexible circuit part is inserted and seated on the side of the cover and the base, the outer width of the image stabilization device is the same, thereby reducing the overall size and uniting the appearance.

By forming a locking groove on the upper portion of the lens holder, and forming a locking projection protruding downward in the cover to be inserted into the locking groove, it prevents the wire spring from being damaged by preventing rotation and rising of the lens holder. .

Figure 4 is a perspective view showing a camera shake correction device according to the present invention, Figure 5 is a one-way exploded perspective view showing a camera shake correction device according to the present invention, Figure 6 shows a camera shake correction device according to the present invention Another direction exploded perspective view, Figure 7 is a cross-sectional view of the camera shake correction apparatus according to the present invention as seen from BB of FIG.

4 to 6, the camera shake correction apparatus according to the present invention includes a base 110, a lens holder 120, a cover 130, a wire spring 140, a first substrate 150, a first 2 includes a substrate 160, a controller 170, and a driver 180, and the driver 180 includes the coil member 181, the upper magnet 182, the lower magnet 183, and the iron piece member 184. It is made, including.

The base 110 has a rectangular shape as a whole, the opening hole which is opened up and down in the center is formed, and the outer edge portion protrudes upwards to be in contact with the cover 130.

In addition, a lower fixing part 111 on which the lower magnet 183 is mounted is formed between the outer side of the base 110, that is, the corner portion protruding upward.

The lower fixing part 111 is formed in four places symmetrical with each other along the outer surface of the base 110, and is formed to be recessed downward from the upper side of the base 110.

In addition, the lower surface of the lower fixing portion 111 is formed with a locking projection 112 protruding upward.

The locking jaw 112 has a bottom surface of the lower fixing portion 111 adjacent to the inside of the base 110 protruding higher than a bottom surface of the lower fixing portion 111 adjacent to the outside of the lower fixing portion 111. will be.

Accordingly, the locking jaw 112 prevents the lower magnet 183 mounted on the outer side of the lower fixing part 111 from moving inward of the base 110, that is, in the direction of the lens holder 120. Function

The base 110 is generally disposed above an image sensor for capturing an image of a subject, and a lens holder 120 having a lens mounted therein is disposed above the base 110.

The size of the lens holder 120 is formed smaller than the inner width of the base 110 so as not to interfere with the inner surface of the base 110, the hole is formed in the center of the lens (not shown).

On both sides of the hole of the lens holder 120, recessed grooves 121 recessed downward are formed, respectively.

In addition, the lens holder 120 is formed in the lower end of the corner portion extending in the shape of a plate, the wire spring 140 is inserted through this corner portion.

In addition, the cover 130 is disposed on the lens holder 120 is mounted to the base 110 to surround the lens holder 120.

The cover 130 has a rectangular shape and an outer edge portion protrudes in the direction of the base 110, and is fixedly engaged with the base 110 so as to surround the lens holder 120.

In addition, an opening hole is formed in a central portion of the cover 130 to communicate with the lens holder 120, and a locking protrusion 133 inserted into the locking groove 121 of the lens holder 120 at both sides of the opening hole. Is formed.

The locking protrusion 133 protrudes downward in the direction of the lens holder 120 and is inserted adjacent to the locking groove 121.

As such, by forming the engaging groove 121 in the upper portion of the lens holder 120, and forming a projection protrusion 133 is formed projecting downward in the cover 130 is inserted into the engaging groove 121, the It prevents the wire spring 140 from being damaged by preventing the lens holder 120 from rotating and rising.

In addition, an upper fixing part 131 is formed between the outer edge portions of the cover 130 protruding toward the base 110.

The upper fixing part 131 is formed in four places symmetrical with each other along the outer surface of the cover 130, like the lower fixing part 111, is formed to be recessed upward from the lower side of the cover 130. .

In addition, the upper surface of the upper fixing part 131 is formed with a locking projection 132 protruding downward.

The locking jaw 132 is formed so that an upper surface of the upper fixing portion 131 adjacent to the inside of the cover 130 protrudes higher than an upper surface of the upper fixing portion 131 adjacent to the outside of the upper fixing portion 131. will be.

Accordingly, the locking jaw 132 has a function of preventing the upper magnet 182 mounted on the outer side of the upper fixing part 131 from moving inward of the cover 130, that is, in the direction of the lens holder 120. Do it.

As described above, the locking jaws 112 and 132 prevent the upper magnet 182 or the lower magnet 183 from moving toward the lens holder 120 in the upper fixing part 131 and the lower fixing part 111. ) To guide the position at the time of assembly of the upper magnet 182 and the lower magnet 183, and prevents the upper fixing portion 131 and the lower fixing portion 111 from being separated. Has the effect of improving.

The wire spring 140 is a metal material through which electricity is bent to the left and right, and when the external force is removed, the wire spring 140 has a property of restoring to its original state.

In addition, the wire spring 140 is formed to be thin and long in the vertical direction, the upper end is mounted to the cover 130 and the lower end is mounted to the lens holder 120 to the lens holder 120 to the cover 130 Elastic support in the upward direction as a reference.

That is, the wire spring 140 generates a tension to lift the lens holder 120 from the base 110 by a predetermined interval.

In addition, in the assembling process of inserting the lens into the lens holder 120, the force is applied to the lens holder 120 in the downward direction, wherein the wire spring 140 is fixed to the cover 130, the upper end does not move The lens holder 120 is supported in an upward direction without tension.

As such, the upper end of the wire spring 140 is mounted on the cover 130 and the lower end is mounted on the lower end of the lens holder 120 so that the lens holder 120 is elastically supported based on the cover 130. As a result, the direction of the force applied to the wire spring 140 when the lens is assembled to the lens holder 120 is generated in the direction in which the wire spring 140 is tensioned, and the wire spring 140 is excessively bent and damaged. Can be prevented.

The wire spring 140 has a lower end penetrating the lens holder 120 and is connected to the first substrate 150 mounted at the lower end of the lens holder 120.

The first substrate 150 is a rectangular PCB substrate made of a synthetic resin of an insulator, and an opening hole communicating with the lens holder 120 is formed in the center thereof, and the wire spring is symmetrical about the opening hole. A first copper plate portion 151 to which the lower end of 140 is inserted and fixed is formed.

The first copper plate part 151 is formed with copper foil adhered along the outer circumferential surface of the hole penetrated up and down so that lead is fused.

That is, the lower end of the wire spring 140 inserted into the first copper plate part 151 is soldered and fixed to the first copper plate part 151.

In addition, an upper end of the wire spring 140 is inserted into the cover 130 to be connected to the second substrate 160 mounted on the cover 130.

The second substrate 160 has a quadrangular shape, and an opening hole through which a center thereof communicates with the lens holder 120 is formed, and an upper end of the wire spring 140 penetrates and is fixed to four locations symmetrically about the opening hole. The second copper plate portion 161 is formed.

Like the first substrate 150, the upper end of the wire spring 140 is fixed to the second copper plate part 161 of the second substrate 160 by soldering.

In addition, a flexible circuit unit 162 is formed on the second substrate 160 to electrically connect the second substrate 160 and the controller 170.

The flexible circuit unit 162 is formed of a flexible printed circuit board (FPCB) to be easily bent.

In addition, the flexible circuit unit 162 is formed to be electrically connected to the second copper plate unit 161.

That is, a metal plate extends between the flexible circuit unit 162 and the second copper plate unit 161 on the second substrate 160 to be electrically connected.

The flexible circuit unit 162 extends in a lower direction of the base 110 along side surfaces of the cover 130 and the base 110.

In this case, a seating groove 135 in which the flexible circuit unit 162 is inserted and seated is formed on side surfaces of the cover 130 and the base 110.

The seating recess 135 has an outer side that is lower in the inner direction of the cover 130 or the base 110 so that the flexible circuit unit 162 of the outer side or the base 110 of the cover 130 is closed. Do not protrude on the outside.

As such, by forming a seating groove 135 in which the flexible circuit unit 162 is inserted and seated on the side surfaces of the cover 130 and the base 110, the overall outer width of the image stabilization device is equalized to reduce the size. It has the effect of uniting the appearance.

The controller 170 is mounted below the base 110 and connected to the flexible circuit unit 162 to control the power supplied to the driver 180.

The driving unit 180 is mounted between the base 110 and the cover 130 to move the lens holder 120 in the horizontal direction when the power is applied.

That is, the driving unit 180 is connected to the lower end of the wire spring 140 or the first substrate 150, and receives power from the control unit 170 through the wire spring 140 electrically to the lens. The holder 120 is moved in the horizontal direction.

In detail, the coil member 181 of the driving unit 180 is a wire in which an electrically conductive metal wire is wrapped in an insulator, and is wound in a direction parallel to the side surface of the lens holder 120.
That is, the coil member 181 is wound around the other end of the iron piece member 184, as will be described later, has a hollow shape with an open center, and the other end of the iron piece member 184 is inserted in the center to be spaced apart. Is placed.

In addition, the coil member 181 is mounted in four symmetrical positions of the outer surface of the lens holder 120.

At this time, the outer surface of the lens holder 120 guides the guide protrusion 122 to guide the position when the assembly of the coil member 181 and to facilitate the fixing is formed.

In addition, the coil member 181 disposed in mutually symmetrical positions on the lens holder 120 has a winding direction formed in opposite directions to each other, and is formed of one line.

As shown in FIG. 7, the coil member 181 is protruded one by one on both sides to be fixed to the first copper plate part 151 of the first substrate 150 together with the lower end of the wire spring 140. They are in electrical communication with each other.

However, the disconnection of the coil member 181 protruding from both sides of the coil member 181 is electrically connected to the wire spring 140 disposed in a diagonal direction.

As such, the lower end of the wire spring 140 and the driving unit 180 are connected to the first substrate 150 on which the first copper plate part 151 through which the lower end of the wire spring 140 is fixed. By electrically communicating with each other, the fixed position of the wire spring 140 and the driving unit 180 may be enlarged and the connection may be facilitated.

In addition, the wire spring 140 and the coil are fixed by fixing the disconnection of the coil member 181 together with the wire spring 140 to the first copper plate part 151 through which the wire spring 140 is fixed. There is an effect of simplifying the assembly process of connecting the disconnection of the member 181.

On the other hand, the first substrate 150 is formed with a avoidance groove 152 is formed in the disconnection of the coil member 181 when fixing the disconnection of the coil member 181 to the first copper plate portion 151.

The evacuation groove 152 is formed to have an outer surface of the first substrate 150 recessed inward, and the size of the evacuation groove 152 is greater than the diameter of the coil member 181.

In this way, the avoidance groove 152 is formed in the first substrate 150 in which the disconnection of the coil member 181 is disposed, and the size of the avoidance groove 152 is larger than the diameter of the disconnection of the coil member 181. By inserting the disconnection of the coil member 181 disposed below the first substrate 150 into the avoidance 152 to prevent interference with the base 110 when the lens holder 120 is moved. It works.

The upper magnet 182 and the lower magnet 183 is formed in a hexahedral shape, and is a magnet magnetized two poles up and down.

In addition, the upper magnet 182 is inserted into the upper fixing portion 131 of the cover 130, the lower magnet 183 is inserted into the lower fixing portion 111 of the base 110.

The upper magnet 182 and the lower magnet 183 is disposed adjacent to the side of the coil member 181, so that the same polarity to face each other to form a magnetic field around.

The iron piece member 184 has a hexahedron shape, one end of which is inserted between the upper magnet 182 and the lower magnet 183, and the other end of the iron piece member 184 is inserted into a central portion of the coil member 181.

That is, one end of the iron piece member 184 is in contact with the lower surface of the upper magnet 182 and the upper surface of the lower magnet 183, the other end is formed to protrude in the direction of the coil member 181 to the coil member 181 Is placed in the insert.
In addition, as shown in Figure 5, the width of both sides of the other end of the iron piece member 184 is smaller than the width of both sides of one end.

Next will be described in detail the operating state of the camera shake correction device of the present invention made of the above configuration

8 is an operation state diagram of the camera shake correction apparatus according to the present invention as seen from B-B of FIG.

Generally, when the camera recognizes a hand shake using a gyro sensor mounted on the camera, the controller 170 supplies power to the coil member 181 to correct the hand shake.

Accordingly, the coil member 181 is electrically connected to the controller 170 through the second substrate 160, the wire spring 140, and the first substrate 150 in the controller 170. Power is supplied from the controller 170 to move the lens holder 120 in the horizontal direction.

As shown in FIG. 7, as the lens holder 120 moves to the right, the lower end of the wire spring 140 moves to the right with respect to the upper end of the wire spring 140, and the wire spring 140 is moved. Will tilt to the right.

At this time, the disconnection of the coil member 181 mounted on the lens holder 120 is fixed to the first substrate 150 together with the lower end of the wire spring 140 and moved to the right side like the lens holder 120. Done.

That is, since the coil member 181 moves together when the lens holder 120 moves horizontally, disconnection of the coil member 181 hardly moves.

In this way, the driving unit 180 is connected to the lower end of the wire spring 140 to be in electrical communication with the wire spring 140, while receiving power through the wire spring 140, the lens holder 120 ) Has an effect of minimizing an external force applied to the driving unit 180 during horizontal movement.

The camera shake correction apparatus of the present invention is not limited to the above-described embodiment, and can be implemented in various modifications within the range to which the technical idea of the present invention is permitted.

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,

FIG. 3 is an exploded perspective view partially showing 'A' of FIG. 2.

4 is a perspective view showing a camera shake correction apparatus according to the present invention,

5 is an exploded perspective view of a camera in one direction showing a camera shake correction apparatus according to the present invention;

6 is an exploded perspective view showing another direction of the camera shake correction apparatus according to the present invention;

7 is a cross-sectional view of the camera shake correction apparatus according to the present invention as seen from B-B of FIG.

8 is an operation state diagram of the camera shake correction apparatus according to the present invention as seen from B-B of FIG.

<Description of the symbols for the main parts of the drawings>

110: base, 120: lens holder,

130: cover, 140: wire spring,

150: first substrate, 160: second substrate,

170: control unit, 180: driving unit,

181: coil member, 182: upper magnet,

183: lower magnet, 184: iron member,

Claims (6)

delete A base; A lens holder disposed above the base and horizontally mounted and having a lens therein; A cover mounted on an upper portion of the base to surround the lens holder; A wire spring having an upper end mounted on the cover and a lower end mounted on the lower end of the lens holder to elastically support the lens holder in a vertical direction; A first substrate mounted on a lower end of the lens holder and having a first copper plate portion fixed through the lower end of the wire spring; A driving unit connected to a lower end of the wire spring or the first substrate and moving the lens holder in a horizontal direction when power is applied through the wire spring; , &Lt; / RTI &gt; The driving unit includes: A coil member mounted to a side of the lens holder and configured to move the lens holder horizontally by forming a magnetic field when power is applied; An upper magnet and a lower magnet mounted between the base and the cover and disposed adjacent to the coil member; An iron piece member having one end mounted between the upper magnet and the lower magnet and the other end inserted into the center of the coil member; Including, Disconnection of the coil member is fixed to the first copper plate portion with the wire spring, camera shake correction device, characterized in that. The method of claim 2, The first substrate is formed with a avoidance groove in which disconnection of the coil member is formed, The camera shake correction device, characterized in that the size of the avoidance groove is formed larger than the diameter of the coil member disconnection. The method of claim 2, The upper side fixing portion is inserted into the upper magnet is inserted into the side of the cover, On the side of the base is formed a lower fixing portion into which the lower magnet is inserted, The image stabilization device for the camera, characterized in that the upper jaw and the lower fixing portion is formed with a stopper for preventing the upper magnet or the lower magnet from moving in the direction of the lens holder. The method according to any one of claims 2 to 4, The camera shake correction device, A control unit mounted under the base to control power supplied to the driving unit; A second substrate mounted on an upper side of the cover and having a second copper plate portion fixed to penetrate an upper end of the wire spring; Including more, The second substrate is provided with a flexible circuit unit for electrically connecting the second substrate and the control unit, The camera shake compensation device, characterized in that the mounting groove is formed on the side of the cover and the base is inserted into the flexible circuit portion. The method according to any one of claims 2 to 4, A locking groove is formed in an upper portion of the lens holder, The cover has a locking projection is inserted into the locking groove is formed projecting downward, The camera shake correction device, characterized in that the rotation and rise of the lens holder is prevented by the locking projection and the locking groove.

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