KR20170143197A - Lens driving device - Google Patents

Abstract

The purpose of the present invention is to provide a lens driving device capable of increasing driving force by reducing a size and increasing efficiency using a coil member and a magnet respectively provided at two corners in an inclined direction. The lens driving device of the present invention comprises: a hub mounted in an image module; an elastic member fixedly mounted on the hub; moving bodies elastically supported by the elastic member in a vertical direction, having a through hole in which a lens is mounted and first corners respectively provided therein in a diagonal direction; a spacer disposed on the hub and surrounding the moving bodies; annular coil members mounted on the first corners, respectively; and magnets disposed at a side of the coil member to be adjacent to each other and formed in a shape gradually widened toward the coil member. The magnet has polarities separated into one end gradually widened toward one side of the coil member and the other end gradually narrower toward the other side of the coil member.

Description

[0001] LENS DRIVING DEVICE [0002]

The present invention relates to a lens driving apparatus for moving a lens in the direction of an optical axis in order to adjust a focus of a small camera mounted on a portable terminal or the like.

The camera module is mounted on a small electronic device such as a portable terminal, and the camera module has a transfer device for transferring the lens to adjust the focus of the camera.

Japanese Patent Application No. 10-0961127 discloses a camera module mounted on a camera device such as a portable terminal.

1 is a view showing a schematic structure of a conventional camera module.

A conventional camera module is composed of a housing 10, a fixed unit 20, a movable unit 30, and a lens barrel 31 in which a lens is accommodated.

The fixed unit 20 is provided in the housing 10 and includes a fixed support member 21, a coil member 24 provided on one side of the fixed support member 21, And a magnetic member (23) provided on the base.

The movable unit 30 is movably supported on the fixed unit 20 by a predetermined magnetic force so as to move the lens barrel 31 along the optical axis and to be slidable with respect to the fixed support member 21 The support member 32 is supported by the movable support member 32 so as to be brought into close contact with the fixed support member 21 by the magnetic force against the magnetic member 23 and is moved and supported by the electromagnetic force with the coil member 24. [ And a magnet member (33) for moving the member (32).

The fixed support member 21 is provided with a first support surface 21a and the movable support member 32 is provided with a second support surface 32a.

Between the first support surface 21a and the second support surface 32a, a ball member 35 for supporting the movement of the movement support member 32 is provided.

This conventional camera module reduces the driving friction of the moving unit 30 with respect to the fixed unit 20 by the ball member 35 provided between the first supporting surface 21a and the second supporting surface 32a However, when the mobile unit 30 is moved, the movable unit 30 may be tilted in the right and left directions due to the difference in the left and right movement displacements, or may flow in the lateral direction, causing the lens optical axis to be distorted.

The shift of the lens optical axis is caused by a difference in frictional force acting on the left and right portions of the movable unit 30 supported by the ball member 35 or a difference in frictional force acting between the first and second support surfaces 21a, ), Which may degrade the performance and durability of the camera or deteriorate the quality of the photographed image.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a lens driving apparatus capable of improving the driving force by reducing the size and increasing the efficiency by providing the coil member and the magnet respectively at two corner portions arranged diagonally The purpose is to provide.

According to an aspect of the present invention, there is provided a lens driving apparatus including: a hub mounted on an image module; An elastic member fixedly mounted on the hub; A moving body elastically supported by the elastic member in a vertical direction and having a through hole through which the lens is mounted and having a first corner portion in a diagonal direction; A spacer disposed on an upper portion of the hub, the spacer surrounding the moving body; An annular coil member mounted on the first corner portion, respectively; A magnet disposed adjacent to a side of the coil member and having a shape gradually widening toward the coil member; Wherein the magnet has a polarity separated at one end where the width gradually increases toward the coil member direction and at another end where the width gradually decreases toward the opposite direction of the coil member.

A cover member surrounding the spacer; And a yoke portion protruding downward to be inserted into a center portion of the annular coil member is formed in the cover member.

A ball member guiding the up and down movement of the moving body; Wherein the movable body is provided with a second corner portion in a diagonal direction which is symmetrical with the first corner portion, respectively, and the ball member is mounted between the second corner portion and the spacer.

The first and second ball guiding parts and the second ball guiding part are vertically arranged in the second corner part, and the first and the second ball guiding parts are alternately arranged in the horizontal direction Disposed,

An induction member mounted on the first corner of the moving body and guiding a rotational force to the moving body by attraction with the magnet; .

An elastic member connecting the hub and the moving body to elastically support the moving body so as to move up and down with respect to the hub; .

The lens driving apparatus of the present invention as described above has the following effects.

By providing the coil member and the magnet at the two corners arranged in the diagonal direction, the size of the coil member and the magnet are maximized, thereby maximizing the use portion of the coil and increasing the efficiency compared to the conventional coil structure. do.

The magnet may be disposed at the first corner portion, and the magnet may be disposed at the third corner portion, respectively. The magnet may be disposed at one end where the width of the wire becomes gradually wider toward the coil member, The coil member and the magnet are disposed at two places while the entire product is downsized, so that the driving force is increased.

Further, by integrally forming the yoke portion on the cover member without having to assemble a separate yoke, the assembling is facilitated, the manufacturing process is reduced, the productivity is increased, and the driving force is improved.

In addition, the first ball guide portion and the second ball guide portion, which are staggered in the vertical and horizontal directions, are formed on the second corner portion of the moving body so that a total of four ball members are applied in different directions, So that the movable body can be guided safely into the space.

 In addition, since the guide members are disposed so as to be opposite to each other with respect to the coil member, the rotational force is permanently applied to the moving body so that the position of the moving body can be kept constant, The shake is reduced and the quality is improved.

1 is a perspective view of a lens driving apparatus according to an embodiment of the present invention,
2 is an exploded perspective view of a lens driving apparatus according to an embodiment of the present invention,
FIG. 3 is a perspective view of a lens driving apparatus according to an embodiment of the present invention,
4 is a cross-sectional view taken along line AA of Fig. 1,
5 is a cross-sectional view as seen from BB of Fig.

1 to 5, a lens driving apparatus according to an embodiment of the present invention includes a hub 100, an elastic member 200, a moving body 300, a spacer 400, a coil member 500, A cover member 700, a ball member 800, and an induction member 900. [

The hub 100 is fixedly mounted on an upper part of an image module for converting an image of a subject into electronic data, and is formed in a flat hexahedral shape. The center of the hub 100 is circularly opened to project an object to the image module.

The elastic member 200 is formed of a leaf spring and elastically supports the moving body 300 to be described later. Specifically, the elastic member 200 includes a first coupling portion 210 fixed to the hub 100, A second engaging part 220 fixed to the moving body 300 to be described later and an elastic part 230 connecting the first engaging part 210 and the second engaging part 220 and being elastically stretchable in the up and down direction .

The elastic member 200 is formed of three pieces, and two of the elastic members 200 are respectively formed with terminal portions 240 connected to the image module for applying power to the coil member 500, which will be described later.

The moving body 300 is formed in a flat hexahedral shape and is mounted on the upper portion of the second engaging portion 220 of the elastic member 200 and is elastically supported in the vertical direction.

A through hole 310 through which the lens is mounted is formed at the center of the moving body 300. A first corner 320 is formed on the outer circumferential surface of the moving body 300 in a diagonal direction about the through hole 310, The second corner portions 330 are formed in the diagonal direction intersecting with the first corner portions 320, respectively.

The first corner portion 320 is a portion on which the coil member 500 to be described later is mounted and a central projection 321 is formed on the upper surface of the first corner portion 320 to be inserted into the center of the coil member 500.

The second corner portion 330 is disposed at an angle of about 90 degrees with respect to the first corner portion 320 and includes a first ball guide portion 331 into which the ball member 800 to be described later is inserted, And a guide portion 332.

As shown in FIG. 4, the first ball guide portion 331 is opened in a trapezoidal shape when viewed from the end face, and is inserted into the space between the inner side surfaces of the spacer 400 ) Is inserted into the space.

4, the second ball guide portion 332 is disposed at a lower portion of the first ball guide portion 331, and when viewed from the end face, the first ball guide portion 331 is horizontal with respect to the first ball guide portion 331, And is opened in a trapezoidal shape like the first ball guide portion 331. The ball member 800 is inserted between the inner side surface of the spacer 400 and a later- The space is formed.

That is, the first ball guide portion 331 is formed by vertically arranging the second ball guide portions 332 so as to be offset from each other in the horizontal direction.

Meanwhile, the spacer 400 is disposed on the upper portion of the hub 100 to surround the outer side of the moving body 300.

Specifically, the spacer 400 is formed in a rectangular frame shape passing through the upper and lower portions. The third corner portion 410 is formed in a diagonal direction corresponding to the first corner portion 320, and the second corner portion 330 which are arranged in a diagonal direction to face the first ball guide portion 331 and the second ball guide in the horizontal direction and form a space into which the ball member 800 to be described later is inserted, A portion 420 is formed.

The lower end of the fourth corner portion 420 is connected to the lower end of the hub 100. The lower end of the fourth corner portion 420 is formed with an opening groove 421 through which the movable body 300 is inserted, And is pressed and laminated in the direction of the hub 100 in contact with the first engaging portion 210 and the second engaging portion 220 of the elastic member 200 located at the upper portion of the elastic member 200.

The coil member 500 is wound in an annular shape in a horizontal direction, and is formed of two pieces and is mounted on the first corner portion 320, respectively.

That is, the coil member 500 is formed in an elliptical ring shape wound in the horizontal direction with respect to the center protrusion 321 of the first corner portion 320.

The magnet 600 is formed in a triangular shape having three planes along a circumference and is formed of two pieces and is mounted one by one at the lower end of the third corner 410 of the spacer 400, As shown in FIG.

Here, one side of the magnet 600 faces the side surface of the coil member 500, and the width of the magnet 600 gradually decreases toward the opposite direction of the coil member 500.

 That is, the magnet 600 has a shape gradually widening toward the coil member 500.

The magnet 600 has a polarity separated from one end where the width gradually increases toward the coil member 500 and another end where the width gradually decreases toward the opposite direction of the coil member 500.

The coil member 500 is disposed on the first corner portion 320 and the magnet 600 is disposed on the third corner portion 410. The magnet 600 is disposed on the coil member 500, The coil member 500 and the coil member 500 are separated from each other by reducing the polarity to one end where the line width gradually widens in the direction of the coil unit 500 and to the other end where the width gradually decreases toward the opposite direction of the coil member 500, The effect of increasing the driving force by disposing the magnet 600 is generated.

Meanwhile, the cover member 700 surrounds the space and protects the product, while tightly fixing the spacer 400 in the direction of the hub 100. The cover member 700 is formed in a shell shape of a hexahedron, .

The cover member 700 is made of a magnetic material and has a yoke portion 710 protruding downward from the inner circumferential surface thereof. The yoke portion 710 is inserted into the center of the coil member 500.

The yoke portion 710 is inserted into the center portion of the coil member 500 to function as a yoke for improving the electromagnetic force.

By forming the yoke 710 integrally with the cover member 700 without assembling a separate yoke as described above, the assembling is facilitated and the manufacturing process is reduced to increase the productivity.

The ball member 800 has a circular spherical shape and has a total of four balls. The first ball guide portion 331 of the second corner portion 330 and the second ball guide portion 332 of the two corner portions 330, Respectively.

The ball member 800 rotates in contact with the fourth corner portion 420 of the spacer 400 when the mobile body 300 moves up and down to reduce friction and prevent shaking when the mobile body 300 moves up and down.

In general, the conventional lens driving apparatus having a ball guide is configured to disperse the ball member 800 along at least four places along the circumference of the moving object 300. In this case, the ball member 800 occupies a large space There has been a problem that the size of the product increases,

However, in the lens driving apparatus according to the embodiment of the present invention, the first ball guide portion 331, which is staggered vertically and horizontally in the second corner portion 330 of the moving body 300, So that a total of four ball members 800 are applied in different directions to each other, so that the movable body 300 can be guided safely in a small space.

The first ball guide portion 331 and the second ball guide portion 332 are arranged vertically and staggered in the horizontal direction so that the first ball guide portion 331 and the second ball guide portion 332 ) Is zero, and the height of the entire product is minimized.

The guide member 900 includes two guide members 900 fixedly mounted on the first corner unit 320 and is made of a magnetic material attached to the magnet so that the moving member 300 is closely contacted with the magnet 600 .

4, any one of the guide members 900 is disposed on the left side of the coil member 500 and the other guide member 900 is disposed on the coil member 500, As shown in FIG.

The guide member 900 pulls the first corner portions 320 of the moving body 300 in directions opposite to each other so that the second corner portion 330 is moved by the ball member 800 The moving body 300 is maintained in a state in which the rotational force is applied in a clockwise direction.

Since the guide members 900 are disposed so as to be opposite to each other with respect to the coil member 500 as described above, the rotational force is permanently applied to the moving body 300, So that the shake is reduced and the quality is improved when the lens is driven.

3, when power is applied to the coil member 500, the lens driving apparatus according to the embodiment of the present invention, which is generated from the magnet 600 and the coil member 500, The movable body 300 moves up and down in the direction of the optical axis by interaction with the magnetic force.

Here, the moving body 300 is in a state in which a rotational force is applied in a clockwise direction by the guide member 900. As the moving body 300 moves up and down with respect to the optical axis, 300) and the spacer (400).

As described above, the lens driving apparatus according to the embodiment of the present invention includes the coil member 500 and the magnet 600 at two corners arranged in the diagonal direction, thereby reducing the size and increasing the efficiency, An effect of improving the appearance is generated.

The coil member 500 may be disposed on the first corner 320 and the magnet 600 may be disposed on the third corner 410. The magnet 600 may be disposed on the coil member 500, The coil member 500 and the coil member 500 are separated from each other by reducing the polarity to one end where the line width gradually widens in the direction of the coil unit 500 and to the other end where the width gradually decreases toward the opposite direction of the coil member 500, The effect of increasing the driving force by disposing the magnet 600 is generated.

Further, since the yoke portion 710 is integrally formed on the cover member 700 without having to assemble a separate yoke, the assembly is made easy, and the manufacturing process is reduced, thereby increasing the productivity.

The first ball guide portion 331 and the second ball guide portion 332 are formed on the second corner portion 330 of the moving body 300 so as to be offset in the vertical and horizontal directions, The force is applied to the members 800 in different directions so that the movable body 300 can be guided safely in a small space.

 Each of the guide members 900 is disposed so as to be opposite to each other with respect to the coil member 500 so that rotational force is permanently applied to the moving member 300 so that the position of the moving member 300 is constant So that the shake is reduced and the quality is improved when the lens is driven.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention as defined by the following claims something to do.

100: hub 200: elastic member
210: first coupling part 220: second coupling part
230: elastic portion 240: terminal portion
300: mobile body 310: through hole
320: first corner portion 321: center projection
330: second corner portion 331: first ball guide portion
332: second ball guide part 400: spacer
410: third corner portion 420: fourth corner portion
421: open groove 500: coil member
600: Magnet 700: Cover member
710: yoke part 800: ball member
900: guide member

Claims (6)

A hub mounted in the image module;
A moving body disposed in the hub and driven up and down, a through hole through which the lens is mounted, and a first corner portion in a diagonal direction;
A spacer disposed on an upper portion of the hub, the spacer surrounding the moving body;
An annular coil member mounted on the first corner portion, respectively;
A magnet disposed adjacent to a side of the coil member and having a shape gradually widening toward the coil member; , ≪ / RTI &
Wherein the magnet has a polarity separated from one end where the width gradually increases toward the coil member direction and another end where the width gradually decreases toward the opposite direction of the coil member.
The method according to claim 1,
A cover member surrounding the spacer; Further comprising:
Wherein the cover member is formed with a yoke portion protruding downward so as to be inserted into the center portion of the annular coil member.
The method according to claim 1,
A ball member guiding the up and down movement of the moving body; Further comprising:
Wherein the movable body is provided with a second corner portion in a diagonal direction symmetrical to the first corner portion,
And the ball member is mounted between the second corner portion and the spacer.
The method of claim 3,
A first ball guide portion and a second ball guide portion are formed in the second corner portion,
Wherein the first ball guide portion and the second ball guide portion are vertically disposed and are offset from each other in the horizontal direction.
The method according to claim 1,
An induction member mounted on the first corner of the moving body and guiding a rotational force to the moving body by attraction with the magnet; Further comprising: a lens driving device for driving the lens.
The method according to claim 1,
An elastic member connecting the hub and the moving body to elastically support the moving body so as to move up and down with respect to the hub; Further comprising: a lens driving device for driving the lens.

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