KR101886386B1 - Lens driving device - Google Patents

Abstract

According to the present invention, by providing a coil member and a magnet at two corners arranged diagonally, the driving force can be improved by increasing the size while reducing the size, and the ball member and the induction member And to stably maintain the optical axis without shaking.
A lens driving apparatus of the present invention comprises: a hub mounted on an image module, the hub having a first corner portion in a diagonal direction; An elastic member fixedly mounted on the hub; A movable body elastically supported by the elastic member in a vertical direction and having a through hole through which the lens is mounted; A coil member fixedly mounted on the first corner portion; A magnet unit disposed on the coil member and fixedly mounted on the moving body; Wherein the coil member and the magnet unit are formed in a shape having three faces along the periphery, and the coil member is formed in an annular shape surrounding the magnet unit.

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 unit 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 coil member and a magnet at two corners arranged diagonally, And it is an object of the present invention to provide a lens driving apparatus which includes a ball member and an induction member in a diagonal direction to stably maintain an optical axis without shaking.

According to an aspect of the present invention, there is provided a lens driving apparatus including: a hub mounted on an image module, the hub having a first corner portion in a diagonal direction; An elastic member fixedly mounted on the hub; A movable body elastically supported by the elastic member in a vertical direction and having a through hole through which the lens is mounted; A coil member fixedly mounted on the first corner portion; A magnet unit disposed on the coil member and fixedly mounted on the moving body; Wherein the coil member and the magnet unit are formed in a shape having three faces along the circumference, and the coil member is formed in an annular shape surrounding the magnet unit.

A cover member surrounding the moving body; A ball member mounted between the moving body and the cover member to guide up and down movement of the moving body; Wherein the movable body is provided with a second corner portion diagonally intersecting the first corner portion, and the ball member is inserted into the second corner portion.

A plurality of ball guide grooves spaced vertically and horizontally are formed in the second corner portion, and the ball members are inserted into the ball guide grooves, respectively.

An induction magnet fixedly mounted on the cover member; An induction member fixedly mounted on the moving body and guiding the moving body in the direction of the induction magnet by attraction force; .

Wherein the hub includes a third corner portion in a diagonal direction intersecting with the first corner portion, and a second corner portion disposed on the upper portion of the first corner portion is provided on the moving body, and the induction magnet is provided on the third corner portion And the guide member is fixedly mounted on the second corner portion.

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.

The magnet unit 500 having three sides along the periphery of the magnet unit 500 and the annular coil member 400 wound around the magnet unit 500. Thus, It is possible to increase the volume-to-volume magnetic efficiency by using the periphery as a magnetic force effective area.

In addition, by arranging the coil member 400 and the magnet unit 500 in a pair of mutually symmetrical corners in the diagonal direction of the optical axis, the effect of improving the performance by increasing the driving force while reducing the size of the product is generated .

In addition, the four ball guide grooves 331 into which the ball member 700 is inserted are vertically and horizontally staggered so that the ball member 700 can be vertically spaced to reduce the overall height of the product Is generated.

The guide magnet 900 and the guide member 900 guide the moving body 300 constantly toward the contact portion 610 and thereby the ball member 700 is brought into close contact with the contact portion 610 The optical axis of the moving body 300 is minimized when the mobile body 300 moves up and down, and the effect of improving the performance and quality of the product is reduced by reducing the occurrence of shaking.

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,
3 is a cross-sectional view taken along line AA of FIG. 1,
Fig. 4 is a cross-sectional view taken along the line BB of Fig. 1,
5 is a cross-sectional view taken at CC in Fig. 1,
6 is a perspective view showing a ball member inserted into a moving body of a lens driving apparatus according to an embodiment of the present invention,

1 is a perspective view of a lens driving apparatus according to an embodiment of the present invention, Fig. 2 is an exploded perspective view of a lens driving apparatus according to an embodiment of the present invention, Fig. 3 is a cross- FIG. 5 is a cross-sectional view taken along line CC of FIG. 1, and FIG. 6 is a perspective view of a ball member 700 inserted into the moving body 300 of the lens driving apparatus according to the embodiment of the present invention.

1 to 6, 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 coil member 400, a magnet unit 500, A cover member 600, a ball member 700, an induction magnet 800, and an induction member 900.

The hub 100 is mounted on an upper portion of the image module. The hub 100 is in the form of a flat hexahedron. The center of the hub 100 is vertically penetrated through the lens toward the image module.

A terminal member 110 for electrically connecting the coil member 400 to the image module to be described later is mounted and fixed on an upper surface of the hub 100 and a support portion 120 is protruded upward along a rim Thereby supporting the elastic member 200 to be described later.

The first corner 130 is formed on the hub 100 so as to be symmetrical with respect to the optical axis of the lens in a diagonal direction.

More specifically, the first corner 130 may be two symmetrically arranged diagonally out of angled portions of the upper surface of the hub 100 having a rectangular shape.

A third corner 140 is formed on an upper portion of the hub 100 at an angled portion diagonally intersecting the first corner 130.

Here, the first corner portion 130 is fixedly mounted with the coil member 400 described later.

The elastic member 200 includes a first fixing part 210 fixed to the upper end of the supporting part 120 and a second fixing part 210 fixed to the moving body 300, And an elastic part 230 formed between the first fixing part 210 and the second fixing part 220 and elastically deforming in the vertical direction.

When the driving force is removed, the elastic member 200 supports the movable body 300 so that the movable body 300 can be moved up and down.

The moving body 300 is formed in a flat hexahedron shape. The moving body 300 is formed with a through hole 310 penetrating vertically so that a lens can be inserted and inserted thereinto, and on the outer side, at a position corresponding to the first corner 130, A second corner portion 330 in which the ball member 700 to be described later is inserted is disposed at a position corresponding to the third corner portion 140, .

The second corner portion 330 is formed symmetrically with respect to the diagonal direction intersecting the first corner portion 130 with respect to the penetrating long 310 and the second corner portion 330 has a plurality of balls A guide groove 331 is formed.

The ball guide groove 331 is a space into which the ball member 700 to be described later is inserted, and is formed in a trapezoidal shape when viewed from a plane.

In addition, the ball guide grooves 331 are formed of four balls, which are arranged alternately up and down and horizontally.

In other words, the ball guide grooves 331 are arranged symmetrically on both sides with respect to the guide member 900, which will be described later, and are disposed between the two ball guide grooves 331 Is larger than the interval between the two ball guide grooves (331) disposed at the lower portion.

In the ball guide groove 331, the ball members 700 to be described later are inserted one by one.

In this way, the four ball guide grooves 331 in which the ball member 700 is inserted are vertically and horizontally staggered to each other, thereby preventing the ball member 700 from being vertically spaced to reduce the overall height of the product Is generated.

The coil member 400 is formed of two pieces, and is fixed to the first corner part 130 one by one, and is formed in an annular shape to surround the outer circumferential surface of the magnet unit 500, which will be described later.

More specifically, the coil member 400 is formed into a triangular annular shape having three faces along the circumference, and one of the longest sides is arranged in the direction of the penetrating long 310, The first corner portion 130 and the second corner portion 130 are located at the corner portions.

The coil member 400 is connected to the image sensor through the terminal member 110 and is powered.

The magnet unit 500 is formed in a triangular bar shape having three sides along the circumference and is formed of two pieces and is disposed on the upper portion of the coil member 400 and fixed to the mounting portion 320 of the moving body 300 .

In this magnet unit 500, one of the longest sides is arranged in the direction of the penetrating lath 310 like the coil member 400, and a vertex between the other two sides is positioned at a corner of the moving body 300 .

In addition, the polarity of the magnet unit 500 is separated in the direction of the vertex between one of the longest sides and the other two sides.

The magnet unit 500 includes a triangular-shaped magnet unit 500 having three surfaces along the circumference and the annular coil member 400 wound around the magnet unit 500. Thus, It is possible to increase the volume-to-volume magnetic efficiency by using the entire circumference of the magnetic field as the effective area of the magnetic force.

In addition, by arranging the coil member 400 and the magnet unit 500 in a pair at the corner portions symmetrical to each other in the diagonal direction, the effect of improving the performance by increasing the driving force while reducing the size of the product is generated.

The magnet unit 500 includes a triangular bar magnet 510 and a triangular plate piece 520 attached to the lower end of the magnet 510. The center of the ferrule 520 has a circular shape An opening hole 521 is formed.

The magnetic piece 520 having the opening 5121 formed at the lower end of the magnet 510 increases the magnetic force of the magnet 510 to improve the driving force.

The cover member 600 is formed of a non-magnetic material and is formed in a hexahedron shape. The cover member 600 surrounds the upper and outer sides of the moving body 300 and is fixedly mounted on the hub 100.

A contact portion 610 in contact with the ball member 700 is formed on the inner side of the cover member 600 at a position corresponding to the third corner portion 140. The contact portion 610 is provided with a guide magnet 610, (800) is inserted and fixed.

The ball member 700 includes four ball guide grooves 331. The ball member 700 is inserted into the ball guide grooves 331 one by one and is brought into contact with the inner side surface of the ball guide groove 331 and the contact portion 610 of the cover member 600 do.

The ball member 700 supports the moving body 300 so that the moving body 300 can be stably moved up and down while being rotated when the moving body 300 moves up and down.

Particularly, the moving body 300 receives a force that is constantly guided by the guide magnet 800 and the guide member 900 in the direction of the contact portion 610 to be described later, 600).

Specifically, the induction magnet 800 is in the shape of a hexahedron and is disposed on the third corner portion 140 of the hub 100 and inserted and fixed to the contact portion 610 of the cover member 600 .

The guide member 900 is made of a magnetic material and is fixed to the second corner portion 330 of the moving body 300 to guide the moving body 300 toward the induction magnet 800 by gravity.

Here, the induction magnet 800 and the guide member 900 are arranged in parallel to the diagonal line toward the second corner portion 330.

Since the guide magnet 800 and the guide member 900 that guide the moving body 300 uniformly toward the contact portion 610 are provided as described above, the ball member 700 is in close contact with the contact portion 610 The optical axis of the moving body 300 is minimized when the mobile body 300 moves up and down, and the effect of improving the performance and quality of the product is reduced by reducing the occurrence of shaking.

In the lens driving apparatus according to the embodiment of the present invention configured as described above, power is applied from the image sensor to the coil member 400, and the coil member 400 and the magnet interact with each other, 300 are moved up and down by the elastic member 200 to adjust the focus of the subject.

Here, the moving body 300 is guided by the induction magnet 800 and the guide member 900 so as to be permanently and constantly in close contact with the third corner 140, i.e., the contact portion 610, The ball member 700 is in constant contact with the inner surface of the ball guide groove 331 and the contact portion 610.

Therefore, when the movable body 300 is moved up and down, the ball member 700 is rotated by contact with the contact portion 610 to reduce friction, and guide the ball member 700 to move up and down smoothly without shaking.

As described above, the lens driving apparatus according to the embodiment of the present invention includes a triangle-shaped magnet unit 500 having three surfaces along the periphery, and an annular coil member 500 wound around the magnet unit 500 400, the magnetic force efficiency of the magnet unit 500 can be increased by using the entire periphery of the magnet unit 500 as a magnetic force effective area.

In addition, by arranging the coil member 400 and the magnet unit 500 in a pair of mutually symmetrical corners in the diagonal direction of the optical axis, the effect of improving the performance by increasing the driving force while reducing the size of the product is generated .

In addition, the four ball guide grooves 331 into which the ball member 700 is inserted are vertically and horizontally staggered so that the ball member 700 can be vertically spaced to reduce the overall height of the product Is generated.

The guide magnet 900 and the guide member 900 guide the moving body 300 constantly toward the contact portion 610 and thereby the ball member 700 is brought into close contact with the contact portion 610 The optical axis of the moving body 300 is minimized when the mobile body 300 moves up and down, and the effect of improving the performance and quality of the product is reduced by reducing the occurrence of shaking.

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.

The present invention relates to an elastic member and a method of manufacturing the same and a method of manufacturing the same. The present invention relates to a magnet unit and a method of manufacturing the magnet unit of the present invention and a method of manufacturing the same. 600: cover member, 610: contact portion, 700: ball member, 800: induction magnet, 900: guide member

Claims (6)

A hub mounted in the image module and having a first corner portion in a diagonal direction, respectively;
A moving body disposed in the hub and driven in a vertical direction and having a through hole through which the lens is mounted;
A coil member fixedly mounted on the first corner portion;
A magnet unit disposed on the coil member and fixedly mounted on the moving body;
A cover member surrounding the moving body;
A ball member mounted between the moving body and the cover member to guide up and down movement of the moving body;
An induction magnet fixedly mounted on the cover member; And
An induction member fixedly mounted on the moving body and guiding the moving body in the direction of the induction magnet by attraction force; , ≪ / RTI &
Wherein the coil member and the magnet unit are formed in a shape having three faces along the circumference,
Wherein the coil member is formed in an annular shape surrounding the periphery of the magnet unit,
Wherein the moving body is provided with a second corner portion in a diagonal direction crossing the first corner portion,
Wherein the plurality of ball members are inserted into the second corner portion.
delete The method according to claim 1,
And a plurality of ball guide grooves spaced vertically and horizontally are formed in the second corner portion, and the ball members are inserted into the ball guide grooves, respectively.
delete The method according to claim 1,
Wherein the hub is provided with a third corner portion in a diagonal direction intersecting with the first corner portion,
Wherein the moving body is provided with a second corner portion disposed at an upper portion of the first corner portion,
The induction magnet is fixedly mounted on the third corner portion,
And the guide member is fixedly mounted on the second corner portion.
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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