KR20060022922A - Lens actuator - Google Patents

Abstract

The present invention relates to a lens driving mechanism, comprising: a driving coil for generating a magnetic force as a current is supplied; A first moving lens assembly comprising a permanent magnet and a lens; A second moving lens assembly comprising a permanent magnet and a lens disposed such that a surface of the first moving lens assembly facing the permanent magnet has an opposite polarity; A lens barrel having a first stopper for determining a first lens support position, and a second stopper surface constituting a second lens support position in accordance with the position of the drive coil; And an elastic member for elastically supporting the first and second moving lens assemblies with the first stopper of the lens barrel, respectively.

Lens, Zoom, Focus, Spring, Drive Coil

Description

Lens drive mechanism {Lens Actuator}             

1 is a conventional lens driving mechanism.

2 is a conceptual diagram showing the construction and operation of Embodiment 1 of the present invention;

3 is a conceptual diagram showing the construction and operation of the second embodiment of the present invention;

4 is a plan view of the leaf spring of the second embodiment of the present invention.

5 is a conceptual diagram of another embodiment of the present invention.

*** Description of the symbols for the main parts of the drawings ***

10: drive coil 20,20 'first moving lens assembly

22,22 'Permanent Magnet 24,24' Lens

30: lens barrel

50,50 '1st stopper 52,52' 2nd stopper

60: coil spring 70: leaf spring

80: magnetic material

P1: first lens support position P2: second lens support position

The present invention relates to a lens driving mechanism of a camera module mounted on a portable electronic device, and more particularly, to a general shooting mode and a macro mode, or a general shooting mode and a zoom of a camera module mounted on an electronic device such as a mobile phone or a PDA. A lens drive mechanism is used to move a lens for a mode or the like.

Recently, many products equipped with a camera module have been introduced to add functions of a digital camera to a small electronic device such as a mobile phone or a PDA. It is going on. In order to secure performance comparable to that of a general digital camera, not only a technology for increasing the resolution of an image, but also a lens driving technology for realizing a zoom function or a macro function is increasing. However, since a camera module mounted on a small electronic device must be smaller than a general digital camera, there is a lot of space constraints in implementing an optical zoom function such as a general digital camera. I use a lot of software zoom to enlarge. Software type zoom has a disadvantage in that resolution decreases because an image formed on an image pickup device is enlarged by a program, and an optical zoom function should be adopted to obtain a better image.

The optical zoom function can be divided into a linear zoom function that continuously moves until the lens reaches a desired magnification, and a step zoom function that moves the lens back and forth to a position that is a macro or determined magnification.

In case of camera module installed in mobile phone or PDA, it is mainly used for snapshot or copying data, so it is enough to have optical 2x zoom or macro function, and the price can be low. Research is active.

In the camera module, two or three lens groups are generally used, and when the light beam enters the sensor from the subject, the first lens group passes through the first lens group, and the second lens group passes second through the second lens group. The lens group is called a third lens group. The lens group can be freely adjusted according to the designer, but two lens groups of the three lens groups are used for magnification and focus adjustment.

In the case of the stem zoom, the position of the lens that determines the magnification and the position of the focused lens according to the magnification are determined by the lens used. It is possible to determine the position of each lens group in the zoom.

One of the conventional step zoom driving mechanisms is the driving mechanism disclosed in Japanese Patent Laid-Open No. 2004-48809 as shown in FIG. In the conventional apparatus, the movable body 100 including the lens 110 and the permanent magnet 120 is fixed to the first lens support position P1 or the second lens support position P2 in order to be fixed to the first magnetic body 130 or the first magnetic body. The two magnetic bodies 140 are fixed by forming magnetic adsorption with the permanent magnet 120 of the movable body 100. In order to move the moving object 100 to the second lens support position P2 or the first lens support position P1, a current is supplied to the driving coil 150 to form a magnetic field according to the left hand law of flaming, but the driving coil ( The movement of the movable body becomes possible according to the interaction between the magnetic field formed by the 150 and the magnetic field of the permanent magnet 120 of the movable body 100.

In the conventional technology as described above, when the lens 110 is fixed at a predetermined position, current is not consumed, thereby reducing power consumption. However, between the magnetic bodies 130 and 140 and the permanent magnet 120 of the mobile body 100, the current is not consumed. There is a disadvantage that the adsorption force is too strong.

In addition, since there is only one movable body 100, macro photography is possible, but in order to perform a zoom function, two movable bodies 100 must be provided to be in charge of zoom and focus adjustment functions, respectively. There was a problem that was followed by constraints.

The present invention is to provide a lens driving mechanism that solves the problems of the prior art as described above, and its object is to make the lens driving mechanism smaller by a simple structure and capable of zooming and focusing as a single driving mechanism. .

Still another object of the present invention is to provide a lens driving mechanism in which each stop position of the lens can be kept constant at all times.

The present invention for achieving the above object, the drive coil for generating a magnetic force as the current is supplied; A first moving lens assembly comprising a permanent magnet and a lens; A second moving lens assembly comprising a permanent magnet and a lens disposed such that a surface of the first moving lens assembly facing the permanent magnet has an opposite polarity; A lens barrel having a first stopper for determining a first lens support position, and a second stopper surface constituting a second lens support position in accordance with the position of the drive coil; And an elastic member for elastically supporting the first and second moving lens assemblies with the first stopper of the lens barrel, respectively.

With the first and second moving lens assemblies positioned at the first lens support position P1 elastically supported to the stopper side of the lens barrel by a spring, a current is applied to the drive coils to provide permanent magnets of the first and second moving lens assemblies. When the magnetic field is formed to attract, the first and second moving lens assemblies move toward the driving coil side, and even if the current is removed from the driving coil, the permanent magnets of the first and second moving lens assemblies have opposite polarities. Therefore, the suction force is applied to position at the second lens support position (P2).

When the current is reversed to the driving coil to form a magnetic field to repel the permanent magnets of the first and second moving lens assemblies, the first and second moving lens assemblies are first and second by magnetic repulsion with the driving coil. Each of them moves to the lens support position, and stops at the first and second lens support positions by the elastic member.

In addition, the drive coil is provided such that the magnetic plate or the magnetic yoke has a surface facing the permanent magnet. When the first and second moving lens assemblies are positioned at the second lens support position P2, the magnetic coil or the magnetic yoke is magnetically coupled to the magnetic plate or the magnetic yoke. It can also be placed in a stable position.

The stopper is screwed with the barrel to precisely adjust the first lens support position P1, and the first and second movable lens assemblies locate the lens in a ring-shaped permanent magnet, and connect the lens with the barrel on the outer circumferential surface of the permanent magnet. It is also preferable to further include a lubrication member that can reduce the frictional force.

Hereinafter, the present invention will be described with reference to the accompanying drawings.

Embodiment 1 as shown in Figure 2, the drive coil 10 for generating a magnetic force as the current is supplied; A first movable lens assembly 20 composed of a permanent magnet 22 and a lens 24; A second moving lens assembly (20 ') comprising a permanent magnet (22') and a lens (24 ') disposed so that a surface of the first moving lens assembly facing the permanent magnet (22) has an opposite polarity; First stoppers 50 and 50 ′ for determining the first lens support position P1 and second stopper surfaces 52 constituting the second lens support position P2 according to the position of the driving coil 10. A lens barrel 30 having a 52 '); It comprises an elastic member for elastically supporting the first and second moving lens assembly (20, 20 ') with the first stopper (50, 50') of the lens barrel (30), respectively.

2 (a) shows that the first and second moving lens assemblies 20 and 20 'are positioned at the first lens support position P1. A coil spring 60 is disposed between the first and second moving lens assemblies 20 and 20 ', so that the first lens is positioned according to stoppers 50 and 50' positioned at both ends of the lens barrel 30, respectively. The first and second moving lens assemblies 20 and 20 'are elastically supported at the support position P1.

When a current is applied to the driving coil 10 to form a magnetic field to suck the permanent magnets 22 and 22 'of the first and second moving lens assemblies 20 and 20' to the driving coil 10, the permanent magnet ( 22 and 22 'are moved to the drive coil 10 side and the movement is stopped by the second stoppers 52 and 52'. The permanent magnets 22 constituting the first moving lens assembly 20 and the permanent magnets 22 'constituting the second moving lens assembly 20' have opposite polarities to each other, and thus the permanent magnets 22 22, 22 ') is self-adsorbed to each other, so that the position can be maintained at the second lens support position P2 as shown in FIG. It will be apparent to those skilled in the art that this position maintenance is possible only when the suction force between the permanent magnets 22 and 22 'is greater than the repulsive force of the coil spring disposed between the first and second moving lens assemblies 20 and 20'. .

To move the first and second moving lens assemblies whose positions are maintained at the second lens support position P2 to the first lens support position P1 as shown in FIG. When the magnetic field is formed, the permanent magnets 22 and 22 'move to the first lens support position P1 in response to the magnetic force generated by the driving coil 10 and the repulsive force of the spring 60.

3 shows an embodiment 2 of the present invention. Instead of installing a coil spring 60 between the first and second moving lens assemblies 20 and 20 ', an outer ring 72 as shown in FIG. A plate spring (70) having a bridge member (76) connecting the inner ring (74) and the inner and outer rings (72, 74) is used, and the outer side of the plate spring (70) to the first stopper (50, 50 '). The invention differs from the first embodiment in that the ring 72 is attached and the first and second moving lens assemblies 20.20 'are attached to the inner ring 74. The principle of operation is the same as in Example 1 invention.

The leaf spring shown in FIG. 4 (A) is a leaf spring of the present patent application No. 10-2004-70984 filed by the applicant and can be used when the moving distance is long, such as a zoom control. When the moving distance is short, it is also possible to use the conventional leaf spring of Fig. 4B.

In FIG. 5, the magnetic body 80 is inserted into the second lens support position P2 so that the permanent magnets 22 and 22 ′ of the first and second moving lens assemblies 20 and 20 ′ are magnetically coupled to the magnetic body 80. It shows what you can achieve. This magnetic material makes it possible to more reliably and easily maintain the position of the first and second movable lens assemblies 20 and 20 'at the second lens support position P2. The magnetic material may use a ring-shaped magnetic plate as shown in FIG. 5, or may wrap the magnetic yoke (not shown) in the driving coil 10 to allow the permanent magnet to self-adsorb with the magnetic yoke.

 5 shows that the magnetic body 80 is applied to the first embodiment of the present invention, but it is natural that the magnetic body 80 can be applied to the second embodiment.

The present invention as described above may enable the macro function as well as zoom and focus adjustment by adjusting the first lens support position and the second lens support position.

In the case of the macro function, the entire lens needs to be slightly moved in the opposite direction to the subject, which constitutes a lens group of one of the first moving lens assembly and the second moving lens assembly, and the remaining first moving lens assembly. This can be done by replacing the lens with no refraction.

Therefore, the lens driver can be used for various camera modules that require macro function or zoom and focus adjustment function.

The lens driving mechanism of the present invention has a simple structure, the zoom and focus can be adjusted with a single driving mechanism, and the lens driving mechanism can be miniaturized. In addition, each stop position of the lens has the effect that can be kept constant at all times even without supply of current.

Claims (6)

A drive coil 10 generating magnetic force as a current is supplied; A first movable lens assembly 20 composed of a permanent magnet 22 and a lens 24; A second moving lens assembly (20 ') comprising a permanent magnet (22') and a lens (24 ') disposed so that a surface of the first moving lens assembly facing the permanent magnet (22) has an opposite polarity; First stoppers 50 and 50 ′ for determining the first lens support position P1 and second stopper surfaces 52 constituting the second lens support position P2 according to the position of the driving coil 10. A lens barrel 30 having a 52 '); And a resilient member for resiliently supporting the first and second moving lens assemblies (20.20 ') with the first stoppers (50, 50') of the lens barrel (30), respectively. The lens driving mechanism of claim 1, wherein the elastic member is a coil spring positioned between the first moving lens assembly and the second moving lens assembly. 2. The elastic member (60) according to claim 1, wherein the elastic member (60) consists of a plate spring (70) having a bridge member (76) connecting the outer ring (72), the inner ring (74) and the inner and outer rings (72, 74). The outer ring 72 of the plate spring 70 is attached to the first stoppers 50 and 50 ', and the first and second moving lens assemblies 20.20' are attached to the inner ring 74. Lens driving mechanism. 4. A lens driving mechanism according to any one of claims 1 to 3, characterized in that a magnetic body (80) capable of magnetic coupling of said permanent magnets (22, 22 ') is provided at a second lens support position. . 5. The lens driving mechanism according to claim 4, wherein the magnetic body (80) is a magnetic yoke that surrounds the drive coil (10). 5. The lens driving mechanism according to claim 4, wherein the magnetic body (80) is a magnetic plate.

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