KR101159171B1 - Lens actuator - Google Patents

Abstract

(Problem) Provided is a lens actuator that is thin in shape, hardly shifts the lens position with respect to the optical axis, and has a large displacement amount with respect to the displacement amount of the driving source.
(Solution means) In a lens actuator having a lever-type displacement magnification mechanism arranged in an annular manner, the opposing portion of the lever-type displacement magnification mechanism that is separately connected from the driving source via the lever portion is crossed with the piezoelectric element serving as the driving source. By using the arrangement structure, it becomes possible to suppress the inclination generated during lens driving and to configure the whole structure in a thin shape.

Description

Lens Actuator {LENS ACTUATOR}

Currently, some mobile communication devices represented by mobile phones have added a camera function, and it is possible to output a captured image to the outside.

A lens actuator of a camera mounted in such a mobile communication device is roughly classified into driving a lens by stretching and displacing a piezoelectric element or the like and driving the lens by a lens tube.

Japanese Unexamined Patent Publication No. 2002-130114 (hereinafter referred to as Patent Document 1) has been filed as a structure for driving the lens by the above-described stretching and displacement. The patent document 1 has a structure in which the shape memory alloy is formed obliquely with respect to the optical axis, and only the displacement in the optical axis direction is taken out from the expansion and contraction direction to drive the lens, and the entire camera mechanism is shortened by shortening the distance between the imaging element and the lens. It is possible to miniaturize.

In addition, Japanese Laid-Open Patent Publication No. 2005-274796 (described as Patent Document 2) has been filed as a structure using a lens barrel, and the lens barrel is moved in the optical axis direction by a magnetic force acting between the coil magnets.

For this reason, it is possible to obtain better immediate response than the conventional drive structure for rotating the barrel, and by using the barrel as a guide, lens driving in the optical axis direction can be performed without deviation in the radial direction.

Japanese Laid-Open Patent Publication 2002-130114 Japanese Laid-Open Patent Publication 2005-274796

However, in Patent Document 1, since the lens is moved in the vertical direction with respect to the optical axis when the lens is driven in a structure in which the lens holder is supported in parallel by the elastic member, the focal position of the lens cannot be made constant with respect to the imaging element. The use efficiency of an imaging element will worsen.

Moreover, since the lens actuator of patent document 2 has a structure which accommodated the barrel inside, it is difficult to set large the moving range of a lens with respect to the thickness of the whole actuator, and it is difficult to make it a thin structure.

In view of the above-described problems, an object of the present invention is to provide a lens actuator that is thin and difficult to shift the lens position with respect to the optical axis, and that a large displacement amount can be obtained with respect to the displacement amount of the driving source.

For the above purpose, in the invention described in claim 1, in the lens actuator of the displacement expanding mechanism mounted type that enlarges the displacement using a lever, a piezoelectric element serving as a driving source and a displacement expanding mechanism connected to both ends thereof are provided. Arranged annularly and using the structure arrange | positioned so that both ends of the said displacement expansion mechanism may be used.

By using the above structure, the lens actuator described in the present invention is capable of converting the displacement of both ends of the piezoelectric element serving as the driving source in the vertical direction. For this reason, the piezoelectric element which is a drive source can be arranged horizontally with respect to the expansion-contraction direction, and the thickness of the whole lens actuator can be made thin.

Further, by displacing the displacement magnification mechanism in an annular manner, the entire frame around the lens can be used as a lever, so that the displacement magnification ratio of the piezoelectric element can be set large, while the lens is kept in parallel by the structure where the ends are crossed. Movement in the optical axis direction becomes possible.

Moreover, in the invention of Claim 2, the displacement expansion mechanism is comprised separately from the case body of an actuator with respect to the lens actuator of Claim 1. It is characterized by the above-mentioned. For this reason, it becomes possible to set the expansion-contraction displacement of a drive source largely, and the whole lens actuator can be comprised in a small size.

In addition, since the position of the end portion of the displacement expansion mechanism can be adjusted by configuring the displacement expansion mechanism as a separate body, it is possible to obtain a lens arrangement adapted to the internal structure of the device on which the lens actuator is mounted when the lens is attached.

Furthermore, in the invention according to claim 3, a plate-shaped spacer is formed at the intersection, and the force in the twisting direction generated at the end of the displacement expansion mechanism can be suppressed by the connection of the lever. Become. In addition, by fixing the intersection portion by the spacer, the relative positions of the end portions can be kept constant and stable lens driving can be performed.

In addition to the effects described above, since the lens actuator according to the present invention uses a piezoelectric element as a driving source, frictional particles do not occur at the time of driving unlike a rotating cylindrical structure, and foreign matter is generated in the optical axis. It is structure that is hard to do.

1 is a perspective view of a lens actuator used in the first embodiment of the present invention.
Fig. 2 is an exploded perspective view of the lens actuator used in the first embodiment of the present invention.
Fig. 3 is a perspective view of the lens actuator used in the second embodiment of the present invention.
Fig. 4 is an exploded perspective view of the lens actuator used in the second embodiment of the present invention.

(Example)

Below, 1st and 2nd embodiment in this invention is shown using FIG.

Fig. 1 shows a perspective view of a lens actuator used in the first embodiment of the present invention. As can be seen from FIG. 1, the lens actuator in the present embodiment enlarges the displacement of the piezoelectric element 5 which is the driving source in the annular arrangement in which the lever part 3 and the displacement expansion mechanism end 4 are connected. The mechanism enlarges the displacement in the displacement enlargement direction C and fixes the displacement enlargement mechanism end 4 to the base 7 so that the expansion and contraction of the piezoelectric element is changed to the displacement in the optical axis direction A. have.

For this reason, when the lens is mounted on the lens holder 1, the displacement of the driving source can be enlarged in the state in which no obstacle is generated on the optical axis, and the lever expansion unit is constituted by configuring the displacement expansion mechanism around the optical axis A. It became possible to ensure the length of (3) and to set the enlargement ratio at the time of the said displacement enlargement large.

2 is an exploded perspective view of the lens actuator shown in the first embodiment. As can be seen from FIG. 2, the displacement switching unit 4a is connected to the lever 3 by a thin, long plate-shaped first connection unit 4b, and the displacement switching unit 4a and the fixing unit 4d are provided. Is connected by a thin long plate-shaped second connecting portion 4c. The lens actuator according to the present embodiment has a drive structure in which the displacement expansion mechanism end portion 4 is interposed with the spacer 6 interposed therebetween.

For this reason, the displacement of the twisting direction which acts on each displacement expansion mechanism edge part 4 arrange | positioned alternately is absorbed by the spacer 6, and the lens holder 1 supported by the lens holder support part 2 is an optical axis ( When moving along A), it was able to drive in a stable state without generating inclination.

In addition, since the lever part 3 is formed separately from the base 7, the planar shape of the entire lens actuator is reduced, and the stretching direction B and the optical axis A of the piezoelectric element 5 serving as the driving source are perpendicular to each other. Since it is a drive structure, it became possible to make thickness thin compared with a lens barrel type lens actuator.

3 is a perspective view of the lens actuator used in the second embodiment of the present invention. As can be seen from FIG. 3, the lens actuator in the present embodiment differs from the lens actuator shown in the first embodiment in that both sides of the displacement-expansion mechanism end portion 4 are levers 3 of each other. We use structure supported by.

For this reason, in this embodiment, the dimension of the thickness direction can be made smaller than the lens actuator of the said Example 1, and the displacement expansion mechanism edge part 4 stresses from the two contact points with the lever part 3, respectively. As a result, the driving range of the lens could be set larger than that of the first embodiment.

4 is an exploded perspective view of the lens actuator used in the present embodiment. As can be seen from FIG. 4, the displacement switching unit 4a is connected to the lever 3, and the displacement switching unit 4a and the fixing unit 4d are connected by the connection unit 4c. In the structure described in the present embodiment, the base 7 provided by the lens actuator described in the first embodiment is not used. For this reason, in addition to the lens actuator of Example 1 mentioned above, thickness reduction was possible further.

In addition, with respect to the lens holder 1, the support block 8 is inserted between the displacement expansion mechanism end part 4 and the lens holder support part 2, and height is adjusted, and also the annular suspension 9 is carried out from both sides. The lens holder 1 is supported. For this reason, it becomes possible to absorb the inclination which arises at the time of movement of the lens holder 1 by the suspension 9, and to suppress the vibration at the time of driving a lens, and to improve immediate response.

Moreover, the structure which changed the thickness of the lens holder 1 into the attachment position e of the lens holder support part 2, and the lens holding part d is used, The support block 8 and the said attachment position are used. By changing the thickness of the wah, a structure in which the focus adjustment can be performed even in a mounting space where the thickness of the lens holder 1 is limited is achieved.

In addition, the bending structure is applied with respect to the end part 4, and the mass productivity is improved, and the elastic material is used for the said end part 4, and the piezoelectric element 5 expanded by the lever part 3 is expanded. When the displacement was changed to the displacement in the optical axis direction A, the displacement in the twisting direction generated at the displacement expansion mechanism end 4 could be absorbed.

As described above, by using the lens actuator described in the present embodiment, it has become possible to provide a lens actuator that is thin, hardly displaces the lens position with respect to the optical axis, and can obtain a large displacement amount with respect to the displacement amount of the drive source.

1: lens holder
2: lens holder support
3: lever
4: end portion of the displacement expanding mechanism
5: piezoelectric element
6: spacer
7: donation
8: support block
9: suspension
A: optical axis direction
B: stretch direction
C: displacement expansion direction
d: lens holding part
e: attachment position

Claims (3)

The displacement of the piezoelectric element in the stretching direction is taken as the driving source,
A lens actuator provided with a base having two lever-type displacement expanding mechanisms for expanding the displacement and converting the displacement in the optical axis direction.
Each of the displacement expansion mechanisms,
One end is fixed, and the lever part in contact with the end of the piezoelectric element,
And an end portion of the displacement expanding mechanism connected to the other end of the lever portion,
End of the displacement expansion mechanism,
A displacement switching unit connected to the other end of the lever;
A fixing part fixed to the base and connected to the displacement converting part through a connecting part,
The piezoelectric element and the two displacement expanding mechanisms formed at both ends of the piezoelectric element are annularly arranged;
A lens actuator in which an end of the displacement expanding mechanism is crossed on an opposite side of the piezoelectric element in the annular arrangement. The method of claim 1,
The lens actuator which comprised the said displacement expansion mechanism separately from the base of the said lens actuator. The method according to claim 1 or 2,
And a plate-shaped spacer at the intersection.

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