KR20060126280A - Image photographing device - Google Patents

Abstract

A small-sized camera is provided to prevent deformation of a leaf spring by preventing floating of a lens holder by coupling the lens holder with a fixing unit, using high-viscosity fluid. A lens group(50) includes plural lenses for varying the zooming ratio of a displayed image of an object. The lens group is mounted on a lens holder(55), which drives the lens group in an optical axis direction. A leaf spring(65) is supported at a fixing unit(60) and guides the lens holder. Viscous fluid couples the fixing unit with the lens holder. A magnet(70) is fixed on one of the fixing unit and the lens holder. A coil(72) is fixed on the other and exposed to a magnetic field, which is generated by the magnet. The coil is wound, so that a driving force is generated when a current is applied to the coil. A magnetic unit(74) is fixed with the coil and floats the lens holder to a predetermined position. An image sensor(80) takes an image of the object. A controller controls the coil and the image sensor.

Description

Miniature Camera Unit {IMAGE PHOTOGRAPHING DEVICE}

1 is a cross-sectional view showing a conventional compact camera device,

2 is a cross-sectional view of a state of use of the small camera device shown in FIG.

3 is an exploded perspective view showing an embodiment of a compact camera device according to the present invention;

4 is a perspective view of the coupled state of the camera device shown in FIG.

5 is a perspective view showing the inside of the camera device shown in FIG.

6 and 7 are perspective views of the state of use of the camera device shown in FIG.

<Explanation of symbols for main parts of drawing>

50: lens group 55: lens holder

56: groove 60: fixed portion

65: leaf spring 66: viscoelastic fluid

70: magnet 72: coil

73: York 74: magnetic material

80: image sensor 90: cover

The present invention relates to a compact camera device, and more particularly, by causing the lens holder to float to an initial position by a magnetic force of the magnet, and using the leaf spring to guide the lens holder to be driven exactly in the optical axis direction, This is to prevent the deformation of the leaf spring while removing the friction generated.

A small communication device such as a mobile phone is equipped with a small camera device.

1 shows a conventional compact camera device.

The compact camera device shown in this figure includes a lens group 500 made up of a plurality of lenses for converting the magnification of a subject, a lens holder 550 for mounting the lens group 500 to drive in the optical axis direction; And a leaf spring supported by the fixing part 600 and the fixing part 600 to lift the lens holder 550 to be movable in the optical axis direction and to guide the lens holder 550 to be driven exactly in the optical axis direction. 650, an actuator supported by the lens holder 550 to drive the fixing part 600 in the optical axis direction, an image sensor 800 for photographing an image of a subject passing through the lens group 500, and an actuator. And a control unit for controlling the image sensor 800.

The leaf spring 650 has a shape in which the width of the leaf spring 650 is narrowed between the portion fixed to the fixing part 600 and the portion fixed to the lens holder 550 to facilitate deformation in the optical axis direction. Therefore, the leaf spring 650 elastically supports the lens holder 550 to flow in the optical axis direction.

In addition, the leaf spring 650 is fixed to at least four places of the lens holder 560, and serves as a guide for preventing the lens holder 560 flow in a direction orthogonal to the optical axis direction.

On the other hand, the actuator, the magnet 710 is fixed to the fixing part 600, and the lens holder 550 is fixed to the lens holder 550 receives the magnetic flux from the magnet 710 when the power is supplied from the control unit in the optical axis direction It consists of a coil 720 for generating a driving force. One pair of magnets 710 and one coil 720 are provided at symmetrical portions.

The actuator also has a yoke 730 for circulating the magnetic flux of the magnet 710 efficiently.

As shown in FIG. 2, when the compact camera device having such a configuration is applied to the coil 720 of the actuator from the control unit, the coil 720 moves in the optical axis direction under the influence of the magnetic flux emitted from the magnet 710. This happens. Therefore, the fixing part 600 to which the coil 720 is fixed moves in the optical axis direction.

In this way, the controller raises or lowers the lens group 500 in the optical axis direction so that the image captured by the image sensor 800 becomes clear.

On the other hand, a camera device having such a structure is mainly mounted on a communication device such as a mobile phone. Cell phones are often subjected to drop shocks due to their use characteristics, so the components mounted on the cell phones should not be deteriorated in a predetermined or less impact. To do this, all parts of the mobile phone are subjected to a drop test.

Normally, the leaf spring 650 has a disadvantage that it is easy to be deformed because it is weak to drop impact.

In order to compensate for this disadvantage, if the spring constant of the leaf spring 650 is made small so that it can be sufficiently curved even when a drop impact is applied, the deformation of the leaf spring 650 can be prevented. However, if the spring constant is small to prevent deformation of the leaf spring 650, the lens holder 550 may move too easily when no current flows in the coil 720, thereby causing a focusing error.

The present invention has been made in view of the above problems, an object of the present invention is to float the lens holder in the initial position by the magnetic force of the magnet, guide the lens holder to drive exactly in the optical axis direction using a leaf spring, viscoelastic fluid By connecting the lens holder and the fixing part to prevent the flow of the lens holder viscoelastic fluid strong viscosity when a sudden impact is applied, to prevent the deformation of the leaf spring while removing the friction generated during the driving of the lens holder.

The present invention for achieving the above object, the lens group consisting of a plurality of lenses for converting the magnification of the subject; A lens holder for mounting the lens group and driving in the optical axis direction; Fixing part; A leaf spring supported by the fixing part to guide the lens holder to flow in the optical axis direction; A viscoelastic fluid connecting the fixing part and the lens holder; A magnet fixed to the fixing part or the lens holder side; The fixing part or the lens holder is fixed to be exposed to the magnetic field of the magnet on the non-fixed side, and receives a magnetic flux of the magnet when a current is applied to drive the lens holder in the optical axis direction. A coil wound to generate; A magnetic body fixed to a side of the fixing part or the lens holder to which the coil is fixed to lift the lens holder with a force attracted by the magnetic force of the magnet to fix the lens holder to a predetermined position; An image sensor for capturing an image of a subject passing through the lens group; And a controller for controlling the coil and the image sensor.

The said viscoelastic fluid consists of ultraviolet curable silicone whose nonvolatile content is 99% or more. Such a viscoelastic fluid has a viscosity of 20000 ± 3000 mpa · s, a standard curing condition of 3000 to 4000mj / cm 2, and a curing shrinkage ratio of 3.0% or less.

As another example, the viscoelastic fluid is made of modified curable silicone having a nonvolatile content of 99% or more. Such a viscoelastic fluid preferably has a viscosity of 11000 ± 3000 mpa · s.

The lens holder is provided with a groove for injecting the viscoelastic fluid.

Hereinafter, with reference to the accompanying drawings, a preferred embodiment of a small camera device according to the present invention will be described in detail.

Figure 3 is an exploded perspective view showing an embodiment of a small camera device according to the present invention, Figure 4 is a perspective view of the combined state of the camera device shown in Figure 3, Figure 5 is a view showing the inside of the camera device shown in FIG. Perspective view.

The compact camera device shown in this figure includes a lens group 50 composed of a plurality of lenses for converting the magnification of a subject; A lens holder 55 for mounting the lens group 50 to drive in the optical axis direction; Fixing part 60; A leaf spring 65 supported by the fixing part 60 to guide the lens holder 55 to flow in the optical axis direction; Viscoelastic fluid 66 connecting the fixing part 60 and the lens holder 55: a magnet 70 fixed to the fixing part 60 or the lens holder 55 side; The magnet 70 of the fixing part 60 or the lens holder 55 is fixed to be exposed to the magnetic field of the magnet 70 on the unfixed side, and receives the magnetic flux of the magnet 70 when a current is applied to the lens holder. A coil 72 wound to generate a force for driving 55 in the optical axis direction; A magnetic body for fixing the coil holder 55 to a fixed position by fixing the coil 72 of the fixing part 60 or the lens holder 55 to the fixed side, and attracting the lens holder 55 by a force attracted by the magnetic force of the magnet 70 ( 74); An image sensor 80 for capturing an image of a subject passing through the lens group 50; And a controller for controlling the coil 72 and the image sensor 80.

The coil 72 receives the magnetic force of the magnet 70 when power is supplied from the controller, generates an electromagnetic force according to Fleming's left hand law, and drives the lens holder 55 in the optical axis direction.

In addition, four or more leaf springs 65 are fixed to the lens holder 55 to prevent the lens holder 55 from flowing in a direction perpendicular to the optical axis direction.

The leaf spring 65 prevents deformation of the leaf spring 65 by making the spring constant small so that the leaf spring 65 can be sufficiently curved even when a drop impact is applied. The leaf spring 65 has a shape in which the width of the leaf spring 65 is narrowed between the portion fixed to the fixing portion 60 and the portion fixed to the lens holder 55 to facilitate deformation in the optical axis direction.

As described above, the leaf spring 65 guides the lens holder 55, so that stick slip or hysteresis does not occur as compared with the conventional way of guiding the lens holder 55 using shafts or guide ribs. This will be excellent.

The viscoelastic fluid 66 consists of ultraviolet curable silicone whose nonvolatile content is 99% or more. The viscoelastic fluid 66 has a viscosity of 20000 ± 3000 mpa · s, a standard curing condition of 3000 to 4000 mj / cm 2, and a curing shrinkage ratio of 3.0% or less.

As another example, the viscoelastic fluid 66 is made of modified curable silicone having a nonvolatile content of 99% or more. Such a viscoelastic fluid 66 preferably has a viscosity of 11000 ± 3000 mpa · s.

The lens holder 55 is provided with a groove 56 for injecting the viscoelastic fluid 66.

Therefore, when the viscoelastic fluid 66 is injected into the groove 56 and irradiated with ultraviolet rays, the viscoelastic fluid 66 becomes a jelly state that does not flow, thereby connecting the fixing part 60 and the lens holder 55 to their own viscosity. .

Then, when the cover 90 covering the circumference of the lens holder 55 is fixed to the fixing part 60, the viscoelastic fluid 66 is not exposed to the outside air.

On the other hand, a yoke 73 is attached to the rear surface of the magnet 70 to circulate the magnetic flux efficiently.

In addition, the magnetic body 74 may freely flow the lens holder 55 in the optical axis direction by floating the lens holder 55 with a force attracted to the magnet 70 to face the strongest magnetic force among the magnets 70. Keep it there. In addition, the magnetic body 74 also serves to restore the lens holder 55 back to its initial position while the lens holder 55 is driven in the optical axis direction.

The coil 72 and the image sensor 80 are both connected to the control unit through the main PC ratio.

Hereinafter, the operation of the present embodiment having the configuration as described above.

When the user presses the photographing button through the keypad installed in the communication device, the controller drives the image sensor 80 to capture an image of the subject passing through the lens group 50. The image sensor 80 converts the captured image into an electrical signal and transmits it to the control unit in the main body through the main PC ratio.

If the captured image is not clear, the controller that receives the image applies power to the coil 72 to perform focusing adjustment.

When power is applied to the coil 72, an electromagnetic force according to Fleming's left-hand rule is generated due to the influence of the magnetic flux from the magnet 70, and the coil 72 moves in the optical axis direction. Therefore, the focusing of the lens group 50 is adjusted to make the captured image clear.

In this process, the leaf spring 65 serves to guide the lens holder 55 to accurately drive in the optical axis direction.

In addition, the magnetic body 74 floats the lens holder 55 by the force attracted to the magnet 70, and restores the lens holder 55 back to the initial position while the lens holder 55 is driven in the optical axis direction.

6 and 7 are perspective views of the state of use of the camera device shown in FIG.

When the lens holder 55 moves from the fixing part 60 in the direction orthogonal to the optical axis direction as shown in FIG. 6 or relatively in the optical axis direction as shown in FIG. 7, the viscoelastic fluid 66 moves the lens holder 55. According to the deformation takes place. Since the viscoelastic fluid 66 has strong viscosity, the resistance increases in proportion to the speed of the lens holder 66.

That is, in the region where the moving speed of the lens holder 55 is slow, the viscoelastic fluid 66 hardly generates resistance as if it were water.

However, when a sudden shock is applied to the small camera device, such as a case where the portable terminal equipped with the small camera device of the present invention falls, the lens holder 55 moves quickly. At this time, the viscoelastic fluid 66 generates a strong resistance as if it is a solid by viscous to hold the lens holder 55 to the fixing part 60 strongly.

Therefore, the displacement that the lens holder 55 moves relative to the fixing part 60 is reduced so as not to impact the leaf spring (65).

As described above, the camera device of the present embodiment is prevented from deforming the leaf spring 65 and damaging the camera device.

As described above, the present invention, by using the magnetic force of the magnet to float the lens holder in the initial position, using a leaf spring guides the lens holder to accurately drive in the optical axis direction, by connecting the lens holder and the fixing portion with viscoelastic fluid When a sudden impact is applied, the viscoelastic fluid prevents the flow of the lens holder with strong viscosity, thereby preventing deformation of the leaf spring while removing friction generated during the driving of the lens holder.

In the above, the present invention has been described as an embodiment, but the present invention is not limited to the above-described embodiments, and the present invention is not limited to the above-described claims, and has a general knowledge in the field of the present invention without departing from the gist of the present invention. Anyone who grows up will be able to make various variations.

Claims (7)

A lens group consisting of a plurality of lenses for converting the magnification of the subject; A lens holder for mounting the lens group and driving in the optical axis direction; Fixing part; A leaf spring supported by the fixing part to guide the lens holder to flow in the optical axis direction; A viscoelastic fluid connecting the fixing part and the lens holder; A magnet fixed to the fixing part or the lens holder side; The fixing part or the lens holder is fixed to be exposed to the magnetic field of the magnet on the non-fixed side, and receives a magnetic flux of the magnet when a current is applied to drive the lens holder in the optical axis direction. A coil wound to generate; A magnetic body fixed to a side of the fixing part or the lens holder to which the coil is fixed to lift the lens holder with a force attracted by the magnetic force of the magnet to fix the lens holder to a predetermined position; An image sensor for capturing an image of a subject passing through the lens group; And Small camera device comprising a control unit for controlling the coil and the image sensor. The method according to claim 1, wherein the viscoelastic fluid, Small camera device, characterized in that made of ultraviolet curable silicone having a nonvolatile content of 99% or more. The method of claim 2, wherein the viscoelastic fluid, Compact camera device, characterized in that the viscosity is 20000 ± 3000mpa.s. The method of claim 2, wherein the viscoelastic fluid, Small size camera device, characterized in that the standard curing conditions are 3000 ~ 4000mj / ㎠, the curing shrinkage is less than 3.0%. The method according to claim 1, wherein the viscoelastic fluid, A compact camera device comprising a modified curable silicone having a nonvolatile content of 99% or more. The method according to claim 5, wherein the viscoelastic fluid, Compact camera device, characterized in that the viscosity is 11000 ± 3000mpa.s. The compact camera device of claim 1, wherein a groove for injecting the viscoelastic fluid is formed in the lens holder.

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