KR20100138269A - Camera lens assembly for mobile-phone functioning as a shutter - Google Patents

Abstract

PURPOSE: A camera lens assembly for a mobile phone with a shutter function is provided to install an operating unit of an AF(Auto Focusing) assembly and an operating unit of the shutter assembly, thereby maximizing usability of a space. CONSTITUTION: An outer frame(210) is inserted into an outer side of an inner frame and has an opening in an optical axis direction. Shutter wings(220,230) are installed on the top of the outer frame. A shutter operating unit(250) is arranged on the other side of the inner frame to enable rotation of the shutter wing on a plane vertical to the optical axis. A PCB(Printed Circuit Board)(260) applies electricity to the shutter operating unit. A shutter cover(240) is installed on the top of the shutter wing to prevent the shutter wing from the outside.

Description

Camera lens assembly for mobile phone with shutter function {CAMERA LENS ASSEMBLY FOR MOBILE-PHONE FUNCTIONING AS A SHUTTER}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a camera lens assembly for a mobile phone having a shutter function, and more particularly to a camera lens assembly for a mobile phone having a shutter function more compact to have a shutter function without significantly changing the height of the autofocus device.

Recently, with the development of digital camera manufacturing technology, cameras are also installed in mobile communication terminals including mobile phones.

The digital camera mounted here must be manufactured in a smaller size in order to meet the light and thin trend of the mobile communication terminal.

In addition, although the level of the camera mounted on the mobile communication terminal is generally 1 million to 2 million pixels class, as the technology develops, a camera having a performance of 8 million pixels or more is being developed one after another.

Here, cameras with a built-in autofocus function for correcting a focal blur caused by a shooting distance of a subject at the time of shooting are increasing.

As described above, in the camera lens assembly having an autofocusing function mounted in a mobile communication terminal, a technology for adding a shutter function that allows the capturing of a clear image by adjusting the amount of light incident on an optical path to obtain a clearer image is developed. However, due to the characteristics of mobile communication terminal, it is having difficulty in development.

In particular, since the shutter assembly having a shutter function must be installed in the optical axis direction, there is a bigger problem in implementing a slim mobile communication terminal as the thickness becomes thicker.

Accordingly, an object of the present invention is to provide a camera lens assembly for a mobile phone having a compact shutter function without a great change in the size of the autofocus assembly.

SUMMARY OF THE INVENTION An object of the present invention is to provide a camera lens assembly for a mobile phone having a shutter function having a thinner thickness by maximizing utilization of space by installing a driving unit of an autofocus assembly and a driving unit of a shutter assembly, respectively.

In addition, the present invention provides a camera lens assembly for a mobile phone having a shutter function that can reduce the manufacturing cost, such as wiring by bonding to the image sensing unit without applying power separately to the driving unit of the autofocus assembly and the driving unit of the shutter assembly. The purpose is to.

The present invention to achieve the above object, the present invention forms an inner space and the inner frame having an opening along the optical axis, the lens assembly is installed in the inner space of the inner frame to enable reciprocating movement in the optical axis direction, and the lens assembly A lens driver installed at one side of the inner frame to drive the lens in an optical axis direction, an image sensing unit installed at a bottom of the inner frame to detect an image transmitted through the opening, and installed to apply electricity to the image sensing unit. An autofocus assembly having a printed circuit board; An outer frame provided to be fitted along an outer surface of the inner frame and having an opening formed in an optical axis direction, a shutter blade formed of at least one wing disposed above the outer frame, and the shutter blade perpendicular to the optical axis. A shutter driver disposed on the other side of the inner frame to be rotatable on a plane, a printed circuit board installed to apply electricity to the shutter driver, and an upper portion of the shutter blade to block the shutter blade from the outside It provides a camera lens assembly for a mobile phone having a shutter function including a shutter assembly having a shutter cover.

Here, the printed circuit board of the shutter assembly is bonded to the printed circuit board of the image sensing unit and electrically connected thereto, and the printed circuit board of the lens driving unit is also preferably bonded to the printed circuit board of the image sensing unit and electrically connected thereto.

In addition, it is preferable that the camera lens assembly for a mobile phone according to the present invention is provided such that the autofocus assembly and the shutter assembly are individually driven.

In addition, the lens driving unit may include a lens driving coil installed on one side of the inner frame to face the lens assembly and a printed circuit board for applying electricity to the lens driving coil, and the shutter driving unit protrudes outward to form driving pins. And a magnetic path is formed by the current flowing through the shutter driving coil and the shutter driving coil formed on one side of the permanent magnet and the hollow magnet formed inside, and the magnetic member and the shutter driving formed at both ends to face different poles of the anode of the permanent magnet. It is preferable to include a printed circuit board for applying electricity to the coil.

In addition, the camera lens assembly for a mobile phone according to the present invention is a projection formed on the outer surface of the inner frame or the inner surface of the outer frame, it is preferable that the receiving groove is formed on the inner surface of the outer frame or the outer surface of the inner frame so that the projection can be removed. Do.

As described above, the camera lens assembly for a mobile phone according to the present invention can be installed at both sides of the autofocus assembly driving unit and the shutter assembly driving unit on both sides to maximize the utilization of the space and at the same time have a thinner and more compact thickness. It works.

In addition, the camera lens assembly for a mobile phone according to the present invention by contacting the printed circuit board of the autofocus assembly drive unit and the shutter assembly drive unit of the image sensing unit to the printed circuit board of the image sensing unit, the driving portion of the autofocus assembly and the shutter assembly There is an effect that can be applied without the need to apply a separate power source.

In addition, since the camera lens assembly for a mobile phone according to the present invention does not need to install a separate line to apply power to the driving unit as described above, there is an effect that can significantly reduce the manufacturing cost.

Hereinafter, an embodiment of a camera lens assembly for a mobile phone according to the present invention will be described with reference to the accompanying drawings.

Figure 1a is a perspective view showing a camera lens assembly for a mobile phone according to the invention, Figure 1b is a perspective view from a different direction from Figure 1a showing a camera lens assembly for a mobile phone according to the invention, Figure 2 is an autofocus according to the present invention 3 is an exploded perspective view showing a camera lens assembly for a mobile phone according to the present invention, Figure 4 is a partial cutaway perspective view showing a camera lens assembly for a mobile phone according to the present invention. 5 is a perspective view illustrating a lens driving unit of a camera lens assembly for a mobile phone according to the present invention, FIG. 6 is a partial cutaway plan view showing a shutter assembly of a camera lens assembly for a mobile phone according to the present invention, and FIG. Perspective view showing closed state of camera lens assembly shutter driver for mobile phone 7B is a perspective view illustrating an open state of a camera lens assembly shutter driver for a mobile phone according to the present invention, and FIG. 8A is a plan view illustrating a closed state of a camera lens assembly shutter driver for a mobile phone according to the present invention, and FIG. 9 is a plan view illustrating an open state of a camera lens assembly shutter driver for a mobile phone according to the present invention, and FIG. 9 is a perspective view showing a camera lens assembly shutter driver for a mobile phone according to the present invention.

As shown in FIGS. 1A, 1B and 2, the camera lens assembly 1000 for a mobile phone according to the present invention includes an autofocus assembly 100 and a shutter assembly 200.

The autofocus assembly 100 forms an inner space as shown in FIG. 3 and has an opening along the optical axis, and is installed to reciprocate in the optical axis direction in the inner space of the inner frame 110. The lens assembly 130, the lens driver 120 installed on one side of the inner frame 110 to drive the lens assembly 130 in the optical axis direction, and are installed on the bottom of the inner frame 110 and transmitted through the opening. The printed circuit board 153 is provided with an image sensing unit 150 for detecting an image, and a printed circuit board 153 installed to apply electricity to the image sensing unit 150.

The inner frame 110 is open so that light is transmitted upward, and one side thereof is open to install the lens driver 120. An inward flange 118 is formed at the edge portion of the side surface formed to install the lens driving unit 120 and is coupled with the stepped portion 125 (shown in FIG. 5) formed on the outer surface of the lens driving unit 120 to be described later. The lens driver 120 is fixed. In addition, the projection 119 is formed on the outer surface of the inner frame 110 is inserted into the receiving groove 215 formed on the side of the outer frame 210 to be described later when assembled.

An image sensing unit 150 for detecting an image from light transmitted through the inner frame 110 is installed at the bottom of the inner frame 110. The image sensing unit 150 includes an image sensor 125 installed on the printed circuit board 153. In this case, the flexible circuit board 151 is provided at one side to supply power to the image sensor and transmit a signal detected by the image sensor to a controller (not shown). In addition, the edge portion of the printed circuit board 153 may be combined with the protrusion 129a of the lens driver 120 and the printed circuit board 129, which will be described later, and the protrusion 260a of the shutter driver 250, the printed circuit board 260. Grooves 154a and 154b are formed, respectively. In addition, an infrared filter 140 is installed above the image sensor 125.

The lens driving unit 120 is installed on one side of the inner frame 110 as shown in FIGS. 4 and 5 to face the lens assembly 130 and the lens driving coil 122 and the lens driving coil 122. It includes a printed circuit board 129 for applying electricity to.

In addition, a hall sensor 123, which is a position displacement sensor for detecting a position of the lens assembly 130, is installed at the center of the lens driving coil 122. Although the Hall sensor is used as the position displacement sensor in this embodiment, other types of position displacement sensors such as an optical sensor may be used as necessary.

In addition, the outside of the lens driving coil 122 concentrates the electric field of the driving coil 122 and the magnetic field of the permanent magnet 135 of the lens assembly 120 to be described between the driving coil 122 and the permanent magnet 135. The lens driver yoke 126 is installed to make it easy.

Therefore, when a current is applied to the lens driving coil 122, an electric field is generated and a driving force capable of reciprocating the lens assembly 130 in the optical axis direction while interacting with the electric field and the magnetic field of the permanent magnet 135 of the lens assembly 130. This happens.

In addition, the lens driver 120 has a guide portion 124 having a guide groove 124a formed thereon so as to enable reciprocation even with a small driving force of the lens assembly on both sides thereof, and the ball 128 inside the guide groove 124a. ) Is installed to enable the cloud.

The lens assembly 130 has at least one lens installed therein, and adjusts the focal length while reciprocating along the optical axis direction.

A permanent magnet 135 is mounted on one side of the lens assembly 130, and the permanent magnet 135 interacts with the lens driving coil 122 installed in the lens driver 120, and the lens assembly ( The driving force for reciprocating 130 in the optical axis direction is generated.

Here, the lens assembly yoke 134 is installed inside the permanent magnet 135 to form a magnetic path of the permanent magnet 135 and to concentrate the magnetic flux in the direction of the lens driver 120.

Next, as shown in FIGS. 6, 7A, 7B, and 8, the shutter assembly 200 is provided to be fitted along the outer surface of the inner frame 110 and has an opening formed in the optical axis direction. 210, shutter blades 220 and 230 made up of at least one wing installed above the outer frame 210, and the shutter blades 220 and 230 are provided to be rotatable on a plane perpendicular to the optical axis. The shutter driver 250 disposed on the other side of the frame 110, the printed circuit board 260 installed to apply electricity to the shutter driver 250, and the shutter blades 220 and 230 are installed on the shutter blades. Shutter cover 240 to block the 220 and 230 from the outside.

The outer frame 210 is provided to accommodate the inner frame 110, and the assembling protrusions 211 and 212 fitted to the assembling holes 242 of the shutter cover 240 are formed on an upper surface thereof. In addition, a long hole 241 is formed at the corner of the upper surface where the assembly protrusion of the outer frame 210 is not formed so that the driving pin 251a of the shutter driver 250 can be inserted and rotated. In addition, rotation center shafts 213 and 214 are formed at both sides of the long hole 241 to which the installation holes 222 of the shutter blades 220 and 230 are fitted. In addition, the inner side of the upper surface of the shutter drive unit 250, the permanent magnet 251 is formed downward so that the permanent magnet 251 is fitted.

Shutter blades 220 and 230 are provided with at least one wing to adjust the exposure time to the image sensor while opening and closing the passage of the incident light through the light diameter. The shutter blade has an installation hole 222 formed to be rotatably inserted into the rotation center shafts 213 and 214 of the upper surface of the outer frame 210, and the shutter driver 250 is formed at one side of the installation hole 222. The driving pin 251a is inserted into the driving hole 221 for opening and closing the shutter blades is formed.

The shutter driver 250 protrudes outward to form a driving pin 251a and a hollow magnet formed therein, a shutter driving coil 253 formed on one side of the permanent magnet 251, and the shutter. The magnetic path is formed by the current flowing through the driving coil 253, and both ends of the magnetic members 252a and 252b and the shutter driving coil 253 are formed so as to face different poles of the anodes of the permanent magnet 251. A printed circuit board 260 is included.

Referring to the operation of the shutter blades by the shutter driver 250, first, when a current is applied to the shutter driver coil 223, magnetic forces are generated in the magnetic members 252a and 252b so that one side of the N pole and the other of the S pole Different polarities will occur. By the magnetic force, the permanent magnet 251 supported by the permanent magnet rotation center shaft 216 of the outer frame 210 is reciprocated by a predetermined angle. Therefore, the driving pin 251a integrally formed with the permanent magnet 251 rotates, and the shutter blades 220 and 230 fitted to the driving pin 251a are opened or closed by the rotation of the driving pin 251a. do.

In addition, the magnetic holding force of the magnetic members 252a and 252b and the permanent magnet 251 do not need to apply a current to the shutter driving coil 253 when the shutter blade is held in the closed or open position. As a result, the shutter blades 220 and 230 maintain their closed or open positions.

1A is a perspective view illustrating a camera lens assembly for a mobile phone according to the present invention.

Figure 1b is a perspective view from a different direction from Figure 1a showing a camera lens assembly for a mobile phone according to the present invention.

Figure 2 is a perspective view showing a separated state of the autofocus assembly and the shutter assembly according to the present invention.

3 is an exploded perspective view showing a camera lens assembly for a mobile phone according to the present invention.

Figure 4 is a partial cutaway perspective view showing a camera lens assembly for a mobile phone according to the present invention.

5 is a perspective view illustrating a lens driving unit of a camera lens assembly for a mobile phone according to the present invention.

Figure 6 is a partial cutaway plan view showing a shutter assembly of a camera lens assembly for a mobile phone according to the present invention.

Figure 7a is a perspective view showing a closed state of the camera lens assembly shutter drive unit for a mobile phone according to the present invention.

Figure 7b is a perspective view showing the open state of the camera lens assembly shutter drive unit for a mobile phone according to the present invention.

8A is a plan view illustrating a closed state of a shutter driver of a camera lens assembly for a mobile phone according to the present invention.

8B is a plan view illustrating an open state of the camera lens assembly shutter driver for a mobile phone according to the present invention;

9 is a perspective view illustrating a shutter driver of a camera lens assembly for a mobile phone according to the present invention;

Claims (7)

An inner frame forming an inner space and having an opening along the optical axis, a lens assembly installed in the inner space of the inner frame to reciprocate in the optical axis direction, and one side of the inner frame to drive the lens assembly in the optical axis direction An autofocus assembly having a lens driver mounted on the bottom surface of the inner frame, an image sensing unit configured to detect an image transmitted through the opening, and a printed circuit board installed to apply electricity to the image sensing unit; An outer frame provided to be fitted along an outer surface of the inner frame and having an opening formed in an optical axis direction, a shutter blade formed of at least one wing disposed above the outer frame, and the shutter blade perpendicular to the optical axis. A shutter driver disposed on the other side of the inner frame to be rotatable on a plane, a printed circuit board installed to apply electricity to the shutter driver, and an upper portion of the shutter blade to block the shutter blade from the outside Camera lens assembly for a mobile phone with a shutter function characterized in that it comprises a shutter assembly having a shutter cover. The method of claim 1, The printed circuit board of the shutter assembly is coupled to the printed circuit board of the image sensing unit, the camera lens assembly for a mobile phone having a shutter function, characterized in that the installation is connected. The method of claim 1, The camera lens assembly for a mobile phone with a shutter function, characterized in that the autofocus assembly and the shutter assembly can be driven individually. The method of claim 3, The lens driving unit includes a lens driving coil installed on one side of the inner frame facing the lens assembly, and a printed circuit board for applying electricity to the lens driving coil. Lens assembly. The method of claim 1, The lens driving unit of the printed circuit board is a camera lens assembly for a mobile phone having a shutter function, characterized in that the electrical connection is installed to the printed circuit board of the image sensing unit. The method of claim 1, The shutter driver protrudes outward to form a driving pin, and a hollow magnet is formed therein, a shutter drive coil formed on one side of the permanent magnet, and a magnetic path is formed by a current flowing through the shutter drive coil. And a printed circuit board for applying electricity to the shutter driving coil and a magnetic member formed to face different poles of the anodes of the permanent magnets. The method of claim 1, A projection lens is formed on an outer surface of the inner frame or an inner surface of the outer frame, and a receiving groove is formed on the inner surface of the outer frame or the outer surface of the inner frame so that the projection can be detached. assembly.

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