KR20080012423A - Camera module - Google Patents

Abstract

A camera module is provided to enable focus fixing lenses to be successively laminatedly joined in the inside of a barrel-integrated housing and enable a cap with a focus adjustment lens to be joined to the upper end of the barrel-integrated housing, thereby reducing significantly a defect caused by a foreign substance according to the sensitivity deterioration of a foreign substance by the maximizing of an interval between an image sensor mounted on the lower end of the housing and the focus adjustment lens. A camera module(100) comprises a barrel-integrated housing(110), a cap(120) and a PCB(Printed Circuit Board)(130). The barrel-integrated housing has openings(114a) in the upper and lower end portions. The cap is joined to the upper end of the housing. The PCB has an image sensor mounted in the center portion and is closely attached to the opening portion of the lower end of the housing. At least one focus fixing lens(115) are laminatedly joined to the inside of the housing.

Description

Camera module

1 is a schematic cross-sectional view of a camera module assembled in a conventional COB method.

Figure 2 is an exploded perspective view of a conventional COB camera module.

3 is an assembled perspective view of the camera module assembled in a COF method.

4 is an assembled perspective view of the camera module according to the present invention.

5 is a cross-sectional view of the camera module according to the present invention.

<Explanation of symbols for the main parts of the drawings>

110. Housing 115. Focus Lock Lens

120.Cap 121.Focus lens

130. Printed circuit board 131. Image sensor

The present invention relates to a camera module using a barrel-integrated housing, and more particularly, to a camera module in which an adjustment lens is incorporated into an upper portion of a barrel-integrated housing in which a fixed lens is stacked and coupled to adjust focus by rotation of the cap. It is about.

Nowadays, portable terminals such as mobile phones and PDAs are being used as a multi-convergence with music, movies, TV, and games as well as simple telephone functions with the development of the technology. The camera module is the most representative. The camera module is being changed from the existing 300,000 pixels (VGA level) to the high pixel center of more than 8 million at the same time, and is being changed to implement various additional functions such as auto focusing (AF) and optical zoom.

In general, the compact camera module (CCM) is a compact and is applied to various IT devices such as a camera camera, a portable mobile communication device such as a PDA, a smart phone, and a toy camera. Increasingly, devices equipped with small camera modules are gradually being released to meet various consumer tastes.

Such a camera module is manufactured using an image sensor such as a CCD or a CMOS as a main component, and collects an image of an object through the image sensor and stores it as data in a memory in the device, and the stored data is stored in the LCD or PC in the device. The image is displayed through a display medium such as a monitor.

The packaging method of an image sensor for a camera module is a flip-chip (Chip On Flim) method, a wire bonding method of a Chip On Board (COB) method, a CSP (Chip Scaled Package) method, etc. Among them, a COF package method and a COB package method are widely used.

1 is a schematic cross-sectional view of a camera module assembled in a conventional COB method, Figure 2 is an exploded perspective view of the camera module of the conventional COB method.

In the conventional camera module 1, a printed circuit board 1 having an image sensor 2 of a CCD or CMOS mounted by wire bonding is coupled to a lower part of a housing 3 made of plastic, and extends above the housing 3. The barrel 6 is manufactured by coupling the barrel 6 in which the cylindrical body 5 extends downward.

The camera module 1 is coupled to the housing 3 and the barrel 6 by screwing the female screw portion 4a formed on the inner circumferential surface of the barrel 4 and the male screw portion 5a formed on the outer circumferential surface of the cylindrical body 5. do.

In this case, an IR cut-off filter (hereinafter referred to as an 'IR filter') is formed between the upper surface of the printed board 1, that is, the lens L mounted on the lower end of the barrel 6 and the image sensor 2. (8) is combined to block the infrared rays of excessive long wavelength flowing into the image sensor (2).

In the camera module assembled as described above, light flowing from a specific object passes through the lens L, and the image is inverted to focus on the surface of the image sensor 2, where the screw is coupled to the upper end of the housing 3. While rotating the barrel 6, the adhesive is injected between the housing 3 and the barrel 6 at the point where the optimal focus is achieved, and the housing 3 and the barrel 6 are adhesively fixed to the final camera module product. In the conventional camera module, the barrel 6 and the housing 3 are coupled to each other by a corresponding rotational structure of the female and male threads 4a and 5a to perform the assembly and focusing processes of the module. You lose.

On the other hand, Figure 3 is an assembling perspective view of a camera module assembled in a COF method, as shown, the conventional camera module 20 is an image sensor 13 for converting the image signal entered through the lens into an electrical signal on the bottom In the sequential coupling of the support housing 12, the lens group 14 for collecting the image signal of the subject to the image sensor 13, and the barrel 15 in which the lens group 14 is stacked in multiple stages It is configured by

The conventional camera module 20 configured as described above has an anisotropic conductive film between the flexible printed circuit board 16 and the image sensor 13 in a state where a plurality of circuit components are mounted on the flexible printed circuit board FPCB 16. An anisotropic conductive film (ACF) 18 or a non-conductive paste (NCP) is inserted and adhesively fixed so as to be energized by applying heat and pressure, and the IR filter 17 is attached to the opposite side.

In addition, as described above in the state in which the barrel 15 in which the plurality of lens groups 14 are built and the housing 12 are temporarily coupled by screwing, the pre-assembled flexible printed circuit board 16 includes the housing 12. It is adhesively fixed to the bottom of the sheet by a separate adhesive.

Meanwhile, a fixed distance of the subject (resolution chart) in front of the barrel 15 after the adhesive fixing of the flexible printed circuit board 16 to which the image sensor 13 is attached and the housing 12 to which the barrel 15 is coupled is fixed. The focus adjustment of the camera module 20 is performed by adjusting the vertical feed amount by the rotation of the barrel 15 screwed to the housing 12, thereby adjusting the lens group 14 and the image sensor. (13) focusing is achieved.

As such, when assembling the camera module represented by the COB and COF packaging methods, the housings 3 and 12 and the barrels 6 and 15 are commonly separated into separate members, so that the barrels 6 and 15 It is difficult to manufacture a mold for forming the female and male threads 4a and 5a on the outer circumferential surface and the inner circumferential surface of the housings 3 and 12, and the female and male threads 4a and 5a are formed at a predetermined angle. Because of the inclination, the optical axis for the plurality of lenses L stacked in the barrels 6 and 15 upon rotational coupling of the housings 3 and 12 and the barrels 6 and 15 along the threads is defined as There is a problem that it is difficult to focus precisely because it can not be tilted by the inclined angle.

In addition, when the housings 3 and 12 and the barrels 6 and 15 are vertically coupled, when the female and male threads 4a and 5a are engaged at the wrong angle, the threads are crushed or the female and male threads 4a are engaged. The fine particles generated by the wear of the joining portion by friction of the 5a drop directly on the top surface of the IR filter 8 or the image sensor 2 and 17, thereby increasing sensitivity to foreign materials. There is a disadvantage that the foreign matter defect rate is significantly increased.

Therefore, the present invention was devised to solve the above-mentioned disadvantages and problems occurring when assembling a conventional camera module, and a housing in which a plurality of fixed lenses are sequentially stacked and coupled is configured as a barrel-integrated body, and for focusing at an upper end of the housing The lens-mounted cap is coupled to allow the module to be adjusted by the rotation of the cap, thereby reducing sensitivity to foreign objects as the gap between the image sensor and the focusing lens positioned at the lower end of the housing is maximized. It is an object of the invention to provide a camera module that is to reduce the defect caused by foreign objects.

The object of the present invention includes a barrel integrated housing having openings at upper and lower portions, a cap coupled to an upper end of the housing, and a printed circuit board mounted at a lower opening of the housing by mounting an image sensor at a central portion thereof. Is achieved by a camera module structure.

The housing is injection molded while the barrel is integrally formed and extended upward, and a plurality of focusing lenses, a pressing ring, and a spacer for maintaining a gap between the lens and the lens are embedded therein.

In addition, the inner peripheral surface of the barrel extending to the upper portion of the barrel is provided with a female screw portion, through the upper opening is a cap coupled to the focus adjustment lens therein is screwed.

At this time, the cap coupled to the upper opening of the housing is rotated within a predetermined range so that the distance between the focus adjusting lens therein and the image sensor mounted on the printed circuit board mounted on the bottom of the housing is adjusted, thereby reducing the distance between the camera module. The focus is adjusted, and when the focus of the lens is completed, the assembly of the camera module is completed as the adhesive is injected and cured between the cap and the barrel at the top of the housing.

Accordingly, the distance between the focusing lens mounted inside the cap and the image sensor coupled to the lowermost end of the housing is maximized, and the fixed lens mounted with the foreign material that may be generated at the coupling interface when the housing and the cap are coupled to each other. As it is blocked by the inflow to the image sensor and the IR filter, it is advantageous to the foreign material defect management, which is the first priority of the cause of the camera module assembly failure.

Matters relating to the operational effects including the technical configuration of the camera module according to the present invention will be clearly understood by the following detailed description with reference to the drawings showing preferred embodiments of the present invention.

First, Figure 4 is an assembled perspective view of the camera module according to the present invention, Figure 5 is a cross-sectional view of the camera module according to the present invention.

As shown, the camera module 100 of the present invention, the housing 110 is formed integrally with the barrel 111, the cap 120 is coupled to the upper end of the housing 110, the housing 110 of It is composed of a printed circuit board 130 is tightly fixed to the bottom.

The housing 110 has a cylindrical barrel 111 extending upward and at least one focusing lens 115 is stacked and coupled therein, and the lens 115 mounted in the housing 110 is made of an elastic material. While maintaining a predetermined interval by the spacer (S) of the tightly coupled by the indentation ring 113.

In addition, the housing 110 has a lower end and an upper end of the barrel 111 extending upwards are formed as openings 114a and 114b so that the lower portion of the cap 120 is coupled through the upper opening 114a. After the lens 115 is inserted through the lower opening 114b, the printed circuit board 130 on which the image sensor 131 is mounted is mounted.

In this case, the image sensor 131 is mounted to the center of the printed circuit board 130 to be electrically connected by wire bonding or flip chip bonding.

The cap 120 coupled through the upper opening 114a of the housing 110 has a male screw portion 122 formed on an outer circumferential surface of the lower extension portion, and a focus adjusting lens 121 is inserted into the barrel 111. It is tightly coupled to the upper end of the housing 110 by screwing with the female screw 112 provided on the inner circumferential surface.

The cap 120 is rotated and moved up and down within a predetermined range at the top of the housing 110, and an image sensor 131 coupled to the focus adjusting lens 121 inside the cap 120 and the lower portion of the housing 110. Adjust the focal length (EFL) by adjusting the interval Here, the focus adjusting lens 121 mounted inside the cap 120 is preferably composed of an aspherical lens whose focal length EFL is variable as it is rotated by itself, and the focus fixing lens 115 in the housing 110. Similarly, the cap 120 is tightly fixed by the press-fit ring 123.

In this case, the rotation of the cap 120 may be manually rotated by a worker or mounted on a jig provided in an automated device to be driven to rotate. The height of the cap 120 for adjusting the focus of the camera module may be controlled. It is preferable that the cap 120 is mounted on a separate jig that is horizontally coupled and adjusted as it should be flowed within a fine range within approximately 30-50 μm.

In the camera module 100 of the present invention configured as described above, the housing 110 and the screw coupling portion of the cap 120 are positioned above the lens 115 tightly coupled in the housing 110. Particles generated during rotational coupling of the cap 120 and the cap 120 are not directly dropped on the upper surfaces of the image sensor 131 and the IR filter 132 mounted inside the bottom of the housing 110.

Therefore, foreign matter defects caused by particles adsorbed to the IR filter 132 and color spot defects such as black spots caused by foreign matters falling on the upper surface of the image sensor 131 are prevented.

In addition, the focus adjusting lens 121 mounted in the image sensor 131 mounted on the printed circuit board 130 coupled to the lower end of the housing 110 and the cap 120 coupled to the upper end of the housing 110. The focus is adjusted by adjusting the distance between the and the bar. Since the distance between the image sensor 131 and the focus adjusting lens 121 can be maximized, the influence on the foreign matter adsorbed to the lens 121 is minimized. There is a technical feature in that the defective inspection rate is lowered.

Preferred embodiments of the present invention described above are disclosed for the purpose of illustration, and various substitutions, modifications, and changes within the scope without departing from the spirit of the present invention for those skilled in the art to which the present invention pertains. It will be possible, but such substitutions, changes and the like should be regarded as belonging to the following claims.

As described above, in the camera module of the present invention, the focusing lens is sequentially stacked and coupled to the inside of the barrel-integrated housing, and the cap mounted with the focusing lens is coupled to the upper end thereof, thereby the image mounted on the lower end of the housing. As the sensitivity of the foreign material is lowered by maximizing the gap between the sensor and the focusing lens, the foreign material defect may be significantly reduced.

In addition, since the barrel is integrally formed with the housing, a separate component for mounting the lens is unnecessary, and thus, the coupling process between the housing and the barrel is eliminated, thereby reducing the number of parts and shortening the man-hour. The effect is expected to lower the cost of manufacturing.

Claims (6)

A barrel integrated housing having openings at upper and lower ends thereof; A cap coupled to the top of the housing; A printed circuit board having an image sensor mounted on a central portion thereof and tightly coupled to a lower opening of the housing; Camera module comprising a. The method of claim 1, The housing, the camera module, characterized in that the at least one focusing lens is coupled to the inside. The method of claim 1, The cap is a camera module, characterized in that the aspherical focusing lens fixed to the press-fit ring therein. The method of claim 1, The cap is a camera module, characterized in that the screw is inserted through the top opening of the barrel-integrated housing formed by the male screw portion formed on the outer peripheral surface and the female screw portion of the barrel inner peripheral surface. The method of claim 1, The image sensor is a camera module, characterized in that mounted in the center of the printed circuit board by wire bonding or flip chip bonding. The upper opening of the barrel-integrated housing in which the focus fixing lens is laminated and coupled therein is screwed by a female screw formed on the outer circumferential surface of the cap on which the focus adjusting lens is mounted and a male screw formed on the inner circumferential surface of the housing. The printed circuit board in which the sensor is mounted at the center is covered, and the distance between the focusing lens and the image sensor is adjusted by adjusting the height by the rotation of the cap. Camera module characterized in that adjusted.

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