KR101960343B1 - Camera lens module - Google Patents

Abstract

A camera lens module of a portable terminal is disclosed. The disclosed camera lens module comprises an outer case; An actuator disposed in the outer case for correcting an unintentional hand movement of the lens or moving the lens along an optical axis; A sensor unit coupled to the outer case so as to face the actuator; And a device that is disposed to be exposed to the outside of the outer case and that is coupled with the external alignment device after assembling the camera lens module to hold the alignment position of the actuator .

Description

Camera lens module {CAMERA LENS MODULE}

An embodiment of the present invention relates to a portable terminal, and more particularly, to a miniaturized camera lens module provided in a portable terminal.

2. Description of the Related Art [0002] In recent years, mobile telephones such as smart phones, which are becoming popular due to the development of mobile communication technology, have become smaller and lighter.

Particularly, a camera lens module used in a portable terminal requires a high capacity and high performance, and a camera lens module compliant with a digital camera (DSLR) class has been actively developed. Furthermore, the camera lens module is being developed in a direction favorable to miniaturization and weight saving while maintaining a high performance high capacity.

The camera lens module used in the portable terminal is equipped with an auto-focusing function, a zoom function, and the like, and is provided with a stabilizer for stabilizing the camera function. Such a camera lens module generally comprises a lens system, a lens driving unit for moving the lens system in the direction of the optical axis to provide a moving force for adjusting the focus, and an image sensor for imaging the light incident through the lens system and converting the light into an image signal .

As an example of a conventional camera lens module mounted on a portable terminal, there are Korean Patent Application No. 2010-0106811 and Korean Patent Application No. 2009-083613.

However, since the portable terminal continues to be miniaturized while maintaining high functionality, the mounted camera lens module also needs to be further miniaturized while maintaining high performance, and it is necessary to improve the product reliability by improving the alignment. It is necessary to improve the assemblability considering the cost.

Korean Public Patent No. 2012-0045333 (Released May 5, 2012) Korean Patent Publication No. 2011-0025512 (published on Mar. 10, 2011)

Accordingly, it is an object of the present invention to provide a camera lens module with improved active alignment.

In order to solve the above problems, an embodiment of the present invention includes an outer case; An actuator disposed in the outer case for correcting an unintentional hand movement of the lens or moving the lens along an optical axis; A sensor unit coupled to the outer case so as to face the actuator; And a device that is disposed to be exposed to the outside of the outer case and that is coupled with the external alignment device after assembling the camera lens module to hold the alignment position of the actuator .

As described above, in the embodiment of the present invention, after assembling the camera lens module, the focal distance and the tilting state between the lens and the image sensor are actively aligned using an external six-axis aligning device, and the alignment state is fixed , Improving the resolution of the image sensor due to the improved alignment.

1 is a plan view schematically showing a camera lens module employing a driving device.
FIG. 2A and FIG. 2B are exploded perspective views sequentially showing the configuration of a camera lens module employing a driving device along an optical axis; FIG.
FIGS. 3 and 4 are assembly perspective views each showing a camera lens module employing a driving device. FIG.
5 is a perspective view showing a state in which a camera lens module employing a driving device is cut in a longitudinal direction.
6 is a perspective view showing a state in which a camera lens module employing a driving device is cut in a lateral direction.
7 is a plan view schematically showing a camera lens module employing a driving device.
Figs. 8 and 9 are assembly perspective views each showing a camera lens module employing another driving device. Fig.
10 is a plan view schematically showing a camera lens module employing another driving device.
11 is an assembled perspective view showing a camera lens module employing another driving device.
12 is an exploded perspective view showing a configuration of a camera lens module according to an embodiment of the present invention.
13 is an assembled perspective view illustrating a camera lens module according to an embodiment of the present invention.
14 is a side view of Fig.
FIG. 15 is an assembled perspective view showing a camera lens module according to an embodiment of the present invention, showing a state in which the outer case is removed. FIG.

The following description, which refers to the accompanying drawings, is provided to assist in an overall understanding of embodiments of the invention as defined by the claims and the equivalents thereof. While this includes various specific details to facilitate such understanding, they are to be regarded merely as illustrative. Accordingly, those skilled in the art will recognize that various changes and modifications of the embodiments described herein may be made without departing from the scope and spirit of the invention. In addition, the description of known functions and configurations is omitted for clarity and brevity.

Hereinafter, the configuration of the driving device of the camera lens module 10 will be described with reference to FIGS. 1 to 6. FIG.

The present invention can be applied to a mobile phone, a palm sized personal computer (PC), a personal communication system (PCS), a personal digital assistant (PDA), a personal digital assistant ), A hand-held PC (HPC), a smart phone, a wireless LAN (Local Area Network) terminal, a laptop computer, a netbook, a tablet PC and the like. Accordingly, the use of the term " portable terminal " should not be used to limit the application of the present invention to a particular type of device.

1 to 6 illustrate a three-dimensional X / Y / Z coordinate system. The 'Z axis' refers to the optical axis along which the lens barrel 102 moves in the vertical direction of the camera lens module, Means the horizontal direction (vertical direction of the optical axis) of the lens module, and the 'Y axis' means the vertical direction (vertical direction of the optical axis, vertical direction of the X axis) of the camera lens module. The AF (Automatic Focus) driver 11 provides a force for moving the lens carrier 103 along the optical axis, and the OIS (Optical Image Stabilizer) drivers 12 and 13 drive the OIS carrier 104 (Hand movement state correction) centering on the optical axis of the camera (not shown).

Referring to Figs. 1 to 6, the driving device 10 of the camera lens module (hereinafter referred to as " module ") will be described in detail. It should be noted that the module to be described below seeks for miniaturization and improvement in assemblability, and in particular, seeks to minimize magnetic field interference.

The driving unit 10 includes a polyhedron type exterior case 100 + 101, a lens system 102 + 103 (lens system) guided along the optical axis in the external case 100 + 101, An AF driver 11 arranged in parallel along the first face 100a of the case 100 + 101 to move the lens system 102 + 103 and an OIS carrier in which the lens system 102 + One or more OIS driving units 12 and 13 arranged along the other surface of the first surface 100a for correcting the balanced state of the lens system 102 + (OIS) position sensing unit (14, 15) mounted on the other side.

The outer case 100 + 101 has a polyhedral shape, in particular, a substantially rectangular parallelepiped shape, and the upper and lower surfaces are substantially square, and the four side surfaces 100a-100d are substantially rectangular. Accordingly, the outer case 100 + 101 has four side surfaces, which will be referred to as first, second, third, and fourth surfaces 100a-100d. The outer surface of the outer case is referred to as a second surface 100b on the opposite side of the first surface 100a and the other surface between the first and second surfaces 100a and 100b is referred to as a third surface 100c And the other side opposite to the third surface 100c is referred to as a fourth surface 100d. The first, second, third, and fourth surfaces 100a-100d are perpendicular to each other.

3 and 4, the OIS carrier 104 is mounted to the first and second OIS driving units 12 and 13 and the first and second OIS position sensing units 14 and 15, First, second and third openings 1041-1043 are respectively formed on the second, third and fourth surfaces 104b-104d facing the second, third and fourth surfaces 100b-100d of the outer case respectively . The first, second and third openings 1041-1043 are formed on the bottom (bottom) of the second, third, and fourth surfaces 104b-104d. The first, second and third openings 1041 to 1043 extend in one direction. The first, second and third openings 1041 to 1043 extend in one direction. The first and second OIS driving units 12 and 13 and the first and second OIS position sensing units 14 and 15, respectively. Further, the OIS carrier has an opening 1040 formed in the first surface. The aperture 1040 is formed in the AF driving unit so that the AF magnet mounted on the lens barrel to be described later is directly faced to the AF coil and the AF position sensing unit and the AF coil and the AF position sensing unit are formed do.

As shown in FIGS. 2A and 2B, the outer case 100 + 101 is a non-magnetic material, and functions as a housing for protecting the components received from the outside while accommodating the remaining components. In the outer case 100 + 101, the two circuit boards 106 and 108 are electrically connected to an external power source (not shown). One circuit board portion 106 extends from the OIS circuit board, and the other circuit board portion 108 is an image sensor circuit board 108. The outer case is formed by combining the upper case 100 and the sensor base 101. The outer case 100 + 101 need not be limited to a rectangular parallelepiped, but may be formed in a cubic shape depending on the mounting arrangement of the inner parts, and may have a polygonal shape of a pentagonal columnar shape or a hexagonal columnar shape. Reference numeral 109 denotes an end portion of the image sensor substrate.

The lens system includes a lens barrel 102 having a lens (not shown), and a lens carrier 103 which houses the lens barrel 102 and moves together along the optical axis. The lens barrel 102 is cylindrical and moves along the optical axis by the AF driving unit 11 while being completely housed in the lens carrier 103. The lens carrier 103 is completely accommodated in the lens barrel 102 and has a flat rectangular magnet mounting groove (not shown) on the outer circumferential surface thereof. The lens carrier 103 is guided along the optical axis by a pair of guide devices. The pair of guide devices includes known guide portions g1 and g2 and ball bearings b1 and b2 received in the guide portions g1 and g2 and performing rolling motion, respectively. The lens barrel 102 may be formed in a structure or an integral structure that can be separated and combined with the lens carrier 103.

The AF driver 11 includes a single AF driver. The OIS drivers 12 and 13 may be disposed on the other surface of the first surface on which the AF driver 11 is located, and two or more OIS drivers 12 and 13 may be disposed . Further, the OIS driver may be disposed at both edges of the AF driver.

Hereinafter, the configuration of the first and second OIS drivers 12 and 13 will be described in detail. The OIS carrier 104 is supported by an OIS base 107 located at the bottom. The first and second OIS drivers 12 and 13 are respectively disposed between the OIS base and the second and third surfaces 104b and 104c of the OIS carrier 104 facing the second and third surfaces of the outer case, Or at the corners between the surfaces to correct the unintentional hand movement of the OIS carrier 104. [ The OIS driver includes a first OIS driver 12 disposed along an OIS carrier second surface 104b on the opposite side of the OIS carrier first surface 104a and a second OIS driver 12 disposed between the first and second surfaces 104a and 104b And a second OIS driver 13 disposed along the OIS carrier third surface 104c in the second OIS carrier. The OIS position sensing unit includes first and second OIS position sensing units 14 and 15 arranged along the fourth surface 104d of the OIS carrier on the opposite side of the third surface 104c. The AF driver 11 and the first OIS driver 12 are opposed to each other and the second OIS driver 13 and the first and second OIS position sensors 14 and 15 face each other.

The first OIS driver 12 is arranged in parallel with the second surface 104b and extends in one direction. The second OIS driver 13 has an elongated shape extending in one direction, And the first and second OIS position sensing units 14 and 15 are arranged in parallel to each other along the third surface 104c. The first and second OIS position sensing units may be arranged in parallel along the fourth surface to control the first and second OIS driving units respectively using the sensed position signals.

The AF driver 11 is mounted between the lens carrier 103 and the OIS carrier 104 in an erect manner and the first and second OIS drivers 12 and 13 are disposed between the OIS base 107 and the OIS carrier 104 The first and second OIS position sensing units 14 and 15 are mounted on the OIS base 107 and the OIS base 107, respectively, And the fourth surface 104d of the OIS carrier, respectively.

The first OIS driver 12 includes a first OIS magnet m2 disposed sideways in a direction parallel to the OIS carrier second surface 104b and a second OIS magnet m2 disposed on the OIS base 107, And a first OIS coil c2 arranged to face the OIS magnet m2. The second OIS driver 13 includes a second OIS magnet m3 which is disposed in a parallel manner along the third surface 104c of the OIS carrier and a second OIS magnet m3 disposed on the OIS base 107, And a second OIS coil c3 arranged to face the second OIS magnet m3.

The term " noyin stays " mentioned above means that the upper surface (the largest surface area) of the elongated plate-shaped first and second OIS magnets m2 and m3 is arranged in parallel with the XY plane. In addition, the upper and lower surfaces of the first and second OIS coils c2 and c3, which are substantially elongated, are arranged parallel to the XY plane. In addition, the upper and lower surfaces of the plate-shaped first and second OIS position sensing units 14 and 15 are arranged parallel to the XY plane. It is easy to assemble the module, but it can also be assembled in the upright form, because the magnet or the coil is mounted while being sideways than the upright state.

The first OIS position sensing unit 14 includes a first OIS position sensing magnet m4-1 arranged to be tilted in a parallel direction along the fourth surface 104d of the OIS carrier, And a first OIS position sensing sensor h2 arranged to face the first OIS position sensing magnet m4-1. The second OIS position sensing unit 15 includes a second OIS position sensing magnet m4-2 disposed in a parallel direction along the fourth surface 104d of the OIS carrier, And a second OIS position sensing sensor (h3) arranged to face the second OIS position sensing magnet (m4-2). The first and second OIA position sensors h2 and h3 include Hall sensors. The first OIS position sensing magnet (m4-1) and the second OIS position sensing magnet (m4-2) are arranged so that their magnetization directions are perpendicular to each other, so that all of the vertical (X, Y axis) Can be detected.

The AF driving unit 11 is a driving unit that is disposed between one surface of the outer case 100a facing one another and one side of the lens carrier 103 and moves the lens carrier 103 along the optical axis. The AF driving unit 11 includes an AF magnet m1 mounted on the outer circumferential surface of the lens carrier 103 in parallel with the one surface of the case and an AF coil m1 disposed on one surface of the OIS carrier facing the AF magnet m1 (c1), an AF position sensor disposed at an opening in the AF coil (c1), an AF driving IC (IC) arranged next to the AF coil (c1) (Y). The AF yoke y may be located on one side of the OIS carrier where the AF coil c1 is located. When the current is applied to the AF coil c1, the lens barrel 102 moves along the optical axis by the electromagnetic force generated between the AF coil c1 and the AF magnet m1, The distance is automatically adjusted. The AF position sensor may include a Hall sensor, and may be formed integrally with a driving IC (IC), and the AF position sensor and the driving IC may be located inside or outside the AF coil.

That is, the AF driving unit 11 is configured such that the AF coil c1 or the AF magnet m1 is exposed to one surface of the outer case 100 + 101 so as to face one opening of the OIS carrier 104, The lens carrier 103 can be driven independently of the OIS carrier 104 along the optical axis by being mounted so that the inner surface of the outer case and the AF coil c1 or the AF magnet m1 are opposed to each other. As a result, the module can be driven by AF and OIS with minimized volume and driving force.

The AF driver 11 further includes an AF circuit board 105 disposed at an upper end of the OIS carrier 104. The first and second OIS drivers 12 and 13 are disposed on the OIS base 16 And an OIS circuit board 106 formed on the substrate. The AF circuit substrate 105 and the OIS circuit substrate 106 are made of a flexible material. The AF circuit substrate 105 and the OIS circuit substrate 106 are arranged in parallel to each other at the upper and lower ends in the direction perpendicular to the optical axis, and are opposed to each other. The AF circuit substrate 105 and the OIS circuit substrate 106 are substantially square in shape and each have four corners. The AF circuit substrate 105 and the OIS circuit substrate 106 are fixedly connected to the respective laterally-formed suspension wires.

The AF and OIS circuit boards 105 and 106 are electrically connected by at least one suspension wire w. That is, the suspension wire w functions to electrically connect the AF flexible circuit board 105 and the OIS flexible circuit board 106, and the AF flexible circuit board 105 and the OIS flexible circuit board 106, Lt; / RTI > Of course, the suspension wire w is a conductor, has elasticity, and is linear. The suspension wires (w) are formed of four pieces, and each of the wires (w) is disposed upright in four corner areas of the OIS carrier. Each of the suspension wires w is installed upright along the optical axis, and the upper end thereof is fixedly connected to the AF flexible circuit board 105, and the lower end thereof is fixedly connected to the OIS flexible circuit board 106. To this end, four AF corners of the AF flexible circuit board 105 are provided with solder holes, and four corners of the OIS flexible circuit board 106 are provided with solder holes. Also, the suspension wire (w) passes through the four corners of the OIS carrier (104).

Preferably, the OIS circuit board 106 is disposed between the OIS carrier 104 and the OIS base 107.

2B, reference character 'f' designates an 'IR filter', and reference character 's' designates an 'image sensor'.

The first OIS magnet m2 and the first OIS coil c2 constituting each of the first OIS driver 12 may be disposed at different positions and the second OIS driver 13 The arrangement of the second OIS magnet m3 and the second OIS coil c3 constituting each other can be changed. In other words, each of the first and second OIS magnets m2 is disposed in the OIS base image 111, and each of the first and second OIS coils c2 is disposed in the OIS carrier first and second openings 14 Can be located.

In the camera lens module, four suspension wires (w) are used to connect the AF flexible circuit board 105 and the OIS flexible circuit board 106. Instead of the suspension wires, the AF flexible circuit board and the OIS flexible circuit board The circuit board can be electrically connected by using a separate flexible circuit board.

Further, the AF magnet and the AF coil constituting the AF driver of the module can be replaced with piezoelectric elements.

Hereinafter, the driving unit 20 of another camera lens module will be described. Fig. 7 is a plan view schematically showing a camera lens module in which the other drive device 20 is employed. 8 and 9 are assembly perspective views each showing a camera lens module employing another driving device. The driving device 20 is different from the driving device 10 in that the first and second OIS driving parts 22 and 23 and the first and second OIS driving parts 22 and 23, 2 OIS position sensing units 24 and 25, and the remaining components are the same. Therefore, in order to avoid redundant substrate, the first and second OIS driving units 22 and 23, (24, 25) will be described.

The driving unit 20 includes a polygonal outer case 200, a lens system 202 + 203 guided along the optical axis in the outer case 200, and a lens system 202 + An AF driver 21 for moving the lens system 202 + 203, an OIS carrier 204 for receiving the lens system 202 + 203, And one or more OIS driving units 22 and 23 and OIS position sensing units 24 and 25 arranged to correct the balanced state of the lens system with mutual resultant forces. The OIS driver includes a first OIS driver 22 disposed along a second surface 200b opposite to the first surface 200a and a second OIS driver 22 disposed between the first and second surfaces 200a and 200b. And a second OIS driver 23 disposed along the third surface 200c. The OIS position sensing unit includes a first OIS position sensing unit 24 disposed along with the first OIS driving unit 22 along the second surface 200b and a second OIS position sensing unit 24 disposed on the opposite side of the third surface 200c And a second OIS position sensing unit 25 disposed along the fourth surface 200d.

The AF driving unit 21 faces the first OIS driving unit 22 and the first OIS position sensing unit 24 while the second OIS driving unit 23 faces the second OIS position sensing unit 25. [ To face each other. Preferably, the first OIS position sensing unit 24 is disposed apart from the second OIS position sensing unit 25, and is disposed on the left side of the first OIS driving unit 22 (reference to FIG. 7) .

8 and 9, the OIS carrier 204 is supported by an OIS base 207 located at the bottom.

The AF driving unit 21 is installed upright along the first surface 200a and the first OIS driving unit 22 and the first OIS position sensing unit 24 are mounted on the lower surface 200b along the second surface 200b. And the second OIS position sensing unit 25 is mounted on the fourth OIS position sensing unit 25 while the second OIS position sensing unit 25 is mounted on the fourth OIS position sensing unit 25, And is mounted on the lower portion along the surface 200d.

Specifically, the first OIS driver 22 includes a first OIS magnet 220 disposed sideways in a parallel direction along an OIS carrier second surface 204b facing the second surface 200b, And a first OIS coil 222 disposed in the OIS base 207 and disposed facing the first OIS magnet 220. The second OIS driver 23 includes a second OIS magnet 230 which is disposed in a parallel manner along a third surface 204c of the OIS carrier facing the third surface 200c, 207 and a second OIS coil 232 disposed facing the second OIS magnet 230.

The first OIS position sensing unit 24 includes a first OIS magnet 220 which is disposed on the OIS base 207 and faces the first OIS magnet 220, And a poison detection sensor 240. The second OIS position sensing unit 25 includes a second OIS position sensing magnet 250 disposed sideways in a direction parallel to the fourth OIS carrier face 204d facing the fourth face 200d, And a second OIS position sensing sensor 252 disposed on the OIS base 207 and arranged to face up and down with the second OIS position sensing magnet 250.

Preferably, the first and second OIS position sensing magnets 220 and 230 are different in length and the first OIS position sensing magnet 220 is longer than the second OIS position sensing magnet 230. Since it shares a part of the first OIS magnet 220.

Preferably, the first OIS driver 22 and the first OIS position sensor 24 are not disposed at the center of the second surface 204b, and the second OIS driver 23 and the second OIS driver 24 The OIS position sensing unit 25 is disposed at the center of the third and fourth surfaces 204c and 204d, respectively.

At this time, the OIS carrier 204 has first, second and third openings 2041, 2042 and 2043 under the second, third and fourth surfaces 204b, 204c and 204d, respectively, And a first OIS position sensing unit 24 are mounted and the second OIS driving unit 23 and the second OIS position sensing unit 25 are mounted. Each of the first, second and third openings 2041, 2042 and 2043 is elongated in one direction. On the other hand, in the driving device 20, the OIS coil and the OIS magnet can be arranged at different positions.

Hereinafter, the driving device 30 of another camera lens module will be described. 10 is a plan view schematically showing a camera lens module in which another driving device 30 is employed. 11 is an assembled perspective view showing a camera lens module in which another driving device 30 is employed.

1, the first and second OIS driving units 32, 32 constituting the driving unit 30 are different from the driving unit 10 shown in FIG. 1, 33 and the first and second OIS position sensing units 34, 35 are the same as those of the first and second OIS position sensing units 34, 35, Only the configuration of the 2 OIS position sensing units 34 and 35 will be described.

The driving device 30 includes a polygonal outer case 300, a lens system 302 + 303 guided along the optical axis in the outer case 300, and a lens system 302 + 303 arranged along the outer case first surface 300a An AF driver 31 for moving the lens system 302 + 303; an OIS carrier 304 for receiving the lens system 302 + 303; And one or more OIS driving units 32, 33 and OIS position sensing units 34, 35 for correcting the balance state of the lens system 302 + 303 with mutual resultant forces.

The OIS driver includes a first OIS driver 32 disposed along a second surface 300b opposite to the first surface 300a and a third OIS driver 32 disposed between the first and second surfaces 300a and 300b. And a second OIS driver 33 disposed along the surface 300c. The OIS position sensing unit includes a first OIS position sensing unit 34 disposed along with the first OIS driver 31 along the second surface 300b and a second OIS position sensing unit 34 disposed along the third surface 300c, And a second OIS position sensing part 35 disposed together with the driving part 32.

The AF driving unit 31 is mounted upright along the first surface 300a in the outer case and the first OIS driving unit 32 and the first OIS position sensing unit 34 are mounted on the second surface 300b And the second OIS driver 33 and the second OIS position sensor 35 are mounted on the lower surface of the second surface 304b along the OIS carrier second surface 304b, And are respectively mounted on the lower surface of the third surface 304c along the third surface 304c of the OIS carrier facing the third surface 300c.

Specifically, the first OIS driver 32 includes a first OIS magnet 320, which is disposed in the parallel direction along the second surface 304b, and a second OIS magnet 320 disposed on the OIS base 307, 1 < / RTI > OIS magnet 320, as shown in FIG. The second OIS driving unit 33 includes a second OIS magnet 330 arranged to be tilted in the parallel direction along the third surface 304c and a second OIS magnet 330 disposed on the OIS base 307, And a second OIS coil 332 arranged to face the second OIS coil 330. [

The first OIS position sensing unit 34 is disposed in the OIS base 307 and shares the first OIS magnet 320. The first OIS position sensing unit 34 includes a first OIS magnet 321, And a sensing sensor 342. The second OIS position sensing unit 35 may include a second OIS position sensing unit 35 that shares the second OIS magnet 330 and is disposed in the OIS base 307 and has a second OIS position And a sensing sensor 352.

Preferably, the first and second OIS magnets 320 and 330 are equal in length to each other, and each of the first and second OIS magnets 320 and 330 is shared by the magnets of the first and second OIS position sensing units 34 and 35.

The first OIS driver 32 and the first OIS position sensor 34 are not disposed at the center of the second surface 304b but are located at the center of the second OIS driver 33 and the second OIS position sensor 34. [ The portions 35 are not disposed at the center of the third surface 304c. This is because some of the first and second OIS magnets are shared.

The OIS carrier 304 has first, second and third surfaces, the first surface (not shown) means a surface facing the first surface 300a of the outer case, and the second surface 304b Refers to a face facing the second face 300b of the outer case and the third face 304c refers to a face facing the third face 300c of the outer case.

The OIS carrier 304 is formed with first and second openings 3041 and 3042 on the bottoms of the second and third surfaces 304b and 304c and the first OIS driver 32 and the first OIS carrier 304, A second OIS driver 33, and a second OIS position sensor 35 are mounted on the first and second OIS sensors 34, 35, respectively. The first and second openings 3041 and 3042 each have a shape extending in one direction.

The configuration of the camera lens module employing the driving device according to various embodiments has been described above. Hereinafter, embodiments of the present invention for improving camera lens alignment during a camera lens module assembling process will be described.

In the small-sized camera lens module employed in the portable terminal, the above-mentioned alignment is meant to align the focal length and the tilting state between the lens and the image sensor about the six axes. In particular, it refers to the six-axis alignment of the actuator after assembly of the camera lens module.

12 to 15, description will be made of an embodiment for improving alignment in the assembling process of the camera lens module 40 according to the present invention. The camera lens module shown in FIG. 1 will be described only in terms of its differences, and the same configuration has already been described.

The alignment refers to adjusting the focal distance and tilting between the lens and the image sensor. Of course, the alignment is to align the camera lens module 40 using a six-axis adjusting device (not shown) from the outside, and for this purpose, the present invention takes the alignment position of the assembled actuator 42 Given this, it implements the alignment between the lens and the image sensor.

The camera lens module 40 according to the present invention includes an outer case 41, an actuator 42, and a sensor unit 43. The outer case 41, the actuator 42, and the sensor unit 43 are aligned and coupled along the optical axis. The outer case (41) and the sensor part (43) provide the outer shape of the camera lens module (40). The actuator 42 is mounted in the inner space provided by the outer case 41 and the sensor unit 43. The bottom surface of the actuator 42 is opposed to the sensor 43. Specifically, the bottom surface of the actuator 42 faces the image sensor S and a lens (not shown) provided in the actuator 42. [ The lens not shown moves along the optical axis by the force provided by the actuator 42, and the lens focal length is adjusted.

The actuator 42 is coupled along the optical axis within the outer case 41 to provide a force to move the lens along the optical axis or to provide a force to adjust the tilting state of the lens. The force for adjusting the focus of the lens along the optical axis is provided by the AF driver, and the force for adjusting the tilting state of the lens along the optical axis is provided by the OIS driver. The actuator 42 includes an OIS carrier, a lens system, an AF driver, and an OIS driver, and the OIS carrier, the lens system, the AF driver, and the OIS driver are the same. However, the OIS carrier includes a holding part 420 to be described later, and will be described with respect to the holding part 420.

The sensor unit 43 includes a sensor base 430 and an image sensor S disposed on the sensor base 430. The sensor unit 43 is provided with a peripheral portion 431 along the periphery of the image sensor S. The image sensor S is connected to an external power source by a flexible circuit board 432. The sensor base 430 has four corners, and at least one elastic body 44 described later is disposed in two corner regions.

The alignment of the camera lens module 40 according to the present invention is applied during the assembly process. That is, the present invention is applied to check and adjust the alignment state of the actuator 42 before the outer case 41, the actuator 42, and the sensor unit 43 are assembled.

After the camera lens module 40 is assembled, the apparatus for aligning six axes (± X, ± Y, ± Z) of the assembled actuator 42 includes an opening 411 provided in the outer case, And a holding part 420 which is disposed on the outer circumferential surface and is exposed to the outside. The device is coupled to a holding part 420, which is not shown, for six-axis alignment (six-axis adjustment with a picker) to align the actuator 42, The alignment of the camera lens module 40 is completed.

The opening 411 is formed on one side surface of the outer case 41. Particularly, among the five outer surfaces outside the outer case 41, four sides except for the top surface 410a are present And the four sides are referred to as first, second, third, and fourth sides 401b-410e, respectively. The aperture 411 may be formed in the first side surface 410b of the first, second, third, and fourth sides 410b-410e where the AF driver and the OIS driver are not disposed, . The opening 411 can be formed in a polygonal shape. A generally rectangular opening is shown in Fig. The opening 411 is formed to expose the holding portion 420 to the outside.

Below the opening 411, a coupling opening 412 is further provided. The engagement opening 412 is coupled to the protrusion of the sensor unit 43 so that the outer case 41 and the sensor unit 43 are engaged with each other.

The holding part 420 is provided integrally with the OIS carrier. The OIS carrier is in the form of a metal plate, and the holding part 420 is formed by bending in the vertical direction after being extended and protruded from the OIS carrier, and is formed into a vertical wall shape. On the other hand, if the OIS carrier is not an metal material but an injection material, the holding part 420 may be injection-molded integrally with the OIS carrier. The holding part 420 is disposed in the vertical direction (optical axis direction) in the OIS carrier so that when the outer case 41, the actuator 42 and the sensor part 43 are coupled in the optical axis direction, (411). This state is shown in Fig.

The holding portion 420 includes at least one engaging hole 421 for engaging with an external six-axis aligning device (not shown). The coupling holes 421 are provided as a pair.

As described above, a plurality of elastic members 44 are disposed and fixed on the upper surface 431 of the sensor unit 43. The elastic body 44 is disposed between the actuator 42 and the sensor portion 43 and is disposed between the bottom surface of the OIS carrier and the upper surface of the sensor portion 43 in more detail. Particularly, the elastic body 44 is disposed in the edge area of the upper surface of the sensor part, and is disposed on both sides of the opening 411 and the holding part 420, respectively.

Each of the elastic members 44 is mounted so as to be opposed to both corner areas and arranged symmetrically. Therefore, the elastic members 44 are disposed to be symmetrical with respect to each other in two pairs. In particular, one pair is disposed on both sides of the holding part 420, Each of the elastic members 44 is a leaf spring having a fixed end and a free end, and the fixed end is fixed to a peripheral edge area of the upper surface of the sensor part 43 by a coupling structure (coupling between projections and holes) Extends from the fixed end and is disposed in close contact with the bottom surface of the OIS carrier. Each of the elastic members 44 is provided with an elastic force in a direction away from the upper surface of the sensor portion 43. The elastic body 44 is supported in close contact with the bottom surface of the OIS carrier to support the actuator 42. Each of the fixed ends is fixed to the edge area of the sensor unit substrate 430, and the respective free ends are respectively in close contact with the bottom surface of the holding part 420.

Particularly, during the assembling process of the camera lens module 40, the alignment of the actuator 42 can be finely adjusted by the elastic body 44. When the viscous material is applied to the place where the elastic body 44 is disposed, the elastic body 44 is deformed due to the viscosity of the elastic body 44, So that the alignment of the alignment equipment not shown can be finely realized. Such a viscous material is preferably a viscous material which hardens after a certain period of time. For example, a UV curing material may be used as the viscous material. The alignment state of the actuator 42 is hardened and fixed by the viscous material.

As described above, the alignment of the camera lens module is improved by aligning and fixing the actuator after assembling the camera lens module.

While the present invention has been particularly shown and described with reference to particular embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims and their equivalents It will be understood.

10: Camera lens module driving device
11: AF driver 12, 13: OIS driver
100, 101: Outer case 104: OIS carrier
103: lens carrier 106, 108: circuit board
w: suspension wire

Claims (11)

A camera lens module comprising:
An OIS carrier mounted in the outer case and having an opening formed on one surface thereof facing the outer case;
A lens carrier accommodated in the OIS carrier and driving the OIS carrier together with the optical axis in a vertical direction;
An OIS driver including an OIS magnet disposed sideways on the lower surface of the OIS carrier and an OIS coil disposed to face the OIS magnet;
An AF circuit board positioned above the OIS carrier; an OIS circuit board positioned below the OIS carrier;
An AF magnet disposed on the lens carrier so as to face the outer case side through the opening and an AF coil disposed on the outer case side and accommodated in the opening so as to face the AF magnet, An AF driver for driving the carrier along the optical axis within the OIS carrier;
Suspension wires electrically connecting and supporting the AF circuit substrate and the OIS circuit substrate; And
And an external alignment unit for aligning the AF driving unit and the OIS driving unit when the camera lens module is assembled. The apparatus of claim 1, further comprising: a polygonal opening on one side of the external case; A holding part protruding from the OIS carrier and exposed to the outside through the polygonal opening to be coupled with the external aligning device;
The camera lens module comprising: delete The method according to claim 1,
Wherein the holding portion is formed in a vertical wall shape and is bent in the vertical direction in the OIS carrier. The method of claim 3,
Wherein the holding portion includes at least one engagement hole for engaging with the external alignment device. The method according to claim 1,
And a plurality of elastic bodies are further provided between the bottom surface of the OIS carrier and the top surface of the sensor unit. 6. The method of claim 5,
Wherein the plurality of elastic members are spaced apart from each other around the upper surface of the sensor unit. The method according to claim 6,
Wherein each of the elastic members is symmetrically arranged in pairs in an edge peripheral region of the upper surface of the sensor portion. 8. The method of claim 7,
Each of the elastic members
A fixed end mounted around the upper surface of the sensor unit; And
And a free end extending from the fixed end and disposed in close contact with the bottom surface of the OIS carrier to support the AF driver and the OIS driver. 9. The method of claim 8,
And the free end is closely attached to the bottom surface of the holding part. 6. The method of claim 5,
And a tilt adjustment of the lens carrier is performed by applying a viscous substance to the elastic body when the AF driver and the OIS driver are aligned. 11. The method of claim 10,
Wherein the viscous material is cured after a lapse of a predetermined time to fix the alignment position.

Images