KR20150117237A - Camera lens module - Google Patents

Abstract

Disclosed is a camera lens module. The camera lens module according to an embodiment of the present invention includes: a shake compensation carrier which receives a lens barrel, and is operated by a shake compensation drive unit; a rolling unit which supports a plane motion of the shake compensation carrier to be perpendicular to an optical axis; and an autofocus carrier for mounting the shake compensation carrier to enable advance and retreat along the optical axis at an opposite side of the shake compensation carrier on the rolling unit. Centers of the shake compensation drive unit and the rolling unit are positioned by being mutually shifted.

Description

[0001] The present invention relates to a camera lens module,

The present invention relates to a camera lens module mounted on a portable mobile device, and more particularly, to a camera lens module having a shake correction function and an auto focus function.

[0002] In recent years, portable terminals such as smart phones (hereinafter referred to as " mobile ") have become multi-converged with music, movies, TVs, games, One of the factors leading to the development of the camera lens module (camera lens module) is.

The camera lens module mounted on the mobile phone has various additional functions such as an auto focus function (AF) and an optical zoom function (OPTICAL ZOOM) in order to meet the recent change in the center of high picture and high function according to the user's demand . In recent years, various attempts have been made to implement an optical image stabilizer in a mobile size.

The hand shake correction technique is a technique for automatically maintaining the focus of the correction lens constituting the camera module so as to move in the direction corresponding to the hand shake, thereby optimally maintaining the resolution of the captured image. In order to implement the camera shake correction technique, a camera module applied to a mobile device, a camcorder, and the like is equipped with an actuator for shake correction for adjusting the focus.

As a hand shake correction actuator, a VCM (Voice Coil Motor) type using a magnetic field and an electric field interaction is well known. This VCM type usually includes a magnetic circuit composed of a coil and a magnetic body disposed on a face to face basis and moves a moving part on which the lens is mounted by using the electromagnetic force generated by the magnetic circuit, And performs corresponding corrections.

In general, a method of applying a total of four magnetic circuits, two pairs facing each other in a two-axis direction, is adopted so that a correction can be performed by moving a driving part in the X and Y 2-axis directions. However, since the space required for applying the four magnetic circuits is required, the overall size of the camera module is increased, and the device configuration becomes complicated, making it difficult to achieve miniaturization of the product.

In order to reduce the size of the module, it is necessary to reduce the size of the driving unit and the number of parts. In this case, the correction of hand shake is inferior in precision and speed. In particular, the hand shake correction is performed by the resultant force acting in orthogonal X, There is a problem in that the driving part is driven beyond the driving range, or unnecessary rotation is generated when the driving part is driven, thereby reducing the accuracy of the correction.

Korean Patent Publication No. 10-2011-0046855 (published on May 5, 2011)

SUMMARY OF THE INVENTION An object of the present invention is to provide a camera lens module capable of miniaturizing a product with a compact structure and performing stable and accurate camera shake correction driving control.

It is another object of the present invention to provide a camera lens module having a highly accurate and highly accurate hand shake correction function by suppressing movement and unnecessary rotation of a driving part exceeding a driving range in a camera shake correction .

The present invention relates to a camera lens module, and more particularly, to a camera lens module, which includes a shake correction carrier which accommodates a lens barrel and is driven by a shake correction driving section, a rolling section that supports a planar motion of the shake correction carrier so as to be orthogonal to an optical axis, And an autofocus carrier mounted on the opposite side of the shake correction carrier so that the shake correction carrier is movable along the optical axis so that the center of the shake correction drive part and the cloud part are shifted from each other.

Here, the cloud portion includes a ball interposed between the autofocus carrier and the shake correction carrier.

Further, in an embodiment of the present invention, the rolling section may include two or more support members integrally provided on corners of the auto-focus carrier and having concave receiving surfaces formed on the upper surface thereof, And at least two balls interposed in such a manner that a part of the supporting part and a part of the supporting part are accommodated in the receiving surface, respectively.

The cloud portion may be disposed outside the magnet included in the shake correction drive portions.

At least one of the balls may be disposed on the outer side of the magnet.

In addition, the balls may be arranged on the outer side of the magnet in pairs.

A line connecting the centers of the two pairs of balls may be parallel to the mounting surface of the magnet.

The pair of balls may be disposed on both sides of the magnet.

The camera lens module according to the embodiment of the present invention effectively utilizes the free space (corner free space) between the driving parts (the shake adjustment carrier and the auto focus carrier mounting the lens barrel) and the fixed part (base) With its compact structure with auto focus function and shake correction function, it can meet both product miniaturization and functionality.

In addition, the embodiment of the present invention is advantageous in that the tilt phenomenon at the time of driving the shake correction carrier is minimized since the center of the swing correction driving part and the rolling part supporting the shake correction carrier are positioned to be offset from each other.

1 is an exploded perspective view of a camera lens module according to an embodiment of the present invention;
2 is a partially exploded perspective view of a camera lens module according to an embodiment of the present invention;
3 is a perspective view illustrating a camera lens module according to an embodiment of the present invention.
FIG. 4 is an exploded perspective view of the camera lens module shown in FIG. 3 taken along the line AA; FIG.
FIG. 5 is an exploded perspective view of the camera lens module shown in FIG. 3 viewed from the BB line direction.
6 is a plan view of a camera lens module in which a cover is omitted.
FIG. 7 is a plan sectional view of the camera lens module shown in FIG. 3 viewed from the CC line direction.
FIG. 8 is a perspective view illustrating a state before coupling of a shake correction carrier and an auto-focus carrier that constitute a camera lens module according to an embodiment of the present invention. FIG.
FIG. 9 is a schematic plan view of a camera lens module according to an embodiment of the present invention to show a layout relationship between an auto-focus drive unit and a shaken correction drive; FIG.
10 is a diagram illustrating an operation state of the camera lens module according to an embodiment of the present invention in relation to correction of shake correction in the X-axis direction.
11 is a view showing an operation state relating to correction of the y-axis shake correction of the camera lens module according to the embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the description of the present invention, a detailed description of known configurations will be omitted, and a detailed description of configurations that may unnecessarily obscure the gist of the present invention will be omitted.

 Axis direction coordinate system, the Z-axis is defined as the optical axis direction, the X-axis is the hand-shake correction direction orthogonal to the Z-axis, which is the optical axis direction, and the Y- Axis direction and another hand-shake correction direction orthogonal to the X-axis on the plane.

1, 2 and 3 are an exploded perspective view, a partially exploded perspective view, and an assembled perspective view, respectively, of a camera lens module according to an embodiment of the present invention. It is an incision perspective view from the line and BB direction. 6 is a plan view of the camera lens module in which the cover is omitted, and FIG. 7 is a plan view of the camera lens module shown in FIG. 3 taken along the line C-C.

1 to 7, a camera lens module according to an embodiment of the present invention includes a shake correction carrier 10 that accommodates a lens barrel 13, an autofocus carrier 10 on which the shake correction carrier 10 is mounted 12). The autofocus carrier 12 mounted with the shake correction carrier 10 is accommodated in the base 14 such that it can be retractably moved along the direction of the optical axis of the lens and the base 14 accommodating the carriers 10, (11) is covered at the top.

The dither correction carrier 10 is mounted on the autofocus carrier 12 so as to be movable in the X and Y axis directions on a plane perpendicular to the optical axis and is disposed between the autofocus carrier 12 and the dither correction carrier 10 There is provided a rolling unit 15 for supporting the planar motion orthogonal to the optical axis of the shake correction carrier 10 with respect to the autofocus carrier 12, that is, the driving for stable shake correction can be stably performed.

When the autofocus carrier 12 on which the shake correction carrier 10 is mounted is viewed in a plane, it is formed into a shape in which one corner portion is removed in the shape of a quadrangle having approximately four corners.

The lens barrel 13 is provided with a lens group (not shown) made up of a plurality of lenses. The lens barrel 13 has a hole (not shown) having a diameter enough to stably accommodate the lens barrel 13 Is omitted) is provided. The base 14 is composed of a bottom portion 140 surrounding the lower surface of the autofocus carrier 12 and a rectangular side portion 142 surrounding the outer surface of the carriers 10 and 12.

An opening through which the infrared filter 190 constituting the image sensor module 19 is to be formed is formed at the center of the bottom portion 140 of the base 14 surrounding the lower surface of the carrier. A filter base 192 on which the infrared filter 190 is mounted is assembled to a lower surface of the bottom portion 140 of the opening and a substrate 196 on which an image sensor 194 is mounted on the bottom surface of the filter base 192 Is assembled, the substrate 196 may be a flexible substrate.

The damping correction carrier 10, which receives the lens barrel 13, is provided in a cylindrical shape and is provided in the form of a hexahedron of the base 14. [ Therefore, when the shake correction carrier 10 is accommodated in the base 14, four free spaces are generated in the respective corner areas of the base 14, and in order to efficiently mount the components and effectively miniaturize the product, The driving portion 16 and the later-described swing restricting portion 155 are disposed.

When a part of the shake correction carrier 10 provided in the form of a cylinder is cut in the optical axis direction, a machining tolerance (for example, an outer diameter of the lens barrel is fluctuated between the outer diameter of the lens barrel 13 and the inner diameter of the shake correction carrier 10 Even if the inner diameter of the correction carrier is larger than the inner diameter of the correction carrier, elastic expansion can be performed within a predetermined range, so that good assembling property can be ensured and there may be deformation to secure a component mounting space by removing a lower end portion.

The auto focus driving unit 16 is disposed in an empty space of one of the four clearance spaces to generate a driving force for moving the auto focus carrier 12 in the optical axis direction and the other three clearance spaces have an external impact A swing restricting portion 155 is disposed to prevent the carriers 10 and 12 carrying the lens barrel 13 from being separated from the optical axis alignment position.

The automatic focus driving unit 16 is an automatic focus driving unit that is mounted on an edge opposite to the corner where the first side surface 144 and the second side surface 146 of the base 14 on which a part of the shake correction driving unit 17, A driving driver 162 disposed on an adjacent side of the focusing coil 160 and an auto focussing magnet 160 mounted on the magnet mounting portion 120 on the outer surface of the autofocus carrier 12 facing the auto focusing coil 160, (164).

The driving driver 162 may be provided in a form mounted on the outside of the camera lens module (a mobile device on which the camera lens module is mounted), and may be omitted. In this case, An autofocusing sensor may be arranged to sense a change in the position of the autofocus carrier 12 relative to the base during focus driving.

A pair of optical axis guide devices 18 (not shown in detail) of a known type including a ball B are disposed on the right and left sides of the auto-focus magnet 164 and the corresponding corner of the base 14, And the back yoke y3 is disposed on the back surface of the auto focus magnet 164 to concentrate the electromagnetic field by the auto focus coil 160 and the magnet to improve the driving efficiency .

7, the optical axis guide device 18 includes a mounting portion 147 at the corner of the base 14 on which a part of the structure (autofocus coil) constituting the autofocus driver 16 is mounted, It is preferable that the guiding surfaces of the guide members 180 formed on both sides are made of an asymmetrical structure (one V-shaped guide surface is U-shaped in cross section and the other guide surface is U-shaped in cross section) so that the movement in the optical axis direction can be smoothly performed.

The auto focus coil 160 generates an electric field by receiving electric power from the substrate 166 disposed at the rear of the auto focus coil 160 so that the electric field generated by the auto focus coil 160 and the force generated by the magnetic field of the auto focus magnet 164 The autofocus carrier 12 is guided by the pair of guide devices 18 in the base 14 to perform a stable back and forth movement along the optical axis without shaking.

Reference is now made to Fig. 8 with respect to the above-described rolling portion for supporting the driving for stabilizing the shake so as to be stable.

8, the rolling portion 15 includes two or more support portions 128 integrally provided at each corner of the auto-focus carrier 12 and having a concave receiving surface on the upper surface thereof, Two or more balls B protruding from the support 128 in a shape corresponding to the support 128 and interposed between the support 128 and the support 128 forming a recessed receiving surface, .

The support 128 is specifically formed at adjacent opposite side edges and diagonally opposite side edges of the magnet mounting portion 163 diagonally disposed at one side edge of the base 14, Is integrally formed on the circumferential surface of the vibration-reduction carrier (10) in a one-to-one correspondence with the support (128). And the ball B is interposed in such a form that a portion and another portion are received on the receiving surface of each of the support 128 and the seat 108. [

The support 128 and the seat cushion 108 are arranged vertically with respect to the optical axis direction after assembly to form one sway suppressing sphere and two or more recessed portions 148, The swing restraining parts 108 and 128 and the concave part 148 constitute the above-described swing restricting part 155 by being provided along the optical axis direction inside the corners of the base 14 corresponding to the restraining part do.

External or internal shocks are generated in the automatic focus adjustment, the camera shake correction, or the camera lens module by the support 128, the seat 108, and the swing restricting portion 155 constituted by the concave portion 148 (10) (12) with respect to the base (14), thereby increasing the impact resistance and reliability.

The side surface of each support 128 protruding from the bottom side of the auto focus carrier 12 and the side surface of the mounting portion 102 described later of the shake correction carrier 10 face each other with a predetermined gap therebetween. The mounting portion 102 is assembled between the regions 128 to prevent excessive movement or deviation of the shake correction carrier 10 relative to the autofocus carrier 12 in the event of an external or internal impact.

The other side of the autofocus driving unit 16 is provided with a shake correction unit 16 for generating a force for planar motion on the XY plane of the shake correction carrier 10 with respect to the autofocus carrier 12, A driving unit 17 is disposed. The shake correction drive unit 17 will be described with reference to FIG. 9 and FIG. 8 attached heretofore.

9 is a diagram schematically showing the arrangement relationship between the autofocus driver and the shake correction driver.

8 and 9, the shake correction driving unit 17 includes a base 14 side surface on both sides of a corner diagonally opposed to one side edge of the base 14 on which the auto focus coil 160 is mounted A coil 170a and a magnet 172a mounted on the outer surface of the vibration-compensating carrier 10 opposite to the first side 144 and the second side 146, respectively, ).

And yokes 174a and 176a (174b and 176b) disposed between the carriers 10 and 12 to correspond to the magnets 172a and 172b.

Specifically, the shake correction driving section 17 is disposed between the first side surface 144 of the base 14 and the shake correction carrier 10 to generate a force for moving the shake correction carrier 10 in the X- 1 shake correction drive unit 17a and the second side 146 of the base 14 orthogonal to the first side 144 and the shake correction carrier 10 so that the shake correction carrier 10 moves in the Y- And a second shake correction drive unit 17b for generating a force for movement.

(Sum) of the components of the X-axis direction force generated by the first shake correction driving section 17 and the components of the Y-axis direction force generated by the second shake correction driving section 17, An appropriate correction corresponding to the hand tremor is made while moving in a plane in the direction in which the resultant force acts on the XY plane on the auto focus carrier 12. [

Specifically, the first shake correction drive section 17a includes a first coil 170a mounted on the first side 144 of the base 14 and a second coil 170b mounted on the first coil 170a of the first side 144 Includes a first magnet (172a) mounted on a mounting surface (102) of a facing vibration correcting carrier (10). The first yoke 174a and the second yoke 176a are disposed on the left and right sides of the first magnet 172a to detect a change in the position of the first magnet 172a with respect to the first coil 170a And a first position detection sensor 178a.

The first and second yokes 174a and 176a are disposed on the first and second magnets 172a and 176b of the first and second magnets 172a and 176b in such a manner that the first and second yokes 174a and 176a are arranged in correspondence to the respective areas divided on the basis of the center axis A1 of the first magnet 172a in the optical axis direction In the same manner as in the first embodiment. Preferably, they are arranged at the same size at symmetrical positions with respect to the axis A1.

Attraction force is applied between the first yoke 174a and the first magnet 172a and the second yoke 176a and the first magnet 172a symmetrically with respect to the axis A1 Thus, in the shake correction driving, the rotation of the shake correction carrier 10 in one direction on the XY plane can be suppressed and can be accurately returned to the optical axis center position after correction.

That is, the first and second yokes 174a and 176a, which are provided so as to correspond to the respective regions divided by the center axis of the first magnet 172a in the optical axis direction, 10 to generate the attraction force with the first magnet 172a so that the vibration correction carrier 10 can perform a stable linear motion with no rotation with respect to the direction in which the shake correction driving force acts.

The first position detection sensor 178a detects the positional change of the first magnet 172a with respect to the first coil 170a. This realizes the position of the shake correction carrier 10 with respect to the base 14 as a change in the magnetic field of the first magnet 172a and detects the position of the first shake correction carrier 10 17 are performed so that the correction for the tremble can be made precisely.

The second shake correction driving section 17b includes a second coil 170b mounted on the second side surface 146 of the base 14 and a second coil 170b facing the second coil 170b on the second side surface 146 And a second magnet 172b mounted on the mounting surface 104 of the vibration correction carrier 10. [ A third yoke 176b and a second yoke 176b are disposed on the left and right sides of the second magnet 172b to detect a change in position of the second magnet 172b with respect to the second coil 170b. 2 position detection sensor 178b (see FIG. 11 to be described later).

The third and fourth yokes 174b and 176b are formed in a shape similar to that of the first and second yokes 174a and 176a and are divided by the center axis A2 of the second magnet 172b in the optical axis direction The shake correction carrier 10 is restrained from rotating in one direction on the XY plane by being dividedly mounted on the other side of the bottom edge of the auto focus carrier 12 so as to form an arrangement corresponding to each of the areas And provides a restoring force so that it can be returned to the optical axis center position after correction.

That is, the third and fourth yokes 174b and 176b, which are provided so as to correspond to the respective regions divided by the center axis of the second magnet 172b in the optical axis direction, 10 to generate a gravitational force with the second magnet 172b so that the shake correction carrier 10 can perform a stable linear motion without rotation in a direction in which the shake correction driving force acts.

The second position detection sensor 178b detects a change in the position of the second magnet 172b with respect to the second coil 170b. This realizes the position of the shake correction carrier 10 with respect to the base 14 as a change in the magnetic field of the second magnet 172b and detects the position of the second shake correction carrier 10 17 are performed so that the correction for the tremble can be made precisely.

Reference numeral 20 denotes an autofocus stopper for determining the Z-axis direction departure prevention and the maximum stroke of the carriers 10 and 12 mounted with the lens barrel 13 when the auto focus is adjusted. Is a shake correction stopper provided to restrict movement of the zoom lens 10 in the Z axis. Reference numeral 179 denotes a substrate on which coils constituting the shake correction driving section 17 are mounted and supplies power thereto.

Although the automatic focus stopper 20 is shown as being provided on the base in the figure, the automatic focus stopper 20 may be formed by forming a step on a cover corresponding to the auto focus stopper 20, In this case, it is preferable that a damper is attached to the stepped surface so that the impact when the carrier is touched can be attenuated.

The unexplained reference symbols y1, y2 and y4 are used for focusing the electromagnetic field to increase the driving efficiency in the automatic focus driving and the shake correction driving, and the first and second shake correction Refers to a back yoke disposed on the back surfaces of the first and second magnets 172a and 172b of the driving portions 17a and 17b.

On the other hand, as shown in Fig. 7, the rolling parts 15 may be positioned so that their centers are shifted from each other with respect to the shake correction driving part 17. [ For example, the ball B of the rolling unit 15 may be disposed outside the magnets 172a and 172b included in the shake correction driving units 17. [ Here, one of the plurality of balls B included in the rolling part 15 is positioned on the outer side of the magnets 172a and 172b, or two balls are paired with the magnets 172a and 172b It may be located outside. 7, a line connecting the centers of the two pairs of balls B may be disposed parallel to the mounting surface of the magnets 172a and 172b, and further, The two balls b may be disposed on both sides of the magnets 172a and 172b, respectively.

In this way, the centers of the rolling portions 15 are shifted from each other with respect to the shake correction driving portion 17, and in particular, the balls B of the rolling portion 15 are displaced by the magnets 172a and 172b included in the shake correction driving portions 17 The ball B serving as a fulcrum when the shake correction carrier 10 is moved by the electromagnetic force acting by the shake correcting driver 17 reduces the tilting phenomenon of the shake correction carrier 10 .

Hereinafter, the camera shake correction performed by the shake correction drive unit having the above-described configuration will be described.

10 (a) and 10 (b) illustrate an operation state of the camera lens module according to the embodiment of the present invention in relation to correction of the shake in the X-axis direction. FIG. 10B is an enlarged perspective view for explaining the relationship between the first magnet and the first and second yokes when the hand-shake correction is performed in the X-axis direction. FIG.

10 (a), when the stationary state, that is, the state where the power source is not inputted, the first magnet 172a and the second magnet 172b are moved toward the first coil 170a and the second magnet 172b Due to the attractive force due to the generating magnetic force, the shake correction carrier 10 is maintained on the autofocus carrier 12 in an alignment state in which the center thereof does not exactly deviate toward the XY plane, .

When power is supplied to the first coil 170a through the substrate 179 of the shake correction driving unit 17 in the stopped state, the electric field of the first coil 170a and the magnetic field of the first magnet 172a interact A force for moving the shake correction carrier 10 in the X-axis direction is generated. When the shake correction carrier 10 accommodating the lens barrel 13 is moved in the X-axis direction .

The first position detection sensor 178a detects a change in the position of the first magnet 172a with respect to the first coil 170a and corrects the position of the vibration correction carrier 10 relative to the base 14, And the feedback control to the first shake correction driver 17 is performed based on the recognized position value with respect to the initial position, thereby correcting the shake precisely.

The first yoke 174a and the second yoke 176a are arranged so as to correspond to the respective regions of the first magnet 172a which are divided with reference to the central axis in the optical axis direction As shown in FIG. 10 (b), the force is exerted uniformly on each of the two divided regions, so that the shake correction carrier 10 performs a stable linear motion without rotation.

11A and 11B illustrate an operation state of the camera lens module according to the embodiment of the present invention in relation to correction of the shake correction in the Y axis direction. FIG. 11A shows the operation principle of the second shake correction drive section FIG. 11B is an enlarged perspective view for explaining the relationship between the second magnet and the third and fourth yokes when the hand-shake correction is performed in the Y-axis direction. FIG.

10, when power is supplied to the second coil 170b through the substrate 179 of the shake correction driving unit 17 in the stopped state, the electric field of the second coil 170b and the electric field of the second magnet 172b A force for moving the shake correction carrier 10 in the Y-axis direction by the interaction of the magnetic field is generated. At this time, this force becomes a force that causes the shake correction carrier 10 accommodating the lens barrel 13 to correspond to the Y-axis direction tremble on the XY plane.

The second position detection sensor 178b detects a change in the position of the second magnet 172b with respect to the second coil 170b and outputs a vibration correction carrier for the base 14 10 in real time and performs feedback control on the second shake correction drive section 17a based on the recognized position value with respect to the initial position, thereby correcting the shake precisely.

The third and fourth yokes 174b and 176b are arranged so as to correspond to the respective regions divided on the basis of the center axis of the second magnet 172b in the optical axis direction As shown in FIG. 11 (b), as shown in FIG. 11 (b), the force is applied to each of the two divided regions uniformly with the force, so that the shake correction carrier 10 performs a stable linear motion without rotation.

Although not shown in the drawings, in the driving for correcting the actual shake, the first shake correction drive unit 17 and the second shake correction drive unit 17 respectively adjust the magnitude and direction in the X-axis and Y-axis directions The other force is simultaneously applied and the shake correction carrier 10 is moved in the direction in which the X-axis and Y-axis angle vector components are combined by the first and second shake correction drive units 17 to correct the shake.

According to the camera lens module according to the embodiment of the present invention as described above, the free space (corner margin space) between the driving parts (the shake adjusting carrier with the lens barrel mounted thereon and the autofocus carrier) and the fixed part It has a compact structure with auto focus function and shake correction function, so it can meet both product miniaturization and functionality.

In addition, due to the plurality of yokes which are arranged in a manner corresponding to the magnets for correction (first and second magnets), it is possible to prevent a malfunction such as a drive part exceeding the range of vibration correction or unnecessary rotation So that it is possible to provide a highly satisfactory camera lens module with high accuracy and precision in the correction of hand shake.

Further, since the carriers mounted on the lens barrel are accommodated in the base, the optical axis alignment between the lens barrel and the image sensor of the image sensor module assembled to the base can be performed in the assembly process of the camera lens module, Since the image sensor module can be adjusted only by adjusting the angle of the assembly, there is an advantage that a troublesome alignment process of the optical axis is not required.

The base 14 is mounted on the shake correction carrier 10 and the automatic focus carrier 10 is mounted on the shake correction carrier 10. In this case, It will be appreciated that there may be variations in which the optical fiber 12 is mounted, and thus such modifications may also fall within the scope of the present invention.

In this modified example, the rolling unit 15 and the first to fourth yokes 176a, 174a, 176b, and 174b applied to the above-described embodiment are disposed between the shake correction carrier 10 and the base 14 It is possible to provide the function of preventing the shake correction drive and the excessive rotation of the shake correction carrier 10 similarly.

In this case, the through-hole is formed in the shake correction carrier 10 where the auto-focus driver is mounted, and the above-described auto focus magnet 164 and the auto focus coil 160, which are applied to one embodiment, In the case where no through hole is provided, an automatic focus driving unit is disposed between the shake correction carrier 10 and the auto focus carrier 12, And the autofocus driving may be realized by applying power to the coil.

In the foregoing detailed description of the present invention, only specific embodiments thereof have been described. It is to be understood, however, that the invention is not to be limited to the specific forms thereof, which are to be considered as being limited to the specific embodiments, but on the contrary, the intention is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the appended claims. .

10: shake correction carrier 11: cover
12: Auto focus carrier 13: Lens barrel
14: Base 15: Cloud portion
16: auto focus drive unit 17: shake correction drive unit
19: Image sensor module 20, 22: Stopper

Claims (8)

A camera lens module comprising:
A shake correction carrier which receives the lens barrel and is driven by a shake correction drive unit;
A cloud portion supporting a planar motion of the shake correction carrier so as to be orthogonal to an optical axis;
And an autofocus carrier mounted on the opposite side of the shake correction carrier with respect to the rolling section such that the shake correction carrier is movably mounted along the optical axis,
Wherein the center of the shaking correction drive part and the cloud part are positioned to be shifted from each other. The method according to claim 1,
Wherein the cloud portion includes a ball interposed between the auto focus carrier and the shake correction carrier. 3. The method of claim 2,
[0028]
At least two supports provided integrally with the edges of the autofocus carrier and having concave receiving surfaces on the top surface;
At least two seats formed on the underside of the shake correction carrier in a shape corresponding to the support and having a concave receiving surface on the underside; And
And at least two balls interposed in a shape in which a portion and another portion of the ball are received on the receiving surface of the support and the seat. 4. The method according to any one of claims 1 to 3,
And the cloud portion is disposed outside the magnet included in the shake correction driving portions. The method of claim 3,
And at least one of the balls is disposed on the outer side of the magnet. 6. The method of claim 5,
Wherein the ball is disposed on the outer side of the magnet in a pair. The method according to claim 6,
And a line connecting the centers of the two pairs of balls is parallel to an installation surface of the magnet. 8. The method according to claim 6 or 7,
And the two pairs of balls are disposed on both sides of the magnet.

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