KR101643771B1 - Camera lens assembly - Google Patents

Abstract

The present invention relates to a camera lens assembly capable of automatically adjusting a focal length of a lens in an optical device mounted on a digital camera or a mobile communication terminal and of maximizing a displacement width of the lens assembly even when the same current is applied A lens assembly provided in the housing; a first magnetic body provided in the lens assembly; and a driving unit provided in the housing and opposed to the first magnetic body. The camera lens assembly includes a housing, a lens assembly provided in the housing, And a second magnetic body provided on the housing and the driving unit, respectively, wherein the second magnetic body interacts with the magnetic field of the first magnetic body to separate the lens assembly from the upper and lower surfaces of the housing along the optical axis direction And the lens assembly is spaced apart from upper and lower surfaces of the housing, The lens assembly can be driven in both directions by changing the direction of the current applied to the coil, and the displacement width of the lens assembly in the same current range Can be realized by more than twice the conventional one.

Camera lens assembly. The lens assembly, the first and second driving portions,

Description

Camera lens assembly {CAMERA LENS ASSEMBLY}

The present invention relates to a camera assembly, and more particularly, to an optical apparatus mounted on a digital camera, a mobile communication terminal, or the like, capable of automatically adjusting a focal length of a lens, And more particularly, to a camera lens assembly that can be implemented.

2. Description of the Related Art [0002] With the advent of compact and lightweight camera lens assemblies due to the recent development of digital camera manufacturing technology, mobile communication terminals equipped with optical lenses and camera elements are becoming popular as cameras can be mounted on mobile communication terminals.

The performance of the camera mounted on the mobile communication terminal at the initial stage of mounting the camera in the mobile communication terminal was significantly lower than that of the commercially available digital camera at that time. For example, at the time when the performance of the entry-level digital camera was 4 million pixels, the number of the cameras mounted on the mobile communication terminal was generally 300,000 pixels, and only one million pixels were installed in the high-end terminals.

In recent years, it has become common to mount a 1-megapixel-level camera on a mobile communication terminal. In the case of a high-grade terminal, a 3-megapixel-level camera similar to a popular digital camera is installed. The terminal successfully commercialized. As described above, the camera function of the mobile communication terminal is improved by improving the precision of the camera lens assembly manufacturing technique.

The construction of such a camera lens assembly is described in detail in Korean Patent Application No. 2007-35155 (2007.04.10) filed by the present applicant.

1, a driving unit 105 is installed on one side of the lens assembly 104 to move the lens assembly 104 in the direction of the optical axis O, And a guide part is provided between the driving part 105 and the driving part 105.

The lens assembly 104 is provided with at least one lens therein, and adjusts the focal distance while moving back and forth along the optical axis O. A magnetic body 141 is mounted on one side of the lens assembly 104. The magnetic body 141 faces the driving unit 105 and generates a driving force for moving the lens assembly 104 in a forward and backward direction while interacting with a coil 155 installed on the driving unit 105.

When a current is applied to the coil 155, the coil 155 generates an electric field, and the electric field of the coil 155 and the magnetic field of the magnetic body 141 interact with each other to move the lens assembly 104 back and forth Thereby generating a driving force.

The lens assembly 104 is brought into close contact with the stopper 153 provided at the lower end of the driving unit 105 in a state where no current is applied to the coil 155. [

That is, one side surface of the lens assembly 104 faces the driving unit base 151, and a lower surface of the lens assembly 104 faces the stopper 153. Therefore, if no current is applied to the coil 155, the lens assembly 104 is stopped at a position where the lower surface of the lens assembly 104 is in close contact with the stopper 153.

In this state, when a current is applied to the coil 155, the electric field generated by the coil 155 and the magnetic field of the magnetic body 141 interact with each other, and the lens assembly 104 is moved along the optical axis O Direction. The moving distance and the moving direction of the lens assembly 104 are set according to the value of the current applied to the coil 155, thereby adjusting the focal length of the camera lens assembly 100.

However, a camera having a higher number of pixels and a higher number of pixels is required to have a larger displacement width of the lens assembly.

For example, in the case of a camera lens module having 5 million pixels, a displacement width of the lens assembly is required to be 300 m or more, and a displacement of 400 m or more is required for a higher pixel number.

However, in the conventional camera lens assembly 100, when a current is applied to the coil 155 in a state where the driving unit 105 is in close contact with the stopper 153 provided at the lower end of the lens assembly 104, It is possible to move only in one direction along the optical axis O direction by the interaction of the optical axis O.

Accordingly, since the lens assembly 104 is in close contact with the stopper 153, its displacement width is limited only in one direction.

Therefore, in order to obtain a large displacement width of the lens assembly, the current intensity of the coil 155 must be intensified or the size of a magnet used as a driving unit should be generally increased.

However, since the maximum current value that can increase the current intensity is limited in the portable terminal, there is a problem that the limitation is limited to the displacement width. When the size of the magnet is increased, the thickness thereof must be increased. Since the thickness of the camera module is increased, the weight of the camera module becomes heavy and a problem of miniaturization of the camera module occurs. In addition, the thickness of the portable terminal becomes thick and it becomes difficult to reduce the weight.

Accordingly, there is a need for a camera lens assembly that enables the lens assembly to be driven in both directions in the camera lens module.

In addition, since the maximum current value of the portable terminal is limited, there is a need for a camera lens assembly capable of realizing the maximum displacement width of the lens assembly through the maximum current value.

Further, it is possible to obtain sharpness of the image even when the lens assembly is driven in both directions to acquire a large displacement, as well as to precisely control the driving position of the lens assembly by the hall sensor, There is a need for a camera lens assembly capable of performing position control.

SUMMARY OF THE INVENTION Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art, and an object of the present invention is to provide a camera lens assembly having an auto focus function and being easy to miniaturize.

Another object of the present invention is to provide a camera lens assembly capable of driving a lens assembly driven in one direction by a conventional stopper in both directions to have a large displacement width.

The present invention also provides a camera lens assembly capable of obtaining a maximum displacement value of a lens assembly using a current value of a portable terminal.

Another object of the present invention is to provide a camera lens assembly which can be mounted on a portable terminal or a portable computer, and which can be miniaturized so as to increase the displacement width of the lens assembly and direct a high pixel.

It is also an object of the present invention to provide a camera lens assembly capable of precisely controlling its position even when the lens assembly is driven in both directions.

To this end,

In a camera lens assembly,

housing;

A lens assembly provided in the housing;

A first magnetic body provided on the lens assembly;

A driving unit provided in the housing and opposed to the first magnetic body;

And a second magnetic body that is provided in the housing and the driving unit and is opposed to and spaced apart from one end and the other end of the first magnetic body,

The second magnetic body interacts with the magnetic field of the first magnetic body to separate the lens assembly from the upper and lower surfaces of the housing along the optical axis direction,

And the lens assembly moves back and forth in both directions along the optical axis direction with respect to the driving unit while being separated from the upper and lower surfaces of the housing

Further,

In a camera lens assembly,

housing;

A lens assembly provided in the housing;

A first magnetic body provided on the lens assembly;

A driving unit provided in the housing and opposed to the first magnetic body;

And an elastic member provided between both ends of the first magnetic body and the stoppers of the housing and the driving unit to separate the lens assembly from the upper and lower surfaces of the housing along the optical axis direction,

And the lens assembly moves back and forth in both directions along the optical axis direction with respect to the driving unit in a state where the lens assembly is spaced apart from the upper and lower surfaces of the housing.

As described above, according to the camera lens assembly of the present invention,

Accordingly, by changing the direction of the current to the coil in the camera lens module, the lens assembly can be driven in both directions, and a displacement of twice or more than the conventional one can be obtained in the same current range.

In addition, the displacement of the lens assembly can be increased without increasing the intensity of the current or increasing the driving unit. Therefore, the size of the camera lens module can be increased without increasing the displacement of the lens assembly, There is an effect.

In addition, since the hall sensor is mounted on the camera lens assembly, it is possible to precisely adjust the focal distance by sensing the change of the lens assembly and to store the initial position of the lens assembly, thereby eliminating the need to separately set the focusing process of the camera lens module. .

The camera lens assembly according to the present invention may include a driving unit for moving the lens assembly in the optical axis direction to one side of the lens assembly in order to realize the automatic focusing distance adjustment function, And a guide portion is provided between the driving portions. In a specific embodiment of the present invention, the driving unit is configured using a voice coil motor, and balls are provided between the lens assembly and the driving unit as a guide unit to facilitate movement of the lens assembly. Since the lens assembly can be smoothly moved forward and backward through the configuration of the guide portion as described above, the structure of the driving unit can be simplified, and the camera lens assembly can be miniaturized and easily attached to a portable device such as a mobile communication terminal .

Hereinafter, a camera lens assembly according to a first preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted so as to avoid obscuring the subject matter of the present invention. .

3 to 5, the camera lens assembly 200 includes a housing 210, a lens assembly 220, a first magnetic body 230, a driving unit 250, and a second magnetic body 240 .

The lens assembly 220 is disposed on the housing 210 and the first magnetic member 230 is coupled to one side of the lens assembly 220. The drive assembly 250 is coupled to the lens assembly 220 To the housing 210 so as to move back and forth in the direction of the optical axis.

The second magnetic body 240 is provided on the housing 210 and the driving unit 250 such that the second magnetic body 240 is spaced apart from the first magnetic body 230 at one end and the other end, respectively. The second magnetic body 240 interacts with the magnetic field of the first magnetic body 230 to separate the lens assembly 220 from the upper and lower surfaces of the housing 210 along the optical axis direction.

If the one end of the first magnetic body 230 is an N pole and the other end is an S pole, the second magnetic body 240 disposed opposite to the N pole of the first magnetic body 230 forms an N pole And the second magnetic body 240 opposed to the S-pole of the first magnetic body 230 forms an S-pole, so that the first magnetic body 230 230, and the repulsive force of the tilting ends of the tilting arms 230,

Accordingly, the lens assembly 220 is spaced apart from the upper surface and the lower surface of the housing 210 by a repulsive force of the first magnetic body 230 and the second magnetic body 240, thereby forming a space.

Therefore, the lens assembly 220 can be moved back and forth in the upward and downward directions along the optical axis O with respect to the driving unit 250 in a state where the lens assembly 220 is spaced apart from the upper and lower surfaces of the housing 210.

As shown in FIGS. 3 and 5, the housing 210 includes a module housing 212 and a cover housing 211.

The module housing 212 is provided to receive the lens assembly 220. Further, the module housing 212 is provided with an opening 222a serving as a photographing path of the image sensor 113, which will be described later. The module housing 212 is mounted on a circuit board 111 and an infrared filter 119 and an image sensor 113 are provided in an opening 212a formed in the module housing 212. [

 On the inner surface of the module housing 212, a guide 212b extends along the optical axis O direction. The guide 212b guides the lens assembly 220 so that the lens assembly 220 can move back and forth only in the optical axis O direction.

The cover housing 211 forms an opening 211a for providing a photographing path of the lens assembly 220 and is coupled to the module housing 212. The lens assembly 220 is housed inside the module housing 212 and the cover housing 211 and the driving unit 250 is provided on one surface of the lens assembly 220 facing the first magnetic body 230.

The sensor assembly 101 for image detection in the camera lens assembly 200 includes an image sensor 113, a circuit board 111, and a flexible printed circuit 115. The image sensor 113 disposed on the image plane is mounted on one side of the circuit board 111 by wire bonding and the flexible printed circuit 115 extends from the circuit board 111 And is connected to the main circuit board of the camera or portable terminal. The image sensor 113 is aligned with the optical axis O along with the infrared filter 119 and the lens assembly 220.

3 and 5, the first magnetic body 230 is mounted on one side of the lens assembly 220, and the driving unit 250 includes a driving unit 250, which forms a stopper 253 at a lower end, And a coil 255 formed on the driving unit base 251 and facing the first magnetic body 230.

As shown in FIGS. 3 and 5, the second magnetic body 240 is provided with a first magnetic member 241 and a second magnetic member 242.

The first magnetic member 241 is provided on the cover housing 211 so as to be positioned opposite to one end of the first magnetic member 230 and has the same pole as one end of the first magnetic member 230 The lens assembly 220 is spaced apart from the cover housing 211 by a predetermined length.

The second magnetic member 242 is provided on the stopper 253 so as to be opposed to the tile end of the first magnetic body 230 and is formed to have the same pole as the tile end of the first magnetic body 230 So that the lens assembly 220 is separated from the stopper 253 by a predetermined length.

5, one end of the lens assembly 220 is fixed to the cover 230 by the interaction between the magnetic field formed at one end of the first magnetic body 230 and the magnetic field of the first magnetic member 241, And the other end of the lens assembly 220 is spaced apart from the housing 211 by a magnetic field generated at the other end of the first magnetic member 230 and a magnetic field of the second magnetic member 242, Is spaced apart from the stopper 253 by a predetermined length.

3 and 5, a hall sensor 257 (Hall sensor 257) for detecting a change in the position of the first magnetic body 230 in a state surrounded by the coil 255 is disposed inside the coil 255, The centers of the lens assembly 220 and the first magnetic body 230 are connected to the Hall sensors 241 and 242 by the interaction between the first and second magnetic members 241 and 242 and the first magnetic body 230, 257, respectively.

5, when a current is applied to the coil 255, the magnetic field of the first magnetic body 230 interacts with the electric field of the coil 255 according to a current application direction, ) In one direction along the optical axis O in both directions. For example, it is driven in at least one of an upward direction and a downward direction about the center of the driving unit 250.

5, the lens assembly 220 is coupled to the housing 210 by the first and second magnetic bodies 230 and 240 while no current is applied to the coil 255, And the upper and lower ends of the hall sensor 257, respectively. In this state, when power is supplied to the camera lens assembly 200, the lens assembly 220 located at the center of the housing 210 is automatically moved to a remote point at a predetermined initial focusing position, And the first magnetic body 230 are interacted with each other.

That is, the lens assembly 220 is positioned on the same line as the center of the driving unit 250 and the first magnetic body 230, and the hall sensor 257 is positioned on the same line. In this state, when power is supplied to the camera lens assembly 200, the auto-focus function is activated and the camera moves to a downward direction (hereinafter referred to as a far point) in which the focus is achieved. When the initial position where the lens assembly 220 is focused by the hall sensor 257 is stored, the lens assembly 220 is automatically moved to the initial position while power is supplied.

3 to 5, when the lens assembly 220 is moved to a remote point by the interaction of the coil 255 and the first magnetic body 230, The amount of current of the coil 255 is specified so as to detect movement of the assembly 220 and to automatically move to the initial focusing position.

3 to 5, when an electric field is applied to the coil 255 by applying a current in one direction, the electric field of the coil 255 and the magnetic field of the first magnetic body 230 are mutually And the lens assembly 220 moves back and forth in at least one direction of the upper side or the lower side of the housing 210. When an electric field is generated by applying a current to the coil 255 in a direction opposite to one direction The electric field of the coil 255 and the magnetic field of the first magnetic body 230 interact with each other and the lens assembly 220 is rotated in the direction opposite to the one direction of the current application direction of the coil 255, 220 in the direction opposite to the driving direction.

As shown in FIG. 3, a guide unit 260 is provided between the lens assembly 220 and the driving unit 250. The guide portion 260 includes a pair of guide grooves 269, receiving grooves 261 and balls 263. The pair of guide grooves 269 are formed on one surface of the lens assembly 220 and the receiving grooves 261 are formed in the driving unit 250 so as to face the guide grooves 269, The balls 263 are accommodated in the respective receiving grooves 261. Each of the balls 263 protrudes from the receiving groove 261 and is in contact with the inner wall of the guide groove 269. The lens assembly 220 is guided by the guide portion 260 And moves in the direction of the optical axis (O) with respect to the driving part (250).

3, the guide grooves 269 extend in the direction of the optical axis O of the lens assembly 220, and the pair of the receiving grooves 261 face one guide groove 269 Respectively.

The operation of the camera lens assembly according to the first preferred embodiment of the present invention will be described in more detail with reference to FIGS. 3 to 5. FIG.

A camera or a portable terminal equipped with the camera lens assembly 200 configured as described above photographs an image inputted through the lens assembly 220 through the image sensor 113.

A repulsive force acts between one end of the first magnetic member 230 and the first magnetic member 241 and a repulsive force acts between the tile end of the first magnetic member 230 and the second magnetic member 242 The lens assembly 220 is spaced apart from the cover housing 211 by a predetermined distance and spaced apart from the stopper 253 by a predetermined distance.

In addition, the lens assembly 220 corresponds to the center of the driving unit 250 and is positioned on the same line as the hall sensor 257.

When power is applied to the camera lens assembly 200 in the initial state of the lens assembly 220, an interaction between the electric field generated by the coil 255 and the magnetic field of the first magnetic body 230 The lens assembly 220 is automatically moved to the far point of the set initial focusing position. Generally, the lens assembly 220 descends downward toward the stopper 253.

The Hall sensor 257 detects the movement of the lens assembly 220 and designates the amount of current of the coil 255 so as to be automatically moved to the initial focusing position.

If the focal length of the lens assembly 220 is not appropriate, the image taken through the image sensor 113 is not clear, and a controller (not shown) of the camera or the mobile communication terminal detects the focal distance, To move forward and backward.

A current is applied to the coil 255 in one direction or another direction according to a signal generated by the controller, and an electric field generated by the coil 255 and a magnetic field of the magnetic body 141 interact with each other, (220) moves back and forth in one of the upward and downward directions about the initial position.

When the lens assembly 220 moves back and forth, the hall sensor 257 senses a change in the position of the lens assembly 220, specifically, the magnetic body 141, and transfers the value to the controller. The control unit compares the signal value generated for moving the lens assembly 220 with the position change value of the lens assembly 220 sensed through the hall sensor 257, 220 again in both upward and downward directions.

As a result, the lens assembly 220 forms a space between the cover housing 211 and the stopper 253 by the first magnetic body 230 and the second magnetic body 240, It is possible to drive the lens assembly 220 in both the upward and downward directions by applying different directions of currents to the coils 255. [ Accordingly, if the driving displacement width of the lens assembly 220 is 200 μm when the current is 80 mA in the conventional camera lens assembly 200, the current direction of the camera lens assembly 200 according to the present invention is reversed, The displacement width can be realized.

Therefore, by providing the second magnetic body 240, it becomes possible to secure a displacement width twice that of the conventional camera lens assembly 200 in the same current range.

Hereinafter, the construction and operation of the camera lens assembly 200a according to the second embodiment of the present invention will be described in more detail with reference to FIGS. 6 and 7. FIG.

Hereinafter, a camera lens assembly 200a according to a second embodiment of the present invention will be described with reference to the camera lens assembly 200 according to the first embodiment, and the description of the same configuration and operation as those of the above- And the same reference numerals used in the first embodiment are used for the same configuration.

6 and 7, the camera lens assembly 200a according to another embodiment of the present invention includes a housing 210, a lens assembly 220 provided in the housing 210, A first magnetic body 230 provided in the assembly 220 and a driving unit 250 provided in the housing 210 so as to face the first magnetic body 230 and an elastic member 240a. The elastic member is disposed between the both ends of the first magnetic body 230 and the housing 210 so that the lens assembly 220 is separated from the upper and lower surfaces of the housing 210 along the optical axis O, And the stopper 253 of the lens assembly 250. The lens assembly 220 is spaced apart from the upper and lower surfaces of the housing 210 so that the lens assembly 220 moves along the optical axis O It moves back and forth in both directions.

The camera lens assembly 200 according to the second embodiment differs from the camera lens assembly 200 according to the first embodiment in that the lens assembly 220 is mounted on the stopper 253 of the driving unit 250, And the second magnetic body 240 is spaced apart from the cover housing 211. In the second embodiment, the lens assembly 220 is fixed to the stopper 253 of the driving unit 250 and the cover housing 211 And the elastic member 240a is spaced apart from the elastic member 240a.

6 and 7, the elastic member 240a includes a first elastic body 241a and a second elastic body 242a.

The first elastic body 241a may be provided to separate the lens assembly 220 from the cover housing 211 and to provide the elastic force to the lens assembly 220 so as to drive the lens assembly 220 in both directions. And the cover housing (211).

The second elastic body 242a may be provided to separate the lens assembly 220 from the stopper 253 and to provide the elastic force to the lens assembly 220 so as to drive the lens assembly 220 in both directions. And a stopper 253 of the driving unit 250. The tilting end of the driving unit 250 and the tilting end of the driving unit 250 are shown in Fig.

6 and 7, when a current is applied to the coil 255, the magnetic field of the first magnetic body 230 interacts with the electric field of the coil 255 according to a current application direction, The assembly 220 is driven in an upward or downward direction from the center of the driving unit 250 along the optical axis O. [ When the lens assembly 220 is driven in the upward direction from the center of the driving unit 250 along the optical axis O, the first elastic body is compressed and the second elastic body is stretched. When the lens assembly 220 is driven downward from the center of the driving unit 250 along the optical axis O, the first elastic body is stretched and the second elastic body is compressed.

7, when the lens assembly 220 is moved to a remote point by the interaction of the coil 255 and the first magnetic body 230, the hall sensor 257 moves the lens assembly 220 And specifies the amount of current of the coil 255 so as to be automatically moved to the initial focus adjustment position.

7, in an initial state in which no current is applied to the coil 255, the lens assembly 220 is moved to the upper and lower ends of the housing 210 by the first elastic body and the second elastic body, And are positioned on the same line as the center of the hall sensor 257 and the driving unit 250. [

In this state, when power is supplied to the camera lens assembly 200, the lens assembly 220 located at the center of the housing 210 is automatically moved to a remote point at a predetermined initial focusing position, 255) and the first magnetic body 230 interact with each other.

When the focal distance of the lens assembly 220 is not appropriate, the controller detects the movement of the lens assembly 220 by the hall sensor 257, And the like.

A current is applied to the coil 255 in one direction or another direction by a signal generated from the controller, and an electric field generated in the coil 255 interacts with a magnetic field of the magnetic body, And moves up and down in the upward or downward direction about the center of the swing arm 250.

If an electric field is generated by applying a current application direction to the coil 255 in one direction, the electric field of the coil 255 interacts with the magnetic field of the first magnetic body 230, The first elastic body and the second elastic body move or stretch in at least one direction of the upper side or the lower side of the housing 210 so that the first elastic body and the second elastic body are respectively tensile or compressively deformed.

When an electric field is generated by applying a current to the coil 255 in a direction opposite to the one direction, the electric field of the coil 255 and the magnetic field of the first magnetic body 230 interact with each other, 220 move back and forth in a direction opposite to the driving direction of the lens assembly 220 in a direction opposite to the one direction of the current application direction of the coil 255 so that the first elastic body 241a and the second elastic body 242a Compression or tensile deformation.

As a result, the lens assembly 220 forms a space between the cover housing 211 and the stopper 253 by the first magnetic body 230 and the elastic member 240a as in the first embodiment The lens assembly 220 is driven in both the upward and downward directions by applying different directions of currents to the coils 255. In other words, will be.

Therefore, in the camera lens assembly 200 according to the present invention, as in the first embodiment, it is possible to realize a displacement width of 200 mu m at 40 mA by reversing the current direction. Accordingly, by providing the elastic member 240a, it becomes possible to secure a displacement width twice as large as that of the conventional camera lens assembly 200 in the same current range.

The camera lens assembly included in the portable electronic device of the present invention is not limited to the above-described embodiments and drawings, and various substitutions, modifications, and changes may be made without departing from the technical spirit of the present invention. Will be apparent to those skilled in the art to which the present invention pertains.

1 is a perspective view showing a configuration of a camera lens assembly according to the related art;

2 is a sectional view of a camera lens assembly according to the prior art;

3 is a perspective view illustrating a configuration of a camera lens assembly according to a first preferred embodiment of the present invention.

4 is a view illustrating a combined state of a camera lens assembly according to a first preferred embodiment of the present invention.

5 is a cross-sectional view along the line A-A 'in FIG. 4;

6 is a perspective view showing a configuration of a camera lens assembly according to a second preferred embodiment of the present invention.

7 is a sectional view of a camera lens assembly according to a second preferred embodiment of the present invention;

Claims (19)

In a camera lens assembly, housing; A lens assembly provided in the housing; A first magnetic body provided on the lens assembly; A driving unit provided in the housing and opposed to the first magnetic body; And a second magnetic body provided on the housing and the driving unit, respectively, The second magnetic body interacts with the magnetic field of the first magnetic body to separate the lens assembly from the upper and lower surfaces of the housing along the optical axis direction, Wherein the lens assembly is moved back and forth in both directions along the optical axis direction with respect to the driving unit while being separated from the upper and lower surfaces of the housing. The method according to claim 1, The housing includes: A module housing housing the lens assembly; And And a cover housing coupled to the module housing and including an opening to provide an imaging path of the lens assembly, Wherein the lens assembly is housed inside the module housing and the cover housing, and the driving unit is provided on one surface of the lens assembly facing the first magnetic body. 3. The method of claim 2, Wherein the first magnetic body is mounted on one side of the lens assembly, Wherein the driving unit includes a driving unit base that forms a stopper at a lower end thereof, and a coil that is formed on the driving unit base and faces the first magnetic member. The method of claim 3, And the second magnetic body comprises: A first magnetic member provided in the cover housing and positioned to face one end of the first magnetic member; And a second magnetic member provided on the stopper and positioned opposite to a tile end of the first magnetic body. 5. The method of claim 4, Wherein one end of the lens assembly is spaced apart from the cover housing by a predetermined distance due to an interaction between a magnetic field formed at one end of the first magnetic member and a magnetic field of the first magnetic member, Wherein the other end of the lens assembly is spaced apart from the stopper by a predetermined distance due to an interaction between a magnetic field formed at the other end of the first magnetic member and a magnetic field of the second magnetic member. 6. The method of claim 5, And a hall sensor provided inside the coil and sensing a change in position of the first magnetic body in a state surrounded by the coil, Wherein the centers of the lens assembly and the first magnetic body are positioned on the same line as the center of the Hall sensor by interaction between the first and second magnetic members and the first magnetic body. The method according to claim 6, Wherein when a current is applied to the coil, the magnetic field of the first magnetic body interacts with the electric field of the coil according to a current application direction to drive the lens assembly in at least one of directions bidirectional along the optical axis. . 8. The method of claim 7, Wherein the lens assembly is positioned on the same line as the center of the hall sensor by forming the space portion at the upper and lower ends of the housing by the first magnetic body and the second magnetic body in a state in which no current is applied to the coil, Wherein when the camera lens assembly is supplied with power, the coil and the first magnetic body are mutually actuated so that the lens assembly located at the center of the housing is automatically moved to a remote point at a predetermined initial focusing position, assembly. 9. The method of claim 8, Wherein the Hall sensor senses movement of the lens assembly when the lens assembly is moved to a remote location by the interaction of the coil and the first magnetic body, Wherein the first and second lens assemblies are arranged on the same plane. 10. The method of claim 9, The electric field of the coil and the magnetic field of the first magnetic body interact with each other, and the lens assembly is moved forward and backward in at least one direction of the upper side or the lower side of the housing, Exercise, The electric field of the coil and the magnetic field of the first magnetic body cooperate with each other when the electric current is applied to the coil in a direction opposite to the one direction and the electric field of the coil and the magnetic field of the first magnetic body interact with each other, Wherein the lens assembly moves back and forth in a direction opposite to a driving direction of the lens assembly. 11. The method of claim 10, And a guide portion provided between the lens assembly and the driving portion, The guide portion A pair of guide grooves formed on one surface of the lens assembly; Receiving grooves formed in the driving unit and facing the guide grooves; And And balls contained in each of the receiving grooves, Wherein each of the balls protrudes from the receiving groove to contact an inner wall of the guide groove, Wherein the lens assembly moves in a direction of an optical axis with respect to the driving unit under the guidance of the guide unit. 12. The method of claim 11, The guide grooves extending in the optical axis direction of the lens assembly, And the pair of receiving grooves are disposed to face the one guide groove. delete delete delete delete delete delete delete

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