KR101070333B1 - Auto focusing apparatus of camera - Google Patents

Abstract

The present invention relates to an apparatus for automatically focusing a camera having a macro function, and in particular, to move a lens in an optical axis direction by using a magnetic field induced between a magnetic body mounted on a carrier and a driver coil facing the carrier, and a focal length for macro shooting. A stopper can be formed at the bottom of the housing that covers the upper part of the carrier to control the lens, while limiting the moving distance of the lens. The macro function can be implemented at low cost with a simple mechanical structure. The automatic focusing device of the camera.

Description

Auto focusing apparatus of camera

The present invention relates to an automatic focusing apparatus employed in a small camera module, and more particularly, to automatically implement a macro function of a camera module at low cost by applying a simple mechanical structure. Relates to a device.

Recently, a mobile phone including a mobile phone has been introduced a multi-function mobile phone that is a complex implementation of a variety of additional functions such as camera, MP3 player or TV reception in addition to the unique function of the mobile phone to make and receive phone calls.

In addition, the design of mobile phones is diversified, and according to the differentiation of products and various demands of consumers, technology development of parts including camera modules embedded in mobile phones is accelerated, and various types of products to satisfy various needs of consumers are provided. It is being developed one after another.

Recently, a camera module equipped with a mega pixel lens has been installed in a mobile phone in a different package method according to its components and driven in various forms. This product adds a flash function to illuminate a dark place, a macro function to manually change the lens focus to shoot a near subject, and a digital zoom and optical zoom function to enlarge an image and a specific part of the subject. It is commercially available.

Among them, the macro function for capturing close-up subjects with precise focus is applied to automatic or manual driving method depending on the driving method, and the small position of the lens due to the fact that the camera embedded in the mobile phone must be made compact. It is realized by adjusting the focus by change.

The manual macro function is mainly applied to a mobile phone camera because it can be applied relatively inexpensive and simple structure compared to the automatic driving method, and the lens focus is directly rotated by a lever protruding out of the lens. It consists of a structure to drive.

However, in the manual macro approach as described above, the volume of the camera module is inevitably increased due to the lever or other constituent members protruding out of the casing. There was a problem that significant restrictions occur in the design of the mobile phone. Accordingly, there is a need for a camera module capable of implementing macro functions at low cost while having a simple mechanical configuration.

Accordingly, the present invention has been made to solve the above problems, an object of the present invention is to move the lens in the optical axis direction by using a magnetic field induced between the magnetic body of the lens-mounted carrier and the coil of the drive unit facing the lens. By adjusting the focal length for macro shooting, while forming a stopper on the bottom of the housing that covers the top of the carrier to limit the moving distance of the lens, a simple mechanical structure is applied to reduce the cost It is to provide an auto focusing device of a camera that can implement an auto macro function.

Automatic focusing apparatus for a camera according to the present invention for solving the above technical problem, the automatic focusing apparatus of the camera, the lens assembly is inserted into the center, the carrier is attached to the magnetic body on one side; A first housing accommodating the carrier and having one side open to face the magnetic material; A drive unit inserted into one open side of the first housing and configured to advance and retract the carrier in an optical axis direction; A second housing covering an upper portion of the carrier and coupled to the first housing, wherein the second housing comprises: an opening formed through an optical axis to allow the lens assembly to be inserted; And a stopper protruding around the opening to limit the movement distance of the carrier in the optical axis direction.

Here, a ball guide in ball contact with the inner surface of the first housing may be installed in the carrier portion located on the left and right of the magnetic material.

At this time, the ball guide, one or more balls; It includes a groove for receiving the ball, the ball guide may be formed integrally with the carrier.

On the other hand, the drive unit, and the yoke for guiding the magnetic field generated from the magnetic body toward the drive unit; A coil generating a driving force of the carrier in response to the magnetic material; And a substrate positioned between the coil and the yoke to provide power to the coil.

Here, the yoke may be formed with a bent portion bent in the inner direction of the first housing in which the carrier is located so that the carrier can be returned by the attraction force with the magnetic material when the power is released.

At this time, the bent portion is preferably provided in a pair on the left, right side of the yoke.

In addition, the carrier may be provided with a protruding jaw that interferes with the stopper of the second housing.

The groove formed in the carrier is preferably formed to have a cross-sectional shape of "V" shape.

In addition, the inside of the first housing may have a semi-circular cross-sectional shape to guide the movement of the carrier and a guide shaft extending along the optical axis direction may be formed.

In addition, the carrier may be formed with a guide groove having a "V" shaped cross-sectional shape in contact with the outer surface of the guide shaft.

In addition, the present invention may be formed so that the attraction portion for moving the carrier in the optical axis direction by forming a attraction force with the magnetic material on the yoke, the attraction portion is inserted into the stopper.

Alternatively, the stopper may be formed by providing an iron piece for moving the carrier in the optical axis direction by the attraction force with the magnetic body.

In this case, the iron piece may be formed to be inserted into the stopper through the insert injection.

According to the present invention having the above-described configuration, the ball guide is integrally formed on one surface of the carrier on which the lens is mounted so as to maintain the rolling contact with the inner surface of the first housing, and the driving unit composed of the coil, the substrate and the yoke carrier A stopper formed around the opening of the second housing while adjusting the focal length for the macro shooting by moving the position of the carrier by using the magnetic field induced between the magnetic material and the coil. By limiting the moving distance of the carrier through, there is an advantage that can minimize the stroke (stroke) and easily implement the macro (macro) function of the camera module at a low cost.

In addition, by applying a ball guide between the carrier and the first housing to facilitate the retraction movement of the lens assembly can reduce the power consumption for driving the lens assembly, and the drive is installed yoke in contrast to the existing AF (Auto focusing) actuator Not only does it eliminate the need for a separate ball guide injection part for injuries, it also eliminates the need for a drive IC to perform autofocusing, so it is structurally simple and inexpensive to manufacture. There is an advantage in that the device can be manufactured.

1 is a perspective view showing an auto focusing apparatus of a camera according to an embodiment of the present invention.
2 is an exploded perspective view of FIG. 1;
3 is a cross-sectional view showing the internal structure of FIG.
Figure 4 is a detailed view showing the detailed structure of the drive unit according to the present invention.
Figure 5 is a detailed view showing in detail the shape and formation position of the stopper formed in the projection jaw and the second housing formed on the carrier of the present invention.
6 is an operating state diagram illustrating a process in which a moving distance of a carrier is limited by a stopper of a second housing after power is applied to a coil;
Figure 7 is a perspective view showing the structure of the semi-circular guide shaft formed in the first housing and the "V" type guide groove formed in the carrier as another embodiment of the present invention.
8 is a cross-sectional view showing in detail the contact relationship between the guide shaft and the guide groove shown in FIG.
9 is a perspective view illustrating a yoke structure of a camera auto focusing apparatus according to a second embodiment of the present invention;
10 is a cross-sectional view showing a state in which the yoke shown in FIG. 9 is applied to an auto focusing device.
FIG. 11 is a perspective view illustrating a housing structure of a camera auto focusing apparatus equipped with iron pieces according to a third embodiment of the present invention; FIG.
12 and 13 are cross-sectional views illustrating a state in which the iron piece structure shown in FIG. 11 is mounted on the stopper portion of the housing in different forms.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an actuator for auto focusing of a small camera module mounted on a portable device such as a mobile communication terminal, and more particularly, between a magnetic body attached to a carrier equipped with a lens and a coil of a driving unit facing the same. It is configured to adjust the focal length by moving the lens in the optical axis direction by using a magnetic field induced in the stopper that can limit the optical axis movement distance of the lens in the bottom surface of the housing covering the upper surface of the carrier (stopper) It provides a camera auto focusing device that can minimize stroke deviation and effectively implement the macro function at low cost.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view showing an auto focusing apparatus of a camera according to an embodiment of the present invention, Figure 2 is an exploded perspective view of Figure 1, Figure 3 is a cross-sectional view showing the internal structure of FIG. And, Figure 4 is a detailed view showing a detailed structure of the drive unit according to the present invention, Figure 5 is a detailed view showing the shape structure and the formation position of the projection jaw formed in the stopper and the carrier formed in the second housing of the present invention in detail . 6 is an operational state diagram illustrating a process in which the moving distance of the carrier is limited by the stopper of the second housing after power is applied to the coil. And, Figure 7 is a perspective view showing the formation structure of the semi-circular guide shaft formed in the first housing and the "V" type guide groove formed in the carrier as another embodiment of the present invention, Figure 8 is a guide shaft and guide shown in Figure 7 It is sectional drawing which shows the contact relationship between grooves in detail.

1 to 8, the apparatus 100 for auto focusing of a camera according to an embodiment of the present invention includes a lens assembly 110 having one or more lenses installed therein and the lens assembly 110 fitted therein. A carrier 120, a first housing 130 in which the carrier 120 is received, a second housing covering an upper portion of the carrier 120 and coupled to the first housing 130. 140 and a driving unit 150 for driving the carrier 120 in the optical axis O direction.

The lens assembly 110 has at least one lens installed therein, and adjusts the focal length of the lens while moving forward and backward along the optical axis O in association with the carrier 120.

The carrier 120 has an insertion hole 121 into which the lens assembly 110 can be inserted in the center of the carrier 120, and a magnetic body 122 is inserted and attached to one surface of the carrier 120.

The carrier 120 is assembled with the lens assembly 110 to be stored in the inner space of the first housing 130.

In addition, one surface of the first housing 130 facing the magnetic material of the carrier 120 is opened to form an opening 131, and a driving unit 150 for driving the carrier 120 includes the opening ( It is inserted through the 131 is installed to face the magnetic body 122.

On the other hand, the present invention is provided with a stopper means for limiting the movement distance of the carrier 120 within a certain range during the movement of the carrier 120 in the optical axis direction by the drive unit 150.

That is, an opening 141 penetrated along the optical axis O direction is formed at the center of the second housing 140 to allow the lens assembly 110 to be inserted therein, and the first and second openings 141 are formed at the periphery of the opening 141. A pair of stoppers 142 protrude downward from the bottom of the two housings 140 so as to limit the moving distance of the carrier 120 in the optical axis direction.

Correspondingly, at one upper surface of the carrier 120, a protruding jaw protrudes a predetermined height in an upward direction so that an interference action with the stopper 142 of the second housing 140 occurs during the advancing and retreating movement of the carrier 120. 127 is provided.

Accordingly, when the carrier 120 into which the lens is inserted moves forward a predetermined distance along the optical axis direction (the upper side in the figure), the second projection 140 may have a protruding jaw 127 formed on one side upper surface of the carrier 120. Interfered with a pair of stoppers 142 formed at the bottom of the to prevent further advancement.

As described above, the present invention forms a stopper 142 protruding downwardly around the opening 141 of the second housing 140 as a stopper for limiting the moving distance of the lens during macro shooting, so that the carrier 120 is in the optical axis direction. By allowing only a certain distance along, so that the carrier 120 can be stopped at a certain moving position without using a separate complicated structure.

A plurality of assembling protrusions 143 and 144 are formed at the bottom of the second housing 140 so as to be engaged with the assembling grooves 133 and 134 formed at the upper edge of the first housing 130. .

The driving unit 150 includes a coil 153 to which power is applied, a substrate 152, and a yoke 151, and is induced between the coil 153 and the magnetic body 122 of the carrier 120. The carrier 120 is advanced and retracted in the direction of the optical axis O by the magnetic field.

The driving unit 150 is manufactured by simply attaching the coil 153 to the substrate 152 at the time of manufacture and then attaching and fixing the coil 153 to one surface of the yoke 151.

The coil 153 generates a driving force for moving the carrier 120 in the optical axis direction by electromagnetic induction and a magnetic body 122 attached to the carrier 120 by an externally applied power source.

The magnetic body 122 is disposed to face the driving unit 150 to generate a driving force for advancing and moving the lens assembly 110 while interacting with the coil 153 installed in the driving unit 150.

The yoke 151 guides the magnetic field of the magnetic body 122 toward the driving unit 150.

The substrate 152 is a flexible flexible substrate (FPCB) and is positioned between the coil 153 and the yoke 151 to provide power to the coil 153.

The lower left and right sides of the yoke 151 have a pair of bent portions 154 vertically bent in the inward direction of the first housing 130 in which the magnetic body 122 is located.

The bent portion 154 forms a attraction force with the magnetic body 122 when the power is released, so that the position of the carrier 120 can be returned to its original state.

According to the configuration of the driving unit 150, the coil 153 generates an electric field as a current is applied to the coil 153, the electric field of the coil 153 and the magnetic field of the magnetic body 122 mutually While acting, the driving force for generating and moving the carrier 120 on which the lens assembly 110 is mounted in the optical axis direction is generated.

On the other hand, the camera auto-focusing device according to the present invention is provided with a separate guide means between the carrier 120 and the first housing 130 to be relative to each other while facing each other linear movement of the optical axis direction of the carrier 120 It is intended to guide.

As a guide means for guiding between the carrier 120 and the first housing 130, the ball guide ball contact with the inner surface of the first housing 130 on the left and right portions of the magnetic body 122 of the carrier 120 125 is installed.

The ball guide 125 includes a plurality of balls 123 and grooves 124 having a “V” shape formed on the carrier 120 to accommodate the balls 123. The ball guide 125 as described above is preferably formed integrally with the carrier 120.

In addition, a guide groove 134 corresponding to the groove 124 formed in the carrier 120 is formed on the inner surface of the first housing 130 corresponding to the ball guide 125.

The ball 123 is accommodated in the groove 124 of the carrier 120, a part of the outer peripheral surface of the ball 123 is in contact with the inner wall of the guide groove 134 of the inner surface of the first housing 130. The ball 123 rotates in the groove 124 and the guide groove 134, respectively, to smoothly move forward and backward of the carrier 120. That is, the ball 123 is to reduce the friction generated during the forward and backward movement of the carrier 120 while rolling (rolling).

At this time, the guide groove 134 is preferably formed as a groove having a "V" shape, similar to the shape of the groove 124 formed in the carrier 120.

In this manner, the groove 124 of the carrier 120 and the guide groove 134 of the first housing 130 are formed in the grooves having a “V” shape to thereby move the forward and backward movement direction of the carrier 120. It can be limited only in the optical axis (O) direction.

On the other hand, in the camera focusing device of the present invention, as shown in the cross-sectional view of Figure 3, a sensor assembly for image detection may be installed in the lower portion of the first housing 130, the sensor assembly is an image sensor, a circuit board It may be composed of a flexible substrate.

An infrared filter 113 is installed in the lower surface opening of the first housing 130. As the opening formed in the lower part of the first housing 130 is closed by the infrared filter 113, the image sensor is completely shielded from the outside and detects only an image incident through the infrared filter 113.

On the other hand, Figure 7 shows the structure of the carrier 120 and the first housing 130 according to another embodiment of the present invention, the semi-circular guide shaft 136 and the carrier 120 formed inside the first housing 130 ) Is a perspective view showing the formation structure of the "V" type guide groove 124, Figure 8 is a cross-sectional view showing in detail the contact relationship between the guide shaft 136 and the guide groove 124 shown in FIG.

As shown in Figure 7 and 8, the present invention is a guide means for guiding between the carrier 120 and the first housing 130, in addition to the above-described guide of the ball contact method of the surface contact method that can be implemented at low cost Can be adopted.

That is, the guide shaft 136 having a semi-circular cross-sectional shape is integrally formed on the inner surface of the first housing 130 facing the carrier 120, and the carrier 120 has an outer surface of the guide shaft 136. It may be configured by integrally forming a guide groove 124 having a "V" cross-sectional shape to be guided in a surface contact.

Thus, by forming the guide means for guiding the drive 120 into the axial guide injection structure instead of the ball guide, it is possible to simplify the structure and minimize the increase in material costs due to ball mounting, low-cost low-cost macro (macro) This can be very useful for actuator implementation.

Referring to the driving principle of the camera auto focusing apparatus according to the present invention having the above-described configuration is as follows.

First, in the initial state in which power is not applied to the coil 153 of the driving unit 150, the lower surface of the carrier 120 on which the lens is mounted is disposed between the magnetic body 122 and the bent portion 154 of the yoke 151. By the attraction force formed it is maintained in close contact with the bent portion 154.

As the current is applied to the coil 153 of the driving unit 150 while the lower surface of the carrier 120 is in close contact with the bent portion 154 of the yoke 151, the driving force corresponding to the applied current value In this case, the carrier 120 moves in the direction of the optical axis O by the driving force, thereby moving the focal point of the lens for macro shooting.

In this process, the carrier 120 is moved away from the bent portion 154 while the current applied to the coil 153 is maintained. At this time, the carrier 120 advances a predetermined distance upwards. When moved, the protruding jaw 127 formed on one side upper surface of the carrier 120 interferes with the stopper 142 formed on the bottom of the second housing 140, thereby preventing the forward movement of the carrier 120. As a result, the carrier 120 can no longer move and stops at that position, so that macro photography is maintained.

Subsequently, when the current applied to the coil 153 is cut off after the photographing is completed, the driving force is dissipated and the carrier 120 is driven by an attractive force acting between the magnetic body 122 and the bent portion 154 of the yoke 151. ) Is returned and stopped at a position in close contact with the bent portion 154 below the yoke 151.

As described above, the present invention is to form a ball guide 125 integrally on one surface of the carrier 120 to which the lens assembly 110 is mounted to maintain a rolling contact with the inner surface of the first housing 130 In addition, the driving unit 150 including the coil 153, the substrate 152, and the yoke 151 is assembled to face the magnetic body 122 of the carrier 120 to be guided between the magnetic body 122 and the coil 153. By moving the position of the carrier 120 using the magnetic field to adjust the focal length for macro shooting while the movement distance of the carrier 120 through the stopper 142 formed on the bottom surface of the second housing 140 By limiting this to minimize the stroke (stroke) deviation of the lens, it is possible to easily implement the automatic macro function of the camera module at a low cost by applying a simple mechanical structure.

In addition, by applying the ball bearing guide means between the carrier 120 and the first housing 130 to facilitate the retreat movement of the lens it is possible to prevent the increase in power consumption due to the driving of the lens, and to focus on conventional AF (Auto focusing) In addition to the actuator, it is not necessary to apply a separate ball guide injection part on the drive unit where the yoke is installed, and there is no need to have a drive IC for automatic adjustment of the focal length. There is an advantage to manufacture a camera autofocus.

On the other hand, the first embodiment of the present invention described above is a form in which macro power is continuously supplied to the coil 153 of the driving unit 150 from the start of macro shooting, that is, from the start of the macro driving to the end of the macro driving. This may cause a problem that may increase power consumption.

In order to solve this problem, in the second embodiment of the present invention, the initial driving current is applied to the coil 153 only when the macro driving starts, and the current is cut off during the macro driving, and the carrier 120 is terminated when the macro driving ends. The present invention proposes a camera auto focus apparatus that can minimize power consumption due to macro driving by supplying only a driving current for returning the power to the original state.

9 is a perspective view illustrating a structure of a yoke 151 of a driving unit 150 in the apparatus for automatically focusing a camera according to the second embodiment of the present invention, and FIG. 10 is a diagram illustrating the yoke 151 of FIG. This is a cross-sectional view showing the state applied to the adjusting device. 9 and 10, in the second embodiment of the present invention, the yoke 151 of the driving unit 150 has a predetermined level with the magnetic body 122 attached to the carrier 120 during macro driving. The attraction portion 155 bent vertically to the magnetic body 122 side is formed to form an attraction force. In this case, as shown in FIG. 10, the attraction unit 155 forms an insertion groove inside the stopper 142 of the second housing 140 to be fitted into the insertion groove.

In addition, the attraction portion 155 is a degree capable of forming a certain level of attraction force with the magnetic body 122 so that the carrier 120 to maintain its movement state toward the attraction portion 155 when the macro 120 is taken in the macro shot It is desirable to have an area and a separation distance of.

For example, an area of the attraction part 155 may be formed to be equal to or larger than an area of the bent part 154 formed at the bottom of the yoke 151. In addition, the attraction unit 155 may be attached to be horizontal to the lower surface of the stopper 142 in some cases, in addition to the manner in which it is inserted into the stopper 142.

In this case, the attraction between the attraction portion 155 and the magnetic body 122 than the attraction force acting between the bent portion 154 of the lower end of the yoke 151 and the magnetic body 122 of the carrier 120 at the center position of the driving unit 150 Since the attraction force applied at the same or greater is formed, the attraction portion 155 and the attraction portion 155 are applied even if the forward current is applied to the coil 153 to initially move the carrier 120 in the optical axis direction of the lens and then block the forward current. The carrier 120 may be maintained at the macro position in the stationary state by the attraction force applied between the magnetic bodies 122, and after the end of the macro photography, a reverse current is applied to automatically return the carrier 120 to the initial position. You can.

As described above, the present invention forms an attraction portion 155 for forming attraction force with the magnetic body 122 at the upper end of the yoke 151 to form a form attached or embedded in the stopper 142 of the second housing 140. In the macro driving, the carrier 120 can be driven and stopped to the macro position by using the attraction force acting between the attraction portion 155 and the magnetic body 122 of the yoke 151 to the coil 153 continuously. Macro shooting can be performed without applying a driving current, and current consumption can be minimized.

On the other hand, Figure 11 is another embodiment of the present invention, while applying the structure of the yoke 151 of the first embodiment as described above as an example configured to install a separate iron piece 160 structure for forming the attraction force with the magnetic body 122 12 and 13 are cross-sectional views illustrating a structure in which the iron piece 160 structure illustrated in FIG. 11 is mounted on an auto focusing device.

As shown in FIGS. 11 and 12, the autofocus adjusting apparatus according to the third embodiment of the present invention uses the yoke 151 structure of the first embodiment (FIG. 4) as described above while the carrier 120 is used as it is. In order to form a magnetic force 122 and a predetermined level of attraction to the magnetic body attached to the) is configured to install a separately produced iron piece 160 structure on the stopper 142 portion of the second housing 140.

In this case, the iron piece 160 may be inserted into and installed between the stoppers 142 formed at the left and right sides of the bottom of the second housing 140, as shown in FIG. 11, or the installation structure of FIG. 13. As shown in the figure, the iron piece 160 may be injection molded by inserting the inside of the stopper 142 during the molding of the second housing 140.

As such, the present invention attaches the iron piece 160 made of a separate structure to the stopper 142 portion of the second housing 140 or to insert injection to form an attraction force for driving the optical axis in the carrier 120. By installing, the carrier 120 can be driven to the macro position by the attraction force acting between the iron piece 160 and the magnetic body 122 during the macro driving, thereby minimizing power consumption due to the continuous supply of current. .

In the foregoing detailed description of the present invention, specific embodiments have been described. However, it will be apparent to those skilled in the art that various modifications can be made without departing from the scope of the present invention.

110: lens assembly 120: carrier
122: magnetic material 123: ball
124: Home 125: Ball Guide
127: protruding jaw 130: first housing
140: second housing 150: drive unit
151: yoke 152: substrate
153: coil 154: bend
155: manpower department 160: iron piece

Claims (14)

In the auto focusing device of the camera,
A carrier into which the lens assembly is inserted in the center and to which the magnetic body is attached;
A first housing accommodating the carrier and having one side open to face the magnetic material;
A drive unit inserted into one open side of the first housing and configured to advance and retract the carrier in an optical axis direction;
A second housing covering an upper portion of the carrier and coupled to the first housing;
The second housing,
An opening formed through the optical axis to allow the lens assembly to be inserted;
A stopper protruding around the opening to limit the movement distance of the carrier in the optical axis direction; And
And an attraction portion for maintaining the moving state of the carrier advanced in the optical axis direction by the forward current applied to the driver through the attraction force with the magnetic material even after the blocking of the forward current. Adjustment device.
The apparatus of claim 1, wherein a ball guide contacting the inner surface of the first housing is provided at the carrier parts positioned at the left and right sides of the magnetic material.
The method of claim 2, wherein the ball guide,
One or more balls;
A groove for receiving the ball,
And the ball guide is formed integrally with the carrier.
The method of claim 1, wherein the driving unit,
A yoke for guiding a magnetic field generated from the magnetic material toward the driving unit;
A coil generating a driving force of the carrier in response to the magnetic material;
And a substrate positioned between the coil and the yoke to provide power to the coil.
5. The bending of claim 4, wherein the yoke is bent in an inward direction of the first housing in which the carrier is located to return the carrier to an initial position when the reverse current is applied to the driving unit by attraction force with the magnetic material. Auto focusing device of the camera, characterized in that formed.
The apparatus of claim 5, wherein the bent portion is provided in pairs on the left and right sides of the yoke.
The apparatus of claim 1, wherein the carrier is provided with a protruding jaw that interferes with the stopper of the second housing.
The apparatus of claim 3, wherein the groove has a cross-sectional shape of "V" shape.
The apparatus of claim 1, wherein a guide shaft extends along an optical axis direction and has a semi-circular cross-sectional shape to guide movement of the carrier.
10. The apparatus of claim 9, wherein the carrier has a guide groove having a “V” shaped cross-sectional shape in contact with an outer surface of the guide shaft.
The apparatus of claim 4, wherein the attractive part is formed by bending an upper portion of the yoke in the magnetic body side and being inserted into the stopper.
The apparatus of claim 1, wherein the attraction portion is a piece of iron provided in the stopper.
The apparatus of claim 12, wherein the iron piece is formed to be inserted into the stopper through insert injection.
The method of claim 5,
The area of the attraction portion is equal to or larger than the area of the bent portion, so that the attraction force between the attraction portion and the magnetic body is equal to or greater than the attraction force between the bent portion and the magnetic body at the center position of the driving unit. Camera auto focusing device.

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