KR101217597B1 - Auto focusing actuator of camera module - Google Patents

Abstract

The present invention relates to an auto focusing device for a camera module, and more particularly, to an auto focusing device for a camera module, which makes it possible to easily realize an auto focusing function of a camera mounted in a portable communication device such as a mobile phone by using a spindle motor principle. Relates to a device.
In other words, the present invention enables a lens-carrying carrier having a lens mounted by a circular magnet and a winding coil to perform forward and backward screw transfer by screwing, as in the spindle motor principle, thereby realizing a small number of parts and a simple assembly structure. At the same time, it aims to provide an auto focusing device for a camera module that can achieve a slimmer product.

Description

Auto focusing actuator of camera module

The present invention relates to an auto focusing device for a camera module, and more particularly, to an auto focusing device for a camera module, which makes it possible to easily realize an auto focusing function of a camera mounted in a portable communication device such as a mobile phone by using a spindle motor principle. Relates to a device.

In addition to rapid technological advances in devices such as digital cameras and smart phones, high-pixel camera modules have been developed and applied.These camera modules include an Auto Focusing (AF) function that automatically focuses a subject. have.

In particular, communication devices such as mobile phones and portable PCs generally include not only a function of transmitting text or voice data but also image data shooting and transmission functions, and camera modules are installed in mobile phones and portable PCs.

However, since mobile phones and portable PCs (hereinafter referred to as portable communication devices) belong to small devices, camera modules installed in portable communication devices also have design constraints that their size must be small. For this reason, the fixed lens method is simple in most portable communication devices.

Therefore, even if the user continuously monitors the image and does not need a separate operation, the autofocus (AF) function, in which the autofocus of the lens is performed by the actuator when the distance of the subject changes, is partially applied to the portable communication device. Too many parts for this, and thus the assembly structure is complicated, in particular, there is an appearance problem that the lens protrudes out of the product to secure the forward and backward drive space of the lens for autofocus.

In addition, as the height of the product increases as the lens protrudes out of the product for auto focus, there is a problem such as reversing the product slim.

The present invention has been made in order to solve the above-mentioned conventional problems, so that the lens-carrier for mounting the lens by the circular magnet and the winding coil to the forward and backward screw transfer according to the screw coupling, as in the spindle motor principle It is therefore an object of the present invention to provide an auto focusing device for a camera module that can realize a small number of parts and a simple assembly structure and at the same time achieve a slim product.

One embodiment of the present invention for achieving the above object is a camera module auto focusing apparatus comprising a cover body defining a camera module mounting space of the portable communication device and an image sensor mounting plate mounted on the rear end of the cover body; And a holder for fixing a hollow coil integrally attached to an inner diameter surface of the cover body; A plurality of winding coils arranged so as to be electrically connected to inner diameters of rear ends of the holder for fixing the coil; A hollow structure having a female screw thread formed on an inner diameter surface thereof, the lens guide body integrally connected to an inner diameter of a middle portion of a holder for fixing a coil; A lens transport carrier having a lens mounted on the front end and a male thread formed on the outer diameter surface of the lens guide body being screwed to the female thread; A structure in which the N pole and the S pole are repeatedly formed along the circumferential direction, the magnet being integrally mounted to the rear end of the lens transport carrier and adjacent to the plurality of winding coils; It provides an auto focusing device for a camera module comprising a.

In one embodiment of the present invention, the inner diameter of the rear end of the holder for fixing the coil is formed with a coil fixing groove along the circumferential direction, characterized in that a plurality of winding coils are fixed at equal intervals in the coil fixing groove.

Preferably, the four winding coils are arranged in the coil fixing groove of the coil fixing holder at equal intervals along the circumferential direction.

More preferably, the circular magnet is characterized in that four N poles and four S poles are formed repeatedly.

Another embodiment of the present invention for achieving the above object is an autofocusing device for a camera module comprising a cover body defining a camera module mounting space of the portable communication device and an image sensor mounting plate mounted to the rear end of the cover body; And a holder for fixing a hollow coil integrally attached to an inner diameter surface of the cover body; A plurality of 1 × �¨ winding coils arranged to be electrically connected to the inner diameter of the rear end of the holder for fixing the coil; A hollow structure having a second male thread formed on the outer diameter surface of the front end and a first female thread formed on the inner diameter surface of the front end, the lens guide body integrally connected to the inner diameter of the middle portion of the holder for fixing the coil; A first lens transporting carrier having a first lens for short distances mounted at a front end thereof, and having a first male thread screwed to a first female thread of a lens guide body at an outer diameter surface thereof; A first circular magnet in which the N pole and the S pole are repeatedly formed along the circumferential direction, the first circular magnet being integrally mounted to the rear end of the first lens transport carrier and adjacent to a plurality of primary driving winding coils; A plurality of secondary driving winding coils arranged to be electrically connected to inner diameters of the front ends of the holders for fixing the coil; A second circular magnet spaced apart from and inserted into an outer diameter surface of the lens guide body; The second lens is mounted on the front end of the distant lens, and the inner diameter surface is a hollow structure having a second female thread screwed to the second male thread of the lens guide body, and the second lens having the rear end integrally connected to the second circular magnet. Transport carriers; It provides an auto focusing device for a camera module comprising a.

In another embodiment of the present invention, a first coil fixing groove is formed in the inner diameter of the rear end of the holder for fixing the coil along the circumferential direction, a second coil fixing groove is formed in the inner diameter of the front end portion, and the first and second coils are formed. A plurality of primary winding winding coils and secondary winding winding coils are fixed at equal intervals in the fixing groove, respectively.

Preferably, four primary driving winding coils and secondary driving winding coils are arranged at equal intervals along the circumferential direction in the first and second coil fixing grooves of the coil fixing holder. .

More preferably, the first and second circular magnets are characterized in that four N-poles and four S-poles are formed repeatedly.

Through the above-mentioned means for solving the problems, the present invention provides the following effects.

According to the present invention, the lens-carrying carrier for mounting the lens by the circular magnet and the winding coil to be screwed forward and backward like the spindle motor principle, automatic focusing of the lens can be made easily.

In particular, the number of parts for forward and backward conveyance of the lens is small, so that a simple assembly structure can be realized and the product can be made slimmer.

In addition, there is an advantage that low-cost production is possible by providing a reduction in the number of parts and a simple assembly structure.

1 and 2 are cross-sectional views showing an auto focusing device for a camera module according to an embodiment of the present invention;
3 is a winding coil connection diagram corresponding to a magnet of an auto focusing device for a camera module according to an embodiment of the present invention;
4 and 5 are cross-sectional views showing an auto focusing device for a camera module according to another embodiment of the present invention;
Figure 6 is a coil winding diagram corresponding to the magnet of the auto focusing device for a camera module according to another embodiment of the present invention.

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

1 and 2 are cross-sectional views illustrating an auto focusing apparatus for a camera module according to an embodiment of the present invention, wherein reference numeral 100 denotes a cover body defining a camera module mounting space of a portable communication device, and reference numeral 102. Indicates the image sensor top plate mounted on the rear end of the cover body.

The present invention is to advance and retract the lens by using the winding coil and the circular magnet, so that the auto focusing of the lens is made, for this purpose, the hollow coil for fixing the winding coil 120 to the inner diameter surface of the cover 100 The coil fixing holder 110 is integrally mounted.

In order to fix the winding coil 120, a coil fixing groove 112 is formed along the circumferential direction at an inner diameter of the rear end of the coil fixing holder 110, and a plurality of coil connecting grooves are electrically connected to each other in the coil fixing groove 112. Winding coils 120 are inserted and fixed at equal intervals.

More specifically, four winding coils 120 are inserted into and fixed in the coil fixing grooves 112 of the coil fixing holder 110, and four winding coils 120 are disposed along the circumferential direction of the coil fixing grooves 112. ) And fix it so that it is equally spaced.

In this case, the winding coil 120 may be mounted with a changed size according to the moving distance of the lens transport carrier 140.

On the other hand, the hollow lens guide body 130 is disposed in the inner diameter of the holder for fixing the coil, the lens guide body 130, the outer diameter of the middle portion is the inner diameter of the middle portion of the holder for fixing the coil 110 It is integrally connected and integrated with the holder 110 for fixing the coil. At this time, an internal thread 132 is formed on the inner diameter surface of the lens guide body 130.

In particular, the lens transport carrier 140 is fastened to the lens guide body 130 so as to be forward or backward by screw transfer.

The lens transfer carrier 140 has a structure in which a lens 142 is mounted and fixed to a front end portion thereof, and a male thread 144 is formed on an outer diameter surface thereof to be screwed to a female thread 132 of the lens guide body 130. It is provided.

At this time, the rear end of the lens transport carrier 140 is integrally mounted with a circular magnet 150 arranged adjacent to the plurality of winding coils 120.

In more detail, the circular magnet 150 has a circular ring shape, and is provided with a structure in which the N pole and the S pole are repeatedly formed along the circumferential direction and integrally mounted to the rear end of the lens transport carrier 140.

Preferably, as can be seen in the accompanying Figure 3, the circular magnet 150 is provided with four N-poles and four S-poles are formed repeatedly along the circumferential direction, four winding coils 120 arranged outside ) And the corresponding state.

Here, look at the operation flow of the auto focusing device for a camera module according to an embodiment of the present invention.

When the current is applied to the four winding coils 120, the winding coil 1 has an N pole, the winding coil 2 has an S pole in the direction in which the current flows, and the winding coil 3 has an N pole. Winding coil 4 has an S pole.

Therefore, as the current is applied to the four winding coils 120, the N pole and the S pole correspond to the N pole and the S pole of the circular magnet 150 arranged therein, and are pushed to each other, and at the same time, the circular magnet ( 150 rotates in the forward direction.

As the circular magnet 150 rotates in the forward direction, the lens transport carrier 140 integrated with the circular magnet 150 rotates in the forward direction, and thus the male thread of the lens transport carrier 140 is rotated. 144 is screwed along the female thread 132 of the lens guide body 130 in the forward direction.

Accordingly, the lens conveyance carrier 140 is advanced by screw conveyance, and auto focusing of the lens 142 mounted on the lens conveyance carrier 140 is performed, and photographed through the lens 142. The object image is recognized by the image sensor 104 fixed to the image sensor mounting plate 102.

On the other hand, when the current is applied to the four winding coils 120 in the opposite direction, the circular magnet 150 is rotated in the reverse direction in accordance with the flow direction of the current flowing in the opposite direction, the male thread of the lens carrier carrier 140 The screw 144 is screwed in the reverse direction along the female thread 132 of the lens guide body 130, and auto focusing of the lens 142 mounted on the lens transfer carrier 140 is performed again.

Here, an auto focusing apparatus for a camera module according to another embodiment of the present invention will be described.

4 and 5 are cross-sectional views illustrating an auto focusing apparatus for a camera module according to another embodiment of the present invention, and reference numeral 200 denotes a cover body defining a camera module mounting space of a portable communication device, and reference numeral 202. Indicates an image sensor mounting plate mounted on the rear end of the cover body.

Another embodiment of the present invention is characterized in that the first lens 242 for short distance and the second lens 282 for long distance are mounted independently of each other by a winding coil and a circular magnet.

To this end, a hollow coil fixing holder 210 is mounted on the inner diameter surface of the cover body 200, and the coil fixing holder 210 has a primary coil winding coil 220 and a secondary drive. Winding coil 260 is spaced apart in the front and rear direction is fixed.

More specifically, the four primary drive winding coils 220 are connected to the first coil fixing groove 212 formed along the circumferential direction at the inner diameter of the rear end of the coil fixing holder 210 so as to be conductive. Four secondary drive winding coils 260 are inserted and fixed at equal intervals along the direction and electrically connected to the second coil fixing groove 214 formed along the circumferential direction in the front end inner diameter along the circumferential direction. It is inserted and fixed at equal intervals.

At this time, the lens guide body 230 of the hollow structure is integrally connected to the inner diameter portion of the holder for fixing the coil 210 is arranged integrally.

The lens guide body 230 has a hollow structure in which a second male thread 232 is formed on a front outer diameter surface and a first female thread 234 is formed on an entire inner diameter surface.

In particular, a first lens transfer carrier 240 is screwed to the first female thread 234 of the lens guide body 230. The first lens 242 is mounted and fixed, and the outer diameter surface has a structure in which a first male thread 244 which is screwed to the first female thread 234 of the lens guide body 230 is integrally formed.

In addition, as shown in FIG. 6, a first circular magnet 250 having a structure in which the N pole and the S pole are repeatedly formed along the circumferential direction is integrally mounted at the rear end of the first lens transport carrier 240. The primary driving winding coils 220 are arranged adjacent to each other.

On the other hand, the second lens transfer carrier 280 is fastened to the second male thread 244 of the lens guide body 230 so that the screw transfer, the second lens transfer carrier 280 is a front end portion The remote second lens 282 is mounted and fixed, and has a hollow structure in which a second female thread 284 is screwed to the second male thread 232 of the lens guide body 230 on the inner diameter surface thereof. .

In addition, as shown in FIG. 6, a second circular magnet 270 is integrally mounted to the rear end of the second lens transport carrier 280, and the second circular magnet 270 also has four N poles and four S poles. The pole is provided in a circular ring type structure repeatedly formed, and is in a state of being arranged adjacent to the secondary coil winding coil 260.

Here, look at the operation flow of the auto focusing device for a camera module according to another embodiment of the present invention.

When a current is applied to the four primary driving winding coils 220, the winding coil 1 has an N pole along the direction in which the current flows, and the winding coil 2 has an S pole, and the winding coil 3 also. Is the N pole, and the winding coil 4 is the S pole.

Accordingly, as the current is applied to the four primary driving winding coils 220, the N pole and the S pole correspond to the N pole and the S pole of the first circular magnet 250 arranged therein, and are pushed together. At the same time, the first circular magnet 250 rotates in the forward direction.

As the first circular magnet 250 rotates in the forward direction, the first lens transfer carrier 240 integrated with the first circular magnet 250 rotates in the forward direction, thereby transferring the first lens. The first male thread 244 of the carrier 240 is screwed in the forward direction along the first female thread 234 of the lens guide body 230.

Accordingly, the first lens transfer carrier 240 is advanced by screw transfer, and auto focusing of the short distance first lens 242 mounted on the first lens transfer carrier 240 is performed. The near-field image captured by the near-field first lens 242 is recognized by the image sensor 204 fixed to the image sensor mounting plate 202.

On the other hand, when a current is applied to the secondary coil winding coil 260, the winding coil 1 has an N pole, the winding coil 2 has an S pole in the direction in which the current flows, and also wound 3 times The coil has an N pole and the winding coil 4 has an S pole.

Therefore, as the current is applied to the secondary coil winding coil 260, the N pole and the S pole correspond to the N pole and the S pole of the second circular magnet 270 arranged therein and are pushed together. At the same time, the second circular magnet 270 is rotated in the forward direction.

As the second circular magnet 270 rotates in the forward direction, the second lens transfer carrier 280 integrated with the second circular magnet 270 rotates in the forward direction, thereby transferring the second lens. The second female thread 244 of the carrier 280 is screwed in the forward direction along the second male thread 232 of the lens guide body 230.

Accordingly, the second lens transfer carrier 280 is advanced by screw transfer, and the auto focusing of the remote second lens 282 mounted on the second lens transfer carrier 280 is performed. The remote object image photographed through the second lens 282 may be recognized by the image sensor 204 fixed to the image sensor mounting plate 202.

On the other hand, if the current in the opposite direction is applied to the primary driving winding coil 220 and the primary driving winding coil 260, according to the flow direction of the current flowing in the opposite direction, the first and second circular magnet ( 250 and 270 are rotated in the reverse direction, so that auto focusing of the short distance first lens 242 and the long distance second lens 282 mounted on the first and second lens transport carriers 240 and 280 are performed again.

100: cover body 102: image sensor mounting plate
104: image sensor 110: holder for fixing the coil
112: coil fixing groove 120: winding coil
130: lens guide body 132: female thread
142 lens 144 male thread
140: lens transport carrier 150: circular magnet
200: cover body 202: image sensor mounting plate
204: image sensor 210: holder for fixing the coil
212: first coil fixing groove 214: second coil fixing groove
220: primary winding coil 230: lens guide body
232: 2nd male thread 234: 1st female thread
240: first lens transfer carrier 242: short-range first lens
244: first male thread 250: first circular magnet
260: winding coil for secondary drive 270: second round magnet
280: carrier for transporting the second lens 282: second lens for the long distance
284 female thread 2

Claims (8)

In the auto focusing device for a camera module comprising a cover body (100) defining a camera module mounting space of a portable communication device and an image sensor mounting plate (102) mounted on the rear end of the cover body (100),
Hollow coil fixing holder 110 is integrally attached to the inner diameter surface of the cover body 100;
A plurality of winding coils 120 arranged in a state in which the rear end portions of the coil fixing holder 110 are electrically connected to each other;
A hollow structure having a female thread 132 formed on an inner diameter surface thereof, the lens guide body 130 being integrally connected to an inner diameter of a middle portion of the holder 110 for fixing the coil;
A lens transport carrier 140 having a lens 142 mounted on a front end thereof and a male thread 144 screwed to an internal thread 132 of the lens guide body 130 on an outer diameter surface thereof;
N and S poles are repeatedly formed along the circumferential direction, the magnets are integrally mounted to the rear end of the lens transport carrier 140, the circular magnet 150 adjacent to the plurality of winding coils 120;
Auto focusing device for a camera module, characterized in that configured to include.
The method according to claim 1,
In the inner diameter of the rear end of the holder for fixing the coil 110 is formed a coil fixing groove 112 along the circumferential direction, and the plurality of winding coils 120 are fixed at equal intervals in the coil fixing groove 112. An auto focusing device for a camera module.
The method according to claim 1,
Auto coil focusing device for a camera module, characterized in that the four winding coils 120 are arranged at equal intervals along the circumferential direction in the coil fixing groove 112 of the coil fixing holder (110).
The method according to claim 1,
The circular magnet 150 is an auto focusing device for a camera module, characterized in that four N-poles and four S-poles are formed repeatedly.
In the auto focusing device for a camera module comprising a cover body 200 defining a camera module mounting space of a portable communication device and an image sensor mounting plate 202 mounted to the rear end of the cover body 200,
A hollow coil fixing holder 210 integrally attached to an inner diameter surface of the cover body 200;
A plurality of primary driving winding coils 220 arranged in a state in which the rear end portions of the coil fixing holder 210 are electrically connected to each other;
The second male screw thread 232 is formed on the outer diameter surface of the front end, and the first female thread thread 234 is formed on the inner diameter surface, and the lens guide body is integrally connected to the inner diameter of the middle portion of the coil fixing holder 210. 230;
The first lens for transferring the first lens 242 is mounted on the front end portion, and the first male thread 244 is screwed to the first female thread 234 of the lens guide body 230 on the outer diameter surface. Carrier 240;
N-pole and S-pole are repeatedly formed along the circumferential direction, the first circular magnet is integrally mounted to the rear end of the first lens transfer carrier 240 and adjacent to a plurality of primary drive winding coils 220. 250;
A plurality of secondary driving winding coils 260 arranged to be electrically connected to inner diameters of the front ends of the holders for fixing the coil 210;
A second circular magnet 270 spaced apart from and inserted into an outer diameter surface of the lens guide body 230;
The second lens 282 for a long distance is mounted on the front end portion, and the inner diameter surface is a hollow structure formed with a second female thread 284 screwed to the second male thread 232 of the lens guide body 230, A second lens transfer carrier 280 integrally connected to an end of the second circular magnet 270;
Auto focusing device for a camera module, characterized in that configured to include.
The method according to claim 5,
A first coil fixing groove 212 is formed in the inner diameter of the rear end portion of the coil fixing holder 210 along the circumferential direction, and a second coil fixing groove 214 is formed in the inner diameter of the front end portion of the coil fixing holder 210. A plurality of primary driving winding coils 220 and secondary driving winding coils 260 are fixed at equal intervals in the coil fixing grooves 212 and 214, respectively.
The method according to claim 5,
Four primary driving winding coils 220 and secondary driving winding coils 260 are spaced equally along the circumferential direction in the first and second coil fixing grooves 212 and 214 of the coil fixing holder 210, respectively. Auto focusing device for a camera module, characterized in that arranged in the form.
The method according to claim 5,
The first and second circular magnets (250,270) are auto focusing device for a camera module, characterized in that four N-poles and four S-poles are formed repeatedly.

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