KR101128149B1 - Shutter device - Google Patents

Abstract

The shutter device of the present invention includes a base having a lens hole through which the reflected light of the subject passes; A first blade and a second blade rotated about a hinge provided in the base to open or close the lens hole; An actuator unit having a slider which is linearly moved at a position eccentric from the hinge so as to exert a rotation moment force on the first blade and the second blade; It includes.

Description

Shutter Device {SHUTTER DEVICE}

The present invention relates to a shutter device for opening and closing the exposure of the lens in an optical imaging device such as a mobile device with a camera.

Recently, the performance of optical imaging devices including camera-equipped mobile devices has been diversified and advanced. Accordingly, the adoption of shutters that open or block the exposure of lenses in general cameras is urgently needed. When a shutter is used in a mobile device with a built-in camera, it is possible to shoot a higher quality image than before, and a condition for fully exhibiting the performance of a high resolution built-in camera is prepared.

However, in a small mobile device, due to the limitation of the installation space and battery consumption, the miniaturization of the shutter device including the shutter and other components for operating the same and the reduction of driving power are considered to be considered in the design.

That is, the conventional shutter device has a large number of parts and a complicated operation structure, which requires an installation space unnecessarily, and has a problem in that battery consumption is large due to large power transmission loss.

In addition, the shutter device must have a high shutter speed so as to instantly open and close the light reflected from the subject. For example, when the shutter is operated by using a plurality of gears or a complicated link structure, the shutter speed is slow, and thus the photographed image There was a problem causing the deterioration of the image quality.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and has a simple power transmission structure to provide a shutter device that can reduce installation space, reduce power consumption, and improve response speed.

The technical problem to be achieved by the present invention is not limited to the technical problem mentioned above, and other technical problems not mentioned above may be clearly understood by those skilled in the art from the following description. will be.

The shutter device of the present invention includes a base having a lens hole through which the reflected light of the subject passes; A first blade and a second blade rotated about a hinge provided in the base to open or close the lens hole; An actuator unit having a slider which is linearly moved at a position eccentric from the hinge so as to exert a rotation moment force on the first blade and the second blade; It includes.

The shutter device of the present invention can reduce the installation space by having a simple power transmission structure, the electromagnetic force of the coil is directly connected to the slider, the power consumption is reduced, and due to the direct structure that does not depend on a large number of link structures The shutter response speed can be improved.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In this process, the size or shape of the components shown in the drawings may be exaggerated for clarity and convenience of description. In addition, terms that are specifically defined in consideration of the configuration and operation of the present invention may vary depending on the intention or custom of the user or operator. Definitions of these terms should be made based on the contents throughout the specification.

1 is a perspective view showing a shutter device of the present invention. 2 is a partial perspective view showing in detail the actuator portion of the shutter device of the present invention. 3 is a perspective view of a shutter device in which the first blade and the second blade are in an open position as an embodiment of the present invention. 4 is a perspective view showing the shutter device of the present invention at the time when the close operation is started. FIG. 5 is a perspective view of a shutter device in which the first blade and the second blade are in a closed position as an embodiment of the present invention. 6 is a perspective view showing the shutter device of the present invention at the time when the open operation is started. 1 to 6, the configuration and operation of the shutter device of the present invention will be described in detail.

The shutter device of the present invention is installed in a miniaturized optical imaging device such as a mobile device with a built-in camera, for example, and opens or closes the lens hole 101 serving as an incident path of light to the lens.

The shutter device includes a base 100 in which the lens hole 101 is formed, a first blade 110a and a second blade 110b for opening and closing the base 100, and an actuator part 500 for driving them.

The base 100 forms a skeleton of the shutter device and is attached to or detached from the optical imaging device by a fastening member. The base 100 has a lens hole 101 through which the reflected light of the subject passes. When the shutter device is fastened to the optical imaging device, the lens group of the optical imaging device faces the lens hole 101.

The first blade 110a and the second blade 110b open or close the lens hole 101. In this embodiment, the first blade 110a and the second blade 110b are rotated around the hinge 104 provided in the base 100, respectively.

Driving force for their rotation is provided by the actuator unit 500. The actuator unit 500 may employ a pneumatic cylinder, a servo motor, or the like, but adopts a driving method by the combination of the coil 230 and the magnet unit 420 to reduce power consumption and reduce light weight.

In addition, since the slider 400 providing the rotation moment force of the first blade 110a and the second blade 110b is linearly moved, the number of parts of the power transmission unit is largely omitted, and thus the blades 110a and 110b. Precise position control is possible. That is, the slider 400 is linearly moved at a position eccentric from the hinge 104 of the base 100 so as to exert a rotation moment force on the first blade 110a and the second blade 110b.

In detail, the actuator part 500 includes a slider 400, a magnet part 420 magnetized with a multipole including a first magnetic pole part 420a and a second magnetic pole part 420b, and a stator 200. The slider 400 is coupled to the first blade 110a and the second blade 110b at a position eccentric from the hinge 104. The hinge holes 114 drilled in the first blade 110a and the second blade 110b, respectively, are loosely fitted to the hinge 104 so as to be rotatable. The boss 410 protruding from the upper side of the slider 400 is loosely fitted into the boss hole 116 drilled into the first blade 110a and the second blade 110b to suppress frictional resistance.

The magnet portion 420 is an embodiment in which a plurality of magnetic poles including a first magnetic pole portion 420a and a second magnetic pole portion 420b are magnetized to one magnet, and the first magnetic pole portion 420a and the second magnetic pole are independent of each other. Various modified embodiments are possible, such as an embodiment in which the magnetic pole parts 420b are magnetized and the plurality of magnets are connected in a line. In addition, three or more different magnetic poles may be provided in the magnet part 420 by forming separate magnetic poles in addition to the first magnetic pole part 420a and the second magnetic pole part 420b.

The first magnetic pole part 420a and the second magnetic pole part 420b are magnetized to have opposite polarities and are formed in a line along the linear movement direction of the slider 400. The first bending portion 481 and the second bending portion 482, which are bent downwardly, the slider 400, move the magnet portion 420 including the first magnetic pole portion 420a and the second magnetic pole portion 420b to the slider 400. Firmly).

The stator 200 linearly moves the slider 400 by applying an electromagnetic force to the first magnetic pole part 420a and the second magnetic pole part 420b. The stator 200 includes a coil 230 facing the magnet portion 420 including the first magnetic pole portion 420a and the second magnetic pole portion 420b, and a core member 240 surrounding the coil 230. .

As a structure for linearly moving the slider 400, the first magnetic pole part 420a and the second magnetic pole part 420b are arranged in a line along the moving direction of the slider 400.

In addition, the coil 230 may be wound to a width Wc smaller than the total extension length of the magnet part 420 including the first magnetic pole part 420a and the second magnetic pole part 420b so that the first magnetic pole part 420a may be wound. And a position biased to any one of the second magnetic pole parts 420b. Therefore, even if a large number of link parts for power conversion are not provided, it is possible to simply obtain a linear movement force in one direction and in the opposite direction.

In addition, the core member 240 includes a first protrusion 241, a pair of second protrusions 242, a connection portion 243, and an edge portion 244. The first protrusion 241 protrudes in one direction of the coil 230 and faces the magnet part 420 including the first magnetic pole part 420a or the second magnetic pole part 420b with the separation plate 250 therebetween. do. The second protrusion 242 protrudes in the other direction of the coil 230 and has an electromagnetic force of opposite polarity to the first protrusion 241 when power is applied to the coil 230.

The first protrusion 241 and the second protrusion 242 are formed by bending a single flat plate, not a structure in which separate parts are combined. Therefore, component tolerances and manufacturing costs can be lowered. The connection part 243 is a part which connects the 1st protrusion part 241 and the 2nd protrusion part 242 provided in one component.

The first protrusion 241 and the connection portion 243 are located inside the coil 230, and the second protrusion 242 and the edge portion 244 are located outside the coil 230.

On the other hand, to apply a greater electromagnetic force to the first magnetic pole portion 420a and the second magnetic pole portion 420b, and to regulate the moving span S of the first magnetic pole portion 420a and the second magnetic pole portion 420b. Provided for the purpose is a pair of edges 244.

The pair of edge portions 244 extends from the edge portion 244 of the second protrusion 242 back to one side of the coil 230 to the first magnetic pole portion 420a and the second magnetic pole portion 420b. It exerts a greater electromagnetic force, thereby reducing the power consumption.

The pair of edge portions 244 has a separation distance D2 greater than the total extension length D1 of the magnet portion 420 including the first magnetic pole portion 420a and the second magnetic pole portion 420b. The movable span S for which the slider 400 is movable is obtained by subtracting the total extension length of the magnet part 420 including the first magnetic pole part 420a and the second magnetic pole part 420b from the edge part 244. Becomes

In addition, a separation plate 250 disposed above the first protrusion 241 is provided. The magnet parts 420 including the first magnetic pole part 420a and the second magnetic pole part 420b are arranged in a row on the separation plate 250. Here, the edge portion 244 extends higher than the separator plate 250. By adjusting the height step H of the edge portion 244 with respect to the separator 250, the moving speed of the slider 400 and the response speed of the first blade 110a and the second blade 110b can be adjusted. There is this.

Accordingly, one of the first magnetic pole portion 420a and the second magnetic pole portion 420b may contact the protruding portion of the edge portion 244 by the first contact position and the second contact position of the slider 400. The movable span S is limited. In addition, when no power is applied to the coil 230, the edge portion 244 allows the slider 400 to maintain the closed position or the open position in spite of an external force such as an impact force.

Meanwhile, a means for guiding linear movement of the slider 400 to which the magnet part 420 including the first magnetic pole part 420a and the second magnetic pole part 420b is coupled is provided. In this embodiment, the linear movement of the slider 400 is guided by moving the magnet part 420 including the first magnetic pole part 420a and the second magnetic pole part 420b in contact with the separator plate 250. .

In addition, the slider 400 may include the first bending part 481 and the second bending part 482 which are in close contact with the side surfaces of the magnet part 420 including the first magnetic pole part 420a and the second magnetic pole part 420b. It includes, the first bending portion 481 is moved in contact with the guide 180 formed in the base 100. Thus, linear movement of the slider 400 is guided.

On the other hand, the repeating accuracy of the open position where the first blade 110a and the second blade 110b open the lens hole 101 and the close position that closes the lens hole 101 is the stopper 102 and the stopper hole 112. Is also achieved.

That is, a stopper hole 112 is formed in each of the first blade 110a and the second blade 110b, and the stopper 102 protrudes from a part of the base 100 exposed by the stopper hole 112. The stopper hole 112 includes a first contact portion 1121 corresponding to one inner wall of the stopper hole 112 and a second contact portion 1122 corresponding to the other inner wall of the stopper hole 112. The stopper 102 includes a close part 1021 corresponding to one outer wall of the stopper 102 and an open part 1022 corresponding to the other outer wall of the stopper 102.

Accordingly, when the first blade 110a and the second blade 110b are closed, the first contact portion 1121 and the close portion 1021 come into contact with each other to close the first blade 110a and the second blade 110b. The location is defined.

The open position of the first blade 110a and the second blade 110b is defined by contacting the second contact portion 1122 and the open portion 1022 during the opening operation of the first blade 110a and the second blade 110b. do.

Next, an operation of the shutter device will be described with reference to FIGS. 3 to 6.

Referring to FIG. 3, the first blade 110a is locked in the open position. When the first magnetic pole portion 420a is in close contact with the edge portion 244 (which is referred to as a first contact position), the first blade 110a can no longer be rotated, thereby opening the first blade 110a. The location is regulated.

In another embodiment, when the second contact portion 1122 of the stopper hole 112 comes into close contact with the open portion 1022 of the stopper 102, the first blade 110a can no longer be rotated, and thus the first The open position of the blade 110a is regulated.

On the other hand, irrespective of whether the coil 230 is powered or not, the suction magnetic force acting between the first magnetic pole portion 420a and the core member 240 or the second magnetic pole portion 420b and the core member 240 are applied. The shaking of the slider 400 is suppressed by the suction magnetic force. Therefore, the slider 400 and the first blade 110a can maintain the predetermined position as they are even under the action of external force such as impact.

Referring to FIG. 4, a state in which the first blade 110a starts to be closed with the open position as the initial position is illustrated. The current direction applied to the coil 230 is as shown by the arrow. According to Fleming's left hand law, the slider 400 is subjected to an electromagnetic force to be moved toward the close position in the right direction. Accordingly, the first blade 110a starts to rotate to the position where the lens hole 101 is closed.

Referring to FIG. 5, the first blade 110a is locked in the closed position. When the second magnetic pole portion 420b is in close contact with the edge portion 244 (which is referred to as a second contact position), the first blade 110a can no longer rotate to the right, and accordingly, the first blade 110a The close position of is regulated.

Similarly, when the first contact portion 1121 of the stopper hole 112 comes into close contact with the closing portion 1021 of the stopper 102, the first blade 110a can no longer be rotated, and thus, the first blade 110a. ) Closed position is regulated.

On the other hand, regardless of whether the power supply of the coil 230, the shaking of the slider 400 by the suction magnetic force acting between the first magnetic pole portion 420a and the second magnetic pole portion 420b and the core member 240 Can be suppressed. Accordingly, the first blade 110a may maintain the closed position despite the external force.

Referring to FIG. 6, a state in which the first blade 110a starts to be opened with the closed position as the initial position is illustrated. The current direction applied to the coil 230 is shown by an arrow, and according to Fleming's left hand rule, the slider 400 receives an electromagnetic force toward an open position in a left direction. Accordingly, the first blade 110a starts to rotate to the position where the lens hole 101 is opened.

On the other hand, the strength of the current applied to the coil 230, the magnetizing force of the first magnetic pole portion 420a and the second magnetic pole portion 420b, the increase or decrease of the area facing the coil 230, the stone of the edge portion 244 By adjusting various design variables such as the degree of exit, the degree of lubrication of the separator 250, and the material of the core member 240, the moving speed of the shutter member reciprocating between the closed position and the open position can be adjusted.

As a simple example, by adjusting the intensity of the current applied to the coil 230, it is possible to adjust the response speed of the shutter member to a precise resolution. Here, unlike the prior art, the number of power transmission or movement direction conversion parts interposed in the actuator part 500 is greatly reduced, and there is no load generated due to play or movement between the parts, thereby reducing power consumption and durability of the shutter device. The effect of improving reliability can be expected.

Although embodiments according to the present invention have been described above, these are merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent embodiments of the present invention are possible therefrom. Therefore, the true technical protection scope of the present invention will be defined by the following claims.

1 is a perspective view showing a shutter device of the present invention.

2 is a partial perspective view showing in detail the actuator portion of the shutter device of the present invention.

3 is a perspective view of a shutter device in which the first blade and the second blade are in an open position as an embodiment of the present invention.

4 is a perspective view showing the shutter device of the present invention at the time when the close operation is started.

FIG. 5 is a perspective view of a shutter device in which the first blade and the second blade are in a closed position as an embodiment of the present invention.

6 is a perspective view showing the shutter device of the present invention at the time when the open operation is started.

<Explanation of symbols for the main parts of the drawings>

100 ... base 101 ... lens hole

102 ... Stopper 1021 ... Close

1022 ... Opening 104 ... Hinge

110a ... first blade 110b ... second blade

112 ... Stopper hole 1121 ... First contact

1122 Second contact 114 Hinge hole

116 Boss Hole 180 Guide

200 ... stator 230 ... coil

240 core member 241 first projection

242 ... 2nd protrusion 243 ... connection

244 Edge 250 Separator

400 ... slider 410 ... boss

420 ... Magnet part

420a ... first stimulator 420b ... second stimulator

481 First Bending Part 482 Second Bending Part

500 ... Actuator part

Claims (12)

A base having a lens hole through which the reflected light of the subject passes; A first blade and a second blade rotated about a hinge provided in the base to open or close the lens hole; An actuator unit having a slider which is linearly moved at a position eccentric from the hinge so as to exert a rotation moment force on the first blade and the second blade; Shutter device comprising a. The method of claim 1, The actuator unit, The slider having a boss coupled to the first blade and the second blade at a position eccentric from the hinge; A magnet part attached to the slider and including a first magnetic pole part and a second magnetic pole part having opposite polarities to each other; And a stator for linearly moving the slider by applying an electromagnetic force to the magnet. The method of claim 1, The actuator unit, The slider having a boss coupled to the first blade and the second blade at a position eccentric from the hinge; A magnet part attached to the slider and having a multi-pole magnetized in one magnet with a first magnetic pole part and a second magnetic pole part having the same shape; And a stator for linearly moving the slider by applying an electromagnetic force to the magnet. The method according to claim 2 or 3, The magnet parts are arranged in a line along the moving direction of the slider, The stator includes a coil wound to a width smaller than the total extension length of the magnet portion is fixed to the position biased to any one of the first magnetic pole portion and the second magnetic pole portion. The method according to claim 2 or 3, The stator includes a coil facing the magnet and a core member surrounding the coil, The core member may include a first protrusion protruding in one direction of the coil, a pair of second protrusions protruding in the other direction of the coil, a connection part connecting the first protrusion and the second protrusion, and the first protrusion. 2, the shutter device including an edge extending from the edge of the protrusion to the one side of the coil again. The method of claim 5, The first protrusion and the connecting portion is located inside the coil, And the second protrusion and the edge portion are located outside the coil. The method of claim 5, The edge portion is provided with a pair, And the pair of edge portions have a separation distance greater than a total extension length of the magnet portion. The method of claim 5, The shutter device when the power is applied to the coil, the first protrusion and the second protrusion has an electromagnetic force of opposite polarity to each other. The method of claim 5, Separation plate disposed on the upper side of the first protrusion is provided, The first magnetic pole part and the second magnetic pole part of the magnet part are arranged in a line on the separation plate, The shutter device is guided by the linear movement of the slider by moving the magnet portion in contact with the separator plate. 10. The method of claim 9, The edge portion extends higher than the separator, The movement span of the slider is limited by a first contact position and a second contact position at which one of the first magnetic pole portion and the second magnetic pole portion of the magnet portion contacts the protruding portion of the edge portion when the slider moves linearly. Shutter device. The method according to claim 2 or 3, The slider includes a first bending portion and a second bending portion in close contact with the side of the magnet portion, And the first bending part is moved in contact with the guide formed on the base to guide linear movement of the slider. The method of claim 1, A stopper hole is formed in each of the first blade and the second blade, and the stopper hole includes a first contact portion corresponding to one inner wall of the stopper hole and a second contact portion corresponding to the other inner wall of the stopper hole, A stopper protrudes from a part of the base exposed by the stopper hole, and the stopper includes a close part corresponding to one outer wall of the stopper and an open part corresponding to the other outer wall of the stopper. The closing position of the first blade and the second blade is defined by contacting the first contact portion and the close portion during the closing operation of the first blade and the second blade, The opening device of the first blade and the second blade is defined by the contact between the second contact portion and the open portion during the opening operation of the first blade and the second blade.

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