KR100938574B1 - Shutter apparatus for camera - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a camera shutter apparatus, comprising: a base for passing light to form a light transmission hole for exposing a film or a charge-coupled device (CCD); An electromagnet mounted on one side of the base; A driving arm disposed on one side of the electromagnet on the base and rotatably installed on the base; First and second shutters that open and close the light transmission hole while simultaneously pivoting about a portion of the base in association with the rotation of the driving arm; And a magnetic part installed on the driving arm, wherein the driving arm is clockwise and counterclockwise by the attraction force and the repulsive force generated between the electromagnet and the magnetic part according to the direction of the electric current transmitted to the electromagnet. And operating the first and second shutters while turning in the direction.

Cameras, mobile phones, small appliances, shutters

Description

Shutter apparatus for camera

The present invention relates to a shutter device, and more particularly, to a shutter device for a camera used in a small digital device.

With the development of digital technology, various digital products such as mobile communication terminals, portable game consoles, personal digital assistants (PDAs), personal multimedia players (PMPs), and digital camcorders have been introduced.

The camera unit installed in such a portable digital device includes a shutter device that can take a picture like a normal camera.

In particular, as the camera of a mobile phone, a mobile communication terminal, becomes high quality, the adoption of a mechanical shutter is essential. In order to slim down a mobile phone, miniaturization and slimming of the camera module are also essential, so it is important to simplify the structure of the shutter device. In addition, the camera unit preferably makes the shutter operation speed as fast as possible in order to take good quality pictures.

However, the conventional camera shutter device used in such a portable digital device adopts a power source having a relatively large size to transfer a predetermined driving force to the shutter in order to ensure a fast driving speed of the shutter, accordingly the shutter device Of course, there was a problem that the size of the entire lens unit is increased. This problem ultimately affects the size of the entire portable digital device, thereby reducing the portability of the portable digital device.

The present invention has been made in order to solve the above problems, while maintaining the driving performance of the shutter, and at the same time to maintain a compact size to provide a shutter device for a camera that can be applied to digital small devices such as mobile phones. .

In order to achieve the above object, the present invention is a base for forming a light transmitting hole for exposing a film or a charge-coupled device (CCD) through light; An electromagnet mounted on one side of the base; A driving arm disposed on one side of the electromagnet on the base and rotatably installed on the base; First and second shutters that open and close the light transmission hole while simultaneously pivoting about a portion of the base in association with the rotation of the driving arm; And a magnetic part installed on the driving arm, wherein the driving arm is clockwise and counterclockwise by the attraction force and the repulsive force generated between the electromagnet and the magnetic part according to the direction of the electric current transmitted to the electromagnet. A shutter device for a camera is provided which operates the first and second shutters while turning in the direction.

The electromagnet is composed of a bobbin and a coil wound on the bobbin, and one end of the bobbin is disposed adjacent to the magnetic part.

The magnetic part may be magnetized at a distance between the north pole and the south pole on one surface of the first and second shutters facing the bobbin corresponding to the swing angle of the driving arm to completely close and open the light transmitting hole. Can be. In this case, the opposing surface facing the bobbin on the other side of the magnetic part is formed convexly so as to have a curvature toward the bobbin side.

In addition, the opposing surface facing the bobbin on the other side of the magnetic part may be formed concave so as to have a curvature on the opposite side of the bobbin. In this case, the surface facing the bobbin on the other side of the magnetic part may be formed in the plane.

Preferably, the magnetic part is disposed in the radial direction of the rotational trajectory of the driving arm, or tangentially to the rotational trajectory of the driving arm.

In addition, the magnetic part is disposed in the radial direction of the rotational trajectory of the drive arm, the magnetic pole of the N pole and the S pole magnetized on both sides; And a pair of magnetic bodies attached to magnetic pole magnetizing surfaces on both sides of the magnetic so that a tip thereof is adjacent to the bobbin. At this time, it is preferable that the pair of magnetic bodies maintain the same interval as the bobbin.

The magnetic part may be disposed in a radial direction of a rotational trajectory of the driving arm, and a pair of magnetic magnets having magnetic poles different from each other at different ends may be disposed on both sides of the driving arm. In this case, it is preferable that the pair of magnetic ends maintain the same distance as the bobbin.

In the present invention as described above, the first and second shutters connected to the drive arm can be operated at high speed while the drive arm is rotated through the ultra-compact drive unit, so that a high-resolution clear picture can be obtained through the camera module installed in the digital compact device. There is an advantage to shooting.

Moreover, the size of the shutter device can be kept compact by employing only a single electromagnet and a single magnetic.

Hereinafter, a configuration of a shutter device for a camera according to a first embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 to 3, the shutter device of the first embodiment includes a base 10, a driver 30, and first and second shutters 50 and 60.

The base 10 is formed in a substantially rectangular tube shape so that a lens module (not shown) can be installed inside, and an extension portion 11 is formed along three inner corners of the upper side. The extension portion 11 is formed with a plurality of fixing projections 13 for fixing the cover 20. In addition, a fixing bracket 15 for fixing the driving unit 30 is installed at the other corner of the base 10. Furthermore, a predetermined circuit portion is formed inside the base 10, and a predetermined PCB (not shown) for applying a current to the coil 33 of the driver 30 is provided.

The fixing bracket 15 is formed with a first guide long hole 15a for slidably connecting the connecting projection 36c of the drive arm 35, and the first guide long hole 15a is rotated by the drive arm 35. It has a curvature corresponding to the trajectory.

In addition, the base 10 includes a plate 17 and a shaft projection 19. The plate 17 closes the upper part of the base 10 in a state where the peripheral part is fixed to the bottom surface of the extension part 11 of the base 10. In addition, the plate 17 is formed with a light transmission hole (17a) at a position corresponding to the lens (not shown) of the lens module installed in the base (10). In addition, the shaft protrusion 19 is formed at one corner of the base 10 adjacent to the fixing bracket 15. The shaft protrusion 19 serves as a central axis of rotation of the first and second shutters 50 and 60.

The cover 20 is formed coaxially with the light transmission hole 17a of the plate 17 as shown in FIG. 2, and has a light transmission hole having a diameter equal to or larger than at least the light transmission hole 17a of the plate 17. 21 is provided. The cover 20 is formed with a plurality of coupling holes 23 through which a plurality of fixing protrusions 13 of the base 10 are inserted. In addition, the cover 20 is formed with a second guide long hole 27 corresponding to the first guide long hole 15a of the fixing bracket 15, and like the first guide long hole 15a, the connecting projection of the driving arm 35. 36c is slidably inserted. Furthermore, the cover 20 is formed with through holes 25 and 29 into which the first hinge protrusion 36a of the driving arm 35 and the shaft protrusion 19 of the base 10 are rotatably inserted, respectively.

The drive unit 30 includes an electromagnet 31, a drive arm 35, and a magnetic 37.

The electromagnet 31 includes a bobbin 32 and a coil 33. Bobbin 32 is the front end (32a) is disposed adjacent to the magnetic 37, the rear end (32b) is fixed between the pair of supporting projections (15b) of the fixing bracket (15). In this case, the tip 32a of the bobbin 32 may be formed to be bent in multiple stages according to the installation position or the installation angle of the driving arm 35 as shown in FIG. 5 in consideration of the distance between the magnetic poles magnetized to the magnetic 37 and the like. Can be.

The coil 33 is wound on the bobbin 31 so that both ends of the bobbin 32 are exposed, and the one-way or reverse current transmitted through the PCB (not shown) is transferred to the bobbin 32 so that the tip of the bobbin 32 ( At 32a), magnetic fields of the north and south poles are generated.

The driving arm 35 includes a cylindrical portion 35a and an arm portion 35b extending at right angles to the axial direction of the cylindrical portion 35a from one side of the cylindrical portion 35a.

The cylindrical part 35a is equipped with the 1st and 2nd hinge protrusions 36a and 36b which are arrange | positioned so that the center may mutually correspond in the axial direction of the cylindrical part 35a in the upper and lower sides. The first and second hinge protrusions 36a and 36b are rotatably coupled to the fixing bracket 15. In addition, the cylindrical part 35a is provided with the insertion hole 35c for fixing the magnetic 37 below the arm part 35b.

The arm part 35b is provided with the connection protrusion 36c which protrudes in the same direction as the 1st hinge protrusion 36a in the upper surface. The connecting projection 36c is slidably inserted into the first and second long holes 53 and 63 of the first and second shutters 50 and 60. In this case, the distance between the first hinge protrusion 36a and the connecting protrusion 36c is set in consideration of an angle at which the first and second shutters 50 and 60 can fully open and close the light transmitting hole 17a. It is preferable.

In the magnetic 37, the tip 37a in which the magnetic pole is magnetized is formed somewhat wider than the rear end 37b. The magnetic 37 is arranged in the radial direction of the rotation radius of the drive arm 35 as the rear end 37b is fixed to the insertion hole 35c of the drive arm 35. In this case, the magnetic poles of the N pole and the S pole are magnetized at predetermined intervals at the tip 37a of the magnetic 37 adjacent to the tip 32a of the bobbin 32, respectively. In this case, it is preferable that the magnetic poles adhere to the opposing surface 37c of the magnetic tip 37a facing the tip 32a of the bobbin 32.

Moreover, the magnetic 37 protrudes so that the opposing surface 37c may have predetermined curvature toward the bobbin 32 so that the space | interval with the opposing surface 37c which faces the front-end | tip 32a of the bobbin 32 may be constant. In this case, the curvature of the opposing surface 37c preferably corresponds to the curvature of the circumference of the rotational trajectory formed by the tip 37a of the magnetic 37 formed in accordance with the rotation of the drive arm 35.

The first shutter 50 includes a first fixing hole 51, a first long hole 53, and a first recess 55. The first projection hole 51 is hingedly inserted into the pivoting projection 19, which is the pivot center of the first shutter 50, and the driving arm 35 is pivoted in the first long hole 53 when the pivoting arm 35 pivots. The connecting projection 36c is slidably inserted in order to rotate the first shutter 50 in the same direction as the turning direction. In this case, the first long hole 53 is formed in one portion of the first shutter 50 adjacent to the first fixing hole 51.

The first recess 55 is formed to have a diameter equal to or larger than the diameter of the light transmission hole 17a on one side of the first shutter 50 in the turning direction. This is to allow the first recess 55 to fully open the light penetrating hole 17a in a state coincided with the circumference of the light penetrating hole 17a. In this case, the first shutter 50 can restrict the turning angle until the first recess 55 is coincident with the circumference of the light transmission hole 17a by appropriately setting the length of the first long hole 53. have.

The second shutter 60 is disposed opposite the first shutter 50, and like the first shutter 50, the second fixing hole 61, the second long hole 63, and the second recess 65. It includes. In this case, the shaft projection 19 inserted into the first fixing hole 51 is hingedly inserted into the second fixing hole 61, and the drive inserted into the first long hole 53 is inserted into the second long hole 63. The connecting projection 36c of the arm 35 is slidably inserted. The second long hole 63 is formed in a portion of the second shutter 60 adjacent to the second fixing hole 61.

In addition, the second recess 65 may have a diameter equal to or larger than the diameter of the light transmission hole 17a on one side of the second shutter 60 in the rotational direction, similar to the first recess 55 of the first shutter 50. It is formed to have. This is to allow the second recess 65 to fully open the light penetrating hole 17a in a state coincided with the circumference of the light penetrating hole 17a. In addition, by setting the length of the second long hole 63 properly, the second shutter 60 can limit the turning angle of the second recess 65 until the second recess 65 coincides with the circumference of the light transmission hole 17a. .

Referring to Figures 4 to 7 the operation of the shutter device according to the first embodiment of the present invention configured as described above is as follows. For reference, FIGS. 4 and 6 illustrate the shutter apparatus of the first embodiment in which the cover 20 is omitted so that the operating states of the first and second shutters 50 and 60 can be clearly understood.

Referring to FIG. 4, the camera shutter device of the first embodiment may be configured to, for example, turn on a camera (not shown), or set a photographing mode in a case of a mobile phone (not shown) having a built-in camera. The 17a is completely closed by the first and second shutters 50 and 60 so that the film or the charge-coupled device (CCD) is not exposed to the light.

In this state, when the shutter button (not shown) is pressed to take a picture, the first and second shutters 50 and 60 are instantaneously turned to open the light transmitting hole 17a as shown in FIG. 6. Hereinafter, the process of switching from the closed state of the light transmission hole 17a (see FIG. 4) to the open state of the light transmission hole 17a (see FIG. 6) will be described in more detail.

As shown in FIG. 4, the bobbin 32 is applied by applying a current in one direction to the coil 33 of the electromagnet 31 in a state where the light transmitting hole 17a is closed by the first and second shutters 50 and 60. When the magnetic pole of the N pole is formed at the tip end 32a of the magnetic pole, the repulsive force acts between the portion of the magnetic pole magnetized at the tip 37a of the magnetic 37 and the tip 32a of the bobbin 32.

Accordingly, the driving arm 35 pivots counterclockwise around the first and second hinge protrusions 36a and 36b as shown in FIG. 7, while the connecting protrusion 36c is connected to the first and second shutters 50,. 60 and sliding along the first and second long holes (53, 63). Subsequently, while the attraction force acts between the portion where the S pole is magnetized on the tip 37a of the magnetic 37 and the tip 32a of the bobbin 32, the first shutter 50 is based on the axle 19. Turning counterclockwise and at the same time the second shutter 60 turns clockwise relative to the shaft projection 19, such that the first and second recesses 55 and 65 are around the light transmission hole 17a. The light transmitting hole 17a is opened while being disposed.

After that, the process of closing the light transmission hole 17a by the driving unit 30 by the first and second shutters 50 and 60, that is, the process of switching from FIG. 6 to FIG. 4 will be described.

When a current is applied to the coil 33 of the electromagnet 31 in the opposite direction when the light transmitting hole 17a is opened, a magnetic field of the S pole is formed at the tip 32a of the bobbin 32, and thus, the magnetic The repulsive force acts between the part where the S pole of the tip 37a of the 37 is magnetized and the tip 32a of the bobbin 32, and the part and bobbin where the N pole of the tip 37a of the magnetic 37 is magnetized. The attraction force acts between the tip ends 32a of the end 32 of FIG.

Accordingly, the driving arm 35 pivots clockwise around the first and second hinge protrusions 36a and 36b, and the connecting protrusion 36c of the driving arm 35 is the first and second shutters 50, respectively. 60 and sliding along the first and second long holes (53, 63). Accordingly, the first shutter 50 pivots clockwise with respect to the shaft projection 19 and at the same time the second shutter 60 pivots counterclockwise with respect to the shaft projection 19, thereby providing a light transmitting hole ( Close 17a).

As described above, the shutter device according to the first exemplary embodiment of the present invention has an N pole selectively generated at the tip 32a of the bobbin 32 adjacent to the tip 37a of the single magnetic 37 through the micro driver 30. And the driving arm 35 can be operated at a high speed as the attraction force and the repulsive force are alternately generated at the tip 37a of the magnetic 37 by the S-pole magnetic field.

For the shutter apparatuses according to the second to fifth embodiments to be described below, the rest of the configuration except for the driving units 130, 230, 330, and 430 is the same as that of the first embodiment. Therefore, the shutter apparatuses of the second to fifth embodiments will only be described with respect to the respective drive units 130, 230, 330 and 430.

8 to 10, a configuration of the driving unit 130 of the shutter apparatus according to the second embodiment will be described.

The driving unit 130 includes an electromagnet 131, a driving arm 135, and a magnetic 137.

Electromagnet 131 includes a bobbin 132 and a coil 133, the specific configuration is formed in the same manner as the first embodiment described above.

As the coil 133 is wound around the bobbin 132 so that both ends of the bobbin 132 are exposed, the one-way or reverse current transmitted through the PCB is transferred to the bobbin 132, so that the north pole of the bobbin 132 is N-pole. And a magnetic field of the S pole.

The driving arm 135 includes a cylindrical portion 135a and an arm portion 135b extending at a right angle with respect to the axial direction of the cylindrical portion 135a from one side of the cylindrical portion 135a. The cylindrical portion 135a includes first and second hinge protrusions 136a and 136b disposed on the upper and lower sides thereof so that their centers coincide with each other in the axial direction of the cylindrical portion 135a. The first and second hinge protrusions 136a and 136b are rotatably coupled to the fixing bracket 15. In addition, the cylindrical part 135a is provided with the jig 136d for fixing the magnetic 137 below the arm part 135b. The jig 136d has a recess 136e to which the rear surface of the magnetic 137 is attached.

The arm portion 135b includes a connecting protrusion 136c on the upper surface in the same direction as the first hinge protrusion 136a. The connecting protrusion 136c is slidably inserted into the first and second long holes 53 and 63 of the first and second shutters 50 and 60. In this case, the distance between the first hinge protrusion 136a and the connecting protrusion 136c is set in consideration of an angle at which the first and second shutters 50 and 60 can fully open and close the light transmitting hole 17a. It is preferable.

The magnetic 137 is formed to be concave so that the opposing surface 137a facing the tip 132a of the bobbin 132 has a predetermined curvature on the opposite side to the tip 132a of the bobbin 132. In this case, the magnetic poles of the N pole and the S pole are magnetized at both edge portions 137b and 137c of the magnetic 137 adjacent to the tip 132a of the bobbin 132, respectively.

In addition, the magnetic 137 may be formed to have the same spacing between the front end 132a of the bobbin 132 and both edge portions 137b and 137c of the magnetic 137.

The driving unit 130 of the shutter apparatus according to the second embodiment is driven in the same process as the driving unit 30 of the first embodiment. That is, referring to FIG. 9, when the magnetic field of the S pole is formed at the tip 132a of the bobbin 132, the driving unit 130 rotates clockwise in the N direction of the magnetic 137. As the pole-magnetized portion is adjacent, the first and second shutters 50 and 60 are operated to close the light transmission hole 17a. On the contrary, referring to FIG. 10, when the N-pole magnetic field is formed at the tip 132a of the bobbin 132, the S 130 of the magnetic 137 is rotated in a counterclockwise direction. As the poles are magnetized, the first and second shutters 50 and 60 are operated to open the light transmission hole 17a.

A configuration of the driving unit 230 of the shutter apparatus according to the third embodiment will be described with reference to FIGS. 11 to 13.

The driving unit 230 includes an electromagnet 231, a driving arm 235, and a magnetic 237.

Electromagnet 231 includes a bobbin 232 and a coil 233, the specific configuration is formed in the same manner as the first embodiment described above.

The driving arm 235 includes a cylindrical portion 235a, an arm portion 235b, first and second hinge protrusions 236a and 236b, a connecting protrusion 236c, and a jig 236d. Same as the second embodiment.

Magnetic 237 has a flat surface facing the front end 232a of the bobbin 232, the magnetic poles of the N pole and the S pole respectively on both sides of the opposite surface 237a of the magnetic 237, respectively. It is magnetized. In this case, the magnetic 237 is made of a rectangular parallelepiped, and the rear surfaces thereof are attached to both corners 236e of the jig 236d, respectively.

Since the driving unit 230 of the shutter apparatus according to the third embodiment is driven in the same manner as the driving unit 130 of the second embodiment, the description of the operation thereof will be omitted.

A configuration of the driving unit 330 of the shutter apparatus according to the fourth embodiment will be described with reference to FIGS. 14 to 16.

The driving unit 330 includes an electromagnet 331, a driving arm 335, and a magnetic 337.

Electromagnet 331 includes a bobbin 332 and a coil 333, the specific configuration is formed in the same manner as the first embodiment described above.

The driving arm 335 includes a cylindrical portion 335a, an arm portion 335b, an insertion hole 335c, first and second hinge protrusions 336a and 336b, and a connecting protrusion 336c. Same as the first embodiment.

The magnetic 337 has a substantially rectangular parallelepiped shape, and the rear end 337c is inserted into and fixed to the insertion hole 335c of the driving arm 335. In this case, the magnetic 337 is arranged in the radial direction of the radius of rotation of the drive arm 335 as in the first embodiment.

In addition, magnetic poles of the north pole and the south pole of the magnetic 337 are attached to the magnetic poles of the N pole and the S pole, respectively, and the first and second magnetic bodies 337a and 337b are attached to the respective magnetized surfaces thereof.

The first and second magnetic bodies 337a and 337b serve as magnetic poles having an N pole and an S pole, respectively, by the magnetic 337, and each tip thereof protrudes more than the tip of the magnetic 337, thus, the N pole. And the tip 332a of the bobbin 332 in which the magnetic field of the S pole is formed. In this case, it is preferable that the interval between the first and second magnetic bodies 337a and 337b and the tip 332a of the bobbin 332 be equal.

The driving unit 330 of the shutter apparatus according to the fourth embodiment is driven in the same manner as the driving units 30, 130, and 230 of the first to third embodiments. That is, referring to FIG. 15, when the magnetic field of the S pole is formed at the front end 332a of the bobbin 332, the driving part 330 has the N pole as the driving arm 335 turns clockwise. The tip of the first magnetic body 337a is positioned adjacent to the tip 332a of the bobbin 332 to operate the first and second shutters 50 and 60 to close the light penetrating hole 17a. On the contrary, referring to FIG. 16, when the N-pole magnetic field is formed at the tip 332a of the bobbin 332, the driving part 330 has an S pole as the driving arm 335 turns counterclockwise. The tip of the two magnetic bodies 337b is positioned adjacent to the tip 332a of the bobbin 332 to operate the first and second shutters 50 and 60 to open the light transmission hole 17a.

17 to 19, a configuration of the driving unit 430 of the shutter device according to the fifth embodiment will be described.

The driving unit 430 includes an electromagnet 431, a driving arm 435, and first and second magnetics 437a and 437b.

The electromagnet 431 includes a bobbin 432 and a coil 433, the specific configuration is formed in the same manner as the first embodiment described above.

The driving arm 435 includes a cylindrical portion 435a, an arm portion 435b, first and second hinge protrusions 436a and 436b, and a connecting protrusion 436c. The cylindrical portion 435a is provided with a jig 436d for attaching the first and second magnetics 437a and 437b to the lower side of the driving arm 435.

The first and second magnetics 437a and 437b have a substantially rectangular parallelepiped shape and are attached and fixed to both sides of the jig 436d, respectively. In this case, the first and second magnetics 437a and 437b are arranged in the radial direction of the radius of rotation of the drive arm 435 as in the first embodiment.

In addition, the tip of the first magnetic 437a is magnetized to the pole of the N pole on one side adjacent to the tip 432a of the bobbin 432, and the tip of the second magnetic 437b is the tip 432a of the bobbin 432. On one side adjacent to the S pole is magnetized.

Furthermore, the tip ends of the first and second magnetics 437a and 437b are protruded more than the tips of the jig 436d, respectively, and are set adjacent to the tip 432a of the bobbin 432. In this case, the interval between the first and second magnetics 437a and 437b and the tip 432a of the bobbin 432 is preferably equal.

The driving unit 330 of the shutter apparatus according to the fifth embodiment is driven in the same manner as the driving unit 330 of the fourth embodiment. That is, referring to FIG. 18, when the magnetic field of the S pole is formed at the tip 432a of the bobbin 432, the driving part 430 rotates the N pole as the magnet is rotated as the driving arm 435 turns clockwise. The tip of the first magnetic 437a is positioned adjacent to the tip 432a of the bobbin 432 to operate the first and second shutters 50 and 60 to close the light transmission hole 17a.

On the contrary, referring to FIG. 19, when the N-pole magnetic field is formed at the tip 432a of the bobbin 432, the S-pole is magnetized as the driving arm 435 turns counterclockwise. The tip of the two magnetic 437b is positioned adjacent to the tip 432a of the bobbin 432 to operate the first and second shutters 50 and 60 to open the light transmission hole 17a.

1 and 2 are assembled and exploded perspective view showing a shutter device for a camera according to a first embodiment of the present invention,

3 is a perspective view illustrating a driving unit of a shutter device for a camera according to a first embodiment of the present invention;

4 is a plan view showing a state in which the first and second shutters of the shutter device for a camera according to the first embodiment close the light transmitting holes, respectively;

5 is a plan view illustrating the driving unit illustrated in FIG. 4;

6 is a plan view showing a state in which the first and second shutters of the shutter device for a camera according to the first embodiment open the light transmission hole, respectively;

7 is a plan view illustrating the driving unit illustrated in FIG. 6;

8 is a perspective view showing a driving unit of a shutter device for a camera according to a second embodiment of the present invention;

9 and 10 are plan views showing an operating state of a driving unit of a shutter device for a camera according to a second embodiment of the present invention;

11 is a perspective view showing a driving unit of a shutter device for a camera according to a third embodiment of the present invention;

12 and 13 are plan views showing an operating state of a driving unit of a shutter device for a camera according to a third embodiment of the present invention;

14 is a perspective view showing a driving unit of a shutter device for a camera according to a fourth embodiment of the present invention;

15 and 16 are plan views showing an operating state of a driving unit of a shutter device for a camera according to a fourth embodiment of the present invention;

17 is a perspective view illustrating a driving unit of a shutter device for a camera according to a fifth embodiment of the present invention;

18 and 19 are plan views illustrating an operating state of a driving unit of a shutter device for a camera according to a fifth embodiment of the present invention.

* Description of Signs for Main Parts in Drawings *

10: base 20: cover

30,130,230.330,430: Drive 31,131,231.331,431: Electromagnet

33,132,232.332,432: coil 35,135,235.335,435: drive arm

37,137,237,337,437a, 437b: Magnetic 337a, 337b: Magnetic material

50: first shutter 60: second shutter

Claims (13)

A base through which light is formed to form a light transmission hole for exposing the film or charge-coupled device (CCD); An electromagnet mounted on one side of the base; A driving arm disposed on one side of the electromagnet on the base and rotatably installed on the base; First and second shutters that open and close the light transmission hole while simultaneously pivoting about a portion of the base in association with the rotation of the driving arm; And, And a magnetic part installed on the driving arm and moving along the rotational trajectory of the driving arm when the driving arm is pivoted. The driving arm operates the first and second shutters while turning clockwise and counterclockwise by the attraction force and the repulsive force generated between the electromagnet and the magnetic part according to the direction of the electric current imparted to the electromagnet, The electromagnet is composed of a bobbin and a coil wound on the bobbin, one end of the bobbin is disposed adjacent to the magnetic part, And the magnetic part is disposed in a radial direction or a tangential direction of a rotational trajectory of the driving arm. delete The method of claim 1, The magnetic part is magnetized at a distance between the north pole and the south pole on one surface of the first and second shutters facing the bobbin corresponding to the swing angle of the driving arm for completely closing and opening the light transmitting hole. A shutter device for a camera, characterized in that. The method of claim 3, The opposite surface facing the bobbin on the other side of the magnetic part is formed to be convex so as to have a curvature toward the bobbin side. The method of claim 4, wherein The opposing surface is a camera shutter device, characterized in that the distance from the bobbin is constant. The method of claim 3, The opposite surface facing the bobbin on the other side of the magnetic part is formed in a concave shape to have a curvature on the opposite side of the bobbin. The method of claim 3, A camera shutter device, characterized in that the surface facing the bobbin on the other side of the magnetic portion made of a flat surface. delete delete A base through which light is formed to form a light transmission hole for exposing the film or charge-coupled device (CCD); An electromagnet mounted on one side of the base; A driving arm disposed on one side of the electromagnet on the base and rotatably installed on the base; First and second shutters that open and close the light transmission hole while simultaneously pivoting about a portion of the base in association with the rotation of the driving arm; And, And a magnetic part installed on the driving arm and moving along the rotational trajectory of the driving arm when the driving arm is pivoted. The driving arm operates the first and second shutters while turning clockwise and counterclockwise by the attraction force and the repulsive force generated between the electromagnet and the magnetic part according to the direction of the electric current imparted to the electromagnet, The electromagnet is composed of a bobbin and a coil wound on the bobbin, one end of the bobbin is disposed adjacent to the magnetic part, The magnetic part is disposed in the radial direction of the rotational trajectory of the drive arm, the magnetic pole of the N pole and the S pole magnetized on both sides; And, And a pair of magnetic bodies respectively attached to magnetic pole magnetizing surfaces on both sides of the magnetic so that a tip thereof is adjacent to the bobbin. The method of claim 10, The pair of magnetic bodies of the camera shutter device characterized in that the front end maintains the same distance as the bobbin. delete delete

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