KR20080082839A - Shutter apparatus for camera - Google Patents

Abstract

A shutter apparatus for a camera is provided to improve operational speed of a shutter by rotating a shutter driving unit using an electromagnet and a permanent magnet so that attractive force and repulsive force are simultaneously applied to the shutter driving unit. A shutter apparatus(1) for a camera comprises a base plate(10) having a large light transmission hole(11), a first shutter(20), a second shutter(30), a shutter driving unit(50), and a shutter electromagnet(60) installed at two sides of the shutter permanent magnet. The shutter driving unit is rotatably installed at a side of the base plate and includes a shutter permanent magnet(57). The first and second shutters rotate on a shutter rotation shaft while overlapping an upper surface of the base plate to open/close the large light transmission hole. The shutter driving unit allows the first and second shutters to rotate on the shutter rotation shaft.

Description

Shutter apparatus for camera

1 is a perspective view showing a shutter device for a camera according to an embodiment of the present invention;

FIG. 2 is an exploded perspective view of the shutter device for a camera of FIG. 1; FIG.

3 is a cross-sectional view taken along line III-III of the camera shutter apparatus of FIG. 1;

4 is a plan view illustrating a state in which the first and second shutters block a large light transmission hole in the shutter device for a camera of FIG. 1;

5 is a plan view showing a state in which a large light transmission hole is opened in the shutter device for a camera of FIG.

6 is a plan view illustrating a state in which a small light transmitting hole is blocked by the first and second shutters in the camera shutter apparatus of FIG. 1.

* Description of the symbols for the main parts of the drawings *

One; A shutter device 3 for a camera; Control

5; Shutter drive unit 7; Aperture Drive Unit

10; Base plate 11; Large light transmission

19; Cover 20; 1st shutter

23; First shutter long 27; Shutter rotation axis

30; Second shutter 33; 2nd shutter long

40; Aperture 43; Aperture

47; Aperture rotation axis 50; Shutter drive

57; Shutter permanent magnet 60; Shutter electromagnet

70; Aperture drive 77; Aperture Permanent Magnet

80; Aperture electromagnet 90; Drive unit frame

93; Shutter guide groove 94; Aperture Guide

The present invention relates to a shutter device, and more particularly, to a shutter device for a camera used in a portable 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 to take good quality pictures.

In addition, in the conventional camera unit used in portable digital devices, the shutter device cannot change the size of a hole through which light enters for miniaturization, and it is common to always use a fixed aperture having a constant size. However, when using the shutter device having a fixed aperture in this way, there is a problem that can not take a high-quality picture because the amount of light introduced into the camera unit can not be adjusted according to the illumination of the shooting location.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and provides a shutter device for a camera having a fast shutter with a small operation size.

An object of the present invention as described above, the base plate having a large light transmission hole; First and second shutters rotatably installed around the axis of rotation of the shutter in a state overlapping the upper surface of the base plate, and opening and closing the large light transmitting hole; A shutter driver installed rotatably on one side of the base plate to allow the first and second shutters to rotate about the shutter rotation axis, and including a shutter permanent magnet; And a shutter electromagnet provided at both sides of the shutter permanent magnet and having a coil wound around the bobbin.

In this case, shutter holes may be formed at one ends of the first and second shutters, and shutter guide pins may be formed in the shutter driver to be inserted into the shutter holes.

In addition, the shutter device for a camera according to the present invention is installed on the upper side of the first and second shutter so as to be rotatable about an aperture rotation axis, the aperture having a small light transmission hole; An aperture drive unit rotatably installed on the base plate to allow the aperture to rotate about the aperture rotation axis and include an aperture permanent magnet; And a diaphragm electromagnet provided at both sides of the diaphragm permanent magnet and having a coil wound around the bobbin, wherein the controller controls the current flowing through the diaphragm electromagnet to rotate the diaphragm driving unit.

In this case, an aperture long hole may be formed at one end of the aperture, and an aperture guide pin inserted into the aperture long hole may be formed at the aperture driving unit.

Preferably, the shutter electromagnet and the diaphragm electromagnet are formed in a "c" shape.

In addition, the rotation axis of the shutter driver and the aperture driver may be coaxially installed.

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

However, in the following description of the present invention, if it is determined that the detailed description of the related known functions or components may unnecessarily obscure the subject matter of the present invention, the detailed description and the detailed illustration will be omitted.

1 is a perspective view illustrating a camera shutter apparatus according to an embodiment of the present invention, and FIG. 2 is an exploded perspective view of the camera shutter apparatus of FIG. 1.

1 and 2, the shutter device 1 for a camera according to an embodiment of the present invention includes a base plate 10, a first shutter 20, a second shutter 30, and a shutter driving unit 5. ), An aperture 40, an aperture driving unit 7, a driving unit frame 90, and a controller 3.

The base plate 10 is formed in a substantially rectangular shape, and a large light transmitting hole 11 through which light passes is formed. An imaging surface (not shown) is provided below the base plate 10, and a predetermined image is formed by light passing through the large light transmitting hole 11.

It is preferable to form a shutter groove 13 on the upper surface of the base plate 10 to limit the operating range of the first and second shutters 20 and 30. In addition, on one side of the large light transmitting hole 11 on the upper surface of the base plate 10 is provided with an aperture stopper 15 for limiting the operating range of the aperture 40.

The first and second shutters 20 and 30 selectively open and close the large light transmitting hole 11 while overlapping or falling apart according to the operation of the shutter driver 5.

The first shutter 20 is hinged on the upper surface of the base plate 10 so as to be rotatable with respect to the base plate 10. In the present exemplary embodiment, the shutter rotation shaft 27 is formed in the base plate 10, and the first shutter hole 20 is formed in the first shutter 20 to be inserted into the shutter rotation shaft 27. Therefore, when the first shutter hole 21 of the first shutter 20 is inserted into the shutter rotation shaft 27, the first shutter 20 can rotate with respect to the base plate 10. In addition, a first shutter long hole 23 is formed in the first shutter 20 to one side of the first shutter hole 21, and the opposite side of the base plate 10 when the second shutter 30 partially overlaps the second shutter 30. The large light transmitting hole 11 can be blocked, and when the second light shutter 30 is separated from each other, the large light transmitting hole 11 is formed in a shape that does not cover the large light transmitting hole 11.

The second shutter 30 is hinged to be rotatable with respect to the base plate 10 above the first shutter 20. In the present embodiment, the first shutter 20 has a shape substantially symmetrical with the first shutter 20. Accordingly, the second shutter 30 has a second shutter hole 31 inserted into the shutter rotation shaft 27 into which the first shutter 20 is inserted. The second shutter hole 33 is formed in the second shutter 30 to one side of the second shutter hole 31, and when the part of the second shutter 30 overlaps with the first shutter 20, the large light transmission of the base plate 10 is performed. The ball 11 may be blocked and formed in a shape that does not cover the large light transmitting hole 11 when the ball 11 is moved away from the first shutter 20.

The shutter driving unit 5 opens and closes the large light transmitting hole 11 of the base plate 10 by causing the first and second shutters 20 and 30 to rotate at a predetermined angle about the shutter rotation axis 27. The shutter drive unit 5 includes a shutter driver 50 and a shutter electromagnet 60.

One end of the shutter driver 50 is rotatably installed at one side of the base plate 10, and the other end thereof is connected to the first and second shutters 20 and 30 so that the first and second shutters 20 and 30 are connected. It rotates about the shutter rotation axis 27. In the present embodiment, the shutter driver 50 has a female shape, and at one end, a shutter driving hole 51 is inserted into the drive shaft 59, and at the other end, the first shutter long of the first shutter 20 ( 23 and a shutter guide pin 53 inserted into the second shutter long hole 33 of the second shutter 30 is formed. When the shutter driver 50 moves in a predetermined angle range around the drive shaft 59, the first and second shutters 20 and 30 are simultaneously rotated by the shutter guide pin 53 at a predetermined angle about the shutter rotation axis 27. Rotate Therefore, the first and second shutters 20 and 30 overlap each other and fall.

In addition, a magnet settling groove 55 in which the shutter permanent magnet 57 is installed is formed below the shutter guide pin 53 of the shutter driver 50. The shutter permanent magnet 57 is formed as a bar magnet and is fixed to the magnet settling groove 55 of the shutter driver 50. When the shutter permanent magnet 57 is installed in the magnet settling groove 55, approximately half of the shutter permanent magnet 57 is preferably exposed to the outside. The magnetic pole of the protruding portion of the shutter permanent magnet 57 exposed to the outside may be either S pole or N pole.

The shutter electromagnet 60 is installed at both sides of the shutter permanent magnet 57 to apply magnetic force to the shutter permanent magnet 57 so that the shutter driver 50 can move within a predetermined angle range. The shutter electromagnet 60 includes a bobbin 61 and a coil 63 wound on the bobbin 61. In the present embodiment, as shown in FIG. 3, the bobbin 61 of the shutter electromagnet 60 is formed in a “c” shape, and a coil 63 is wound around the central portion 67 of the bobbin “c”. have. Such bobbin 61 is preferably formed of a magnetic material. The shutter permanent magnet 57 installed in the shutter driver 50 is positioned between the arms “65” and “66” of the “c” character of the shutter electromagnet 60. The shutter permanent magnet 57 is positioned on either arm of the arms 65 and 66. It is pulled by the magnetic force of 57, and is in close contact. Accordingly, the shutter driver 50 rotates a predetermined angle in both arms 65 and 66 of the shutter electromagnet 60 according to the magnetic poles formed on both arms 65 and 66 of the bobbin 61 of the shutter electromagnet 60. .

The diaphragm 40 is formed with a small light transmission hole 45, it is rotatably installed on the base plate 10 on the upper side of the first and second shutters (20, 30). The diaphragm 40 may be provided below the first and second shutters 20 and 30. The iris 40 is rotatably installed around the iris rotation shaft 47 formed on the upper surface of the base plate 10. Therefore, the diaphragm 40 is formed with an aperture hole 41 inserted into the diaphragm rotation shaft 47. The small light penetrating hole 45 has a smaller diameter than the large light penetrating hole 11, and when the diaphragm 40 rotates to block the large light penetrating hole 11, the diaphragm 40 is stopped by the diaphragm stopper 15. The center of the small light transmission hole 45 is formed at a position coinciding with the center of the large light transmission hole (11). Therefore, when the diaphragm 40 comes to the position of the large light transmission hole 11, the amount of light incident on the imaging surface is reduced. On the opposite side of the aperture hole 41, an aperture long hole 43 into which the aperture guide pin 73 is inserted is formed.

The aperture driving unit 7 allows the aperture 40 to rotate about an aperture rotation axis 47 by an angle so that the small light transmission hole 45 is positioned on the large light transmission hole 11 of the base plate 10. . The aperture driving unit 7 includes an aperture driving unit 70 and an aperture electromagnet 80.

One end of the aperture driving unit 70 is rotatably installed on the base plate 10, and the other end thereof is connected to the aperture 40 to allow the aperture 40 to rotate about the aperture rotation shaft 47. In the present embodiment, the aperture driving unit 70 is formed in a female shape, and at one end, an aperture driving hole 71 is inserted into the driving shaft 59, and the other end of the aperture guide pin is inserted into the aperture long hole 43. 73) is formed. When the aperture driver 70 moves in a predetermined angle range about the drive shaft 59, the aperture 40 is rotated by the aperture guide pin 73 about the aperture rotation axis 47. In this case, the aperture driver 70 is preferably installed to rotate on the same axis as the shutter driver 50. In the present embodiment, as shown in FIG. 1, the aperture driving hole 71 of the aperture driving unit 70 is inserted into the drive shaft 59 of the shutter driving unit 50.

In addition, a magnet settling groove 75 in which the aperture permanent magnet 77 is installed is formed below the aperture guide pin 73 of the aperture drive unit 70. The diaphragm permanent magnet 77 is formed as a bar magnet similar to the shutter permanent magnet 57 and is fixed to the magnet settling groove 75 of the diaphragm driver 70. When the diaphragm permanent magnet 77 is installed in the magnet settling groove 75, approximately half of the diaphragm permanent magnet 77 is preferably exposed to the outside. The magnetic pole of the protrusion of the diaphragm permanent magnet 77 exposed to the outside may be arbitrarily determined among the S pole and the N pole.

The diaphragm electromagnet 80 is installed at both sides of the diaphragm permanent magnet 77 to apply magnetic force to the diaphragm permanent magnet 77 so that the diaphragm driving unit 70 may move within a predetermined angle range. In the case of the present embodiment, since the structure of the diaphragm electromagnet 80 is similar to the shutter electromagnet 60 described above, a detailed description thereof will be omitted. The diaphragm permanent magnet 77 installed in the diaphragm driving unit 70 is positioned between the arms of the diaphragm electromagnet 80 at the two arms 85 and 86 of the diaphragm electromagnet 80. One arm is pulled by magnetic force and is in close contact. Therefore, the aperture driver 70 rotates a predetermined angle in both arms 85 and 86 of the aperture electromagnet 80 according to the magnetic pole formed in the aperture electromagnet 80.

Meanwhile, between the first and second shutters 20 and 30 and the aperture 40, the intermediate plate 17 does not interfere with each other when the first and second shutters 20 and 30 operate or the aperture 40 operates. It is preferable to install). In this embodiment, the intermediate plate 17 is formed of a film. The intermediate plate 17 is formed with a hole 17a having a size corresponding to the large light transmitting hole 11 formed in the base plate 10.

In addition, a cover 19 for protecting the diaphragm 40 is installed above the diaphragm 40. The cover 19 is formed with a hole 19a having a size corresponding to the large light transmitting hole 11.

The drive unit frame 90 is formed integrally with the base plate 10 on one side of the base plate 10, the drive shaft 59 and the shutter electromagnet 60 of the shutter drive unit 5 and the aperture drive unit 7. And the diaphragm electromagnet 80. For convenience of assembly, the drive unit frame 90 is preferably formed of the upper drive unit frame 91 and the lower drive unit frame 92. That is, the upper drive unit frame 91 is formed integrally with the base plate 10, and the lower drive unit frame 92 is formed to be separated from the upper drive unit frame 91.

Shutter guide grooves 93 and aperture guide grooves 94 for guiding movement of the shutter guide pins 53 and the aperture guide pins 73 are respectively formed on the upper surface of the upper driving unit frame 91 which is connected to the base plate 10. Is formed. An upper fixing groove 95 is formed between the shutter guide groove 93 and the aperture guide groove 94 to fix the upper end of the drive shaft 59.

In addition, the lower driving unit frame 92 is formed with a shutter electromagnet fixing groove 96 and an aperture electromagnet fixing groove 97 for fixing the shutter electromagnet 60 and the aperture electromagnet 80, and the shutter electromagnet fixing groove 96. And a lower fixing groove 98 for fixing the lower end of the driving shaft 59 on the lower surface of the lower driving unit frame 92 between the diaphragm electromagnet fixing groove 97.

The controller 3 controls the current flowing through the coils 63 and 83 of the shutter electromagnet 60 and the aperture electromagnet 80 so that both arms 65 and 66 of the shutter electromagnet 60 and both arms of the aperture electromagnet 80 are controlled. 85, 86) to control the stimulus induced. The controller 3 is preferably formed of a PCB substrate and installed on the bottom surface of the lower drive unit frame 92.

Hereinafter, the operation of the shutter device 1 for a camera according to the present invention having the above structure will be described in detail with reference to the accompanying drawings.

First, a case of taking a picture by operating the shutter will be described.

Before the shutter is operated, the first and second shutters 20 and 30 partially overlap each other as shown in FIG. 4 to block the large light transmitting holes 11 formed on the upper surface of the base plate 10. Therefore, external light does not enter the imaging surface through the large light transmission hole 11. In this case, the shutter guide pin 53 of the shutter driver 50 is located at the second position 93b of the base plate 10, that is, the shutter guide groove 93 of the drive unit frame 90. That is, the protrusion of the shutter permanent magnet 57 of the shutter driver 50 is in close contact with the second arm 66 of the arms 65 and 66 of the shutter electromagnet 60.

In this state, when the control unit 3 receives the shutter operation signal, the control unit 3 sends a current to the shutter electromagnet 60. If the magnetic pole of the protruding portion 57a of the shutter permanent magnet 57 of the shutter driver 50 is the S pole, the control unit 3 determines that the second arm 66 of the shutter electromagnet 60 becomes the S pole. A current flows through the coil 63 of the shutter electromagnet 60 so that one arm 65 becomes the N pole. Then, the protrusion of the shutter permanent magnet 57, which is the S pole, is repulsed by the S pole of the second arm 66 of the shutter electromagnet 60 and attracted by the N pole of the first arm 65 to receive the first arm. Go to (65). At this time. Since the shutter permanent magnet 57 is installed in the shutter driver 50, the shutter driver 50 moves from the second arm 66 of the shutter electromagnet 60 to the first arm 65 around the drive shaft 59. Rotate Then, the shutter guide pin 53 of the shutter driver 50 moves from the second position 93b of the shutter guide groove 93 to the first position 93a. When the shutter guide pin 53 moves from the second position 93b of the shutter guide groove 93 to the first position 93a, the first and second shutter holes 23 and 33 and the shutter guide pin 53 are moved. As a result, the first shutter 20 and the second shutter 30 rotate about the shutter rotation axis 27. When the shutter guide pin 53 is positioned at the first position 93a of the shutter guide groove 93, the first and second shutters 20 and 30 are separated from each other as shown in FIG. The through hole 11 is opened. Therefore, external light is incident on the imaging surface through the large light transmission hole 11.

As soon as the shutter guide pin 53 is positioned at the first position 93a of the shutter guide groove 93 as shown in FIG. 5, the controller 3 again flows a current in the opposite direction to the shutter electromagnet 60. Then, the first arm 65 of the shutter electromagnet 60 has an S pole, and the second arm 66 has an N pole. Then, the shutter permanent magnet 57 in close contact with the first arm 65 is repulsed by the first arm 65, which is the S pole, and receives the attraction force by the second arm 66, which is the N pole. Go to (66). Therefore, the shutter guide pin 53 of the shutter driver 50 also moves from the first position 93a of the shutter guide groove 93 to the second position 93b. Then, the first and second shutters 20 and 30 which are separated from each other as shown in FIG. 5 are partially overlapped as shown in FIG. 4 to block external light from entering the large light transmitting hole 11.

In the case where the first and second shutters 20 and 30 function as a shutter for the small light transmitting hole 45, the aperture 40 has a large light transmitting hole 11 as shown in Figs. The same method as described above, except that the first and second shutters 20 and 30 operate in the state positioned above the.

The shutter device for a camera 1 according to the present invention rotates the shutter drive unit 50 by the magnetic force of the electromagnet and the permanent magnet, so that the structure can be simply formed, and the shutter drive unit 50 generates a manpower and a repulsive force in the rotational direction. Since it receives at the same time, the operation speed of the shutter is faster than the shutter apparatus according to the prior art.

Next, the case where the aperture 40 of the shutter device 1 is operated will be described. The shutter device 1 for a camera according to the present invention can select two aperture modes according to the amount of incident light. Accordingly, when there is little light in the place to be photographed, a large aperture mode may be selected such that light is incident through the large light transmitting hole 11 as shown in FIG. 5, and when there is a lot of light in the place to be photographed, as shown in FIG. The small aperture mode may be selected such that light is incident through the ball 45. The aperture mode may be manually selected by the user or may automatically select the aperture mode by detecting the amount of light at the place to be photographed using a light receiving sensor or the like.

1 and 6, when the aperture 40 is in the small aperture mode, that is, when the small light transmitting hole 45 is positioned above the large light transmitting hole 11, the aperture guide pin of the aperture driving unit 70 is used. 73 is located at the second position 94b of the aperture guide groove 94. At this time, the protrusion of the diaphragm permanent magnet 77 of the diaphragm driver 70 is in close contact with the second arm 86 of both arms 85 and 86 of the diaphragm electromagnet 80.

In this state, when the aperture mode conversion signal is received, the control unit 3 flows a current through the coil 83 of the aperture electromagnet 80 to move the aperture driver 70 toward the first arm 85. If the magnetic pole of the protrusion of the diaphragm permanent magnet 77 of the diaphragm driver 70 is the S pole, the controller 3 causes the second arm 86 of the diaphragm electromagnet 80 to become the S pole, and the first arm ( An electric current flows through the coil 83 of the diaphragm electromagnet 80 so that 85 may become an N pole. Then, the protrusion of the diaphragm permanent magnet 77 is repulsed by the S pole of the second arm 86 of the diaphragm electromagnet 80, and the first arm 85 receives the attraction force by the N pole of the first arm 85. Move to). At this time. Since the diaphragm permanent magnet 77 is installed in the diaphragm driving unit 70, the diaphragm driving unit 70 moves toward the first arm 85 from the second arm 86 of the diaphragm electromagnet 80 around the driving shaft 59. Rotate Then, the aperture guide pin 73 of the aperture driver 70 moves from the second position 94b of the aperture guide groove 94 formed in the drive unit frame 90 to the first position 94a. When the aperture guide pin 73 moves from the second position 94b of the aperture guide groove 94 to the first position 94a, the aperture guide pin 73 is inserted into the aperture hole 43 to stop the aperture ( 40 is rotated about the aperture rotation axis 47. When the aperture guide pin 73 is positioned at the first position 94a of the aperture guide groove 94, the aperture 40 is positioned at one side of the large light transmission hole 11 as illustrated in FIG. 5. The penetration hole 11 is completely exposed.

On the contrary, upon receiving the aperture mode conversion signal in the large aperture mode, the controller 3 again flows the current to the aperture electromagnet 80 so that the small light transmission hole 45 of the aperture 40 becomes the large light transmission hole 11. Position the center on top of

Since the control unit 3 controls the diaphragm electromagnet 80 to rotate the diaphragm 40, the detailed description thereof will be omitted.

As described above, the shutter device for a camera according to the present invention drives the shutter drive unit using a permanent magnet and an electromagnet, thereby simplifying the structure. Therefore, the size of the camera shutter device can be made small so as to be suitable for portable digital devices.

In addition, since the repulsive force and the attraction force simultaneously act in the rotational direction of the shutter driving unit and the aperture driving unit in the camera shutter apparatus according to the present invention, the operation speed of the shutter and the aperture can be faster than the shutter and the aperture according to the prior art.

The present invention is not limited to the above-described specific embodiments, and simple components that can be carried out by those skilled in the art without departing from the spirit of the present invention described in the claims below. Substitutions, additions, deletions, and alterations of are within the scope of the claims.

Claims (7)

A base plate having a large light transmission hole; First and second shutters rotatably installed around the axis of rotation of the shutter in a state overlapping the upper surface of the base plate, and opening and closing the large light transmitting hole; A shutter driver installed rotatably on one side of the base plate to allow the first and second shutters to rotate about the shutter rotation axis, and including a shutter permanent magnet; And A shutter electromagnet installed at both sides of the shutter permanent magnet and having a coil wound around the bobbin; The method of claim 1, Shutter holes are formed at one end of the first and second shutters, respectively. The shutter driving unit is a shutter device for a camera, characterized in that the shutter guide pin is inserted into the shutter hole. The method of claim 1, An aperture provided on the upper and lower sides of the first and second shutters so as to be rotatable about an aperture rotation axis and having a small light transmission hole; An aperture drive unit rotatably installed on the base plate to allow the aperture to rotate about the aperture rotation axis and include an aperture permanent magnet; And The diaphragm electromagnet is installed on both sides of the aperture permanent magnet, the coil is wound around the bobbin; further comprising a shutter device for a camera. A base plate having a large light transmission hole; An aperture provided on the upper surface of the base plate so as to be rotatable about an axis of rotation of the aperture and having a small light transmission hole; An aperture drive unit rotatably installed on the base plate to allow the aperture to rotate about the aperture rotation axis and include an aperture permanent magnet; And The diaphragm is installed on both sides of the aperture permanent magnet, the diaphragm electromagnet coil wound around the bobbin; comprising a shutter device for a camera. The method according to claim 3 or 4, An aperture long hole is formed at one end of the aperture, The aperture driving unit is a camera shutter device characterized in that the aperture guide pin is inserted into the aperture long hole is formed. The method according to any one of claims 1 to 4, The shutter electromagnet and the aperture electromagnet is a shutter device for a camera, characterized in that formed in the "c" shape. The method according to any one of claims 1 to 4, And a rotation shaft of the shutter driver and the aperture driver is coaxially installed.

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