JP2005156896A - Camera diaphragm apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a camera diaphragm apparatus where the fluctuation of output voltage of a Hall element is appropriately corrected even if the fluctuation occurs due to a change in ambient temperature, and the stop amount of an aperture part can be highly accurately set. <P>SOLUTION: In the camera diaphragm apparatus, three light control members 35 are made movable in a direction of shielding/opening the aperture part 25a cooperatively with the rotation of a driving ring 27, and a sensor magnet 28 is arranged on the driving ring 27, and the Hall element 24a is arranged on the side facing the sensor magnet 28 of a base member 25, and the output voltage of the Hall element 24a outputted in accordance with the magnetic flux of the sensor magnet 28 is corrected so as to come close to a reference voltage previously inputted to a control part (not illustrated). <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a camera diaphragm device, and more particularly to a camera diaphragm device suitable for photographing a subject image.

  A conventional camera diaphragm device will be described with reference to FIGS. As shown in FIG. 5, a conventional camera diaphragm apparatus has a filter base plate 2 having a circular opening 2a laminated and disposed below a shutter base plate 1 having a circular opening 1a. A first blade body 3 and a second blade body 4, which are diaphragm blades, are disposed between 2 and the shutter base plate 1.

The first blade body 3 is formed with a triangular diaphragm edge 3a that functions as a diaphragm for the openings 1a and 2a. The second blade body 4 includes a diaphragm edge 3a of the first blade body 3 and A triangular aperture edge 4a formed in the opposite direction is formed.
Further, in order to transmit the rotation of the rotor 5a described later, the first blade 3 is provided with a first drive pin 3b, and the second blade 4 is provided with a second drive pin 4b.
Also, on one surface side of the shutter base plate 1, an actuator 5 for driving the first and second blade bodies 3 and 4 is disposed in the vertical direction in the figure where the respective diaphragm edges 3a and 4a intersect.

The actuator 5 includes a rotor 5a that is rotatable over a predetermined angular range of the rotation center, an excitation coil (not shown) that can rotationally drive the rotor 5a, and an output voltage corresponding to a change in magnetic flux. Is changed to a hall element (not shown) that can detect the rotation direction and rotation angle of the rotor 5a.
An arm-shaped drive arm 5b is formed to extend from the rotor 5a. The drive arm 5b is engaged with the first elongated hole 6a of the swing lever 6, and the rotor 5a is swung by a predetermined rotation angle rotation. The moving lever 6 swings in the clockwise direction and the counterclockwise direction.
In addition to the first long hole 6a, the swing lever 6 has a second long hole 6b that can be engaged with the first drive pin 3b of the first blade body 3 on one end side on the right side in the figure, and a left side in the figure. A third elongated hole 6c that can engage with the second drive pin 4b of the second blade body 4 is formed on the other end side.

For example, when a camera aperture device having such a configuration is mounted on a digital movie camera, for example, first, in the first shutter operation in which the shutter button is lightly operated before shooting, the aperture corresponding to the ambient brightness is selected. The actuator 5 is driven to rotate the rotor 5a shown in FIG. 5 in the clockwise direction so that the openings 1a and 2a are in the amount. Then, the drive arm 5b slides on the inner surface of the first long hole 6a, so that the swing lever 6 rotates in the clockwise direction.
And the 1st drive pin 3b engaged with the 2nd long hole 6b is pushed down below illustration, and the 1st blade | wing body 3 moves below.
Further, the second drive pin 4b that engages with the third long hole 6c is pushed upward in the drawing, and the second blade body 4 moves upward.

Moreover, the output voltage output from the Hall element changes corresponding to the change of the magnetic flux as the rotor 5a rotates. When the changing output voltage matches the aperture amount previously input as a control map on the camera side, the driving of the electromagnetic arc tutor 5 is stopped and the rotation of the rotor 5a is stopped.
As a result, as shown in FIG. 6, the aperture amount of the opening 1a (2a) formed by the aperture edges 3a and 4a of the first and second blade bodies 3 and 4 becomes an optimum value for photographing. A moving image is photographed by the image sensor (CCD).
JP 2001-281725 A

However, in the Hall element as described above, the output voltage corresponding to the aperture amount varies as shown in A1 and A2, as shown in FIG. 7, due to the ambient temperature change.
If the output voltage varies due to such a change in ambient temperature, the aperture amount of the opening 1a (2a) formed by the aperture edges 3a, 4a of the first and second blade bodies 3, 4 may vary. It was.
The present invention has been made in view of the above-described problems, and even when variations occur in the output voltage of the Hall element due to changes in ambient temperature, the variations are appropriately corrected to reduce the aperture amount of the opening. An object of the present invention is to provide a camera diaphragm device that can set the above with high accuracy.

As a first means for solving the above-described problems, a camera diaphragm device according to the present invention includes a base member having a predetermined thickness, an opening having a predetermined aperture formed through the base member, and driving of the actuator. A light adjusting member capable of shielding or opening the opening by force,
The base member is provided with a drive ring that can rotate in a predetermined rotation angle range in one direction and the other direction by the actuator, and the light adjusting member opens the opening in conjunction with rotation of the drive ring. The drive ring is movable in a shielding direction or an opening direction. A sensor magnet is disposed on the drive ring. A hall element is disposed on the base member on the side facing the sensor magnet. The output voltage of the Hall element output corresponding to the magnetic flux of the magnet is corrected so as to approach a reference voltage preset in the control unit.

  Further, as a second solving means for solving the above problem, the correction is performed when the light adjusting member opens or shields the opening.

  As a third means for solving the problem, the drive ring is formed with a rotation restricting portion capable of restricting rotation within a predetermined rotation angle range, and the base member is provided with the rotation restricting portion. An abutting wall is formed on which the portion can abut, and the drive ring is rotated to correct the output voltage when the rotation restricting portion abuts against the abutting wall.

  As a fourth means for solving the above problem, the correction is performed in conjunction with a shutter operation.

  In the camera diaphragm device of the present invention, the output voltage of the Hall element output corresponding to the magnetic flux of the sensor magnet is corrected so as to approach the reference voltage set in advance in the control unit. Even if the temperature changes, the output voltage of the Hall element can be kept constant near the pressure on the basis, and the aperture amount of the opening can be performed with high accuracy without variation.

  Further, since the output voltage is corrected when the light adjusting member opens or shields the opening, the output voltage can be set to the maximum value or the minimum value, and the variation in the aperture amount can be further reduced. it can.

  In addition, the output voltage is corrected when the rotation restricting portion formed on the drive ring by rotating the drive ring comes into contact with the contact wall of the base member, so that the position where the output voltage is corrected does not vary. It can be carried out.

  In addition, since the correction is performed in conjunction with the shutter operation, the operability of the camera is good.

  DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments of a camera diaphragm device according to the present invention will be described below with reference to FIGS. FIG. 1 is an exploded perspective view of a camera diaphragm device according to the present invention, and FIGS. 2 to 4 are plan views for explaining the operation of a light adjusting member according to the present invention.

First, as shown in FIG. 1, in the camera aperture device electricity according to the embodiment of the present invention, an actuator 21 as a drive source for reciprocatingly driving a drive ring 8 described later at a predetermined angle is provided at the bottom. It is arranged.
The actuator 21 has a support member 22 made of a resin material. The support member 22 has an outer peripheral side wall 22a formed in an arc shape. Further, the support member 22 is formed with two coil storage portions 22b adjacent to each other on the left and right sides of the central partition wall 22c on the inner peripheral surface side of the side wall 22a.

From the front side and the rear side of the side wall 22a in the drawing and the partition wall 22c, snap engaging support portions 22d that protrude upward and are formed in a hook shape are formed.
The snap engaging portion 22d can be snap-supported on a base member 25 described later. A coil group 23 is attached to the two coil storage portions 22b. The coil group 23 includes a yoke 23a made of a magnetic material and having a substantially U-shaped outer shape, and an air core portion 23c of the coil 23b is inserted into the yoke 23a so that the coil group 23 is attached to the coil housing portion 22b. Thus, the actuator 21 is assembled.
Further, a detection sensor 24 is disposed at a position away from the actuator 21 by a predetermined dimension at a position facing a sensor magnet 29 described later. The detection sensor 24 includes a hall element 24a and a sensor substrate 24b made of an FPC (flexible printed circuit board) on which the hall element 24a is placed.

In addition, the actuator 21 is attached to the back surface of the base member 25 having a substantially circular outer shape by snapping and supporting the snap engaging portions 22d.
The base member 25 is made of a resin material or the like, and as shown in FIGS. 1 and 2, the outer shape is formed in a substantially circular shape, and a circular opening 25a having a diameter of a predetermined dimension is formed at the center thereof. A blade support surface 25b is formed around the opening 25a. The blade support surface 25b has a flat surface and is projected in a ring shape.
In addition, the base member 25 has a peripheral wall 25c formed on the outer peripheral portion thereof with a predetermined width dimension and height dimension.

Further, a ring-shaped groove portion 26 engraved with a predetermined depth is formed between the blade support surface 25b and the peripheral wall 25c, and a drive ring 20 (to be described later) is rotatably positioned in the groove portion 26. ing.
Further, on the bottom surface of the groove portion 26 shown in FIG. 1, a driving hole 26a formed in an arc shape with a predetermined width dimension and length dimension on the left side in the figure, and a slightly narrower width than the driving hole 26a on the near side in the figure is formed. The sensor hole 26b is formed through.
Also, from the groove portion 26 on the right side of the figure, first, second, and third pins 26c, 26d, and 26e, which are blade support portions that rotatably support a light adjusting member 35, which will be described later, are 120 °, respectively. Projections are formed at predetermined intervals with a predetermined thickness and height.

In addition, a fourth pin 26f having a thickness substantially the same as that of the first pin 26c is formed to protrude in the vicinity of the lower side of the first pin 26c, which is a blade support portion formed on the right side of the base member 25 in the figure. A fifth pin 26g formed thicker than the fourth pin 26f is formed in the vicinity of the lower side of the fourth pin 26f in the drawing.
Further, the base member 25 is provided with a filter support surface 26h formed higher than the blade support surface 25b on the upper side of the first pin 26c in the figure, and an ND filter 37 (to be described later) is provided from the filter support surface 26h. A filter support portion 26j having a predetermined thickness that is rotatably supported is formed to protrude.
Further, the base member 25 is formed with a recessed left side of the peripheral wall 25c in the drawing so that the first and second contact walls 26k can contact one of the drive rings 27 and the other rotation restricting portions 27e, 27f, which will be described later. 26m is formed.

In addition, a drive ring 27 formed in a ring shape following the ring shape of the groove portion 26 is disposed in the groove portion 26 so as to be rotatable within a predetermined angle range. The drive ring 27 is formed with three first, second, and third drive pins 27a, 27b, and 27c protruding at predetermined heights at equally spaced positions of 120 °.
In addition, a lock release pin 27d is formed to protrude outside the first drive pin 27a on the right side of the drive ring 27 in the figure. Further, the drive ring 27 is protruded from the left side in the figure, and one rotation restricting portion 27e and the other rotation restricting portion 27f are formed.

A drive magnet 28 having a substantially arc shape and a predetermined width dimension is fixed to the lower surface side of the drive ring 27 with an adhesive or the like. An arc-shaped sensor magnet 29 is fixed with an adhesive or the like.
The drive magnet 28 has one magnetic pole magnetized on the bottom surface and the other magnetic pole magnetized on the bottom surface. The sensor magnet 29 has one magnetic pole magnetized at one end of the arc shape and the other magnetic pole magnetized at the other end.

Such a drive ring 27 is placed in the groove 26 of the base member 25 with the drive magnet 28 aligned with the drive hole 26a and the sensor magnet 29 aligned with the sensor hole 26b.
On the lower side of the base member 25 facing the drive magnet 28, the actuator 21 can be snapped and supported. When the actuator 21 is snap-supported on the base member 25, the coil 23 b is positioned with a gap of a predetermined dimension at a position facing the drive magnet 28.
In the pair of coils 23b in this state, a magnetic flux generated by applying a predetermined current to one coil 23b acts in a direction in which the drive magnet 28 is repelled, and the other coil 23b is connected to the one coil 23b. Magnetic flux generated by applying a current in the opposite direction acts in the direction in which the drive magnet 28 is attracted. As a result, the drive ring 27 rotates in one direction within a predetermined rotation angle range.
Further, by reversing the energizing direction of each coil 24, the drive ring 27 rotates in the other direction opposite to the one direction.

A detection sensor 24 can be attached to the lower surface of the base member 25 facing the sensor magnet 29 with a screw (not shown) or the like.
When the detection sensor 24 is attached to the base member 25 with screws or the like, the hall element 24a faces the sensor magnet 29 with a predetermined gap.
When the drive ring 27 rotates, the output voltage of the Hall element 24a changes, and the control unit on the camera (not shown) side detects this change in the output voltage so that the rotation angle of the drive ring 27 can be detected. It has become.

A blade receiving plate 30 having a plate-like smooth sliding surface 30a is disposed on the upper surface of the drive ring 27 placed in the groove 26 on the left side in the figure. The sliding surface 30a is disposed so as to be slightly higher than the blade support surface 25b of the base member 25, and a part of a light adjusting member 35 described later can slide on the sliding surface 30a.
A first spring member 31 is inserted and supported in each of the first pin 26c to the third pin 26e of the base member 25. A second spring member 32 is inserted and supported by the fourth pin 26f, and a third spring member 33 is supported by the fifth pin 26g.
A fitting hole 34 a of the lock member 34 is fitted and supported on the fourth pin 26 f that has inserted and supported the second spring member 32. As shown in FIG. 3, the lock member 34 is constantly urged counterclockwise (inward) by elastically urging the outer peripheral side to the third spring member 33.

Further, as shown in FIG. 3, the lock member 34 has a lock pin 34 b protruding from an upper end portion in the figure, and this lock pin 34 b is retracted from the opening 25 a of the base member 25, which will be described later. It is possible to lock the movement of the ND filter 37 by elastically contacting the lock portion 39.
That is, the lock member 34 is a lock mechanism that can lock the movement of the ND filter 37 in a state where the ND filter 37 described later is retracted from the opening 25a.

A plurality of light adjusting members 35, which are thin diaphragm blades made of a stainless plate or the like, are rotatably supported by the first to third pins 26c to 26e that are blade support portions. Each light adjusting member 35 has a support hole 35a that can be supported by the first to third pins 26c to 26e on one end side, and a blade having a large area on the other end side facing the support hole 35a. A portion 35b is formed, and the opening portion 25a can be shielded by the blade portion 35b.
Further, a slit-like long hole 35c is formed in the blade portion 35b at a position near the support hole 35a, and the drive pin 27a of the drive ring 27 is fitted into the long hole 35c.

The three light adjusting members 35 are arranged such that the blade portions 35b overlap each other in a state where the support holes 35a are supported by the first to third pins 26c to 26e.
The three light adjusting members 35 are energized to the coil 23b of the actuator 21 and the drive ring 27 rotates clockwise or counterclockwise, whereby the first to third drive pins 27a to 27c, which are blade support portions, By sliding along the inner surface of each of the long holes 35c, the three light adjusting members 35 can move in the direction of shielding the opening 25a or the direction of opening the opening.

When the drive ring 27 rotates counterclockwise, the blade portions 35b of the three light adjustment members 35 rotate in a direction to open the opening 25a. As a result, as shown in FIG. 2, the opening 25a is opened.
Further, when the drive ring 27 rotates in the clockwise direction, the blade portions 35b of the three light adjustment members 35 rotate in a direction to shield the opening 18a.
As a result, the three blade portions 35b overlap with each other so that the light adjusting member 35 is in a shielded state (not shown) in which the opening 25a is shielded.

Each light adjustment member 35 is elastic in a direction in which the vicinity of the support hole 35a is hooked on the first spring member 31 inserted and supported by the first to third pins 26c and 26e to shield the opening 25a. It is energized.
Therefore, the light adjusting member 35 is generated between the first to third drive pins 27a to 27c of the drive ring 27 and the respective long holes 35c when the light adjustment member 35 rotates in a direction to shield or open the opening 25a. Backlash can be prevented.

A thin partition plate 36 made of stainless steel or the like is disposed on the three light adjustment members 35. The partition plate 36 has a base portion 36a having a substantially circular outer shape, and three projecting portions 36b, 36c and 36d having different width dimensions are formed outwardly on the outer peripheral portion of the base portion 36a. The protrusions 36b, 36c, and 36d are positioned and fixed inside the peripheral wall 25c of the base member 25.
An opening 36e is formed at the center of the base portion 36a of the partition plate 36 and has the same center as the opening 25a of the base member 25 and a slightly larger opening diameter than the opening 25a.
In addition, arc-shaped long holes 36f through which the drive ring 27 can be rotated by a predetermined amount in a state where the three drive pins 27a of the drive ring 27 are positioned are formed in the base portion 36a at equal intervals of 120 °. Yes.

Further, from the partition plate 36, a filter support portion 26j of the base member 25 protrudes upward at a predetermined height, and an ND filter 37 is rotatably supported by the filter support portion 26j.
As shown in FIG. 2, the ND filter 37 has a thin plate-like support plate 38 made of, for example, a resin material, and the filter support portion of the base member 25 is located near one end portion on the right side of the support plate 38 in the drawing. A support hole 38a, which can be rotatably fitted, is formed in 26j. An outer end portion of the support hole 38a is partially formed in a concave shape, and a lock portion 39 is provided. When the lock pin 34b of the lock member 34 is engaged with the lock portion 39, the ND filter 37 is locked and the movement is restricted.

The ND filter 37 has a filter portion 40 made of an ND (neutral density) filter fixed to the other end portion of the support plate 38 on the left side in the figure with an adhesive or the like. The filter unit 40 covers the opening 25a of the base member 25, so that the amount of light passing through the opening 25a is in the second exposure state, which is less than the first exposure state.
Further, the ND filter 37 has a cam hole 38b formed on the inner surface of the support plate 38 between the filter portion 40 and the support hole 38a. The first drive pin 27a on the right side of the drive ring 27 that is inserted into and engaged with the long hole 35c of the light adjusting member 35 is engaged with the cam hole 38b.

Then, with the filter portion 40 of the ND filter 37 covering the opening 25a, the drive ring 27 is rotated counterclockwise by a predetermined angle, so that the moving drive pin 27a slides along the inner surface of the cam hole b. By moving, the filter unit 40 moves in a direction to retract from the opening 25a.
Further, the ND filter 37 is configured such that the upper portion of the lock portion 39 is cut out at the right end portion of the support plate 38 in the figure, and the second spring member 32 is latched.
Therefore, the ND filter 37 is elastically urged by the second flower member 32, and is always urged in a direction in which the filter unit 40 shields the opening 25 a of the base member 25.

Since the ND filter 37 having such a configuration is disposed on the light adjustment member 35 via the partition plate 36, even if both the ND filter 37 and the light adjustment member 35 rotate simultaneously, they interfere with each other. There is no.
A drive ring 27, three light adjusting members 35, a partition plate 36, and an ND filter 37 are stacked in the peripheral wall 25 c of the base member 25. A metal that covers the ND filter 37 is placed on the ND filter 37. A cover member 41 made of a plate is provided.

The cover member 41 is formed with an opening 41a that is slightly larger than the opening 25a in the center of the base member 25 facing the opening 18a.
A semicircular concave portion 41b is formed in a part of the outer peripheral portion of the cover member 41, and the support portion 39 of the ND filter 37 is positioned in the concave portion 41b.
Further, a support portion 41 c is formed on the outer peripheral portion of the cover member 41 by being bent downward, and the support portion 41 c can be snapped and supported on the base member 25.

In assembling the camera diaphragm device of the present invention having such a structure, first, the actuator 21 is driven from above the base member 25 in a state where the actuator 21 is snapped and the detection sensor 24 is attached with a screw (not shown) or the like. A ring 27, a lock member 34, three light adjusting members 35, a partition plate 36, an ND filter 37, and the like are placed in order.
Thereafter, the cover member 41 is covered from above the ND filter 37, and the cover member 41 is snap-supported on the base member 25, whereby the camera diaphragm device of the present invention is assembled.
In addition, the output voltage of the Hall element 24a when the ambient temperature is, for example, room temperature, is input in advance to a control unit (not shown) on the camera side as a reference voltage B as indicated by a solid line in FIG.

The diaphragm operation of the camera (not shown) using the camera diaphragm device of the present invention assembled as described above will be described. First, the operator first lightens, for example, a shutter button (not shown) before photographing. The first shutter operation is performed by operating.
Accordingly, currents in different directions are passed through the pair of coils 23b of the actuator 21, and magnetic fluxes in different directions are generated in the pair of coils 23b.
When the drive ring 27 is rotated, for example, in the counterclockwise direction by a pair of yokes 23a in which different magnetic poles are excited, as shown in FIG. The first abutting wall 26k is abutted to stop the rotation.
The three light adjusting members 35 at this time are in an open state in which the opening 25a is opened.

When the light adjusting member 35 is in the open state, the Hall element 24a faces the one magnetic pole on the left side of the sensor magnet 29 shown in FIG. 1, and the output voltage shown in FIG. The Max value intersects with.
When the ambient temperature at the time of shooting is higher than normal temperature, the output voltage of the Hall element 34a becomes A1 indicated by a broken line. The control unit compares the output voltage A1 and the reference voltage B in advance. The output voltage is corrected by the control unit so as to approach the reference voltage B.
Thereafter, the drive ring 27 is rotated clockwise until the output voltage from the Hall element 24a reaches a value corresponding to the brightness of the subject.

As a result, the aperture amount of the opening 25a can be set to the optimum exposure state, for example, as shown in FIG. 3, corresponding to the brightness of the subject to be photographed.
When the ambient temperature is lower than room temperature, the output voltage of the Hall element 34a is as shown in A2 in FIG. 7. Even when the output voltage is A2, the control unit corrects the output voltage so as to approach the reference voltage B. It is like that.

When the opening 25a is in the optimum exposure state, the energization of the coil 24a of the actuator 21 is stopped and the rotation of the drive ring 27 is stopped.
Then, the magnetic force of the yoke 23a that has lost the magnetic force is lost, and the driving magnet 28 is attracted to the yoke 23a by the magnetic force of the driving magnet 28.
As a result, the rotation of the drive ring 27 can be regulated in an optimal exposure state.
For this reason, even when moving pictures or the like are continuously shot, the movement of the drive ring 27 can be restricted, so that the subject can be shot in an optimal exposure state.

The above-described camera diaphragm device according to the present invention can perform optimum photographing by narrowing the opening 25a to an optimum exposure state even when the ambient temperature is high or low due to a difference in environmental conditions.
In the embodiment of the present invention, the arc tutor 21 has been described as a non-contact type with respect to the drive ring 27. good.

It is a disassembled perspective view of the diaphragm | throttle device for cameras regarding this invention. It is a top view explaining operation | movement of the light adjustment member concerning this invention. It is a top view explaining operation | movement of the light adjustment member concerning this invention. It is a top view explaining operation | movement of the light adjustment member concerning this invention. It is a top view explaining operation | movement of the conventional aperture stop apparatus for cameras. It is a top view explaining operation | movement of the conventional aperture stop apparatus for cameras. It is a graph explaining the output voltage of a Hall element.

Explanation of symbols

21 Actuator 22 Support member 23 Detection sensor 23a Yoke 23b Coil 24 Detection sensor 24a Hall element 25 Base member 26 Groove 27 Drive ring 28 Drive magnet 29 Sensor magnet 30 Blade receiving plate 31 First spring member 32 Second spring member 34 Lock member 35 Light adjusting member 36 Partition plate 37 ND filter 38 Support plate 40 Filter portion 41 Cover member

Claims (4)

A base member having a predetermined thickness; an opening having a predetermined diameter formed through the base member; and a light adjusting member capable of shielding or opening the opening by a driving force of an actuator.
The base member is provided with a drive ring that can rotate in a predetermined rotation angle range in one direction and the other direction by the actuator, and the light adjusting member opens the opening in conjunction with rotation of the drive ring. It is movable in a shielding direction or an opening direction, a sensor magnet is disposed on the drive ring, and a hall element is disposed on the base member on the side facing the sensor magnet,
An aperture device for a camera, wherein the output voltage of the Hall element output corresponding to the magnetic flux of the sensor magnet is corrected so as to approach a reference voltage preset in a control unit. 3. The camera diaphragm device according to claim 2, wherein the correction is performed when the light adjustment member opens or shields the opening. The drive ring is formed with a rotation restricting portion capable of restricting rotation within a predetermined rotation angle range, and the base member is formed with a contact wall with which the rotation restricting portion can come into contact, and the drive ring 3. The aperture control device for a camera according to claim 1, wherein the output voltage is corrected when the rotation restricting portion comes into contact with the contact wall by rotating the rotation restricting portion. 4. The aperture device for a camera according to claim 1, wherein the correction is performed in conjunction with a shutter operation.

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