JP2012027301A - Shutter driving device and camera - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a shutter driving device and a camera that can improve the adjustment accuracy of curtain speed and can make the adjustment of the curtain speed easy at the same time.SOLUTION: A first gear part 151 having a large number of teeth for adjusting curtain speed and a second gear part 152 which has a small number of teeth and which engages with a tool for rotating crown-shaped locking parts 150 are provided in the crown-shaped locking parts 150, thereby being capable of improving the adjustment accuracy of the curtain speed and making the adjustment of the curtain speed easy at the same time.

Description

  The present invention relates to a shutter driving device that drives a shutter device, and a camera including the shutter driving device.

  The camera is provided with a shutter device that opens and blocks a photographing aperture for guiding subject light. In this shutter device, the shutter blades (light shielding curtain blade group) travel at a high speed so that the photographing aperture is opened and shielded. This shutter device is provided with a driving spring for moving the light shielding blade group at a high speed and a curtain speed adjusting device for adjusting the traveling speed (curtain speed) of the light shielding blade group by adjusting the biasing force of the driving spring. Yes. In this curtain speed adjusting device, the biasing force of the drive spring is increased or decreased by adjusting the winding strength of the drive spring.

  This curtain speed adjusting device is configured such that the winding strength of the drive spring is adjusted according to the phase of the ratchet member. The ratchet member is locked at a predetermined phase when one of a plurality of teeth carved at a predetermined pitch on the outer periphery of the ratchet member is engaged with the claw portion (see Patent Document 1).

JP 2003-66508 A

  In the shutter drive device described in the above-mentioned patent document, when adjusting the phase of the ratchet member, the ratchet member is rotated by engaging an adjusting tool with the teeth of the ratchet member. In order to increase the resolution of adjusting the phase of the ratchet member, that is, the strength of the winding of the drive spring, it is necessary to reduce the tooth pitch of the ratchet member and increase the number of teeth. However, if the teeth of the ratchet member are made smaller, it becomes difficult to engage the adjusting tool, and the phase of the ratchet member becomes difficult to adjust.

(1) A shutter driving device according to a first aspect of the present invention is a shutter driving device for driving a shutter device having a light shielding blade and an arm to which the light shielding blade is attached. A lever, one end attached to the drive lever, a drive spring for applying an urging force to the drive lever, and a member for adjusting the urging force, the other end of the drive spring being attached, and a shaft that is rotatable about the rotation axis A biasing force adjusting member that increases the biasing force when rotated in one direction around the rotation axis and decreases the biasing force when rotated in the other direction around the rotation shaft, and biasing force adjustment An anti-rotation claw that engages with the member and prevents the biasing force adjusting member from rotating in the other direction, and the biasing force adjusting member includes a first pawl that engages with the anti-rotation pawl and the rotation shaft. Multiple incisions on the center circle A first gear portion provided and a second gear that is different from the first gear portion, and in which a plurality of second claws are provided on a circumference centering on the rotation axis The number of first claws provided in the first gear portion is greater than the number of second claws provided in the second gear portion.
(2) A camera according to a sixth aspect of the invention includes the shutter driving device according to any one of the first to fifth aspects.

  According to the present invention, it is possible to improve both the adjustment accuracy of the curtain speed and the ease of adjusting the curtain speed.

It is sectional drawing of the single-lens reflex type camera body which concerns on this invention, (a) is sectional drawing seen from the upper surface, (b) is sectional drawing seen from the side surface. It is the figure which looked at a part of sequence shutter drive unit and a part of light-shielding curtain mechanism from the front. It is an exploded view about a part of sequence shutter drive unit. It is an exploded view about a part of sequence shutter drive unit. It is a figure when the vicinity of a locking crown is seen from the left side. It is a perspective view when the vicinity of a locking crown is seen from diagonally forward.

  1 to 6, an embodiment of a shutter driving device and a camera according to the present invention will be described. FIG. 1A is a cross-sectional view of a single-lens reflex camera body 1 that is a camera equipped with a shutter driving device according to the present invention as viewed from above, and FIG. 1B is a view of the camera body 1 as viewed from the side. FIG. The camera body 1 includes a mirror box 10, a sequence shutter drive unit 100, a light-shielding curtain mechanism 400, an image sensor 3, a sequence motor 4, a viewfinder optical system 20, a photometric unit 5, an AF unit 6, A rear display monitor 7 is provided. Reference numeral 8 denotes a battery mounted in the camera body 1. A photographing lens 2 is attached to the front surface of the camera body 1. For convenience of explanation, the vertical direction, the horizontal direction, and the front-rear direction of the camera body 1 are defined as shown in each drawing.

  The mirror box 10 accommodates the main mirror 11 and the sub mirror 12 and forms a photographing optical path. The mirror box 10 is attached to the camera body 1. The sequence shutter drive unit 100 is a drive mechanism that drives a front curtain light shielding blade group and a rear curtain light shielding blade group, which will be described later, of the aperture mechanism, the mirror rotation mechanism, and the light shielding curtain mechanism 400. Details of the sequence shutter drive unit 100 will be described later. The light-shielding curtain mechanism 400 is a known device that has a front-curtain light-shielding blade group and a rear-curtain light-shielding blade group, and opens and shields the photographing aperture for a predetermined time.

  The image sensor 3 is composed of a solid-state image sensor such as a CCD or CMOS, and converts the subject image formed by the photographing lens 2 into an electrical signal. The sequence motor 4 is a drive source that generates the drive force of the sequence shutter drive unit 100. The viewfinder optical system 20 includes a pentaprism 21 and an eyepiece lens 22 and is used for observing an image (subject image) of subject light reflected by the main mirror 11. The photometric unit 5 is a CCD unit that performs photometry using subject light emitted from the pentaprism 21. The AF unit 6 performs focus detection using subject light incident through the main mirror 11 and the sub mirror 12. The rear display monitor 7 uses, for example, a liquid crystal display device and displays various information at the time of shooting, an image of a subject image obtained by imaging, a through image (also referred to as a live view image or a live preview image), and the like. To do.

  2 is a view of a part of the sequence shutter drive unit 100 and a part of the light-shielding curtain mechanism 400 as viewed from the front, and FIGS. 3 and 4 are exploded views of a part of the sequence shutter drive unit 100. FIG.

--- Sequence shutter drive unit 100 ---
The sequence shutter drive unit 100 is provided with each cam, each lever, each gear, and the like on the sequence base plate 110. The sequence ground plane 110 has a first ground plane (not shown) and a second ground plane 112 that are substantially orthogonal to each other, and is formed in a substantially L shape when viewed from above by the first ground plane and the second ground plane 112. Yes.

  A first ground plane (not shown) extends in the front-rear direction and the vertical direction of the camera body 1. A front curtain charge cam, a rear curtain charge cam, a front curtain charge cam lever, a rear curtain charge cam lever, and an aperture control lever (not shown) are attached to the left side surface of the first base plate. A mirror drive cam, an aperture control lever drive cam, a mirror drive cam lever, and an aperture control lever drive cam lever (not shown) are attached to the right side surface of the first base plate.

  The second ground plane 112 extends in the left-right direction and the up-down direction of the camera body 1. A front curtain drive lever 141, a rear curtain drive lever 142, a front curtain magnet 143, and a rear curtain magnet 144 are attached to the front surface of the second base plate 112. In addition, on the front surface of the second base plate 112, a shaft 112g that pivotally supports a later-curtain drive lever 141 described later and a shaft 112h that pivotally supports a rear-curtain drive lever 142 described later stand. It is installed. In addition, a buffer member 113 is attached to the bases 112i and 112j on the front surface of the second base plate 112. The buffer member 113 is a member for absorbing an impact when the front curtain drive lever 141 and the rear curtain drive lever 142 are stopped. On the rear surface of the second base plate 112, a front curtain main arm support pin and a front curtain driven arm support pin (not shown), a rear curtain main arm support pin, and a rear curtain driven arm support pin are provided upright. The second ground plate 112 extends from the rear end of the first ground plate toward the left side.

  The sequence ground plane 110 is attached to the left side surface of the mirror box 10 on the right side surface of the first ground plane. The sequence ground plate 110 has a light shielding mechanism 400 attached to the rear surface of the second ground plate 112.

  A front curtain charge cam (not shown) drives a front curtain drive lever 141 (to be described later) via a front curtain charge cam lever (not shown) to charge the front curtain light shielding blade group 411 (FIG. 2) of the light shielding curtain mechanism 400. The cam. A rear curtain charge cam (not shown) drives a rear curtain drive lever 142 (to be described later) via a rear curtain charge cam lever (not shown) to charge the rear curtain light shielding blade group 431 (FIG. 2). The cam. The front curtain charge cam and the rear curtain charge cam are rotatably supported with respect to the first base plate. The front curtain charge cam and the rear curtain charge cam are rotated by the driving force of the sequence motor 4.

  The aperture control lever (not shown) is a lever that is pivotally supported on the first base plate and is a member that drives the aperture of the photographic lens 2.

  The front curtain drive lever 141 is a lever for driving the front curtain light-shielding blade group 411, and has a hollow shaft portion 141a, a front curtain drive lever protrusion 141b, a magnet attracting portion 141e, and a contact portion 141g. (FIGS. 3 and 4) and attached to the second base plate 112 so as to be rotatable.

  The hollow shaft portion 141a is a hollow shaft that stands on the front surface of the front curtain drive lever 141 and extends forward. The front curtain drive lever protrusion 141 b is a shaft-like portion that stands upright on the rear surface of the front curtain drive lever 141 and extends rearward, and the front end portion thereof is the front curtain main arm 421 of the front curtain light shielding blade group 411. It engages with an engagement hole 421b provided in. The front curtain drive lever protrusion 141b protrudes to the rear surface side of the second main plate 112 so as to be able to engage with the engagement hole 421b of the front curtain main arm 421, and the front curtain is driven by the rotation of the front curtain drive lever 141. A long hole 112c is provided in the second base plate 112 so as not to hinder the movement of the drive lever protrusion 141b.

  The magnet attracting portion 141e is a part that is provided on the front surface of the front curtain drive lever 141 and is attracted by a front curtain magnet 143 described later. The contact portion 141g is a portion that is provided on the front surface of the front curtain drive lever 141 and contacts the buffer member 113.

  The front curtain drive lever 141 is provided with a through hole 141f from the front end surface to the rear end surface of the hollow shaft portion 141a (FIGS. 3 and 4). A shaft 112g erected on the second ground plane 112 is inserted into the through hole 141f. Thereby, the front curtain drive lever 141 is pivotally supported by the shaft 112g.

  A spring 145 that is a torsion coil spring that biases the front curtain drive lever 141 is disposed on the outer periphery of the hollow shaft portion 141a. One end 145a (the rear end in FIGS. 3 and 4) of the spring 145 is engaged with the front curtain drive lever 141. The other end 145b (the front end in FIGS. 3 and 44) of the spring 145 is locked to a locking crown 150 described later. The front curtain drive lever 141 is urged clockwise by the urging force of the spring 145 about the central axis of the hollow shaft portion 141a when the front curtain drive lever 141 is viewed from the front.

  The front curtain drive lever 141 is attached with a front curtain overcharge absorption lever 147 via a spring 148A, and the front curtain drive lever 141 and the front curtain overcharge absorption lever 147 rotate integrally. The front curtain overcharge absorption lever 147 is a lever for absorbing overcharge when the front curtain light shielding blade group 411 is reset by the bending of the spring 148A, and has a contact portion 147a. The front curtain overcharge absorption lever 147 urges the front curtain drive lever 141 in the counterclockwise direction in FIG. 2 with a spring 148A.

  When the abutting portion 147a is pressed upward by a front curtain charge cam lever (not shown) driven by a front curtain charge cam (not shown) coming into contact with the abutting portion 147a, the front curtain overcharge absorption lever 147 is Together with the front curtain drive lever 141, it rotates counterclockwise as shown in FIG. 2 against the urging force of the spring 145. After the magnet attracting portion 141e comes into contact with the front curtain magnet 143 and the rotation of the front curtain drive lever 141 in the counterclockwise direction is restricted, the front curtain charge cam lever (not shown) further presses the contact portion 147a. When the first curtain overcharge absorbing lever 147 is rotated in the counterclockwise direction so as to bend the spring 148A, the first curtain charge cam lever overcharge movement is absorbed.

  The rear curtain drive lever 142 is a lever for driving the rear curtain light shielding blade group 431, and includes a hollow shaft portion (not shown), a front curtain drive lever protrusion (not shown), a magnet attracting portion 142e, 142g (FIG. 2), and is attached to the second main plate 112 so as to be rotatable. The rear curtain drive lever 142 is configured similarly to the front curtain drive lever 141. That is, the hollow shaft portion (not shown) is the same portion as the hollow shaft portion 141a, and the front curtain drive lever protrusion (not shown) is the same portion as the front curtain drive lever protrusion 141b, and the magnet attracting portion 142e. Is the same part as the magnet attracting part 141e, and the contact part 142g is the same part as the contact part 141g.

  Specifically, the hollow shaft portion (not shown) is a hollow shaft that stands on the front surface of the rear curtain drive lever 142 and extends forward. The rear-curtain drive lever protrusion is a shaft-like portion that stands upright on the rear surface of the rear-curtain drive lever 142 and extends rearward, and a tip portion of the rear-curtain drive lever 142 projects from the rear curtain main arm 441 of the rear-curtain shading blade group 431. It engages with an engagement hole (not shown) provided. It should be noted that the rear curtain drive lever projection protrudes from the rear surface of the second main plate 112 so that it can engage with the engagement hole of the rear curtain main arm 441, and the rear curtain drive lever 142 rotates by the rotation of the rear curtain drive lever 142. The second base plate 112 is provided with a long hole 112d so as not to hinder the movement of the part (FIGS. 2 and 4).

  The magnet attracting portion 142e is a portion that is provided on the front surface of the rear curtain drive lever 142 and is attracted by a rear curtain magnet 144 described later. The contact portion 142g is a portion that is provided on the front surface of the rear curtain drive lever 142 and contacts the buffer member 113.

  The rear curtain drive lever 142 is provided with a through hole (not shown) from the front end surface to the rear end surface of the hollow shaft portion. A shaft 112h erected on the second ground plate 112 is inserted into the through hole. Thus, the rear curtain drive lever 142 is pivotally supported on the shaft 112h.

  A torsion coil spring (not shown) that urges the rear curtain drive lever 142 is disposed on the outer periphery of the hollow shaft portion. One end of the torsion coil spring is locked to the trailing curtain drive lever 142, and the other end is locked to the locking crown 150. The rear curtain drive lever 142 is urged clockwise around the central axis of the hollow shaft portion when the rear curtain drive lever 142 is viewed from the front by an urging force of a torsion coil spring (not shown).

  Further, the rear curtain drive lever 142 is attached with a rear curtain overcharge absorption lever 149 via a spring 148B different from the torsion coil spring (not shown), and the rear curtain drive lever 142 and the rear curtain overcharge absorption lever are attached. And 149 rotate integrally. The rear curtain overcharge absorption lever 149 is a lever for absorbing overcharge when the rear curtain light shielding blade group 431 is reset by the bending of the spring, and has a contact portion 149a. The trailing curtain overcharge absorption lever 149 is the same lever as the leading curtain overcharge absorption lever 147, and a detailed description thereof will be omitted.

  The front curtain magnet 143 is a magnet that attracts and holds the magnet attracting portion 141e of the front curtain drive lever 141 that is in contact with the exciting coil when energized. When the energization to the exciting coil is stopped, the front curtain magnet 143 releases the magnet attracting portion 141e so as to be detachable.

  The trailing curtain magnet 144 is a magnet that attracts and holds the magnet attracting portion 142e of the trailing curtain drive lever 142 that is in contact with the exciting coil when energized. When the energization of the exciting coil is stopped, the rear curtain magnet 144 releases the magnet attracting portion 142e so as to be detachable.

When the light-shielding curtain mechanism 400 is attached to the above-described sequence shutter drive unit 100, the parts of the light-shielding curtain mechanism 400 have the following relationships (a) to (f) with the parts of the sequence shutter drive unit 100.
(A) A front curtain main arm support pin (not shown) is inserted into the rotation shaft hole 421a (FIG. 4) of the front curtain main arm 421. As a result, the front curtain main arm 421 is pivotally supported by the front curtain main arm support pin so as to be rotatable.

(B) The front curtain drive lever protrusion 141 b of the front curtain drive lever 141 is inserted into the engagement hole 421 b of the front curtain main arm 421. As a result, the front curtain drive lever protrusion 141b of the front curtain drive lever 141 engages with the engagement hole 421b of the front curtain main arm 421.

(C) A front curtain driven arm support pin (not shown) is inserted into the rotation shaft hole 422a (FIG. 4) of the front curtain driven arm 422. As a result, the front curtain driven arm 422 is pivotally supported by the front curtain driven arm support pin.

(D) A rear curtain main arm support pin (not shown) is inserted into a rotation shaft hole (not shown) of the rear curtain main arm 441 (FIG. 2). Accordingly, the rear curtain main arm 441 is pivotally supported by the rear curtain main arm support pin so as to be rotatable.

(E) The rear curtain drive lever protrusion (not shown) of the rear curtain drive lever 142 is inserted into the engagement hole (not shown) of the rear curtain main arm 441. As a result, the rear curtain drive lever protrusion of the rear curtain drive lever 142 is engaged with the engagement hole of the rear curtain main arm 441.

(F) A rear curtain follower arm support pin (not shown) is inserted into a rotation shaft hole (not shown) of the rear curtain follower arm 442 (FIG. 2). Thus, the rear curtain driven arm 442 is pivotally supported by the rear curtain driven arm support pin so as to be rotatable.

  Accordingly, when the front curtain main arm 421 and the front curtain driven arm 422 are driven to rotate around the front curtain main arm support pin and the front curtain driven arm support pin, the front curtain light shielding blade group 411 is driven in conjunction with the front curtain main arm support pin and the front curtain driven arm support pin. . That is, the three blades of the front-curtain light-shielding blade group 411 are driven by a well-known link mechanism constituted by the front-curtain main arm 421 and the front-curtain driven arm 422, and the photographing opening 461 of the light-shielding curtain mechanism 400 is driven. (FIG. 2) is configured to move up and down.

  Similarly, when the rear curtain main arm 441 and the rear curtain follower arm 442 are driven to rotate around the rear curtain main arm support pin and the rear curtain follower arm support pin, the rear curtain light shielding blade group 431 is driven in conjunction with the rear curtain main arm support pin 442 and the rear curtain follower arm support pin 442. . In other words, the three blades of the rear curtain light shielding blade group 431 are driven in conjunction by a well-known link mechanism constituted by the rear curtain main arm 441 and the rear curtain driven arm 442, and the photographing opening 461 of the light shielding curtain mechanism 400. Is configured to move up and down.

  Before the start of shooting, the excitation coils of the front curtain magnet 143 and the rear curtain magnet 144 are not energized, and the excitation coils are demagnetized. Further, the sequence motor 4 is stopped before the start of photographing.

  The contact portion 147a of the front curtain overcharge absorbing lever 147 is pushed upward by a front curtain charge cam and a front curtain charge cam lever (not shown) (FIG. 2). Therefore, the front curtain drive lever 141 is rotated counterclockwise and stopped when viewed from the front of the camera body 1 against the urging force of the spring 145.

  At this time, since the front curtain drive lever protrusion 141b of the front curtain drive lever 141 is moved upward, when the front curtain main arm 421 of the light shielding curtain mechanism 400 is viewed from the front of the camera body 1, the rotation shaft hole is reached. It stops in a state of being rotated counterclockwise about 421a. Therefore, the front-curtain light shielding blade group 411 is lifted upward and stopped in a state where the photographing opening 461 is shielded from light.

  A contact portion 149a of the trailing curtain overcharge absorbing lever 149 is pushed upward by a trailing curtain charge cam and a trailing curtain charge cam lever (not shown). Therefore, the rear curtain drive lever 142 is rotated counterclockwise and stopped when viewed from the front of the camera body 1 against the biasing force of a spring (not shown).

  At this time, since the rear curtain drive lever protrusion (not shown) of the rear curtain drive lever 142 is moved upward, the counterclockwise when the rear curtain main arm 441 of the light shielding curtain mechanism 400 is viewed from the front of the camera body 1. Stopped in a state rotated in the direction. Therefore, the rear curtain light shielding blade group 431 is pulled up and stopped in a state of being retracted above the photographing opening 461.

  When a release button (not shown) is pressed and a release signal is input from a release switch (not shown), a release operation described below is performed. A control circuit (not shown) excites the front curtain magnet 143 and the rear curtain magnet 144. Thus, the front curtain magnet 143 and the rear curtain magnet 144 attract and hold the magnet attracting portion 141e of the front curtain drive lever 141 and the magnet attracting portion 142e of the rear curtain drive lever 142 which are in contact with each other. When the release signal is input, the control circuit (not shown) starts the rotation of the sequence motor 4 and rotates each cam (not shown) by a predetermined rotation angle. Stop. The stop timing of the sequence motor 4 is controlled by a control circuit (not shown) by detecting the phase of a cam code board (not shown).

  By rotation of the sequence motor 4, the front curtain charge cam lever (not shown) is separated from the contact portion 147 a of the front curtain overcharge absorption lever 147. However, since the front curtain magnet 143 attracts and holds the magnet attracting portion 141e of the front curtain drive lever 141, the front curtain drive lever 141 is viewed from the front of the camera body 1 against the biasing force of the spring 145. Is stopped while rotating counterclockwise. That is, the front curtain light shielding blade group 411 is stopped in a state where the photographing opening 461 is shielded.

  Further, the rotation of the sequence motor 4 causes the rear curtain charge cam lever (not shown) to move away from the contact portion 149a of the rear curtain overcharge absorption lever 149. However, since the rear curtain magnet 144 attracts and holds the magnet attracting portion 142e of the rear curtain drive lever 142, the rear curtain drive lever 142 is seen from the front of the camera body 1 against the biasing force of a spring (not shown). When stopped, it is stopped while rotating counterclockwise. That is, the rear curtain light shielding blade group 431 is stopped in a state of being retracted above the photographing opening 461.

  Although detailed description is omitted, after that, the aperture of the taking lens 2 is narrowed down to the control aperture value. Thereafter, a control circuit (not shown) stops energization of the exciting coil of the front curtain magnet 143. As a result, the magnet attracting portion 141e of the front curtain drive lever 141 is releasably released, so that the front curtain drive lever 141 rotates clockwise when viewed from the front of the camera body 1 by the biasing force of the spring 145. To do. When the front curtain drive lever protrusion 141b is moved downward by the rotation of the front curtain drive lever 141, the front shaft main arm 421 of the light shielding curtain mechanism 400 is viewed from the front of the camera body 1, and the rotational shaft hole 421a. It is rotated clockwise around the center. As a result, the front curtain light blocking blade group 411 moves the photographing opening 461 downward to open the photographing opening 461. At this stage, the rear curtain light shielding blade group 431 is stopped in a state of being retracted above the photographing opening 461.

  The front curtain drive lever 141 rotated by the urging force of the spring 145 stops when the contact portion 141g contacts the buffer member 113 attached to the pedestal 112i. At this time, the buffer member 113 absorbs an impact caused by the collision of the contact portion 141g, and suppresses repulsion (bound) in the counterclockwise direction of the contact portion 141g (that is, the front curtain drive lever 141).

  Imaging is performed by controlling the accumulation of electric charges in the image sensor 3 by an electronic shutter controlled by a control circuit (not shown) while the photographing aperture 461 is opened. When the charge accumulation in the image sensor 3 is completed and the imaging is completed, a control circuit (not shown) stops energization to the excitation coil of the trailing curtain magnet 144. As a result, the magnet attracting portion 142e of the rear curtain drive lever 142 is releasably released, so that the rear curtain drive lever 142 is clockwise when viewed from the front of the camera body 1 by a biasing force of a spring (not shown). Rotate. When the rear curtain drive lever projection (not shown) is moved downward by the rotation of the rear curtain drive lever 142, the rear curtain main arm 441 of the light shielding curtain mechanism 400 is clockwise when viewed from the front of the camera body 1. Is rotated. Accordingly, the rear curtain light shielding blade group 431 moves the photographing opening 461 downward to shield the photographing opening 461. This completes the release operation and the shooting operation.

  The trailing curtain drive lever 142 rotated by the biasing force of a spring (not shown) is stopped when the contact portion 142g contacts the buffer member 113 attached to the pedestal 112j. At this time, the buffer member 113 absorbs the impact caused by the collision of the abutting portion 142g, and suppresses the bounce of the abutting portion 142g (that is, the rear curtain drive lever 142) in the counterclockwise direction in the drawing.

  When the above-described release operation and photographing operation are completed, the following reset operation is performed subsequently. The control circuit (not shown) starts the rotation of the sequence motor 4 and rotates each cam (not shown) to the rotation phase before starting the release, and then stops the sequence motor 4.

  As a result, the contact portion 147a of the front curtain overcharge absorption lever 147 is pushed upward by a front curtain charge cam and a front curtain charge cam lever (not shown). Therefore, the front curtain drive lever 141 is rotated counterclockwise and stopped when viewed from the front of the camera body 1 against the urging force of the spring 145.

  As a result, the front curtain drive lever protrusion 141b of the front curtain drive lever 141 moves upward, and when viewed from the front of the camera body 1, the front curtain main arm 421 of the light shielding curtain mechanism 400 is moved through the rotation shaft hole 421a. Turn counterclockwise about the center. Therefore, the front curtain light shielding blade group 411 travels upward and shields the photographing opening 461. In this way, the front curtain light blocking blade group 411 is reset (shutter charged).

  Similarly, a contact portion 149a of the trailing curtain overcharge absorbing lever 149 is pushed upward by a trailing curtain charge cam and a trailing curtain charge cam lever (not shown). Therefore, the rear curtain drive lever 142 rotates counterclockwise and stops when viewed from the front of the camera body 1 against the biasing force of a spring (not shown).

  As a result, the rear curtain drive lever protrusion (not shown) of the rear curtain drive lever 142 moves upward, and when viewed from the front of the camera body 1, the rear curtain main arm 441 of the light shielding curtain mechanism 400 is counterclockwise. Rotate. Therefore, the rear curtain light blocking blade group 431 travels upward and retracts above the imaging opening 461. In this way, the rear curtain light blocking blade group 431 is reset (shutter charged).

  With the above-described reset operation, the light-shielding curtain mechanism 400 returns to the state before shooting starts (before the release starts).

--- About the locking crown 150 ---
The locking crown 150 will be described with reference to FIGS. 5 is a view when the vicinity of the locking crown 150 is viewed from the left side, and FIG. 6 is a perspective view when the vicinity of the locking crown 150 is viewed obliquely from the front. The locking crown 150 adjusts the strength (biasing force) of a spring (not shown) that urges the spring 145 and the trailing curtain drive lever 142 that is a torsion coil spring similar to the spring 145, at the time of release. This is a member (biasing force adjusting member) for adjusting the traveling speed (curtain speed) of the front curtain light shielding blade group 411 and the rear curtain light shielding blade group 431. Since both the structures and functions of the two locking crowns 150 are the same, in the following description, the locking crown 150 that adjusts the biasing force of the spring 145 will be described, and the rear curtain drive lever 142 will not be biased. Description of the locking crown 150 that adjusts the biasing force of the illustrated spring is omitted.

  The locking crown 150 is a covered cylindrical member and has a first gear portion 151 and a second gear portion 152. The first gear portion 151 is a portion that engages with a rotation preventing claw 162 of the presser plate 160 described later, and a plurality of first claws 151 a are formed on the outer surface of the cylindrical portion of the locking crown 150. The second gear portion 152 is a portion provided in front of the first gear portion 151 (upper part in FIGS. 3 and 4), and a plurality of second claws 152 a are formed on the outer surface of the cylindrical portion of the locking crown 150. ing. The second gear portion 152 is a portion to which a tool for rotating the locking crown 150 is engaged for adjusting the biasing force of the spring 145.

  The other end 145 b side of the spring 145 is inserted on the cylindrical inner surface side of the locking crown 150. The other end 145 b of the spring 145 is locked to a locking portion (not shown) provided on the cylindrical inner surface of the locking crown 150. A shaft hole 153 into which the tip portion of the shaft 112g of the second base plate 112 is inserted is provided in the front surface of the locking crown 150, that is, the portion corresponding to the lid portion of the front end surface of the cylinder. In addition, a mark 154 is provided on the front surface of the locking crown 150 as a guide for adjusting the biasing force of the spring 145. For example, the mark 154 is attached every 90 degrees with the shaft hole 153 (the shaft 112g) as the center. Note that one of the marks 154 has an angular position around the shaft hole 153 (the shaft 112g), and the engagement of the inner surface of the cylinder of the engagement crown 150 to which the other end 145b of the spring 145 is engaged is not shown. It is provided so as to coincide with the part.

  The arrangement position of the locking crown 150 of the present embodiment is the front side of the front curtain drive lever 141 and the spring 145, and is the same as the arrangement position of the conventional locking crown.

  As shown in FIGS. 5 and 6, the front surface of the locking crown 150 is prevented from coming off from the shaft 112 g of the second ground plate 112 by the pressing portion 161 of the pressing plate 160. In addition, in FIG. 2-4, description of the pressing board 160 is abbreviate | omitted. The pressing plate 160 is a member fixed to the second ground plate 112 and includes a pressing portion 161 and an anti-rotation claw 162. When the presser plate 160 is attached to the second ground plate 112, the presser portion 161 serves as a retaining member (presser plate) that prevents the locking crown 150 from coming off the shaft 112g forward. The holding portion 161 is provided with a hole 161a through which the tip of the shaft 112g is inserted when the holding plate 160 is attached to the second ground plate 112 (FIG. 6).

  The anti-rotation claw 162 is a plate-like portion extending in the clockwise direction on the outer periphery of the first gear portion 151 around the shaft 112g when viewed from the front. The anti-rotation claw 162 has its tip portion (claw tip) 162a urged toward the first gear portion 151 (inward of the circumference centering on the shaft 112g) by its elastic force. The anti-rotation claw 162 has a claw tip 162a engaged with the first claw 151a of the first gear portion 151, and is biased by the spring 145 (reaction force of the force by which the spring 145 biases the front curtain drive lever 141). When viewed from the front, the locking crown 150 is prevented from rotating counterclockwise around the shaft 112g.

  As a result, the other end 145 b of the spring 145 is fixed to the second base plate 112 via the locking crown 150 and the rotation prevention claw 162. Therefore, the front curtain drive lever 141 to which the one end 145a of the spring 145 is attached is urged clockwise around the shaft 112g when viewed from the front with respect to the second base plate 112 by the urging force of the spring 145. The

--- About the 1st gear part 151 and the 2nd gear part 152 ----
The first gear portion 151 and the second gear portion 152 are gear portions having substantially the same pitch diameter. The number of teeth of the first gear portion 151 (that is, the number of first claws 151a) is larger than the number of teeth of the second gear portion 152 (that is, the number of second claws 152a). This is because the urging force of the spring 145, that is, the curtain speed of the front curtain light shielding blade group 411 can be finely adjusted as the number of teeth of the first pawl 151a is larger. Further, the smaller the number of teeth of the second gear portion 152 is, the larger the size of the second claw 152a is, so that the tool for rotating the locking crown 150 can be easily engaged. Therefore, in this embodiment, it is possible to achieve both improvement in the accuracy of adjusting the curtain speed of the front curtain light blocking blade group 411 and ease of adjustment. In the present embodiment, the number of teeth of the first gear portion 151 is three times the number of teeth of the second gear portion 152.

  Further, the number of teeth of the second gear portion 152 (the size of the second claw 152a) is the same number of teeth (the same size) as that of the conventional locking crown. Moreover, the said part of the conventional latching crown is a part which engages with the nail | claw equivalent to the rotation prevention nail | claw 162 of this Embodiment while engaging with a tool. Therefore, in the locking crown 150 of the present embodiment, the biasing force of the spring 145 (that is, the curtain speed of the front-curtain shading blade group 411) is three times more accurate (1/3 fineness) than the conventional locking crown. ) Can be adjusted. Further, since the number of teeth of the first gear portion 151 is three times the number of teeth of the second gear portion 152, when adjusting the curtain speed, one tooth of the conventional locking crown is related to this embodiment. Since the crown 150 corresponds to three first claws 151a, it is easy for a person who adjusts the curtain speed to know how much the locking crown 150 should be rotated. For example, for those who have empirically understood that it is only necessary to adjust two teeth of a conventional locking crown, it is only necessary to adjust six first claws 151a in the locking crown 150 of the present embodiment. This makes it easier to adjust the curtain speed.

  Since the second gear portion 152 is provided in front of the first gear portion 151 and adjacent to the first gear portion 151, the locking crown 150 is used when adjusting the curtain speed of the front curtain shading blade group 411. It is easy to engage the tool with the (second gear portion 152), and it is easy to adjust. Since the first gear portion 151 is provided at a position closer to the spring 145 than the second gear portion 152, the tool approached from the front to rotate the locking crown 150 interferes with the rotation prevention claw 162. It becomes difficult, and it is easy to engage a tool with the 2nd gear part 152, and to adjust easily. Further, since the disposition position of the locking crown 150 is the same as the disposition position of the conventional locking crown, the disposition position of the rotation prevention claw 162 is the same as that of the conventional claw corresponding to the rotation prevention claw 162, and is designed. There are few changes and the increase in cost can be suppressed. Furthermore, since the first gear portion 151 and the second gear portion 152 are provided adjacent to each other, an increase in the size of the locking crown 150 can be suppressed, and an increase in the size of the sequence shutter drive unit 100 can be suppressed.

  The shape of the first claw 151a is such that when the first claw 151a contacts the claw tip 162a of the rotation preventing claw 162, the locking crown 150 does not rotate counterclockwise around the shaft 112g when viewed from the front. The shape is similar to that of the teeth of a ratchet wheel (ratchet gear). Therefore, in order to rotate the locking crown 150 counterclockwise around the shaft 112g when viewed from the front, the claw tip 162a is separated from the first claw 151a against the elastic force of the rotation prevention claw 162. It is necessary to let When the locking crown 150 is rotated clockwise around the shaft 112g when viewed from the front, the claw tip 162a does not have to be separated from the first claw 151a.

  The shape of the second claw 152a is the same as the shape of the first claw 151a. That is, the shape of the 2nd nail | claw 152a is a shape similar to the tooth | gear of a ratchet wheel (ratchet gear).

  The length along the extending direction of the shaft 112g of the first claw 151a is longer than the length along the extending direction of the shaft 112g of the second claw 152a. That is, the thickness of the first claw 151a in the front-rear direction is larger than the thickness of the second claw 152a in the front-rear direction. Thereby, the number of teeth of the first gear portion 151 is larger than the number of teeth of the second gear portion 152, and the size of the first claw 151a is smaller than the size of the second claw 152a, but the biasing force of the spring 145 is reduced. The strength of the acting first claw 151a can be ensured.

---- Modified example ---
(1) In the above description, the number of teeth of the first gear portion 151 is three times the number of teeth of the second gear portion 152, but the present invention is not limited to this. For example, the number of teeth of the first gear portion 151 may be twice or four times the number of teeth of the second gear portion 152. If the number of teeth of the first gear portion 151 is an integer multiple of 2 or more of the number of teeth of the second gear portion 152, the same effects as the above-described effects can be obtained. Further, even if the number of teeth of the first gear portion 151 is not an integral multiple of the number of teeth of the second gear portion 152, for example, if it is 1.5 times, the number of teeth of the conventional locking crown (that is, the second number) In the locking crown 150 of the present embodiment, this corresponds to three first claws 151a. Therefore, for those who adjust the curtain speed, how much the locking crown 150 is rotated. It is easy to understand sensuously. Further, for example, if the magnification is 2.5 times, the two teeth of the conventional locking crown correspond to the five first claws 151a in the locking crown 150 of the present embodiment. It is easy for a person who adjusts the amount to know how much the locking crown 150 should be rotated. That is, even when the number of the second claws 152a is the number of a of the first claws 151a (a is an integer larger than 3, preferably about 3 to 8), the same effects as the above-described effects can be obtained. .

(2) In the above description, the first gear portion 151 and the second gear portion 152 are provided adjacent to each other, but are not necessarily adjacent. However, if the first gear portion 151 and the second gear portion 152 are adjacent to each other, the locking crown 150 can be downsized, which contributes to downsizing of the sequence shutter drive unit 100 and the camera body 1.

(3) In the above description, the camera body 1 is a digital camera provided with the image sensor 3, but the present invention may be applied to a silver salt camera.
(4) In the above description, the light-shielding curtain mechanism 400 has two sets of light-shielding curtain blade groups, that is, the front-curtain light-shielding blade group 411 and the rear-curtain light-shielding blade group 431, but the present invention is not limited to this. For example, the light shielding blade mechanism 400 may have one set of light shielding blade groups.
(5) You may combine each embodiment and modification which were mentioned above, respectively.

  The present invention is not limited to the embodiment described above, and in a shutter drive device that drives a shutter device having a light shielding blade and an arm to which the light shielding blade is attached, the shutter drive device rotates about a rotation axis. A drive lever that drives the arm, a drive spring that is attached at one end to the drive lever and applies a biasing force to the drive lever, and a member that adjusts the biasing force. An urging force adjusting member that is pivotally supported by the shaft and increases the urging force when rotated in one direction around the rotation axis, and decreases the urging force when rotated in the other direction around the rotation axis. And an anti-rotation claw that engages with the urging force adjusting member to prevent the urging force adjusting member from rotating in the other direction, and the urging force adjusting member engages with the anti-rotation claw. Circle with nail centered on rotation axis A plurality of first gear portions provided on the top and a gear portion different from the first gear portion, wherein the second claw is provided on the circumference around the rotation axis. And the number of first claws provided in the first gear part is greater than the number of second claws provided in the second gear part. It includes a shutter driving device having various structures and a camera having various structures provided with the shutter driving device.

DESCRIPTION OF SYMBOLS 1 Camera body 100 Sequence shutter drive unit 141 Front-curtain drive lever 142 Rear-curtain drive lever 145 Spring 150 Locking crown 151 1st gear part 151a 1st nail | claw 152 2nd gear part 152a 2nd claw 160 Holding plate 162 Anti-rotation claw 400 Shading curtain mechanism 411 Front curtain light shielding blade group 421 Front curtain main arm 431 Rear curtain light shielding blade group 441 Rear curtain main arm

Claims (6)

In a shutter driving device for driving a shutter device having a light shielding blade and an arm to which the light shielding blade is attached,
A drive lever that rotates around a rotation axis to drive the arm;
A drive spring having one end attached to the drive lever and applying a biasing force to the drive lever;
A member for adjusting the urging force, wherein the other end of the drive spring is attached, is pivotally supported around the rotation axis, and is rotated in one direction around the rotation axis; An urging force adjusting member that increases the urging force and reduces the urging force when rotated in the other direction around the rotation axis;
An anti-rotation claw that engages with the biasing force adjusting member and prevents the biasing force adjusting member from rotating in the other direction;
The biasing force adjusting member includes: a first gear portion in which a plurality of first claws that engage with the rotation preventing claws are formed on a circumference around the rotation axis; and the first gear portion. And a second gear portion in which a plurality of second claws are engraved on a circumference around the rotation axis,
The number of the 1st nail | claw provided in the said 1st gear part is more than the number of the 2nd claw provided in the said 2nd gear part, The shutter drive device characterized by the above-mentioned. The shutter drive device according to claim 1,
The shutter driving device characterized in that the first gear portion and the second gear portion are adjacent to each other in a direction along the rotation axis. In the shutter drive device according to claim 1 or 2,
The shutter driving device according to claim 1, wherein the first gear portion is provided between the driving spring and the second gear portion. In the shutter drive device according to any one of claims 1 to 3,
The shutter driving device according to claim 1, wherein a length of the first claw in the direction along the rotation axis is longer than a length of the second claw in the direction along the rotation axis. In the shutter drive device according to any one of claims 1 to 4,
The number of the first claws provided in the first gear portion is an integer multiple of 2 or more of the number of the second claws provided in the second gear portion. Drive device.   A camera comprising the shutter driving device according to claim 1.

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