JP2013182060A - Mirror unit and imaging device - Google Patents

Abstract

A highly durable mirror drive mechanism and camera are provided.
In addition to the first contact member that defines the mirror down position of the main mirror, a second contact member with which the main mirror contacts the balancer that absorbs the kinetic energy of the main mirror when the mirror is down is provided. Provide. The balancer moves to the standby position after the release operation is started, and during the return operation, the balancer makes the second member contact the main mirror before the first contact member that defines the mirror down position of the main mirror. Absorbs kinetic energy. Thereafter, the balancer moves to a retracted position where the second member is located at a position away from the main mirror that has stopped by contacting the first member, and stops.
[Selection] Figure 2

Description

  The present invention relates to a mirror driving mechanism and a camera including the mirror driving mechanism.

  A single-lens reflex camera includes a main mirror that guides subject light to a viewfinder optical system, and a sub mirror that guides subject light to a distance measuring sensor. The main mirror and the sub mirror are configured to move to a mirror-up position that is retracted from the photographing optical path at the time of imaging, and to move to a mirror-down position after imaging and return to the photographing optical path again. In a single-lens reflex camera configured as described above, a balancer that absorbs the kinetic energy of the main mirror when returning to the mirror down position in order to reduce the bounce phenomenon of the main mirror when the main mirror returns to the mirror down position. Is provided (see Patent Document 1).

JP-A-9-274249

  A sub mirror is attached to the main mirror. The sub-mirror reflects the incident subject light toward the distance measuring sensor. If the attitude of the sub mirror at the mirror down position is deviated, the incident optical axis of the subject light incident on the distance measuring sensor is deviated, and the distance measuring accuracy is lowered. The attitude of the sub-mirror at the mirror-down position, that is, the position of the main mirror (main mirror) at the mirror-down position is defined by the position of the pins provided on the main mirror receiver as a balancer in the camera described in the above-mentioned patent document. However, in the camera described in the above-mentioned patent document, every time the main mirror is mirrored down, the main mirror holding frame for fixing the main mirror collides with a pin provided on the main mirror receiver. For this reason, the collision part between the main mirror holding frame and the pin is worn out, and the position of the main mirror at the mirror down position, that is, the attitude of the sub mirror may change over time. For this reason, the incident optical axis of the subject light incident on the distance measuring sensor is shifted, which may reduce the distance measuring accuracy.

  A mirror driving mechanism and a camera according to the present invention include a main mirror that rotates between a mirror-up position that is retracted from the imaging optical path and a mirror-down position that is inserted into the imaging optical path and guides subject light to the viewfinder optical system, A first abutting member fixed at a predetermined position that abuts on the main mirror rotated to a position to define a mirror down position of the main mirror, and a second abutting member that abuts and separates from the main mirror And a second abutting member that is separated from the main mirror immediately before the main mirror rotates from the mirror-up position toward the mirror-down position and reaches the mirror-down position. A balancer that moves the member together with the second abutting member by abutting the member against the main mirror and absorbing the kinetic energy of the main mirror. Between the time when the main mirror starts to rotate to the mirror-up position and the time when the main mirror starts to rotate toward the mirror-down position and comes into contact with the second contact member. The second abutting member is moved to a standby position where the second abutting member is located at a first position closer to the main mirror than the first abutting member, stops, and then moved to the first position. After the abutting member comes into contact with the main mirror rotated toward the mirror down position, the second abutting position is separated from the main mirror by a second position along the rotating direction of the main mirror. When the main mirror rotates from the mirror-up position to the mirror-down position, the first mirror comes into contact with the second contact member. Stops at the mirror down position. Characterized in that it.

  According to the present invention, durability of the mirror drive mechanism and the camera can be improved.

It is sectional drawing of the camera body which concerns on 1st Embodiment. It is a figure which shows the relationship between the main mirror and each part of a balancer mechanism in a mirror down position before the release start in 1st Embodiment. It is a figure which shows the relationship between the main mirror in the mirror up position of 1st Embodiment, and each part of a balancer mechanism. It is a figure which shows the relationship between a main mirror and each part of a balancer mechanism when the contact part of a main mirror contacts the balancer side mirror receiving pin at the time of mirror down in 1st Embodiment. It is a figure which shows the relationship between the main mirror in the mirror down position, and each part of a balancer mechanism before the release start in 2nd Embodiment. It is a figure which shows the relationship between the main mirror in the mirror up position of 2nd Embodiment, and each part of a balancer mechanism. It is a figure which shows the relationship between the main mirror and each part of a balancer mechanism when the contact part of a main mirror contact | abuts to the balancer side mirror receiving pin at the time of the mirror down in 2nd Embodiment.

--- First embodiment ---
A first embodiment of a mirror driving mechanism and a camera according to the present invention will be described with reference to FIGS. FIG. 1A is a cross-sectional view of a single-lens reflex camera body 1 that is a camera according to the first embodiment, as viewed from above, and FIG. 1B is a view of the camera body 1 as viewed from the side. It is sectional drawing. The camera body 1 is provided with a mirror box 10, a balancer mechanism 100, a sequence shutter drive unit 200, a light shielding curtain mechanism 400, an image sensor 3, and a sequence motor 4. The camera body 1 is provided with a finder optical system 20, a photometric unit 5, an AF unit 6, a rear display monitor 7, and a control board 30. 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 balancer mechanism 100 is used for the main mirror 11 and the like when the main mirror 11 and the sub mirror 12 moved to the mirror-up position retracted from the imaging optical path during imaging return to the imaging optical path again and stop at the mirror-down position after imaging. This is a mechanism for reducing the bounce phenomenon, and is provided on the side surface of the mirror box 10. The balancer mechanism 100 suppresses the bounce phenomenon by absorbing the kinetic energy of the main mirror 11 and the like when returning to the mirror down position. The balancer mechanism 100 will be described in detail later.

  The sequence shutter drive unit 200 is a drive mechanism that drives a diaphragm mechanism, a mirror rotation mechanism, and a light-shielding curtain mechanism 400 (not shown). Description of the details of the sequence shutter drive unit 200 is omitted. The light shielding curtain mechanism 400 includes a front curtain light shielding blade group and a rear curtain light shielding blade group, and is driven by the sequence shutter driving unit 200 to open the photographing opening for a predetermined time. is there. The details of the light shielding device 400 will be omitted.

  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 200. 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 includes a distance measuring sensor and 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. Note that the through image is a pre-captured image that is repeatedly acquired by the image sensor 3 as a pre-shooting stage. The main shooting is a shooting performed in response to an operation signal (shooting instruction) when a release button (not shown) is fully pressed. The control board 30 is a board on which a control circuit 31 that controls the entire camera body 1 is mounted.

  FIG. 2 is a cross-sectional view of the camera body 1 as seen from the right side, showing the relationship between the main mirror 11 and each part of the balancer mechanism 100 at the mirror down position before the release is started. In addition, in each figure after FIG. 2, description of the submirror 12 is abbreviate | omitted. A mirror holding frame (not shown) that holds the main mirror 11 is provided with an abutting portion 13 that abuts a mirror receiving pin 191 described later. The main mirror 11, the sub mirror 12, the mirror holding frame, the contact portion 13, and the like are pivotally supported by the mirror support shaft 14 so as to be integrated. In order to suppress the inertial mass of the integrated main mirror 11 and the like, the contact portion 13 is made of a resin, a metal having a small specific gravity (such as titanium or a titanium alloy), or the like.

  When the main mirror 11 is rotated to the mirror down position by a mirror rotation mechanism (not shown), the abutment portion 13 abuts on the mirror receiving pin 191 so that the position and posture at the mirror down position are determined. The mirror receiving pin 191 is attached to the mirror box 10, for example. The position of the mirror receiving pin 191 is adjusted and fixed at the assembly stage of the camera body 1.

  The balancer mechanism 100 includes a mirror interlocking lever 110, a balancer locking lever 120, and a balancer 130. The balancer mechanism 100 is provided, for example, on the outer side of the mirror box 10. The mirror interlocking lever 110 is a lever attached to a mirror holding frame (not shown) that holds the main mirror 11, for example, and rotates in conjunction with the main mirror 11. The balancer locking lever 120 is a lever having two arms, for example, pivotally supported so as to be rotatable in the clockwise and counterclockwise directions around a fixed shaft 161 that does not move. In the vicinity of the tip of one arm (mirror side arm) 121 extending diagonally right upward in the figure, a mirror interlocking lever receiving pin 122 extending in a direction perpendicular to the paper surface shown in the figure is erected. In the vicinity of the tip of the other arm (balancer side arm) 123 that extends in the diagonally downward right direction in the figure, a balancer locking pin 124 that extends in a direction perpendicular to the paper surface shown in the figure is provided upright.

  The balancer locking lever 120 is urged clockwise by a balancer locking lever urging spring 162. That is, the balancer locking lever urging spring 162 is a spring having one end locked to the balancer side arm 123 and the other end locked to the fixed portion 181 that does not move, for example, a torsion coil spring.

  The balancer 130 is a substantially fan-shaped member that is pivotally supported in the illustrated clockwise and counterclockwise directions around a fixed stationary shaft 163, and is integrally formed around the mirror support shaft 14 when the mirror is down. Thus, the main mirror 11 is rotated so that the moment of inertia is substantially the same as the moment of inertia of the main mirror 11 and the like. The balancer 130 includes a small-diameter portion 131, a large-diameter portion 132 in the lower right direction of the small-diameter portion 131, and a locking portion 133 provided between the small-diameter portion 131 and the large-diameter portion 132. Further, the balancer 130 is provided with balancer side mirror receiving pins 134 extending in a direction perpendicular to the illustrated paper surface.

  The small diameter portion 131 is a portion corresponding to a curved surface having a partial arc shape centered on the fixed shaft 163. The large-diameter portion 132 is a portion corresponding to a curved surface having a partial arc shape with a radius larger than that of the small-diameter portion 131 around the fixed shaft 163. The locking portion 133 is a stepped portion caused by a difference in radius between the small diameter portion 131 and the large diameter portion 132 around the fixed shaft 163. The small-diameter portion 131, the large-diameter portion 132, and the locking portion 133 are each configured to come into contact with the balancer locking pin 124 of the balancer locking lever 120, which will be described in detail later.

  The balancer side mirror receiving pin 134 is arranged at a position closer to the fixed shaft 163 side than the arrangement position of the small diameter part 131 and the large diameter part 132 and is fixed to the balancer 130. The balancer-side mirror receiving pin 134 abuts before the mirror receiving pin 191, as will be described later, immediately before the main mirror 11 rotates from the mirror-up position toward the mirror-down position and reaches the mirror-down position. Abuts against the portion 13. In addition, the outer periphery of the balancer side mirror receiving pin 134, that is, the portion that comes into contact (collision) with the contact portion 13 is constituted by a buffer member 134a. The buffer member 134a is a member for suppressing the impact sound at the time of collision with the abutting portion 13 and reducing the sound generated when the mirror is down, and has a hardness higher than that of the abutting portion 13, such as hard urethane rubber. It is made of a material that is low and elastically deforms when it collides with the contact portion 13.

  The balancer 130 is urged counterclockwise by a balancer return spring 164 about a fixed shaft 163 that does not move. That is, the balancer return spring 164 is a spring in which one end is locked by a locking portion 135 provided in the balancer 130 and the other end is locked by a fixed portion 182 that does not move, for example, a torsion coil spring. The imbalanced balancer limiting member 183 is a member that limits the range of rotation of the balancer 130 in the counterclockwise direction shown in the figure by the urging force of the balancer return spring 164. A buffer member 183a is provided on the rear surface of the balancer limiting member 183, that is, on the surface in contact with the balancer 130 as will be described later.

  As shown in FIG. 2, in the state before the release is started, the balancer locking pin 124 of the balancer locking lever 120 abuts on the locking portion 133 of the balancer 130 so that the balancer return spring 164 urges the counterclockwise direction in the drawing. The balancer 130 is locked against this. That is, since the balancer locking lever 120 is urged clockwise in the figure by the urging force of the balancer locking lever urging spring 162, the balancer locking pin 124 moves toward the fixed shaft 163 (in the lower left direction in the figure). The small diameter part 131 of the balancer 130 is pressed. Since the balancer 130 is urged counterclockwise in the figure by the urging force of the balancer return spring 164, the locking portion 133 presses the balancer locking pin 124.

  The positional relationship between the locking portion 133 and the balancer locking pin 124, the shape of the locking portion 133, the biasing force of the balancer locking pin 124 by the balancer locking lever biasing spring 162, the biasing direction, and the position of the fixed shaft 161, The biasing force of the locking portion 133 by the balancer return spring 164, the biasing direction, the position of the fixed shaft 163, and the like are appropriately set. Therefore, in the state before the release is started, the balancer locking pin 124 and the locking portion 133 are not released from engagement, and the balancer 130 is locked against the counterclockwise biasing force of the balancer return spring 164. Is done.

  As shown in FIG. 2, in the state before the start of the release, the contact portion 13 attached to the mirror holding frame (not shown) contacts the mirror receiving pin 191 and the main mirror 11 stops at the mirror down position. Yes. As described above, the balancer 130 is locked against the counterclockwise urging force of the balancer return spring 164 shown in the figure. At this time, the balancer side mirror receiving pin 134 (and the buffer member 134a) It is separated from the contact portion 13. That is, the balancer side mirror receiving pin 134 (and the buffer member 134 a) are located farther from the contact portion 13 than the mirror receiving pin 191 along the rotation direction of the main mirror 11. Further, when the balancer locking pin 124 contacts the small diameter portion 131, the balancer locking lever 120 is prevented from rotating clockwise in the illustrated direction against the biasing force of the balancer locking lever biasing spring 162. However, the mirror interlocking lever receiving pin 122 is separated from the mirror interlocking lever 110. The position of the balancer 130 at this time is called a retracted position.

  Therefore, as shown in FIG. 2, in the state before the release start, the mirror receiving pin 191 determines the mirror down position of the main mirror 11, that is, the attitude and angle of the main mirror 11 and the sub mirror 12 at the mirror down position.

  In this state, when a release button (not shown) is fully pressed, a release operation is started. When the release operation is started, the main mirror 11 and the like integrated as described above are driven by a mirror rotation mechanism (not shown), and the main mirror 11 is shown clockwise from the mirror down position toward the mirror up position. Begin to rotate. As the main mirror 11 rotates, the mirror interlocking lever 110 also starts to rotate clockwise in the figure.

  When the mirror interlocking lever 110 rotates in the clockwise direction in the figure, the mirror interlocking lever 110 abuts on the mirror interlocking lever receiving pin 122 of the balancer locking lever 120 that has been separated before starting the release, and pushes it up in the diagonally upper left direction in the figure. . As a result, the balancer locking lever 120 rotates counterclockwise around the fixed shaft 161 against the biasing force of the balancer locking lever biasing spring 162. When the balancer locking lever 120 rotates counterclockwise, the balancer locking pin 124 also rotates counterclockwise about the fixed shaft 161, so that the balancer locking pin 124 and the locking portion 133 of the balancer 130 are not connected. The engagement is released.

  When the engagement between the balancer locking pin 124 and the locking portion 133 is released, the balancer 130 starts to rotate in the counterclockwise direction around the fixed shaft 163 by the biasing force of the balancer return spring 164. The counterclockwise rotation of the balancer 130 is limited (restricted) by a non-moving balancer limiting member 183. That is, the balancer 130 rotated counterclockwise in the drawing stops when the left end in the drawing contacts the balancer limiting member 183 (buffer member 183a). The position of the balancer 130 when the balancer 130 comes into contact with the balancer limiting member 183 and stops is called a standby position.

  FIG. 3 is a cross-sectional view of the camera body 1 viewed from the right side, showing the relationship between the main mirror 11 and each part of the balancer mechanism 100 after the mirror up is completed, that is, at the mirror up position. The main mirror 11 and the like which are integrally rotated in the clockwise direction in the drawing are retracted from a photographing optical path (not shown) and stopped above the photographing optical path. The balancer locking lever 120 is stopped against the biasing force of the balancer locking lever biasing spring 162 as the mirror interlocking lever receiving pin 122 is pushed up by the mirror interlocking lever 110. At this time, the balancer locking pin 124 is separated from the large-diameter portion 132 of the balancer 130 in the diagonally upper right direction in the figure.

  The balancer 130 is stopped at the standby position as described above. At the standby position, the balancer-side mirror with respect to the balancer 130 so that the balancer-side mirror receiving pin 134 comes into contact with the contact portion 13 of the main mirror 11 before the mirror receiving pin 191 during a later-described return operation (when the mirror is down). The position of the receiving pin 134 is defined. That is, the balancer-side mirror receiving pin 134 (and the buffer member 134a) in the standby position is located on the diagonally upper left side of the main mirror 11 with respect to the rear surface of the contact portion 13 in the mirror-down position shown in FIG. It is in a position closer to the main mirror 11 than the mirror receiving pin 191 along the rotation direction. The balancer 130 moves to the standby position after the main mirror 11 starts to turn to the mirror-up position and then the main mirror 11 starts to turn to the mirror-down position, and the contact portion 13 moves to the balancer side. It may be completed until it abuts on the mirror receiving pin 134.

  Almost simultaneously with the completion of the mirror up described above, the light-shielding curtain mechanism 400 is driven by the sequence shutter drive unit 200, and the front-curtain light-shielding blade group and the rear-curtain light shielding blade group travel. Thereby, the image sensor 3 is exposed for a predetermined time. Thereafter, a return operation for returning each part of the camera body 1 to the state before the start of photographing (before the start of release) is started.

  When the returning operation is started, the main mirror 11 and the like integrated as described above are driven by a mirror rotation mechanism (not shown), and the main mirror 11 is shown counterclockwise from the mirror up position to the mirror down position. Begins rotating in the direction. As the main mirror 11 rotates, the mirror interlocking lever 110 also starts to rotate counterclockwise.

  As a result of this counterclockwise rotation, the mirror interlocking lever 110 moves in a direction away from the mirror interlocking lever receiving pin 122 of the balancer locking lever 120, that is, in the diagonally lower right direction in the figure. Thereby, the balancer locking lever 120 rotates clockwise around the fixed shaft 161 by the biasing force of the balancer locking lever biasing spring 162. When the balancer locking lever 120 rotates in the clockwise direction, the balancer locking pin 124 also rotates in the clockwise direction around the fixed shaft 161. Here, the balancer 130 is stopped at the standby position from the start of the mirror down until the contact portion 13 of the main mirror 11 contacts the balancer side mirror receiving pin 134 (that is, the buffer member 134a) of the balancer 130. Therefore, until the contact portion 13 contacts the balancer side mirror receiving pin 134, the balancer locking pin 124 contacts the large-diameter portion 132 of the balancer 130, so that the balancer locking lever 120 rotates in the clockwise direction. Stops. Since the mirror interlocking lever 110 further rotates counterclockwise in the drawing together with the main mirror 11, the mirror interlocking lever 110 moves away from the mirror interlocking lever receiving pin 122.

  FIG. 4 is a cross-sectional view of the camera body 1 viewed from the right side, showing the relationship between the main mirror 11 and each part of the balancer mechanism 100 when the contact portion 13 contacts the balancer side mirror receiving pin 134 when the mirror is down. It is. As described above, the balancer-side mirror receiving pin 134 of the balancer 130 in the standby position is located obliquely upper left in the drawing with respect to the rear surface of the contact portion 13 in the mirror-down position shown in FIG. Therefore, as shown in FIG. 4, when the mirror is down, the balancer side mirror receiving pin 134 contacts (collises) the contact portion 13 of the main mirror 11 before the mirror receiving pin 191.

  As described above, since the buffer member 134a is provided on the outer periphery of the balancer side mirror receiving pin 134, an impact sound at the time of collision between the balancer side mirror receiving pin 134 and the contact portion 13 is suppressed.

  When the contact portion 13 collides with the balancer-side mirror receiving pin 134, the balancer 130 absorbs the moment of inertia (kinetic energy) of the main mirror 11 and the like integrated as described above. As a result, the integrated main mirror 11 and the like are greatly decelerated, but further rotated counterclockwise in the figure, and the contact portion 13 contacts the mirror receiving pin 191 and stops. As a result, the main mirror 11 returns to the mirror down position (FIG. 2) defined by the mirror receiving pin 191.

  The balancer 130 that has absorbed the moment of inertia of the main mirror 11 and the like rotates in the clockwise direction in the figure against the urging force of the balancer return spring 164. By rotating the balancer 130 in the clockwise direction in the figure, the small diameter part 131 also moves in the clockwise direction in the figure, so that the balancer locking pin 124 of the balancer locking lever 120 is relatively moved from the large diameter part 132 to the small diameter part 131. Moving. As described above, since the balancer locking lever 120 is urged clockwise by the balancer locking lever urging spring 162 in the drawing, the balancer locking pin 124 moves toward the vicinity of the fixed shaft 163 with a small diameter portion of the balancer 130. 131 is pressed.

  Thereafter, the balancer 130 stops rotating in the clockwise direction in the figure by the urging force of the balancer return spring 164 and starts to reverse in the counterclockwise direction in the figure. When the balancer 130 rotates counterclockwise in the figure, the balancer locking pin 124 comes into contact with the locking portion 133 to lock the balancer 130 in the retracted position against the urging force of the balancer return spring 164. Thereby, the balancer 130 and the balancer locking lever 120 return to the state before the release start. That is, the main mirror 11 and each part of the balancer mechanism 100 return to the state before the release start shown in FIG.

The mirror driving mechanism and camera of the first embodiment described above have the following operational effects.
(1) The mirror receiving pin 191 and the balancer side mirror receiving pin 134 that contact the contact portion 13 of the main mirror 11 when the mirror is down are configured to be separate members. The mirror receiving pin 191 is configured to define the mirror down position of the main mirror 11, and the balancer 130 is configured to be provided with the balancer side mirror receiving pin 134. Further, the balancer 130 moves from the retracted position to the standby position during the release operation and stops, and the balancer side mirror receiving pin 134 contacts the contact portion 13 of the main mirror 11 during the return operation, and then moves to the retracted position. Configured to stop. Further, when the main mirror 11 rotates from the mirror-up position toward the mirror-down position, the main mirror 11 contacts the balancer-side mirror receiving pin 134 and then contacts the mirror receiving pin 191 and stops at the mirror-down position. did.

  Thus, a member (balancer side mirror receiving pin 134) that contacts the contact portion 13 to absorb the kinetic energy of the main mirror 11, and a member (mirror receiving pin) that defines the posture of the main mirror 11 and the like in the mirror down position. 191). Therefore, the periphery of the balancer 130, such as a sliding portion between the fixed shaft 163 and the balancer 130, a contact portion between the contact portion 13 and the balancer side mirror receiving pin 134, a contact portion between the balancer locking pin 124 and the locking portion 133, etc. Even if these parts are worn, the posture (angle accuracy) of the main mirror 11 and the sub mirror 12 at the mirror down position is not adversely affected. Therefore, the accuracy of the photometry calculation using the subject light reflected by the main mirror 11 and the distance measurement calculation using the subject light reflected by the sub mirror 12 can be maintained for a long time, and a highly durable camera can be provided. .

  In addition, since the balancer side mirror receiving pin 134 that contacts the contact portion 13 does not define the posture of the main mirror 11 or the like, the contact portion 13 of the balancer side mirror receiving pin 134 contacts the contact portion 13. A buffer member 134a that can be elastically deformed by contact can be provided. This contributes to noise reduction when the mirror is down.

  Furthermore, since the balancer 130 is configured to move to the retracted position and stop during the return operation, re-collision with the contact portion 13 of the main mirror 11 can be prevented, and the bounce of the main mirror 11 and the like can be prevented from being prolonged. Contributes to continuous shooting speed improvement.

(2) The balancer locking lever 120 is configured to lock and release the balancer 130. As a result, the balancer 130 can be locked and released with a simple configuration, so that an increase in cost can be suppressed and the durability of the balancer mechanism 100 can be improved. In addition, the same effect is produced by making the member which latches the balancer 130, and the means which cancel | releases latching by making at least one member the same member.

(3) The balancer locking lever 120 is provided with a balancer locking pin 124 that contacts the balancer 130 and locks the balancer 130 that has moved to the retracted position, and is locked to the balancer 130 by the balancer locking pin 124. The locking part 133 is configured to be provided. In addition, the balancer locking lever 120 locks the locking portion 133 with the balancer locking pin 124, so that the balancer 130 is held at the retracted position against the urging force of the balancer return spring 164, and when the mirror is raised, The balancer locking lever 120 is rotated by the mirror interlocking lever 110 that is interlocked with the rotation of the mirror 11 so that the locking of the locking portion 133 by the balancer locking pin 124 is released. Further, the balancer 130 is configured to move from the retracted position toward the standby position by the urging force of the balancer return spring 164 when the locking portion 133 is unlocked by the balancer locking pin 124. As a result, the structure of the balancer mechanism 100 can be simplified, and the balancer mechanism 100 operates reliably, so that the balancer mechanism 100 has high reliability.

--- Second Embodiment ---
A second embodiment of the mirror driving mechanism and the camera according to the present invention will be described with reference to FIGS. In the following description, the same components as those in the first embodiment are denoted by the same reference numerals, and different points will be mainly described. Points that are not particularly described are the same as those in the first embodiment. This embodiment is different from the first embodiment in that the balancer 130 is held at the standby position mainly by a friction brake.

  FIG. 5 is a cross-sectional view of the camera body 1 as viewed from the right side, showing the relationship between the main mirror 11 and each part of the balancer mechanism 100 of the second embodiment before the release start. The balancer mechanism 100 includes a mirror interlocking lever 110, a balancer 130, and a friction brake device 140. In the second embodiment, the mirror interlocking lever 110 pushes up a mirror interlocking lever receiving pin 136 (to be described later) of the balancer 130 in the diagonally upper left direction when the mirror is raised. In the second embodiment, the balancer locking lever 120 in the first embodiment is not present.

  The balancer 130 according to the second embodiment does not need to be provided with the locking portion 133. Therefore, it is not necessary to form the small diameter part 131 and the large diameter part 132 in the first embodiment. Therefore, in the balancer 130 of the second embodiment, the radius of curvature of the arc portion 137 corresponding to the arc portion of the fan is substantially constant. In the vicinity of the arc portion 137 of the balancer 130, a mirror interlocking lever receiving pin 136 extending in a direction perpendicular to the paper surface shown is erected and fixed to the balancer 130.

  The friction brake device 140 is a device that holds the balancer 130 rotated in the clockwise direction in the figure during the return operation against the urging force of the balancer return spring 164 at the retracted position by frictional force. That is, as shown in FIG. 5, in the state before the release start, the friction brake device 140 holds the balancer 130 against the urging force in the counterclockwise direction by the balancer return spring 164 and holds it in the retracted position. Yes.

  Then, as shown in FIG. 5, in the state before the release start, the contact portion 13 attached to the mirror holding frame (not shown) contacts the mirror receiving pin 191 and the main mirror 11 stops at the mirror down position. Yes. As described above, the balancer 130 is locked against the counterclockwise urging force of the balancer return spring 164 shown in the figure. At this time, the balancer side mirror receiving pin 134 (and the buffer member 134a) It is separated from the contact portion 13. Further, the mirror interlocking lever receiving pin 136 is separated from the mirror interlocking lever 110.

  Therefore, as shown in FIG. 5, in the state before the start of the release, the mirror receiving pin 191 determines the mirror down position of the main mirror 11, that is, the posture and angle of the main mirror 11 and the sub mirror 12 at the mirror down position.

  In this state, when a release button (not shown) is fully pressed, a release operation is started. When the release operation is started, the main mirror 11 and the like integrated as described above are driven by a mirror rotation mechanism (not shown), and the main mirror 11 is shown clockwise from the mirror down position toward the mirror up position. Begin to rotate. As the main mirror 11 rotates, the mirror interlocking lever 110 also starts to rotate clockwise in the figure.

  When the mirror interlocking lever 110 rotates in the clockwise direction in the figure, the mirror interlocking lever 110 contacts the mirror interlocking lever receiving pin 136 of the balancer 130 that has been separated before the start of the release, and pushes it up in the diagonally upper left direction in the figure. Thereby, the balancer 130 is rotated counterclockwise in the figure against the frictional force of the friction brake device 140, and the holding in the retracted position by the friction brake device 140 is released.

  When the holding at the retracted position by the friction brake device 140 is released, the balancer 130 rotates counterclockwise in the figure about the fixed shaft 163 by the urging force of the balancer return spring 164, and waits by the imbalanced balancer limiting member 183. Stop at position.

  FIG. 6 is a cross-sectional view of the camera body 1 as viewed from the right side, showing the relationship between the main mirror 11 and each part of the balancer mechanism 100 after the mirror up is completed, that is, at the mirror up position. The main mirror 11 and the like which are integrally rotated in the clockwise direction in the drawing are retracted from a photographing optical path (not shown) and stopped above the photographing optical path. The balancer 130 is stopped at the standby position as described above. In FIG. 6, the mirror interlocking lever 110 is in contact with the mirror interlocking lever receiving pin 136 of the balancer 130. However, since the balancer 130 is biased counterclockwise in the figure by the balancer return spring 164, the mirror interlocking lever 110 and the mirror interlocking lever receiving pin 136 may be separated after completion of mirror up.

  Almost simultaneously with the completion of mirror up, the light-shielding curtain mechanism 400 is driven by the sequence shutter drive unit 200, and the front-curtain light-shielding blade group and the rear-curtain light-shielding blade group travel. Thereby, the image sensor 3 is exposed for a predetermined time. Thereafter, the return operation is started.

  When the returning operation is started, the main mirror 11 and the like integrated as described above are driven by a mirror rotation mechanism (not shown), and the main mirror 11 is shown counterclockwise from the mirror up position to the mirror down position. Begins rotating in the direction. As the main mirror 11 rotates, the mirror interlocking lever 110 also starts to rotate counterclockwise.

  As a result of the counterclockwise rotation shown in the figure, the mirror interlocking lever 110 moves away from the mirror interlocking lever receiving pin 136 of the balancer 130, that is, in the illustrated diagonally lower right direction. Even if the mirror interlocking lever 110 is separated from the mirror interlocking lever receiving pin 136, the balancer 130 is pressed against the imbalanced balancer limiting member 183 by the urging force of the balancer return spring 164. Accordingly, the balancer 130 is stopped at the standby position until the contact portion 13 of the main mirror 11 contacts the balancer side mirror receiving pin 134 (that is, the buffer member 134a) of the balancer 130 from the start of the mirror down.

  FIG. 7 is a cross-sectional view of the camera body 1 viewed from the right side, showing the relationship between the main mirror 11 and each part of the balancer mechanism 100 when the contact portion 13 contacts the balancer side mirror receiving pin 134 when the mirror is down. It is. As described above, the balancer-side mirror receiving pin 134 of the balancer 130 in the standby position is located obliquely upper left in the drawing with respect to the rear surface of the contact portion 13 in the mirror-down position shown in FIG. Therefore, as shown in FIG. 7, when the mirror is down, the balancer side mirror receiving pin 134 contacts (collises) the contact portion 13 of the main mirror 11 before the mirror receiving pin 191.

  When the contact portion 13 collides with the balancer-side mirror receiving pin 134, the balancer 130 absorbs the moment of inertia (kinetic energy) of the main mirror 11 and the like integrated as described above. As a result, the integrated main mirror 11 and the like are greatly decelerated, but further rotated counterclockwise in the figure, and the contact portion 13 contacts the mirror receiving pin 191 and stops. As a result, the main mirror 11 returns to the mirror down position (FIG. 5) defined by the mirror receiving pin 191.

  The balancer 130 that has absorbed the moment of inertia of the main mirror 11 and the like rotates in the clockwise direction in the figure against the urging force of the balancer return spring 164 and is stopped at the retracted position by the frictional force of the friction brake device 140. Retained. Thereby, the balancer 130 returns to the state before the release start. That is, the main mirror 11 and each part of the balancer mechanism 100 return to the state before the release start shown in FIG.

  Here, in the second embodiment, the balancer side mirror receiving pin 134, the friction brake device 140, and the mirror interlocking lever receiving pin 136 are arranged in the order from the fixed shaft 163. The reason is as follows. is there. That is, in order to efficiently absorb the moment of inertia of the main mirror 11 and the like, it is desirable to dispose the balancer side mirror receiving pin 134 at a position close to the fixed shaft 163 that is the rotation center of the balancer 130. In order to hold the balancer 130 in the retracted position with a small frictional force, it is desirable to dispose the friction brake device 140 at a position far from the fixed shaft 163. In order to release the holding of the balancer 130 by the friction brake device 140 with a small force, it is desirable to dispose the mirror interlocking lever receiving pin 136 at a position farther from the fixed shaft 163 than the friction brake device 140. In the present invention, the arrangement positions of the balancer side mirror receiving pin 134, the friction brake device 140, and the mirror interlocking lever receiving pin 136 are not limited to the above-described arrangement positions.

  In the second embodiment described above, the following operational effects are obtained in addition to the operational effects of the first embodiment. That is, the balancer 130 is configured to be held in the retracted position by the friction brake device 140, and the mirror interlocking lever receiving pin 136 of the balancer 130 in the retracted position is pushed up by the mirror interlocking lever 110, whereby the balancer 130 of the balancer 130 by the friction brake device 140 is pushed. It was configured to release the hold. As a result, the means for holding the balancer 130 in the retracted position and the means for releasing the holding can be configured by different members, so that the design is easier than the case where these means are configured by one member. Cost can be reduced. Further, since these means can be arranged separately, it is easy to arrange even in a small space, which contributes to the miniaturization of the balancer mechanism 100 and consequently the miniaturization of the camera body 1.

  In each of the above-described embodiments, the shape of the balancer 130 when viewed from the side surface of the camera body 1 is substantially fan-shaped, but the present invention is not limited to this. If the moment of inertia of the main mirror 11 and the like can be absorbed efficiently, the balancer 130 is configured such that, for example, a weight is provided at the other end of the shaft-like member whose one end is pivotally supported by the fixed shaft 163. It is good also as shapes other than a fan shape.

  Further, the shape of the locking portion 133 in the first embodiment is schematically shown in order to explain the function of preventing the balancer 130 from rotating by contacting the balancer locking pin 124 of the balancer locking lever 120. Shape. Therefore, the shape of the locking portion 133 in the first embodiment is not limited to the shape shown in FIGS.

  Further, the shape of the mirror interlocking lever 110 in each of the above-described embodiments, the shape of the balancer locking lever 120 in the first embodiment, and the like are also the functions of the mirror interlocking lever 110 and the balancer locking lever 120 described above. As long as this function is exhibited, the shape is not limited to the shape shown in each drawing.

  And each embodiment and modification which were mentioned above may be combined, respectively.

  Note that the present invention is not limited to the above-described embodiment, and it is between the mirror-up position that is retracted from the photographing optical path and the mirror-down position that is inserted into the photographing optical path and guides the subject light to the finder optical system. A main mirror that rotates, a first abutting member fixed at a predetermined position that abuts the main mirror rotated to the mirror down position and defines a mirror down position of the main mirror, and abuts the main mirror And a second abutting member that is spaced apart from the main mirror, and a second abutting member provided immediately before the main mirror rotates from the mirror-up position toward the mirror-down position and reaches the mirror-down position. A balancer that moves the second abutting member separated from the main mirror to abut the main mirror to absorb the kinetic energy of the main mirror and move with the second abutting member; The rotation of the main mirror after the main mirror starts to rotate to the mirror up position and before the main mirror starts to rotate toward the mirror down position and contacts the second contact member. The second contact member is moved to the standby position where the second contact member is located closer to the main mirror than the first contact member along the moving direction, stops, and moves to the first position. The second abutting member is in contact with the main mirror rotated toward the mirror down position, and then the second abutting member is further away from the main mirror than the first abutting member along the rotating direction of the main mirror. When the main mirror moves from the mirror-up position to the mirror-down position, the main abutment comes into contact with the second abutment member. After that, the mirror comes into contact with the first contact member. Mirror drive mechanism of the various structures, characterized in that the stop in the down position, and is intended to include cameras for various structures with the mirror driving mechanism.

DESCRIPTION OF SYMBOLS 1 Camera body, 3 Image sensor, 5 Photometry unit, 6 AF unit, 10 Mirror box, 11 Main mirror, 12 Sub mirror, 13 Contact part, 100 Balancer mechanism, 110 Mirror interlock lever, 120 Balancer latch lever, 124 Balancer engagement Stop pin, 130 balancer, 133 locking portion, 134 balancer side mirror receiving pin, 134a buffer member, 136 mirror interlocking lever receiving pin, 140 friction brake device, 164 balancer return spring, 183 balancer limiting member, 191 mirror receiving pin

The present invention relates to a mirror unit and an imaging apparatus .

The mirror unit according to claim 1 includes a mirror, a mirror member that is pivotally supported between a first position and a second position, and a defining member that defines the second position of the mirror member. And when the mirror member rotates from the first position to the second position via the third position, the mirror member contacts the mirror member so that the mirror member does not contact the defining member at the third position. And a moving member that moves with a force generated by contact with the mirror member.
The mirror unit according to claim 9 includes a mirror, a mirror member pivotally supported between the first position and the second position, and the mirror member from the first position to the third position. When rotating to the second position via, the moving member that contacts the mirror member at the third position and moves by the force generated by the contact with the mirror member, and the mirror member at the second position And a holding member that holds the moving member so that the moving member does not come into contact with the mirror member.
An imaging apparatus according to a tenth aspect is the mirror unit according to any one of the first to ninth aspects, a finder optical system for observing subject light reflected by the mirror, and an image of the subject. And an imaging unit that generates image data.

Claims (7)

A main mirror that rotates between a mirror-up position that retracts from the imaging optical path and a mirror-down position that is inserted into the imaging optical path and guides subject light to the viewfinder optical system;
A first abutting member fixed at a predetermined position that abuts on the main mirror rotated to the mirror down position and defines the mirror down position of the main mirror;
A second abutting member that abuts and separates from the main mirror;
The second contact member is provided, and the main mirror is separated from the main mirror immediately before the main mirror rotates from the mirror up position toward the mirror down position and reaches the mirror down position. A balancer that abuts the second abutting member against the main mirror to absorb the kinetic energy of the main mirror and moves with the second abutting member;
The balancer includes a period from when the main mirror starts to rotate to the mirror up position until the main mirror starts to rotate toward the mirror down position and contacts the second contact member. Then, the second abutting member moves to a standby position where the second abutting member is positioned closer to the main mirror than the first abutting member along the rotation direction of the main mirror. The second abutting member that has stopped and moved to the first position comes into contact with the main mirror rotated toward the mirror down position, and then moves along the rotating direction of the main mirror. The second abutting member moves to a retracted position where the second abutting member is located at a second position farther from the main mirror than the first abutting member, and stops.
When the main mirror rotates from the mirror up position toward the mirror down position, the main mirror comes into contact with the second contact member and then comes into contact with the first contact member and stops at the mirror down position. A mirror drive mechanism characterized by: In the mirror drive mechanism according to claim 1,
Balancer biasing means for biasing the balancer from the retracted position toward the standby position;
The balancer that has moved to the retracted position against the urging force of the balancer urging means after the main mirror has rotated to the mirror-down position and until it starts to rotate toward the mirror-up position again. Holding means for holding in the retracted position;
The mirror drive mechanism further comprising: release means for releasing the holding of the balancer by the holding means. In the mirror drive mechanism according to claim 2,
At least a part of members constituting the holding means and at least a part of members constituting the releasing means are the same member. In the mirror drive mechanism according to claim 3,
The holding means and the releasing means constitute the holding means and have a locking lever constituting the releasing means,
The locking lever is provided with a locking lever side locking portion that contacts the balancer and locks the balancer moved to the retracted position,
The balancer is provided with a balancer side locking portion locked by the locking lever side locking portion,
The locking lever holds the balancer in the retracted position against the biasing force of the balancer biasing means by locking the balancer side locking portion with the locking lever side locking portion, The main mirror is driven in conjunction with the rotation from the mirror down position to the mirror up position to release the locking of the balancer side locking portion at the locking lever side locking portion,
The balancer moves from the retracted position toward the standby position by the urging force of the balancer urging means when the locking of the balancer side locking portion at the locking lever side locking portion is released. A mirror drive mechanism characterized by that. In the mirror drive mechanism according to claim 2,
The mirror drive mechanism according to claim 1, wherein the holding means is made of a member different from a member constituting the releasing means. In the mirror drive mechanism according to claim 5,
The holding means is a friction brake means that holds the balancer moved to the retracted position against the biasing force of the balancer biasing means at the retracted position by a frictional force,
The releasing means is driven in conjunction with the rotation of the main mirror from the mirror-down position to the mirror-up position, and the balancer is moved from the retracted position to the standby position against the frictional force of the friction brake means. A release lever for releasing the holding of the balancer by the friction brake means by rotating it toward
The balancer moves from the retracted position toward the standby position by the urging force of the balancer urging means when the holding of the balancer by the friction brake means is released by the release lever. Drive mechanism. The mirror drive mechanism according to any one of claims 1 to 6,
A viewfinder optical system for observing subject light reflected by the main mirror;
A sub-mirror attached to the main mirror and reflecting subject light for distance measurement;
A distance measuring sensor for measuring distance using the subject light reflected by the sub-mirror;
An image pickup means for picking up a subject image of the subject light that has passed through the photographing optical path.

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