JP6512771B2 - Mirror drive - Google Patents

Description

  The present invention relates to a mirror drive device provided with a mechanism for driving a mirror at high speed.

  Conventionally, in a quick return mirror mechanism such as a single lens reflex camera, the main mirror and the sub mirror are moved at high speed in and out of the light path (shooting light path) from the shooting optical system. In the photographing optical path, each mirror is positioned at a predetermined stop position by contacting a stopper provided on the mirror box, and guides light to the finder optical system and the focus detection unit.

JP, 2008-175920, A

  When the mirror drive mechanism disclosed in Patent Document 1 performs the mirror down operation, the biasing force of the mirror drive lever spring 41 drives the mirror drive lever 40 at high speed. The mirror 3 is driven in the down direction by the biasing force of the mirror down spring 35. Even if the mirror drive lever 40 is driven at high speed, if the mirror 3 can not follow the mirror drive lever 40, it is not possible to speed up the mirror down operation. In order to prevent this, it is conceivable to make the biasing force of the mirror down spring 35 sufficiently large, but in this case, the load at the time of the mirror-up operation is greatly increased.

  In view of such a point, the present invention provides a mirror driving device capable of following the movement of the mirror driving member at the time of mirror down operation without increasing the load at the time of mirror up operation. It is.

The mirror drive device of the present invention comprises: a mirror; and a mirror box rotatably mounted between a first position where the mirror is positioned in the light path and a second position where the mirror retracts from the light path. And a mirror drive member rotatably mounted on the mirror box to drive the mirror, the mirror drive member having an engagement portion engaged with the mirror, and the mirror being the second An acceleration section for increasing the moving speed of the mirror and a decelerating section for decreasing the moving speed of the mirror when moving from the position to the first position are provided, and the engagement is performed in the acceleration section A part engaging with the mirror, and the engagement between the engaging part and the mirror is released in the decelerating section .

  The mirror can follow the movement of the mirror driving member at the time of mirror down operation without increasing the load at the time of mirror up operation.

It is a figure explaining the composition of the digital single-lens reflex camera which carried out the present invention. FIG. 6 is an exploded perspective view illustrating the configuration of a mirror drive unit 1000. FIG. 10 is an exploded perspective view of a mirror charge unit 600 and a mirror drive lever unit 700. It is a figure explaining mirror drive unit 1000 of a completion state. FIG. 17 is a diagram for explaining an engagement state of mirror box 500 and mirror drive lever unit 700 and an engagement state of mirror drive lever unit 700 and rotary plate 604. It is the figure which abbreviate | omitted the motor 601, the gear base 602, the gear 603, and the cover 606 from one side view of the mirror box 500. FIG. It is a figure explaining the state of each part when the mirror unit 400 is a mirror down position. It is a figure explaining the state of each part immediately after starting mirror up operation. It is a figure explaining the state of each part immediately before completion of mirror up operation. It is a figure explaining the state of each part when the mirror unit 400 is in a mirror up position. It is a figure explaining the state of each part immediately after starting mirror down operation. It is a figure explaining the state of each part arrange | positioned at one side of mirror box 500 in mirror down operation. It is a figure explaining the state of each part in front of the end of mirror down operation.

  FIG. 1 is a view for explaining the configuration of a digital single-lens reflex camera which is an example of an imaging apparatus provided with a mirror driving device according to the present invention.

  In FIG. 1, an interchangeable lens 200 is attached to the camera body 1. The camera body 1 includes a focus detection unit 31, an optical finder unit 4, a mirror drive unit 1000, and an imaging sensor 33. The mirror drive unit 1000 drives the mirror unit 400 between the mirror down position (first position) and the mirror up position (second position). The mirror unit 400 has a main mirror holder 502 for holding the main mirror 501 and a sub mirror holder 504 for holding the sub mirror 503. The main mirror holder 502 is rotatably attached to the mirror box 500. The sub mirror holder 504 is rotatably attached to the main mirror holder 502.

  In the state shown in FIG. 1A, the mirror unit 400 is located in the optical path, and the light flux that has passed through the interchangeable lens 200 is separated by the main mirror 501. The light beam reflected by the main mirror 501 is guided to the pentaprism 22 of the optical finder unit 4. On the other hand, the light flux transmitted through the main mirror 501 is reflected by the sub mirror 504 and is guided to the focus detection unit 31. Therefore, in the state of FIG. 1A, the light flux that has passed through the interchangeable lens 200 is not guided to the imaging sensor 33. In the state shown in FIG. 1A, the main mirror holder 502 and the sub mirror holder 504 are located at the mirror down position.

  In the state of FIG. 1B, the mirror unit 400 retracts from within the optical path. More specifically, the main mirror holder 502 is retracted above the mirror box 500 from the state of FIG. At this time, the sub mirror holder 504 also retracts above the mirror box 500 in a state of being overlapped with the main mirror holder 502. In the state of FIG. 1B, the light flux that has passed through the interchangeable lens 200 is guided to the imaging sensor 33 without being guided to the optical finder unit 4 and the focus detection unit 31. In the state shown in FIG. 1B, the main mirror holder 502 and the sub mirror holder 504 are located at the mirror-up position.

  As shown in FIGS. 1A and 1B, the mirror drive unit 1000 can drive the main mirror holder 502 and the sub mirror holder 504 between the mirror down position and the mirror up position.

  FIG. 2 is an exploded perspective view illustrating the configuration of the mirror drive unit 1000. In FIG. 2, O indicates the center of the luminous flux incident on the camera body 1.

  As shown in FIG. 2, the mirror drive unit 1000 includes a mirror unit 400, a mirror box 500, a mirror charge unit 600, a mirror drive lever unit 700, and a sub mirror drive unit 800.

  The mirror unit 400 has a main mirror holder 502 for holding the main mirror 501 and a sub mirror holder 504 for holding the sub mirror 503.

  The main mirror 501 is held by the main mirror holder 502. The main mirror holder 502 is formed with a rotation shaft 502 a. The rotation shaft 502 a is pivotally supported by the mirror box 500. The main mirror holder 502 is attached to the mirror box 500 so as to rotate around the rotation shaft 502a. An abutting surface 502 b is formed on the main mirror holder 502. When the main mirror holder 502 is in the mirror down position, the abutment surface 502 b abuts on the main mirror positioning shaft 507.

  The main mirror holder 502 is formed with a first shaft portion 502 c. The mirror drive cam 701c of the mirror drive lever 701 abuts on the first shaft portion 502c. The main mirror holder 502 is formed with a second shaft portion 502 d. When the main mirror holder 502 is in the mirror up position, the engagement cam portion 702d of the mirror down lever 702 engages with the second shaft portion 502d. The engagement cam portion 702d of the mirror down lever 702 functions as an engagement portion that engages with the mirror.

  An abutting portion 502 e is formed on the main mirror holder 502. In the case where the main mirror holder 502 is pivoted from the mirror up position to the mirror down position, the contact portion 502e and the contact portion 504d of the sub mirror holder 504 are in contact before the main mirror holder 502 is in the mirror down position. Contact. When the main mirror holder 502 is in the mirror down position, the contact between the contact portion 502e and the contact portion 504d is released.

  The sub mirror 503 is held by the sub mirror holder 504. A hole 504 a is formed in the sub mirror holder 504. The shaft 502 f of the main mirror holder 502 is engaged with the hole 504 a of the sub mirror holder 504, and the sub mirror holder 504 is pivotally supported by the shaft 502 f of the main mirror holder 502. The sub mirror holder 504 pivots about an axis 502 f of the main mirror holder 502. The sub mirror holder 504 is formed with a drive cam 504 b. The sub mirror drive shaft 803 b formed on the sub mirror drive lever 803 engages with the drive cam 504 b. An abutting surface 504 c is formed on the sub mirror holder 504. When the sub mirror holder 504 is in the mirror down position, the abutment surface 504 c abuts on the sub mirror positioning shaft 801 b. The sub mirror holder 504 is formed with a contact portion 504 d. In the case where the sub mirror holder 504 is pivoted from the mirror up position to the mirror down position, the contact portion 504 d abuts on the contact portion 502 e of the main mirror holder 502 before the sub mirror holder 504 becomes the mirror down position. . When the sub mirror holder 504 is in the mirror down position, the contact between the contact portion 504 d and the contact portion 502 e is released.

  As shown in FIG. 2, a mirror up stopper 505 is attached to the mirror box 500. When the main mirror holder 502 is in the mirror up position, it collides with the tip of the main mirror holder 502. The mirror-up stopper 505 is formed of an elastic member capable of absorbing an impact, and can absorb the impact even if the tip of the main mirror holder 502 collides.

  As shown in FIG. 2, a shaft holding plate 506 is attached to the rear surface of the mirror box 500. The shaft holding plate 506 mounts the main mirror holder 502 on the mirror box 500 and then mounts the shaft holding plate 506 on the mirror box 500 to hold the rotation shaft 502 a of the main mirror holder 502. Thus, the main mirror holder 502 is rotatably attached to the mirror box 500.

  As shown in FIG. 2, a main mirror positioning shaft 507 is attached to one side surface of the mirror box 500.

  The main mirror positioning shaft 507 is formed of an eccentric pin. When the main mirror positioning shaft 507 is rotated, the mirror down position of the main mirror holder 502 can be adjusted.

  As shown in FIG. 2, a main mirror down spring 508 is attached to one side surface of the mirror box 500. The main mirror down spring 508 biases the first shaft portion 502 c of the main mirror holder 502 with the main mirror holder 502 directed to the mirror down position.

  As shown in FIG. 2, a mirror charge unit 600 is attached to one side of the mirror box 500. The mirror charge unit 600 has a motor 601 and a gear base 602. The motor 601 is supported by the gear base 602. The gear base 602 is attached to one side of the mirror box 500 by a screw 602s.

  A looped grooved cam portion 500 a is formed on one side surface of the mirror box 500. The grooved cam portion 500a has an outer cam surface 500a1 and an inner cam surface 500a2. The grooved cam portion 500a functions as a cam portion formed on the mirror box.

  FIG. 3 is an exploded perspective view of mirror charge unit 600 and mirror drive lever unit 700. The gear 603 and the rotating plate 604 are attached to the gear base 602. The gear 603 is pivotally supported by the gear base 602 at a rotation center 603 a. The rotating plate 604 is pivotally supported by the gear base 602 at a rotation center 604 a. The gear 603 and the rotary plate 604 are rotatably attached to the gear base 602. When the gear 603 and the rotary plate 604 are attached to the gear base 602, the gear portion 603b formed on the outer peripheral surface of the gear 603 and the gear portion 604c formed on the outer peripheral surface of the rotary plate 604 mesh with each other. The driving force of the motor 601 is transmitted to the gear 603. Accordingly, the driving force of the motor 601 is transmitted to the rotary plate 604 via the gear 603. The rotating plate 604 functions as a rotating member that is rotationally driven by a motor 601 as a driving source.

  The rotary plate 604 is formed with an elongated hole 604 b and locking portions 604 d and 604 e. The rotary spring 605 is attached to the rotary plate 604. The winding portion of the rotary spring 605 is locked to the locking portion 604d, and the fixed end 605c of the rotary spring 605 is locked to the locking portion 604e. The rotating spring 605 functions as a biasing member.

  As shown in FIG. 3, after the gear 603 and the rotary plate 604 are attached to the gear base 602, the cover 606 is attached to the gear base 602, and the cover 606 is fixed to the gear base 602 by screws 606s.

  As shown in FIG. 2, a mirror drive lever unit 700 is attached to one side of the mirror box 500. The mirror drive lever unit 700 has a mirror drive lever 701, a mirror down lever 702, a link lever 703, a rotation shaft 704, and a mirror down lever return spring 705. As shown in FIG. 3, the mirror driving lever 701 is formed with a cylindrical portion 701a, a connecting hole 701b and a mirror driving cam 701c. Shaft portion 500 c formed on one side surface of mirror box 500 is inserted into cylindrical portion 701 a. The mirror drive lever 701 is attached to the mirror box 500 so as to rotate around the shaft 500 c. The mirror drive lever 701 is rotatably attached to the mirror box 500 and functions as a mirror drive member for driving the mirror unit 400.

  As shown in FIG. 3, the mirror down lever 702 is formed with a hole 702a, a contact portion 702b, a locking groove 702c and an engagement cam portion 702d. The locking groove portion 702c is formed in the contact portion 702b.

  As shown in FIG. 3, the link lever 703 is formed with a cylindrical portion 703a, a contact portion 703b, a follower portion 703c, a drive shaft portion 703d, and a locking groove portion 703e. As shown in FIG. 3, the cylindrical portion 703 a is formed so as to protrude toward the mirror down lever 702. The cylindrical portion 703 a is inserted into the hole 702 a of the mirror down lever 702. As shown in FIG. 3, the follower portion 703 c is formed on the side facing the mirror box 500 of the link lever 703. When the mirror drive lever unit 700 is attached to one side surface of the mirror box 500, the follower portion 703c slides on the outer cam surface 500a1 or the inner cam surface 500a2 of the groove cam portion 500a. The link lever 703 is rotatably attached to the mirror drive member, and functions as a link member having a follower portion that slides the cam portion.

  As shown in FIG. 3, the drive shaft portion 703 d is formed on the surface opposite to the surface of the link lever 703 on which the follower portion 703 c is formed. The locking groove 703e is formed at the root of the drive shaft 703d.

  As shown in FIG. 3, the rotation shaft 704 is formed with a small diameter portion 704 a, a large diameter portion 704 b, and a spring holding portion 704 c. The large diameter portion 704 b of the rotating shaft 704 is inserted into the cylindrical portion 703 a of the link lever 703, and the small diameter portion 704 a of the rotating shaft 704 is inserted into the connection hole 701 b. The cylindrical portion 703 a of the link lever 703 is inserted into the hole 702 a of the mirror down lever 702. Therefore, the mirror drive lever 701 and the link lever 703 are coupled such that the mirror drive lever 701 rotates with respect to the link lever 703.

  As shown in FIG. 3, the winding portion of the mirror down lever return spring 705 is held by the spring holding portion 704 c of the rotation shaft 704. The fixed end of the mirror down lever return spring 705 is locked to the link lever 703, and the movable end of the mirror down lever return spring 705 is locked to the locking groove 702c of the mirror down lever 702. The mirror down lever return spring 705 biases the mirror down lever 702 such that the contact portion 702 b of the mirror down lever 702 and the contact portion 703 b of the link lever 703 abut.

  When the mirror drive lever unit 700 and the mirror charge unit 600 are attached to one side of the mirror box 500, the drive shaft 703 d is inserted into the elongated hole 604 formed in the rotary plate 604. Then, the movable end of the rotary spring 605 is locked in the locking groove portion 703 e of the link lever 703. As a result, the drive shaft 703 d is biased by the rotary spring 605 in the direction away from the rotation center 604 a of the rotary plate 604 inside the elongated hole 604.

  As shown in FIG. 2, a reduction lever 511 and a reduction lever return spring 510 are attached to one side of the mirror box 500. The decelerating lever 511 is formed with a pivot shaft portion 511a, an abutment portion 511b, and an abutment portion 511c.

  The reduction lever 511 is attached to the mirror box 500 so as to rotate around the rotation shaft 511a. The winding portion of the reduction lever return spring 510 is disposed on the rotation shaft portion, the fixed end is engaged with the mirror box 500, and the movable end is engaged with the reduction lever 511. The contact portion 511 c of the reduction lever 511 is in contact with the reduction lever stopper 509 by the biasing force of the reduction lever return spring 510. The decelerating lever 511 is attached to the mirror box 500 such that the contact portion 511b of the decelerating lever 511 enters the groove cam portion 500a. The decelerating lever 511 functions as a decelerating member mounted so as to be displaceable between an entering state in which the moving track of the follower unit enters and a retracted state in which the moving track of the follower unit is retracted.

  As shown in FIG. 2, a sub mirror drive unit 800 is attached to the other side of the mirror box 500. The sub mirror drive unit 800 has a sub mirror positioning plate 801, a sub mirror pressing spring 802, a sub mirror drive lever 803, and a rotation shaft 804. The sub mirror positioning plate 801 is formed with a hole 801 a, a sub mirror positioning shaft 801 b, and a hole 801 c. The sub mirror positioning plate 801 is attached to the mirror box 500 so as to rotate around the hole 801 a. The sub mirror positioning plate 801 rotates around the hole 801 a to adjust the position of the sub mirror positioning shaft 801 b. After adjusting the position of the sub mirror positioning shaft 801b, the sub mirror positioning plate 801 is fixed to the mirror box 500 with a screw 801s. The sub mirror drive lever 803 is formed with a hole 803a, a sub mirror drive shaft 803b and a locking portion 803c. The rotation shaft 804 is inserted into the hole 803 a and fitted into the hole 801 c of the sub mirror positioning plate 801. Thus, the sub mirror drive lever 803 is attached to the sub mirror positioning plate 801 so as to rotate about the rotation shaft 804. The winding portion of the sub mirror pressing spring 802 is fixed to the other side of the mirror box 500 by a screw 802 s. The fixed end of the sub mirror pressure spring 802 is locked to the mirror box 500, and the movable end of the sub mirror pressure spring 802 is locked to the locking portion 803c.

  FIG. 4 is a diagram for explaining the mirror drive unit 1000 in a completed state. FIG. 4A is a front view of the mirror drive unit 1000. FIG. FIG. 4B is a view of the mirror drive unit 1000 viewed from VIEW_A (the other side surface of the mirror box 500) in FIG. 4A. FIG. 4C is a view of the mirror driving unit 1000 viewed from VIEW_B (one side surface of the mirror box 500) in FIG. 4A.

  As shown in FIG. 4B, the sub mirror drive lever 803 is biased counterclockwise in FIG. 4B by the sub mirror holding spring 802.

  As shown in FIG. 4C, a mirror drive lever unit 700 is attached to one side of the mirror box 500, and a mirror charge unit 600 is attached to cover the mirror drive lever unit 700.

  FIG. 5 is a view for explaining the relationship between the groove cam portion 500a formed in the mirror box 500 and the follower portion 703c of the link lever 703, and the relationship between the rotary plate 604 and the drive shaft portion 703d of the link lever 703. FIG. 5A is a view for explaining the engaged state of the mirror box 500, the mirror drive lever unit 700, and the rotary plate 604. FIG. FIG. 5B is an enlarged view of a portion A of FIG. 5A, illustrating the sliding relationship between the groove cam portion 500a formed in the mirror box 500 and the follower portion 703c of the link lever 703. is there. FIG. 5C is a view for explaining the engagement relationship between the rotary plate 604 and the drive shaft 703 d of the link lever 703.

  As shown in FIG. 5A, a shaft 500c is formed on one side of the mirror box 500. The mirror drive lever unit 700 is attached to the mirror box 500 by inserting the cylindrical portion 701 a of the mirror drive lever 701 into the shaft portion 500 c. At this time, the follower portion 703c of the link lever 703 is engaged with the groove cam portion 500a. At this time, the drive shaft 703 d of the link lever 703 is engaged with the elongated hole 604 of the rotary plate 604, and the movable end 605 b of the rotary spring 605 is engaged with the locking groove 703 e of the link lever 703. When the rotary plate 604 is rotationally driven by the motor 601, the follower portion 703c slides on the groove cam portion 500a and moves in the arrow R direction in FIG. In FIG. 5, a follower unit 703c indicated by a solid line indicates the position of the follower unit 703c when the mirror unit 400 is in the mirror down position.

  As shown in FIG. 5A, when the rotary plate 604 is rotationally driven in the direction of arrow R by the motor 601, the follower portion 703c slides on the outer cam surface 500a1 or the inner cam surface 500a2 of the groove cam portion 500a.

  As shown in FIG. 5C, the winding portion of the rotary spring 605 is locked to the locking portion 604d, and the fixed end 605c of the rotary spring 605 is locked to the locking portion 604e. The movable portion 605 b of the rotary spring 605 is locked in the locking groove 703 e formed in the drive shaft 703 d of the link lever 703. Even when the rotary plate 604 is driven to rotate, the rotary spring 605 always biases the drive shaft 703 d outward. Since the drive shaft portion 703d of the link lever 703 is always urged outward by the urging force of the rotary spring 605, as shown in FIG. 5B, the follower portion 703c is a groove cam except for a part of the section It slides on the outer cam surface 500a1 of the portion 500a.

  When the rotary plate 604 makes one rotation in the arrow R direction from the state where the mirror unit 400 is at the mirror down position, the follower portion 703c slides the groove cam portion 500a from the section 4001 to the section 4006 as shown in FIG. Do.

  A conductive contact piece is provided on the surface 604 e of the rotary plate 604. The gear base 602 is provided with a conductive pattern on which the conductive contact piece slides. The rotational phase of the rotary plate 604 can be detected by the conductive contact piece sliding on the conductive pattern. The mirror driving unit 1000 according to the present embodiment detects which of the sections 4001 to 4006 the follower unit 703 c is in, based on the detected rotational phase of the rotary plate 604. Based on this detection result, control of start, stop, acceleration, and deceleration of the motor 601 can be performed.

  In FIG. 5B, a section 4001 is a section in which the mirror unit 400 is stopped at the mirror down position. In this section, the motor 601 is controlled to stop. Section 4002 is a section in which the mirror unit 400 moves from the mirror down position to the mirror up position. The motor 601 is subjected to acceleration control in this section. The section 4002 is an acceleration section for increasing the moving speed of the mirror unit 400.

  Section 4003 is a section immediately before the mirror-up operation of the mirror unit 400 ends. In this section, the motor 601 is decelerated and controlled. Section 4003 is a decelerating section in which the moving speed of the mirror unit 400 is decelerated.

  In FIG. 5B, a section 4004 is a section in which the mirror unit 400 is stopped at the mirror-up position. In this section, the motor 601 is controlled to stop. Section 4005 is a section in which the mirror unit 400 moves from the mirror up position to the mirror down position. The motor 601 is subjected to acceleration control in this section. Section 4005 is an acceleration section in which the moving speed of the mirror unit 400 is increased.

  Section 4006 is a section immediately before the mirror down operation of the mirror unit 400 ends. In this section, the motor 601 is decelerated and controlled. Section 4006 is a decelerating section in which the moving speed of the mirror unit 400 is decelerated.

  FIG. 6 is a view in which the motor 601, the gear base 602, the gear 603, and the cover 606 are omitted from one side view of the mirror box 500 shown in FIG. 4C.

  As shown in FIG. 6, a mirror drive lever unit 700, a reduction lever 511, a reduction lever return spring 510, a main down spring 508, and a rotary plate 604 are disposed on one side of the mirror box 500. The rotary plate 604 is pivotally supported by the gear base 602, and the movement in the axial direction is restricted by the cover 606 and disposed at the position shown in FIG.

  In the state shown in FIG. 6, the mirror unit 400 is at the mirror down position.

  The mirror-up operation and the mirror-down operation of the mirror drive unit 1000 of the present embodiment will be described below with reference to FIGS.

  FIG. 7 is a diagram for explaining the state of each part when the mirror unit 400 is in the mirror down position. FIG. 7A is a view for explaining the state of each component disposed on one side of the mirror box 500 when the mirror unit 400 is in the mirror down position. FIG. 7A is a view in which the mirror box 500 is omitted from one side view of the mirror box 500 shown in FIG. FIG. 7B is a view for explaining the sliding relationship between the groove cam portion 500a formed in the mirror box 500 and the follower portion 703c of the link lever 703 when the mirror unit 400 is in the mirror down position. . FIG. 7C is a view for explaining the engagement between the rotary plate 604 and the drive shaft 703 d of the link lever 703 when the mirror unit 400 is in the mirror down position. FIG. 7D is a view for explaining the states of the main mirror holder 502 and the sub mirror holder 504 when the mirror unit 400 is in the mirror down position.

  As shown in FIG. 7A, in this state, the contact surface 502b of the main mirror holder 502 is the main mirror by the force with which the main mirror down spring 508 biases the first shaft portion 502c of the main mirror holder 502. It is in contact with the positioning shaft 507. In this state, the mirror drive cam 701c of the mirror drive lever 701 is not in contact with the first shaft portion 502c. At this time, the engagement cam portion 702 d of the mirror down lever 702 is not engaged with the second shaft portion 502 d of the main mirror holder 502. Due to the biasing force of the mirror down lever return spring 705, the contact portion 702b of the mirror down lever 702 and the contact portion 703b of the link lever 703 are in contact with each other.

  As shown in FIG. 7B, in this state, the follower portion 703c of the link lever 703 is located in the section 4001, and the motor 601 is controlled to stop. As shown in FIG. 7C, since the drive shaft portion 703d of the link lever 703 is biased outward by the biasing force of the rotary spring 605, the follower portion 703c of the link lever 703 is of the groove cam portion 500a. It is in contact with the outer cam surface 500a1.

  As shown in FIG. 7D, in this state, the contact surface 502b of the main mirror holder 502 contacts the main mirror positioning shaft 507. The abutment surface 504c of the sub mirror holder 504 abuts on the sub mirror positioning shaft 801b. At this time, the contact portion 502e of the main mirror holder 502 and the contact portion 504d of the sub mirror holder 504 do not contact each other, and a gap is formed between the contact portion 502e and the contact portion 504d.

  When the motor 601 is started in the state shown in FIG. 7 and the mirror driving unit 1000 starts the mirror-up operation, the state shown in FIG. 8 is obtained.

  FIG. 8 is a diagram for explaining the state of each part immediately after the mirror-up operation is started. FIG. 8A is a view for explaining the state of each component disposed on one side of the mirror box 500 immediately after the mirror-up operation is started. FIG. 8 (a) is a diagram corresponding to FIG. 7 (a). FIG. 8B is a view for explaining the sliding relationship between the groove cam portion 500a formed in the mirror box 500 and the follower portion 703c of the link lever 703 immediately after the mirror-up operation is started. FIG. 8C is a view for explaining the engagement relationship between the rotary plate 604 and the drive shaft portion 703d of the link lever 703 immediately after the mirror-up operation is started. FIG. 8D is a view for explaining the states of the main mirror holder 502 and the sub mirror holder 504 immediately after the mirror-up operation is started.

  As shown in FIG. 8A, in this state, the contact surface 502b of the main mirror holder 502 is the main mirror by the force with which the main mirror down spring 508 biases the first shaft portion 502c of the main mirror holder 502. It is in contact with the positioning shaft 507. Between the state shown in FIG. 7A and the state shown in FIG. 8A, only the mirror drive lever unit 700 moves. Thus, in the state shown in FIG. 8A, the mirror drive lever 701 slightly pivots from the state shown in FIG. 7A, and the mirror drive cam 701c of the mirror drive lever 701 is moved to the first shaft portion 502c. It abuts. In the state shown in FIG. 8A, the mirror unit 400 and the reduction lever 511 are in the same state as the state shown in FIG. 7A. The mirror down lever 702 moves integrally with the link lever 703 between the state shown in FIG. 7A and the state shown in FIG. 8A.

  As shown in FIG. 8B, in this state, the follower portion 703c of the link lever 703 moves from the section 4001 to the section 4002. In the section 4002, the motor 601 is controlled to accelerate. At this time, the rotational phase of the rotary plate 604 is as shown in FIG. Since the drive shaft portion 703d of the link lever 703 is biased outward by the biasing force of the rotary spring 605, the follower portion 703c of the link lever 703 slides on the outer cam surface 500a1 of the groove cam portion 500a. When the follower portion 703c slides from the section 4001 to the section 4002 while sliding on the outer cam surface 500a1 of the groove cam section 500a, the link lever 703 pushes up the mirror drive lever 701. As the mirror drive lever 701 is pushed up, as shown in FIG. 8A, the mirror drive cam 701c of the mirror drive lever 701 abuts on the first shaft portion 502c. When the mirror drive cam 701c of the mirror drive lever 701 abuts on the first shaft portion 502c, it switches to the section 4002 and the motor 601 is gradually accelerated. The cam surface shape of the outer cam surface 500a1 in the section 4002 is formed such that the amount of rotation of the mirror drive lever 701 is large. Therefore, the acceleration effect by the acceleration control of the motor 601 and the acceleration effect by the cam surface shape of the outer cam surface 500a1 are exerted.

  Immediately after the mirror-up operation is started, the mirror unit 400 is in the same state as shown in FIG. As shown in FIG. 8 (d), in this state, the contact surface 502b of the main mirror holder 502 contacts the main mirror positioning shaft 507. The abutment surface 504c of the sub mirror holder 504 abuts on the sub mirror positioning shaft 801b. At this time, the contact portion 502e of the main mirror holder 502 and the contact portion 504d of the sub mirror holder 504 do not contact each other, and a gap is formed between the contact portion 502e and the contact portion 504d.

  When the mirror-up operation of the mirror drive unit 1000 proceeds from the state shown in FIG. 8, the state shown in FIG. 9 is obtained.

  FIG. 9 is a diagram for explaining the state of each part immediately before the end of the mirror-up operation. FIG. 9A is a view for explaining the state of each component disposed on one side surface of the mirror box 500 immediately before the end of the mirror-up operation. FIG. 9 (a) is a diagram corresponding to FIG. 7 (a). FIG. 9B is a view for explaining the sliding relationship between the groove cam portion 500a formed in the mirror box 500 and the follower portion 703c of the link lever 703 immediately before the end of the mirror-up operation. FIG. 9C is a view for explaining the engagement relationship between the rotary plate 604 and the drive shaft portion 703d of the link lever 703 immediately before the end of the mirror-up operation. FIG. 9D is a view for explaining the states of the main mirror holder 502 and the sub mirror holder 504 immediately before the end of the mirror-up operation.

  As shown in FIG. 9A, in this state, the mirror drive cam 701c of the mirror drive lever 701 pushes up the first shaft portion 502c against the biasing force of the main mirror down spring 508. The mirror-up operation of the mirror unit 400 is started between the state shown in FIG. 8A and the state shown in FIG. In the state shown in FIG. 9 (a), the reduction lever 511 is in the same state as the state shown in FIG. 7 (a). The mirror down lever 702 moves integrally with the link lever 703 between the state shown in FIG. 8A and the state shown in FIG. 9A.

  As shown in FIG. 9B, in this state, the follower portion 703c of the link lever 703 moves from the section 4002 to the section 4003. In a section 4003, deceleration control of the motor 601 is started. At this time, as shown in FIG. 8C, since the drive shaft portion 703d of the link lever 703 is biased outward by the biasing force of the rotary spring 605, the follower portion 703c of the link lever 703 is a groove cam It slides on the outer cam surface 500a1 of the portion 500a. When the follower portion 703c slides from the section 4002 to the section 4003 while sliding on the outer cam surface 500a1 of the groove cam section 500a, the link lever 703 further pushes up the mirror driving lever 701. When switched to the section 4003, the motor 601 is gradually decelerated. The cam surface shape of the outer cam surface 500a1 in the section 4003 is formed such that the amount of rotation of the mirror drive lever 701 is small. Therefore, the braking effect by the deceleration control of the motor 601 and the braking effect by the cam surface shape of the outer cam surface 500a1 are achieved.

  As shown in FIG. 9D, the contact surface 502b of the main mirror holder 502 is separated from the main mirror positioning shaft 507, and a mirror-up operation is performed. When the sub mirror drive shaft 803 of the sub mirror drive lever 803 slides on the drive cam 504 b, the contact surface 504 c of the sub mirror holder 504 is separated from the sub mirror positioning shaft 801 b, and mirror up operation is performed. Further, as the mirror-up operation progresses, the distance between the contact portion 502e and the contact portion 504d becomes larger.

  When the mirror-up operation of the mirror drive unit 1000 proceeds from the state shown in FIG. 9, the state shown in FIG.

  FIG. 10 is a diagram for explaining the state of each part when the mirror unit 400 is in the mirror up position. FIG. 10A is a view for explaining the state of each component disposed on one side of the mirror box 500 when the mirror unit 400 is in the mirror up position. FIG. 10 (a) is a diagram corresponding to FIG. 7 (a). FIG. 10B is a view for explaining the sliding relationship between the groove cam portion 500a formed in the mirror box 500 and the follower portion 703c of the link lever 703 when the mirror unit 400 is in the mirror up position. . FIG. 10C is a view for explaining the engagement between the rotary plate 604 and the drive shaft 703 d of the link lever 703 when the mirror unit 400 is in the mirror up position. FIG. 10D is a view for explaining the states of the main mirror holder 502 and the sub mirror holder 504 when the mirror unit 400 is in the mirror up position.

  As shown in FIG. 10A, in this state, the mirror drive cam 701c of the mirror drive lever 701 further pushes up the first shaft portion 502c against the biasing force of the main mirror down spring 508, and the main mirror holder The tip end of the contact 502 abuts on the mirror-up stopper 505. In the state shown in FIG. 10A, the mirror-up operation of the mirror unit 400 ends. In the state shown in FIG. 10 (a), the reduction lever 511 is in the same state as the state shown in FIG. 7 (a). The mirror down lever 702 moves integrally with the link lever 703 between the state shown in FIG. 9A and the state shown in FIG.

  As shown in FIG. 10B, in this state, the follower portion 703c of the link lever 703 is located in the section 4004. In section 4004, the motor 601 is controlled to stop. As shown in FIG. 10C, the drive shaft portion 703d of the link lever 703 is biased outward by the biasing force of the rotary spring 605. When the mirror unit 400 is in the mirror up position, the direction in which the rotary spring 605 biases the drive shaft 703 d of the link lever 703, and the main mirror down spring 508 is the first shaft 502 c of the main mirror holder 502. The direction of biasing is the opposite. The force by which the rotation spring 605 biases the drive shaft portion 703d of the link lever 703 is stronger than the force by which the main mirror down spring 508 biases the first shaft portion 502c of the main mirror holder 502, so the mirror unit 400 It is held in the up position. However, the drive shaft 703 d of the link lever 703 is pressed by the force with which the main mirror down spring 508 biases the first shaft 502 c of the main mirror holder 502. As a result, as shown in FIG. 10C, the follower portion 703c of the link lever 703 is not in contact with the outer cam surface 500a1 of the groove cam portion 500a. At this time, the follower portion 703c of the link lever 703 is not in contact with the inner cam surface 500a2 of the groove cam portion 500a. In the section 4004, the follower portion 703c of the link lever 703 is not in contact with either the outer cam surface 500a1 of the groove cam portion 500a or the side cam surface 500a2. Further, in the section 4004, the outer cam surface 500a1 and the inner cam surface 500a2 are formed so that the gap from the follower portion 703c to the outer cam surface 500a1 and the gap from the follower portion 703c to the inner cam surface 500a2 are substantially equal. It is done.

  When the mirror unit 400 bounces after the tip of the main mirror holder 502 collides with the mirror-up stopper 505, the follower portion 703c abuts on the inner cam surface 500a2 in the section 4004. That is, the range in which the mirror unit 400 can bounce at the mirror-up position is limited to the range from the position where the follower portion 703c abuts the outer cam surface 500a1 to the position where the follower portion 703c abuts the inner cam surface 500a2. Thus, the mirror drive unit 1000 of the present embodiment limits the bound amount of the mirror unit 400.

  As shown in FIG. 10 (d), the sub mirror drive shaft 803 of the sub mirror drive lever 803 further slides on the drive cam 504b from the state of FIG. 9 (d), and the main mirror holder 502 and the sub mirror holder 504 are in the mirror up state. Become.

  When the motor 601 is started in the state shown in FIG. 10 and the mirror driving unit 1000 starts the mirror down operation, the state shown in FIG. 11 is obtained.

  FIG. 11 is a diagram for explaining the state of each part immediately after the mirror down operation is started. FIG. 11A is a view for explaining the state of each component arranged on one side surface of the mirror box 500 immediately after the mirror down operation is started. FIG. 11 (a) is a diagram corresponding to FIG. 7 (a). FIG. 11B is a view for explaining the sliding relationship between the groove cam portion 500a formed in the mirror box 500 and the follower portion 703c of the link lever 703 immediately after the start of the mirror down operation. FIG. 11C is a view for explaining the engagement relationship between the rotary plate 604 and the drive shaft 703 d of the link lever 703 immediately after the mirror down operation is started. FIG. 11D is a view for explaining the states of the main mirror holder 502 and the sub mirror holder 504 immediately after the start of the mirror down operation.

  As shown in FIG. 11A, in this state, the link lever 703 is slightly pivoted counterclockwise from the state shown in FIG. The mirror down lever 702 moves integrally with the link lever 703 between the state shown in FIG. 10A and the state shown in FIG. As a result, the engagement cam portion 702 d of the mirror down lever 702 is engaged with the second shaft portion 502 d of the main mirror holder 502. Further, in the state shown in FIG. 11 (a), the mirror drive lever 701 slightly pivots from the state shown in FIG. 10 (a). As a result, the main mirror down spring 508 pushes the first shaft portion 502 c of the main mirror holder 502 to push down the main mirror holder 502, and the tip of the main mirror holder 502 is separated from the mirror up stopper 505.

  As shown in FIG. 11B, in this state, the follower portion 703c of the link lever 703 moves from the section 4004 to the section 4005. At this time, the rotational phase of the rotary plate 604 is as shown in FIG. The drive shaft portion 703d of the link lever 703 is biased outward by the biasing force of the rotary spring 605, but the biasing force of the main mirror down spring 508 weakens the force for moving the drive shaft portion 703d outward. As a result, when switching from the section 4004 to the section 4005, the follower portion 703c slides on the inner cam surface 500a2 of the groove cam portion 500a. When the follower portion 703c completely enters the section 4005, the relationship between the biasing direction of the drive shaft portion 703d by the rotation spring 605 and the biasing direction of the first shaft portion 502c due to the biasing force of the main mirror down spring 508 changes. . Therefore, the force by which the rotary spring 605 biases the drive shaft 703 d gradually increases, and the follower 703 c does not slide on the inner cam surface 500 a 2 and slides on the outer cam surface 500 a 1. The cam surface shapes of the outer cam surface 500a1 and the inner cam surface 500a2 in the section 4005 are formed such that the amount of rotation of the mirror drive lever 701 is large. When the follower portion 703c slides on the outer cam surface 500a1 or the inner cam surface 500a2, the link lever 703 pushes the mirror drive lever 701 down.

  In a section 4005, acceleration control of the motor 601 is performed. The cam surface shapes of the outer cam surface 500a1 and the inner cam surface 500a2 in the section 4005 are formed such that the amount of rotation of the mirror drive lever 701 is large. Therefore, the acceleration effect by the acceleration control of the motor 601 and the acceleration effect by the cam surface shape of the outer cam surface 500a1 are exerted.

  In the section 4005, since the motor 601 is controlled to be accelerated, there is a possibility that the main mirror holder 502 can not follow the movement of the mirror drive lever 701 when the mirror drive lever 701 moves at high speed. Taking this point into consideration, in this embodiment, as shown in FIG. 11A, in this state, the engagement cam portion 702d of the mirror down lever 702 is the second shaft portion 502d of the main mirror holder 502. It is in an engaged state. In other words, the mirror down lever 702 is configured to pull in the second shaft portion 502 d of the main mirror holder 502. Thus, even if the mirror drive lever 701 is moved at high speed, the main mirror holder 502 can follow the movement of the mirror drive lever 701. That is, as shown in FIG. 11A, the main mirror holder 502 is pushed down by the biasing force of the main mirror down spring 508 and pulled down by the mirror down lever 702.

  As shown in FIG. 11 (d), in this state, the main mirror holder 502 and the sub mirror holder 504 are substantially the same as the state shown in FIG. 10 (d). Not in contact.

  When the mirror down operation of the mirror drive unit 1000 proceeds from the state shown in FIG. 11, the state shown in FIG.

  FIG. 12 is a diagram for explaining the state of each part during the mirror down operation. FIG. 12A is a view for explaining the state of each component arranged on one side of the mirror box 500 during the mirror down operation. FIG. 12 (a) is a diagram corresponding to FIG. 7 (a). FIG. 12B is a view for explaining the sliding relationship between the groove cam portion 500a formed in the mirror box 500 and the follower portion 703c of the link lever 703 during the mirror down operation. FIG. 12C is a view for explaining the engagement relationship between the rotary plate 604 and the drive shaft 703 d of the link lever 703 during the mirror down operation. FIG. 12D is a view for explaining the states of the main mirror holder 502 and the sub mirror holder 504 during the mirror down operation.

  As shown in FIG. 12A, in this state, the engagement cam portion 702d of the mirror down lever 702 is engaged with the second shaft portion 502d of the main mirror holder 502. The link lever 703 is slightly pivoted relative to the mirror down lever 702 against the biasing force of the mirror down lever return spring 705. Therefore, the contact portion 702 b of the mirror down lever 702 and the contact portion 703 b of the link lever 703 are not in contact with each other. In this state, the main mirror holder 502 is pushed down by the biasing force of the main mirror down spring 508 and pulled down by the mirror down lever 702.

  As shown in FIG. 12B, in this state, the follower portion 703c of the link lever 703 moves from the section 4005 to the section 4006. In a section 4006, the deceleration control of the motor 601 is started. Between the state shown in FIG. 11B and the state shown in FIG. 12B, when the follower portion 703c completely enters the section 4005, the follower portion 703c slides on the outer cam surface 500a1. As shown in FIG. 12A, in this state, the biasing force of the main mirror down spring 508 does not act in the direction to weaken the biasing force of the rotary spring 605. As shown in FIG. 12C, since the drive shaft portion 703d of the link lever 703 is biased outward by the biasing force of the rotary spring 605, the follower portion 703c of the link lever 703 is a groove cam portion 500a. Sliding on the outer cam surface 500a1. Therefore, as shown in FIG. 12B, when the follower portion 703c enters the section 4006, the follower portion 703c abuts on the contact portion 511b of the reduction lever 511. As a result, the load on the link lever 703 momentarily increases, and the link lever 703 slightly pivots relative to the mirror down lever 702 against the biasing force of the mirror down lever return spring 705. When the follower portion 703c abuts on the abutting portion 511b, the link lever 703 is braked.

  As shown in FIG. 12 (d), the sub mirror drive shaft 803 of the sub mirror drive lever 803 slides further on the drive cam 504b from the state of FIG. 11 (d), and the main mirror holder 502 and the sub mirror holder 504 perform mirror down operation. Is going.

  When the mirror down operation of the mirror drive unit 1000 proceeds from the state shown in FIG. 12, the state shown in FIG. 13 is obtained.

  FIG. 13 is a diagram for explaining the state of each part immediately before the end of the mirror down operation. FIG. 13A is a view for explaining the state of each component arranged on one side surface of the mirror box 500 immediately before the end of the mirror down operation. FIG. 13 (a) is a diagram corresponding to FIG. 7 (a). FIG. 13B is a view for explaining the sliding relationship between the groove cam portion 500a formed in the mirror box 500 and the follower portion 703c of the link lever 703 immediately before the end of the mirror down operation. FIG. 13C is a view for explaining the engagement relationship between the rotary plate 604 and the drive shaft portion 703d of the link lever 703 immediately before the end of the mirror down operation. FIG. 13D is a view for explaining the states of the main mirror holder 502 and the sub mirror holder 504 immediately before the end of the mirror down operation.

  As shown in FIG. 13A, in this state, the engagement between the engagement cam portion 702d of the mirror down lever 702 and the second shaft portion 502d of the main mirror holder 502 is released. The reduction lever 511 is pivoted counterclockwise against the biasing force of the reduction lever return spring 510. Further, in this state, the contact portion 702b of the mirror down lever 702 and the contact portion 703b of the link lever 703 are in contact with each other by the biasing force of the mirror down lever return spring 705.

  As shown in FIG. 13B, in this state, the follower portion 703c of the link lever 703 completely enters the section 4006. Between the state shown in FIG. 12 (b) and the state shown in FIG. 13 (b), the follower portion 703c abuts on the contact portion 511b of the reduction lever 511 and resists the biasing force of the reduction lever return spring 510. The decelerating lever 511 is pivoted counterclockwise. That is, when the follower portion 703c abuts on the contact portion 511b of the reduction lever 511, the contact portion 511b of the reduction lever 511 retracts from the movement trajectory of the follower portion 703c from the entering state in which the movement trajectory of the follower portion 703c is entered. Shift to the retracted state.

  When the follower portion 703c rotates the speed reduction lever 511, the instantaneous load fluctuation of the link lever 703 is eliminated. As a result, as shown in FIG. 13A, the contact portion 702b of the mirror down lever 702 and the contact portion 703b of the link lever 703 contact with each other by the biasing force of the mirror down lever return spring 705. As shown in FIG. 13C, the drive shaft portion 703d of the link lever 703 is biased outward by the biasing force of the rotary spring 605. When the follower portion 703c rotates the reduction lever 511, the biasing force of the reduction lever return spring 510 acts in the direction to weaken the biasing force of the rotary spring 605, but the biasing force of the rotary spring 605 is stronger. Thus, the follower portion 703c slides on the outer cam surface 500a1.

  The cam surface shape of the outer cam surface 500a1 in the section 4006 is formed such that the amount of rotation of the mirror drive lever 701 is small. Therefore, the braking effect by the deceleration control of the motor 601, the braking effect by the cam surface shape of the outer cam surface 500a1, and the braking effect by the rotation of the reduction lever 511 by the follower portion 703c are exhibited.

  As shown in FIG. 13D, the sub mirror drive shaft 803 of the sub mirror drive lever 803 further slides on the drive cam 504b from the state of FIG. 12D. In this state, the drive cam 504 b is formed such that the opening angle between the main mirror holder 502 and the sub mirror holder 504 is larger than the opening angle between the main mirror holder 502 and the sub mirror holder 504. Thus, the contact portion 502e of the main mirror holder 502 and the contact portion 504d of the sub mirror holder 504 contact. The contact between the contact portion 502e and the contact portion 504d causes the sub mirror holder 504 to be braked.

  In general, when the mirror drive lever unit 700 drives the main mirror holder 502, the effect is limited to the main mirror holder 502 even if the mirror drive lever unit 700 performs a deceleration operation. However, in the mirror drive unit 1000 according to the present embodiment, when the main mirror holder 502 is decelerated, the main mirror holder 502 and the sub mirror holder 504 abut each other and are integrated. By this, the decelerating operation of the mirror drive lever unit 700 acts on the integrated one of the main mirror holder 502 and the sub mirror holder 504. That is, the sub mirror holder 504 can also be braked.

  Further, in the present embodiment, the contact portion 504 d is formed so that the contact portion 504 d and the contact surface 504 c of the sub mirror holder 504 are located on opposite sides of the hole portion 504 a of the sub mirror holder 504. There is. Thus, the contact portion 504d and the contact surface 504c can be separated, and even if the contact portion 504d is deformed, the contact surface 504c is hardly affected. The contact portion 504d is formed such that the distance 5002 from the contact portion 504d to the hole portion 504a is smaller than the distance 5001 from the hole portion 504a to the contact surface 504c. That is, by bringing the contact portion 504d closer to the hole portion 504a which is the rotation center of the sub mirror holder 504, an increase in impact force due to inertia is avoided. Further, the contact portion 502e is in contact with the contact portion 502e such that an impact generated when the contact portion 502e and the contact portion 504d contact is in a direction parallel to the surface of the main mirror holder 502 (the direction of the arrow 2002). The contact portion 504d is formed.

  When the mirror-down operation of the mirror drive unit 1000 proceeds from the state shown in FIG. 13, the state shown in FIG. 7 is obtained. As described above, in FIG. 7, the mirror unit 400 is at the mirror down position.

  As shown in FIG. 7A, in this state, the contact surface 502b of the main mirror holder 502 is in contact with the main mirror positioning shaft 507. The urging portion of the reduction lever 511 is in contact with the reduction lever stopper 509 due to the biasing force of the reduction lever return spring 510.

  As shown in FIG. 7B, when the follower portion 703c is positioned in the section 4001, the decelerating lever 511 is rotated clockwise until the contact portion 511c abuts on the decelerating lever stopper 509 by the biasing force of the decelerating lever return spring 510. Move. When the follower unit 703c is positioned in the section 4001, shock or the like is given to the mirror driving unit 1000, and the reduction lever 511 prevents the movement of the follower section 703c even if the follower unit 703c tries to move from the section 4001 toward the section 4006 Do. That is, the speed reduction lever 511 also functions as a restricting member that restricts the movement of the follower portion 703c in the section 4001 in the direction opposite to the R direction (see FIG. 5B).

  As shown in FIG. 7D, in this state, the contact portion 502e of the main mirror holder 502 and the contact portion 504d of the sub mirror holder 504 do not contact, and the contact portion 502e and the contact portion 504d There is a gap between them.

  When the abutment surface 502b of the main mirror holder 502 abuts on the main mirror positioning shaft 507, and the abutment surface 504c of the sub mirror holder 504 abuts on the sub mirror positioning shaft 801b, the mirror unit 400 bounces. At this time, since the mirror drive cam 701c of the mirror drive lever 701 is not in contact with the first shaft portion 502c, only the mirror unit 400 bounces. Since the main mirror holder 502 and the sub mirror holder 504 are sufficiently decelerated until the mirror unit 400 reaches the mirror down position, the bounce of the mirror unit 400 can be attenuated in a short time.

400 mirror unit (mirror)
500 mirror box 500a grooved cam (cam)
500a1 outer cam surface 500a2 inner cam surface 502 main mirror holder 504 sub mirror holder 510 reduction lever return spring 511 reduction lever (reduction member)
601 Motor 604 Rotating plate (rotating member)
605 Rotating spring (biasing member)
701 Mirror drive lever (mirror drive member)
702 mirror down lever 703 link lever (link member)
703c follower portion 703d drive shaft portion 705 mirror down lever return spring 1000 mirror drive unit

Claims (8)

With the mirror,
A mirror box rotatably mounted between a first position where the mirror is located in the optical path and a second position where the mirror retracts from the optical path;
And a mirror drive member rotatably mounted on the mirror box to drive the mirror.
The mirror driving member has an engaging portion that engages with the mirror,
When the mirror moves from the second position to the first position, an acceleration section for increasing the moving speed of the mirror and a deceleration section for decreasing the moving speed of the mirror are provided.
The mirror drive device characterized in that the engagement portion engages with the mirror in the acceleration section, and the engagement between the engagement section and the mirror is released in the deceleration section . When the mirror is in the second position, the engagement portion engages with the mirror, and when the mirror is in the first position, engagement between the engagement portion and the mirror is released. The mirror drive device according to claim 1 , A cam portion is formed on the mirror box.
The mirror drive device according to claim 1 or 2 , further comprising a link member rotatably attached to the mirror drive member and having a follower portion that slides the cam portion. The cam portion is a groove cam portion in which an inner cam surface and an outer cam surface are formed,
When the follower portion slides on the inner cam surface, the follower portion does not slide on the outer cam surface.
The mirror driving device according to claim 3 , wherein when the follower portion slides on the outer cam surface, the follower portion does not slide on the inner cam surface. A rotating member engaged with the link member and rotationally driven by a drive source;
The mirror driving device according to claim 4 , further comprising: a biasing member attached to the rotating member and biasing the follower portion toward the outer cam surface. The follower portion slides on the outer cam surface when the mirror moves from the first position to the second position,
When the mirror stops at the second position, the follower does not abut the outer cam surface.
The follower portion slides on an outer cam surface when the mirror moves from the second position to the first position,
The mirror driving device according to claim 4 or 5 , wherein when the mirror stops at the first position, the follower portion abuts on the outer cam surface. The mirror driving device according to claim 6 , wherein the follower portion abuts on the inner cam surface when the mirror bounces. An imaging device comprising the mirror drive device according to any one of claims 1 to 7 .

Images