JP6136749B2 - Mirror unit and imaging device - Google Patents

Description

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

There is a drive mechanism that drives a mirror member of a camera from a retracted position to an advanced position by an urging force of a lever member (see Patent Document 1). In the drive mechanism, when the mirror member abuts against the stopper pin against the biasing force of the lever member, the lever member bounces, but the bounce is reduced by reducing the speed by abutting the cam on the lever member. The structure which suppresses is known (refer the same gazette).
[Prior art documents]
[Patent Literature]
[Patent Document 1] Japanese Patent Publication No. 7-85158

  However, since the speed of the lever member is lowered by the cam in the drive mechanism, the speed of the mirror member is lowered accordingly, and the time until the mirror member comes into contact with the stopper pin is increased. There is.

  As a first aspect of the present invention, a mirror member supported to be rotatable between an advanced position and a retracted position, a drive lever for driving the mirror member, and a drive lever, the mirror member is attached to the advanced position. By holding a part of the mirror member between the drive lever and the drive lever, the drive member has a biasing member that drives the mirror member to the advanced position, and a cam surface that presses the drive lever. A cam member for generating a driving force for rotating the drive lever from the advanced position to the retracted position, and the cam surface is a period from when the mirror member moves from the retracted position to the advanced position. A mirror unit is provided having a profile in which the lever is spaced from the cam member when the biased mirror member abuts the drive lever.

  In addition, as a second aspect of the present invention, an imaging device including the mirror unit is provided.

  The above summary of the present invention does not enumerate all necessary features of the present invention. A sub-combination of these feature groups can also be an invention.

1 is a schematic cross-sectional view of a single-lens reflex camera 100. FIG. 1 is a schematic cross-sectional view of a single-lens reflex camera 100. FIG. 5 is a perspective view of a mirror driving unit 500. FIG. FIG. 6 is a schematic diagram showing the operation of the mirror driving unit 500. FIG. 6 is a schematic diagram showing the operation of the mirror driving unit 500. FIG. 6 is a schematic diagram showing the operation of the mirror driving unit 500. FIG. 6 is a schematic diagram showing the operation of the mirror driving unit 500. FIG. 6 is a schematic diagram showing the operation of the mirror driving unit 500. FIG. 6 is a schematic diagram showing the operation of the mirror driving unit 500. FIG. 6 is a schematic diagram showing the operation of the mirror driving unit 500. 5 is a graph showing the amount of movement of a main mirror 420. 5 is a side view of a mirror driving unit 501.

  Hereinafter, the present invention will be described through embodiments of the invention, but the following embodiments do not limit the invention according to the claims. In addition, not all the combinations of features described in the embodiments are essential for the solving means of the invention.

  FIG. 1 is a schematic cross-sectional view of a single-lens reflex camera 100. The single-lens reflex camera 100 includes a lens unit 200 and a camera body 300.

  For the purpose of simplifying the description, in the following description, the side on which the object to be imaged by the single-lens reflex camera 100 is described as the front side or the front end side. In the single-lens reflex camera 100, the side on which the camera body 300 is disposed with respect to the lens unit 200 is referred to as a rear side or a back side.

  The lens unit 200 includes a fixed cylinder 210, lens groups 220, 230, and 240, a lens side control unit 250, and a lens side mount unit 260. One end of the fixed cylinder 210 is coupled to the camera body 300 by fitting the body side mount part 360 and the lens side mount part 260 of the camera body 300.

  The coupling between the lens side mount portion 260 and the body side mount portion 360 can be released by a predetermined operation. Therefore, another lens unit 200 having the lens side mount 260 of the same standard can be mounted on the camera body 300.

  The lens groups 220, 230, and 240 are arranged along the optical axis X inside the fixed cylinder 210 to form an optical system. Some or all of the lens groups 220, 230, and 240 can be moved along the optical axis X. Thereby, the magnification or focus position of the optical system can be changed.

  The lens side control unit 250 controls the lens unit 200 itself and also communicates with the body side control unit 322 of the camera body 300. Thereby, the lens unit 200 attached to the camera body 300 operates in cooperation with the camera body 300.

  In the camera body 300, a mirror unit 400 is disposed on the opposite side of the body side mount portion 360 with respect to the lens unit 200. A focusing screen 346 is horizontally disposed above the mirror unit 400.

  A pentaprism 344 is disposed further above the focusing screen 346, and a finder optical system 342 is disposed behind the pentaprism 344, respectively. The rear end of the viewfinder optical system 342 is exposed as a viewfinder 340 on the back surface of the camera body 300.

  In the camera body 300, a focal plane shutter 380, an optical filter 372, and an image sensor 370 are sequentially arranged behind the mirror unit 400. The focal plane shutter 380 opens and closes, and opens or closes the image sensor 370 with respect to the incident subject light flux.

  The optical filter 372 is installed immediately before the image sensor 370 and removes infrared rays and ultraviolet rays from the subject light flux incident on the image sensor 370. The optical filter 372 also functions as a protective glass that protects the surface of the image sensor 370.

  Further, the optical filter 372 reduces the spatial frequency of the subject luminous flux as a low-pass filter when a subject luminous flux having a spatial frequency exceeding the Nyquist frequency of the image sensor 370 enters. Thereby, the occurrence of moire in the image captured by the image sensor 370 is suppressed.

  The image sensor 370 disposed behind the optical filter 372 is formed by a photoelectric conversion element such as a CCD sensor or a CMOS sensor. A main substrate 320 and a rear display unit 330 are sequentially disposed behind the image sensor 370. Electronic circuits such as a body side control unit 322 and an image processing unit 324 are mounted on the main board 320. The rear display unit 330 is formed of a liquid crystal display panel or the like, and is exposed on the rear surface of the camera body 300.

  The mirror unit 400 includes a main mirror holding frame 410 and a main mirror 420. The main mirror holding frame 410 is pivotally supported by the main mirror rotating shaft 430 while holding the main mirror 420.

  Further, the main mirror holding frame 410 has a mirror pin 490 that protrudes to the side surface on the front side of the sheet. The main mirror holding frame 410 rotates around the main mirror rotation shaft 430 by driving the mirror pin 490 from the outside of the mirror unit 400.

  The mirror unit 400 also has a sub mirror holding frame 450 and a sub mirror 460. The sub mirror holding frame 450 is pivotally supported from the main mirror holding frame 410 by a sub mirror rotating shaft 470 while holding the sub mirror 460.

  The sub mirror 460 rotates with respect to the main mirror 420 by a link mechanism that operates as the main mirror 420 rotates. When the main mirror holding frame 410 rotates, the sub mirror 460 and the sub mirror holding frame 450 move together with the main mirror holding frame 410.

  In the illustrated mirror unit 400, the front end of the main mirror holding frame 410 is lowered in the mirror unit 400 and is in contact with the receiving pin 440. As a result, the main mirror 420 advances to the inside of the mirror unit 400 and is positioned at an advance position that obliquely crosses the optical axis X of the subject light beam.

  The main mirror 420 at the advanced position transmits a part of the subject light beam in the half mirror region formed in a part of the main mirror 420 and makes it incident on the sub mirror 460. Part of the subject luminous flux incident on the sub mirror 460 is reflected toward the focusing optical system 390 and enters the focus detection sensor 392.

  The focus detection sensor 392 detects the defocus amount in the optical system of the lens unit 200 and notifies the body side control unit 322 of it. The body-side control unit 322 communicates with the lens-side control unit 250 to move any of the lens groups 220, 230, and 240 so as to cancel the detected defocus amount. Thus, the lens unit 200 forms a subject image on the imaging surface of the image sensor 370.

  The main mirror 420 at the advanced position reflects a part of the subject light flux and guides it to the focusing screen 346. The focusing screen 346 is at a position optically conjugate with the imaging surface of the imaging element 370, and visualizes a subject image formed by the optical system of the lens unit 200.

  The subject image connected to the focusing screen 346 is observed from the viewfinder 340 through the pentaprism 344 and the viewfinder optical system 342. The subject image through the pentaprism 344 is observed as an erect image from the finder 340.

  A part of the subject light beam emitted from the pentaprism 344 is received by the photometric sensor 350 disposed above the finder optical system 342. When the release button of the camera body 300 is pressed halfway, the photometric sensor 350 detects the subject brightness from a part of the received subject luminous flux.

  The body-side control unit 322 calculates imaging conditions such as an aperture value, a shutter speed, and ISO sensitivity according to the detected subject brightness. Accordingly, the single-lens reflex camera 100 is in a state where it can shoot a subject under appropriate shooting conditions.

  FIG. 2 is a schematic cross-sectional view of the single-lens reflex camera 100. FIG. 2 shows a state in the camera body 300 where the main mirror 420 is rotated to the retracted position retracted from the optical path of the subject light flux in the mirror unit 400. Elements that are the same as those in FIG. 1 are given the same reference numerals, and redundant descriptions are omitted.

  When the release button of the single-lens reflex camera 100 is fully pressed, the main mirror 420 rotates clockwise in the drawing and moves to the retracted position. When the main mirror 420 rotates toward the retracted position, the main mirror holding frame 410 stops when the front end upper surface comes into contact with the stopper 480.

  The sub mirror holding frame 450 also rises together with the main mirror holding frame 410 and rotates about the sub mirror rotation shaft 470 to become substantially horizontal. As a result, the main mirror 420 and the sub mirror 460 are retracted from the optical path of the subject light flux. Therefore, the subject luminous flux incident on the mirror unit 400 travels straight in the mirror unit 400.

  Subsequently, in the camera body 300 in which the release button is fully pressed, the focal plane shutter 380 is opened. As a result, the subject luminous flux incident from the lens unit 200 passes through the optical filter 372 and is received by the image sensor 370.

  The image sensor 370 converts the received subject luminous flux into an electrical signal and outputs it. The electric signal output from the image sensor 370 is converted into image data in the image processing unit 324. The image data generated by the image processing unit 324 is stored as an image file in a secondary recording medium such as a flash memory.

  When the photographing is thus completed, the focal plane shutter 380 is closed, and the main mirror 420 and the sub mirror 460 are returned to the advanced position shown in FIG. In this manner, in the single-lens reflex camera 100, the main mirror 420 and the sub mirror 460 repeat reciprocating rotation for each photographing.

  The main mirror 420 in the retracted position is not used as a reflecting mirror. Therefore, when the main mirror 420 moves from the advanced position to the retracted position, the main mirror at the retracted position may not be positioned precisely as long as it is retracted from the optical path of the subject light beam in the mirror unit 400.

  On the other hand, when the main mirror 420 is moved from the retracted position to the advanced position, the main mirror 420 guides the light flux to the focus detection sensor 392 and the photometric sensor 350, so that the main mirror 420 accurately reaches the advanced position defined by the receiving pin 440. It is preferably positioned. Therefore, when the main mirror 420 moves to the advanced position, it is desirable that the main mirror 420 quickly stops at the advanced position.

  In the following description, the state in which the main mirror 420 is in the retracted position is referred to as “mirror up state”, and the operation in which the main mirror 420 is moved from the advanced position to the retracted position is referred to as “mirror up operation”. The state in which the main mirror 420 is in the retracted position is referred to as “mirror down state”, and the operation in which the main mirror 420 returns from the retracted position to the advanced position is referred to as “mirror down operation”.

  FIG. 3 is a perspective view showing the mirror driving unit 500 alone. In the camera body 300 shown in FIGS. 1 and 2, the mirror driving unit 500 is disposed on the side of the mirror unit 400 on the near side with respect to the paper surface of FIG. The mirror driving unit 500 includes a motor 510, a speed reduction unit 530, a mirror down gear 540, a mirror up gear 550, and a drive lever 560.

  Motor 510 has a pinion gear 520 and a torque limiter 522 attached to the output shaft. The pinion gear 520 rotates with the output shaft of the motor 510 within a range up to the maximum torque set in the torque limiter 522.

  Therefore, the rotational driving force generated by the motor 510 is transmitted to the outside by the pinion gear 520 within a range up to a preset maximum torque. When a load exceeding the set maximum torque is applied, the pinion gear 520 rotates idly with respect to the output shaft to protect the motor 510.

  The speed reduction unit 530 includes a plurality of speed reduction gears 532, 534, and 536 engaged with each other. The reduction gear 532 meshes with the pinion gear 520 and is rotationally driven from the motor 510. The speed reduction unit 530 transmits the rotational driving force while reducing the rotational speed through the train wheel formed by the speed reduction gears 532, 534, and 536.

  The mirror down gear 540 meshes with the reduction gear 536 of the reduction unit 530 and is driven to rotate. As a result, the mirror down gear 540 rotates around the rotation shaft 542. The mirror down gear 540 has a mirror down cam 544 formed integrally on the side surface. The mirror down cam 544 rotates around the rotation shaft 542 together with the mirror down gear 540.

  The mirror up gear 550 meshes with the mirror down gear 540 and is driven to rotate. As a result, the mirror up gear 550 rotates around the rotation shaft 552 in the opposite direction to the mirror down gear 540. Further, the mirror up gear 550 has a mirror up cam 554 formed integrally on its side surface. The mirror up cam 554 rotates around the rotation shaft 552 together with the mirror up gear 550.

  The drive lever 560 is supported by a swing bearing 562 provided at the lower end in the figure, and swings around a swing shaft inserted through the swing bearing 562. In the middle of the drive lever 560 in the longitudinal direction, a mirror down follower 566 that protrudes from the drive lever 560 in a direction intersecting the longitudinal direction of the drive lever 560 is disposed. When the mirror down follower 566 is pushed by the cam surface of the mirror down cam 544, the drive lever 560 swings counterclockwise in the drawing.

  A spring hook 564 is integrally formed on the side surface of the drive lever 560. One end of a lever spring 580 inserted through the swing bearing 562 is hooked on the spring hook 564.

  The lever spring 580 biases the drive lever 560 in a direction in which the mirror down follower 566 is pressed against the cam surface of the mirror down cam 544. Therefore, when no other load is applied to the drive lever 560, the mirror down follower 566 is pressed against the cam surface of the mirror down cam 544.

  A contact lever 570 is disposed near the upper end of the drive lever 560 in the drawing. The contact lever 570 is pivotally supported on a side surface of the drive lever 560 by a rotation shaft 572 formed integrally with the drive lever 560. As a result, the contact lever 570 rotates around the rotation shaft 572 with respect to the drive lever 560.

  Further, the contact lever 570 has a stopper that contacts the lower surface of the drive lever 560. Thereby, the rotation range of the contact lever 570 is restricted at a position where the upper end of the contact lever 570 slightly protrudes from the drive lever 560.

  A spring hook 574 is integrally formed on the side surface of the contact lever 570. One end of a mirror down spring 590 inserted through an engaging portion 568 provided in the middle of the drawing of the drive lever 560 is hooked on the spring hook 574. Since the other end of the mirror down spring 590 is in contact with the rotating shaft of the contact lever 570 in the state shown in FIG. 3, the contact lever 570 is urged clockwise and is in contact with the lower surface of the drive lever 560. .

  FIG. 4 is a side view showing a part of the mirror driving unit 500, and shows a state where the main mirror 420 is in the advanced position where it has advanced into the mirror unit 400. Elements common to FIGS. 1 to 3 are denoted by the same reference numerals, and redundant description is omitted.

  The drive lever 560 has a mirror up follower 567. The mirror up follower 567 protrudes from the side surface of the drive lever 560 in the opposite direction to the mirror down follower 566 in the downward direction in the figure. When pushed from the cam surface of the mirror up cam 554, the mirror up follower 567 swings the drive lever 560 clockwise around the swing shaft inserted into the swing bearing 562.

  When the main mirror 420 is in the advanced position, the lower surface of the main mirror holding frame 410 near the end opposite to the main mirror rotating shaft 430 contacts the receiving pin 440 so that the main mirror holding frame 410 is within the mirror unit 400. Positioned. When the main mirror holding frame 410 is positioned, the position of the mirror pin 490 provided on the main mirror holding frame 410 is also fixed.

  At this time, the mirror down follower 566 of the drive lever 560 is in contact with the mirror down cam 544, and the mirror up follower 567 is in contact with the mirror up cam 554. As a result, the drive lever 560 is sandwiched and fixed between the mirror down cam 544 and the mirror up cam 554.

  In the above state, the upper end portion 592 of the mirror down spring 590 comes into contact with the mirror pin 490, and the biasing force of the mirror down spring 590 presses the mirror pin 490 downward, that is, the main mirror holding frame 410 is pressed against the receiving pin 440. Acts as a force.

  FIG. 5 is a partial side view of the mirror driving unit 500 and shows a state in which the main mirror holding frame 410 has started the mirror up operation. Elements common to FIGS. 1 to 4 are given the same reference numerals, and redundant description is omitted.

When the mirror-up operation is started, the rotational drive force of the motor 510 is transmitted via the reduction unit 530, the mirror-down gear 540 rotates in the direction of arrow A ₁ in FIG. Further, the mirror-up gear 550 meshing with the mirror-down gear 540 rotates in the direction of the arrow _{B 1.}

As the mirror up gear 550 rotates, the mirror up cam 554 also rotates. As a result, the diameter of the mirror up cam 554 in contact with the mirror up follower 567 with respect to the rotation shaft 552 gradually increases. Thus, the mirror-up follower 567 is pushed by the cam surface of the mirror-up cam 554, drive lever 560 is swung in the direction of the arrow C ₁ around the shaft rocking inserted through the swing bearing 562.

As the drive lever 560 swings, the upper end portion of the drive lever 560 and the contact lever 570 rise to push up the mirror pin 490. Thus, it rotates in the direction of the main mirror holding frame 410 the arrow _{D 1.}

Incidentally, in response to the gradually increasing diameter of the mirror up cam 554 with respect to the rotating shaft 552, the diameter of the mirror down cam 544 with respect to the rotating shaft 542 gradually decreases. Thus, the distance between the mirror-up cam 554 and the mirror-down cam 544 is maintained, the driving lever 560 is allowed to move in the direction of arrow C _1.

  Further, when the drive lever 560 starts to swing, the upper end of the drive lever 560 in the drawing is pulled up by the biasing force of the mirror down spring 590. Thus, the urging force of the mirror down spring 590 also contributes to the initial acceleration of the drive lever 560.

  FIG. 6 is a partial side view of the mirror driving unit 500 and shows a state in which the mirror up operation of the main mirror holding frame 410 is completed and the main mirror 420 is in the retracted position.

  In this state, the mirror down follower 566 of the drive lever 560 is in contact with the mirror down cam 544 and the mirror up follower 567 is in contact with the mirror up cam 554. As a result, the drive lever 560 is sandwiched and fixed between the mirror down cam 544 and the mirror up cam 554.

  The mirror pin 490 is pushed up to the upper surface of the contact lever 570 that is urged clockwise by the drive lever 560 and the mirror down spring 590. At this time, the mirror pin 490 is located away from the upper end 592 of the mirror down spring 590 and is not sandwiched between the mirror down spring 590 and the contact lever 570.

  As already described with reference to FIG. 2, the front end of the main mirror holding frame 410 is in contact with the stopper 480 provided on the camera body 300. Therefore, the main mirror holding frame 410 is positioned at the retracted position by the main mirror rotating shaft 430 and the stopper 480.

  FIG. 7 is a partial side view of the mirror driving unit 500 and shows a state in which the main mirror holding frame 410 has started a mirror down operation.

When the mirror-down operation is started, the mirror-down gear 540 driven to rotate by a motor 510 via a reduction gear unit 530 rotates in the direction of arrow A _2. The mirror-up gear 550 also rotates in the direction of arrow _{B 2.}

As a result, the mirror down cam 544 also rotates, and the diameter of the cam profile that contacts the mirror down follower 566 gradually increases with respect to the rotation shaft 542. Thus, the mirror-down follower 566 is pushed by the cam surface of the mirror-down cam 544, the drive lever 560 is swung in the direction of arrow C ₂ around the insertion has been pivot shaft to the swing bearing 562.

Corresponding to the gradually increasing diameter of the mirror down cam 544 relative to the rotating shaft 552 on the cam surface of the mirror down cam 544, the cam surface of the mirror up cam 554 gradually decreases in diameter relative to the rotating shaft 552. Accordingly, the driving lever 560 is allowed to move in the direction of arrow C _2.

When the mirror-down cam 544 is rotated in the direction of arrow A _2, the mirror-down spring 590 which is supported by the drive lever 560 also drops. As a result, a force that rotates in the direction of the arrow D < _b > ₂ acts on the main mirror holding frame 410.

  However, due to the inertia of the main mirror holding frame 410, the rotation of the main mirror holding frame 410 is delayed from the swing of the drive lever 560 at the beginning of the mirror down operation. Therefore, at the beginning of the mirror down operation, there is a period in which the distance between the mirror pin 490 and the upper surface of the contact lever 570 increases. At this time, the mirror down spring 590 whose upper end 592 is pushed up by the mirror pin 490 is elastically deformed so that the distance between the upper end 592 and the lower end is increased.

  FIG. 8 is a partial side view of the mirror driving unit 500 and shows a state following the state shown in FIG. 7 in the mirror down operation. FIG. 8 shows a state in which the main mirror holding frame 410 has started to move against the inertia of the main mirror holding frame 410.

Continuing to FIG. 7, the mirror down gear 540 rotates in the direction of arrow A ₃ and the mirror up gear 550 rotates in the direction of arrow B ₃ . As a result, the mirror down cam 544 continues to push down the mirror down follower 566 of the drive lever 560. Therefore, the drive lever 560 is further swung in the direction of arrow _{C 3.}

Corresponding to the gradually increasing diameter of the mirror down cam 544 relative to the rotating shaft 552 on the cam surface of the mirror down cam 544, the cam surface of the mirror up cam 554 gradually decreases in diameter relative to the rotating shaft 552. Accordingly, the driving lever 560 is allowed to move in the direction of arrow C _3.

  In this case, when the mirror down cam 544 and the mirror down follower 566 are in contact with each other, a gap is formed between the mirror up cam 554 and the mirror up follower 567 on the cam surface of the mirror up cam 554. A drive section 556 is formed. In order for the drive lever 560 to move while being sandwiched between the mirror down cam 544 and the mirror up cam 554, the drive lever 560, the mirror down cam 544 and the mirror up cam 554 have gaps that become loose, The gap due to the drive section 556 is larger than the gap that becomes loose and the gap that is plus the tolerance.

As the drive lever 560 swings, the urging force of the mirror down spring 590 increases to overcome the inertia of the main mirror holding frame 410 and the mirror pin 490 is attracted toward the contact lever 570. Thus, the main mirror holding frame 410 starts to rotate in the direction of D _3. Thereafter, the mirror pin 490 collides with the upper surfaces of the drive lever 560 and the contact lever 570.

  FIG. 9 is a partial side view of the mirror driving unit 500 and shows a state next to the state shown in FIG. 8 in the mirror down operation.

When the mirror pin 490 collides with the upper surface of the contact lever 570 by the biasing force of the mirror down spring 590 during the mirror down operation, the momentum of the main mirror holding frame 410 is transmitted to the drive lever 560. Here, when the mirror pin 490 collides with the contact lever 570 and the drive lever 560, the mirror up follower 567 faces the non-drive section 556 of the mirror up cam 554 and is separated from the cam surface. Therefore, in the momentum transferred from the main mirror holding frame 410, the drive lever 560 away from the cam surface of the mirror-down cam 544, it rotates in the direction of arrow C _4. The momentum of the main mirror holding frame 410 is reduced by the amount transmitted to the drive lever 560.

  In other words, the non-drive section 556 in the mirror up cam 554 is driven by being biased by the biasing force of the mirror down spring 590 after the mirror pin 490 has once separated from the contact lever 570 and the drive lever 560 during the mirror down operation. It has a cam profile that separates from the mirror up follower 567 when it contacts the lever 560. Thereby, the momentum of the main mirror holding frame 410 can be attenuated during the mirror down operation.

While driving lever 560 is away from the cam surface of the mirror-down cam 544 is also rotated in the direction of arrow D ₄ by the momentum of the main mirror holding frame 410 itself. Incidentally, during the operation, rotation of the mirror-down gear 540 shown by the arrow A _4, the rotation of the mirror-up gear 550 shown by the arrow B ₄ continues.

  Here, the drive lever 560 is urged clockwise by a lever spring 580 in the drawing. Therefore, by increasing the biasing force of the lever spring 580, the momentum of the main mirror holding frame 410 at the time of collision can be greatly attenuated. Further, by increasing the weight of the drive lever 560 and the member that is displaced together with the drive lever 560, the same action as strengthening the lever spring 580 can be obtained.

  However, if the biasing force of the lever spring 580 is too large, the mirror pin 490 will rebound when the mirror pin 490 collides with the drive lever 560. Therefore, it is desirable that the biasing force of the lever spring 580 is such that the mirror pin 490 does not rebound when the mirror pin 490 collides with the drive lever 560.

  FIG. 10 is a partial side view of the mirror driving unit 500 and shows a state immediately before the mirror down operation is completed.

  In the illustrated stage, the main mirror holding frame 410 abuts on the receiving pin 440. As described above, the momentum of the main mirror holding frame 410 is reduced at the immediately preceding stage. Therefore, when the main mirror holding frame 410 collides with the receiving pin 440, vibration caused by the main mirror holding frame 410 rebounding to the receiving pin 440 is suppressed.

  As a result, the main mirror 420 quickly stops at the advanced position. For the purpose of making the main mirror 420 stationary more quickly, the receiving pin 440 may be further provided with a buffering function to alleviate the impact when the main mirror holding frame 410 collides.

Further, as shown in, at the time of contact with the pin 440 received by the main mirror holding frame 410, the rotation and the rotation in the direction of arrow B ₅ of the mirror-up gear 550 in the direction of arrow A ₅ in the mirror-down gear 540 Is continuing. Therefore, the drive lever 560 is continued to be driven by the mirror-down cam 544 rotates, the swing in the direction of arrow C ₅ of the drive lever 560 is also continued.

  For this reason, the mirror down spring 590 descending together with the drive lever 560 pushes down the mirror pin 490. However, since the main mirror holding frame 410 is already positioned by the main mirror rotating shaft 430 and the receiving pin 440, the position of the mirror pin 490 does not move. Therefore, as the drive lever 560 swings, the mirror down spring 590 is elastically deformed in a direction in which the upper end portion 592 and the lower end portion of the mirror down spring 590 are separated from each other.

  The urging force generated by the mirror down spring 590 that is elastically deformed as described above acts in a direction in which the oscillation of the drive lever 560 in the counterclockwise direction in the drawing is stopped. Therefore, after the main mirror holding frame 410 contacts the receiving pin 440, the drive lever 560 is strongly braked.

  When the mirror down gear 540 and the mirror up gear 550 are further rotated from the state shown in FIG. 10, the mirror driving unit 500 returns to the state shown in FIG. 4 again. As a result, the drive lever 560 is sandwiched between the mirror down cam 544 and the mirror up cam 554 and fixed at a fixed position in the mirror down state.

  FIG. 11 is a graph showing a series of operations from the states shown in FIGS. 6 to 10 to the state shown in FIG. For the purpose of comparison with the embodiment, in addition to the operation of the mirror unit 400, the operation of the comparative example and the like are also shown.

  In the graph of FIG. 11, the horizontal axis indicates the time elapsed when the main mirror holding frame 410 starts to rotate from the mirror-up state, and the time when the single main mirror holding frame 410 first contacts the receiving pin 440. In arbitrary units. In the graph of FIG. 11, the vertical axis indicates the position of the main mirror holding frame 410 according to an angle, where the position of the main mirror holding frame 410 when the main mirror 420 is in the advanced position is zero.

  In the graph of FIG. 11, a curve indicated by a chain line described at the top of the legend indicates the operation of the main mirror holding frame 410 alone for comparison. That is, the movement of the main mirror holding frame 410 when the main mirror holding frame 410 urged toward the mirror down position by the urging member is released at the mirror up position and is freely brought into contact with the receiving pin 440. Show. As shown in the drawing, the main mirror holding frame 410 that collides with the receiving pin 440 is largely rebounded, and subsequent vibrations are not converged within the range shown in the drawing.

  In the graph of FIG. 11, the curve of the movement amount of the drive lever indicated by the alternate long and short dash line indicates the movement amount of the drive lever 560 driven by the mirror down cam 544. As shown in the figure, the drive lever 560 swings in a smoothly continuous curve from the mirror up position to the mirror down position of the main mirror 420.

  In the graph of FIG. 11, the curve of the embodiment shown in practice indicates the amount of movement of the main mirror holding frame 410 driven by the mirror driving unit 500 having the above characteristics. At the beginning of the mirror down operation, the movement amount of the main mirror holding frame 410 is delayed with respect to the movement amount of the drive lever 560 due to elastic deformation of the mirror down spring 590.

  However, when the mirror pin 490 collides with the drive lever 560 at the time indicated by the arrow P in the drawing, the moving speed of the main mirror holding frame 410 decreases rapidly. For this reason, the amount of jumping of the main mirror holding frame 410 when it contacts the receiving pin 440 is small. Therefore, the vibration of the main mirror holding frame 410 is rapidly attenuated and stops at the time indicated by the arrow Q in the drawing.

  In the graph of FIG. 11, the curve of the comparative example indicated by the dotted line indicates the amount of movement of the main mirror holding frame 410 driven by the driving unit of the comparative example instead of the mirror driving unit 500. The driving unit of the comparative example used here is different from the mirror driving unit 500 in the cam profile of the mirror up cam 554.

  The mirror up cam 554 included in the drive unit of the comparative example has a cam profile that continues to contact the mirror up follower 567 even when the mirror pin 490 biased by the mirror down spring 590 collides with the drive lever 560 during the mirror down operation. Have. Therefore, when the mirror pin 490 collides with the drive lever 560 at the time indicated by the arrow P in the drawing, the main mirror holding frame 410 is bounced back to the drive lever 560.

  For this reason, when the main mirror holding frame 410 comes into contact with the receiving pin 440, the rotation speed of the main mirror holding frame 410 is high, and the main mirror holding frame 410 generates a large vibration. Therefore, in the comparative example, as shown by the arrow R in the figure, a long time elapses until the vibration of the main mirror 420 converges.

  FIG. 12 is a side view showing the structure of another mirror drive unit 501. The mirror driving unit 501 has the same structure as the mirror driving unit 500 except for the part described below. Therefore, common elements are denoted by the same reference numerals, and redundant description is omitted.

  The mirror drive unit 501 includes a drive lever 561, a connecting rod 610, and a connecting member 620. The drive lever 561 is swingably supported by the swing bearing 562.

  The drive lever 561 is common to the drive lever 560 of the mirror drive unit 500 in that it has a spring hook 564, a mirror up follower 567, an engagement portion 568, and a contact lever 570. The drive lever 561 is different from the drive lever 560 in that the drive lever 561 does not have a mirror down follower 566.

  The connecting member 620 is supported by the rotation shaft 622 and is driven to rotate around the rotation shaft 622 by the rotation driving force generated by the motor 510. A mirror up cam 624 is integrally arranged on the side surface of the connecting member 620. The mirror up cam 624 has a cam surface that pushes the mirror up follower 567 of the drive lever 561, and a non-drive section 626 is provided on a part of the cam surface of the mirror up cam 624.

  The connecting member 620 connects the mirror up cam 624 and the connecting rod 610. The connecting rod 610 is engaged at its upper end in the figure with the engaging portion 568 of the drive lever 561 together with the mirror down spring 590 so as to be rotatable. A long hole 612 is provided near the lower end of the connecting rod 610 in the drawing. An engagement shaft 628 provided on the side surface of the connecting member 620 is inserted through the elongated hole 612. Thereby, the connecting rod 610 is connected to the connecting member.

  When the connecting member 620 is driven to rotate clockwise in the drawing in the mirror driving unit 501, the mirror up cam 624 pushes up the mirror up follower 567 of the driving lever 561 and swings the driving lever 561 clockwise in the drawing. As a result, the main mirror holding frame 410 rotates, and the main mirror 420 performs a mirror up operation from the advanced position toward the retracted position.

  At this time, the engaging shaft 628 of the connecting member 620 moves inside the elongated hole 612 of the connecting rod 610. Therefore, the upper end of the connecting rod 610 in the drawing moves according to the engaging portion 568 of the drive lever 561, and the connecting rod 610 allows the drive lever 561 to swing.

  When the mirror drive unit 501 in which the main mirror holding frame 410 is in the mirror up state performs the mirror down operation, the connecting member 620 is driven to rotate counterclockwise in the drawing. As a result, the engagement shaft 628 moves inside the elongated hole 612 and reaches one end of the elongated hole 612. Subsequently, the connecting rod 610 is pulled by the connecting shaft of the connecting member 620 to lower the engaging portion 568 of the drive lever 561. As a result, the drive lever 561 swings counterclockwise in the drawing to mirror the main mirror holding frame 410.

  The mirror up cam 624 is provided with a non-drive section 626. The non-drive section 626 is applied by the biasing force of the mirror-down spring 590 after the mirror pin 490 is once separated from the contact lever 570 and the drive lever 561 during the mirror-down operation, similarly to the non-drive section 556 of FIG. It has a cam profile that is separated from the mirror up follower 567 when it is biased and abuts against the drive lever 561.

  Therefore, when the mirror pin 490 collides with the contact lever 570 and the drive lever 561 during the mirror down operation, the drive lever 561 receives the momentum of the main mirror holding frame 410 from the mirror pin 490 and swings counterclockwise in the figure. To do. As a result, as in the case of the mirror driving unit 500, the impact when the mirror pin 490 biased by the mirror down spring 590 collides with the drive lever 561 can be reduced. Therefore, the main mirror 420 can be quickly stopped at the advanced position.

  As mentioned above, although this invention was demonstrated using embodiment, the technical scope of this invention is not limited to the range as described in the said embodiment. It will be apparent to those skilled in the art that various modifications or improvements can be added to the above-described embodiment. It is apparent from the scope of the claims that the embodiments added with such changes or improvements can be included in the technical scope of the present invention.

100 single lens reflex camera, 200 lens unit, 210 fixed cylinder, 220, 230, 240 lens group, 250 lens side control unit, 260 lens side mount unit, 300 camera body, 320 main board, 322 body side control unit, 324 image processing , 330 Rear display unit, 340 finder, 342 finder optical system, 344 penta prism, 346 focusing screen, 350 photometric sensor, 360 body side mount, 370 image sensor, 372 optical filter, 380 focal plane shutter, 390 focusing optical System, 392 focus detection sensor, 400 mirror unit, 410 main mirror holding frame, 420 main mirror, 430 main mirror rotating shaft, 440 receiving pin, 450 sub mirror holding frame, 460 sub mirror 470 Sub-mirror rotation shaft, 480 stopper, 490 Mirror pin, 500, 501 Mirror drive unit, 510 motor, 520 pinion gear, 522 Torque limiter, 530 Deceleration unit, 532, 534, 536 Deceleration gear, 540 Mirror down gear, 544 Mirror Down cam, 542, 552, 572, 622 Rotating shaft, 550 Mirror up gear, 554, 624 Mirror up cam, 556, 626 Non-drive section, 560, 561 Drive lever, 562 Oscillating bearing, 564, 574 Spring hook, 566 Mirror down follower, 567 Mirror up follower, 568 Engagement part, 570 Contact lever, 580 Lever spring, 590 Mirror down spring, 592 Upper end part, 610 Connecting rod, 612 Long hole, 620 Connecting member, 628 Engagement axis

Claims (8)

A mirror member supported rotatably between the advanced position and the retracted position;
A drive lever for driving the mirror member;
Provided in the drive lever, urges the mirror member to the advanced position, and holds the mirror member together with the drive lever to the advanced position by sandwiching a part of the mirror member with the drive lever. A biasing member to be driven;
A cam member having a cam surface that presses the drive lever, and causing the drive lever to generate a driving force for rotating the mirror member from the advanced position to the retracted position;
With
The cam surface is a period until the mirror member moves from the retracted position to the advanced position, and when the mirror member biased by the biasing member comes into contact with the drive lever, A mirror unit having a profile in which a lever is spaced from the cam member.   2. The mirror unit according to claim 1, further comprising another urging member that urges the drive lever in a direction opposite to the urging direction of the mirror member by the urging member to increase an inertial mass of the drive lever. .   The mirror unit according to claim 2, wherein the other urging member applies an urging force smaller than the urging force of the urging member to the drive lever.   4. The apparatus according to claim 1, further comprising another cam member that has a cam surface that presses the drive lever, and that causes the drive lever to generate a drive force that rotates the mirror member from the retracted position to the advanced position. The mirror unit according to any one of the above.   The mirror unit according to claim 4, wherein the drive lever in the retracted position is positioned between the cam member and the other cam member.   4. The connecting member according to claim 1, further comprising a connecting member that is coupled at one end to the drive lever and that pulls the drive lever to rotate the mirror member from the retracted position to the advanced position. Mirror unit.   The mirror unit according to claim 6, wherein the drive lever in the retracted position is positioned by being pulled by the connecting member and pressed against the cam member.   The imaging device provided with the mirror unit as described in any one of Claim 1- Claim 7.

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