JP2015225108A - Mirror holding mechanism and imaging device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To solve the problem in which a component for preventing a rebound increases in a rebound prevention mechanism to quicken an exposure start, and further a system for preventing the rebound has been complicate.SOLUTION: A mirror holding mechanism according to one embodiment of the present invention is a mirror holding mechanism to be installed in a camera body, and the mirror holding mechanism comprises: a main mirror unit that rotates between a first state obliquely provided in a subject light flux and a second state retreated from the subject light flux; and a sub-mirror unit that interlocks with the main mirror unit to oscillate, is obliquely provided in the subject light flux in the first state, and is retreated from the subject light flux in the second state. In an operation displacing from the first state to the second state, the sub-mirror unit displacing toward a retreat direction is configured to perform a first contact with the main mirror unit at timing when the main mirror unit rebounds at an end to displace in an oblique providing direction.

Description

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

When the main mirror provided on the camera body moves from the advanced position where the main mirror has advanced into the subject light beam to the retracted position where the main mirror is retracted outside the subject light beam, the start of exposure is accelerated by preventing the main mirror from bouncing back at the retracted position. A bounce prevention mechanism is known as much as possible. In the rebound prevention mechanism, an electromagnet is provided at the retracted position, and the electromagnet attracts the sub mirror holding the main mirror at the retracted position (for example, see Patent Document 1).
[Prior art documents]
[Patent Literature]
[Patent Document 1] JP-A-6-175223

  In the above bounce prevention mechanism, the number of parts for preventing bounce has increased. Furthermore, the system for preventing the bounce was complicated.

  In order to solve the above-described problem, the mirror holding mechanism according to the first aspect of the present invention is a mirror holding mechanism installed in the camera body, and includes a first state obliquely provided in the subject luminous flux and the subject luminous flux. The main mirror that rotates between the retracted second states, and swings in conjunction with the main mirror, is obliquely provided in the subject light flux in the first state, and is retracted from the subject light flux in the second state In the operation of displacing the first mirror from the first state to the second state, the sub mirror displacing in the retracting direction is the timing when the main mirror bounces back at the end and is displaced in the oblique direction. Make initial contact with the department.

  An imaging apparatus according to a second aspect of the present invention includes the above mirror holding mechanism, the imaging element, and an exposure control unit that starts exposure of the imaging element in synchronization with the contact.

  The summary of the invention does not enumerate all the features of the present invention. In addition, a sub-combination of these feature groups can also be an invention.

It is principal part sectional drawing of the single-lens reflex camera provided with the mirror holding mechanism. FIG. 6 is a perspective view of the vicinity of a mirror box when the main mirror is obliquely installed in a subject light beam. FIG. 6 is a perspective view of the vicinity of the mirror box when the main mirror is retracted from the subject light beam. It is a figure which shows a diagonal installation state. It is a figure which shows the state in the middle of the main mirror holding frame shifting from the oblique installation state to the retracted state. It is a figure which shows the state which the main mirror holding frame contact | abutted against the butting part. It is a figure which shows the state in which the main mirror holding frame bumped against the butting part and bounced back. It is a figure which shows the state which a sub mirror holding frame contacts the main mirror holding frame first. It is a figure which shows an evacuation state.

  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 cross-sectional view of a main part of a single-lens reflex camera 10 provided with a mirror holding mechanism 300. The single-lens reflex camera 10 functions as an imaging device by combining the lens unit 20 and the camera body 30.

  The lens unit 20 includes a lens group 21 arranged along the optical axis 11. The lens group 21 guides the subject luminous flux to the camera body 30 so as to be incident on an effective pixel of the image sensor 45 described later. The lens group 21 includes a focus lens, a zoom lens, and the like, and is configured to be movable in the optical axis direction in response to instructions for focus adjustment and field angle adjustment. The lens unit 20 includes a lens mount 22 at a connection portion with the camera body 30, engages with a camera mount 52 included in the camera body 30, and is integrated with the camera body 30.

  The mirror holding mechanism 300 includes a main mirror unit 310 and a sub mirror unit 320. The main mirror unit 310 includes a main mirror 311 and a main mirror holding frame 312. The sub mirror unit 320 includes a sub mirror 321 and a sub mirror holding frame 322. The camera body 30 includes a main mirror 311 that reflects a subject light beam incident from the lens unit 20 and a focus plate 36 on which the subject light beam reflected by the main mirror 311 forms an image. The main mirror 311 is held by the main mirror holding frame 312 and rotates around the main mirror rotation shaft 313 so that the main mirror 311 is obliquely provided as a first state obliquely provided in a subject light beam centered on the optical axis 11. Then, the retracted state as the second state retracted from the subject luminous flux can be taken. Although a specific structure will be described later, a down positioning pin 34 is provided as a positioning member for positioning the main mirror 311 in an oblique state, and an abutting portion 62 as an end portion for positioning in the retracted state. The abutting portion 62 is formed integrally with the mirror box 61. The abutting portion 62 protrudes toward the inside of the mirror box 61. The abutting portion 62 has such a high rigidity that the main mirror holding frame 312 can be rebounded. In the present embodiment, since the main mirror holding frame 312 is rebounded, the abutting portion 62 uses a highly rigid inelastic material, for example, polycarbonate, but has an appropriate rigidity to adjust the rebound coefficient. An elastic body may be used.

  When the subject image is guided to the focus plate 36 side, the main mirror holding frame 312 that holds the main mirror 311 contacts the down positioning pin 34, and the main mirror 311 is obliquely provided in the subject light beam. The focus plate 36 is disposed at a position conjugate with the light receiving surface of the image sensor 45. The subject image formed on the focus plate 36 is converted into an erect image by the pentaprism 40 and is observed by the user through the eyepiece optical system 41.

  A region near the optical axis 11 of the main mirror 311 in the oblique state is formed as a half mirror, and a part of the incident light flux of the subject is transmitted therethrough. The transmitted subject luminous flux is reflected by the sub mirror 321 held by the sub mirror holding frame 322 that swings in conjunction with the main mirror 311, and is guided to the AF optical system 42. The sub mirror holding frame 322 is pivotally supported on the sub mirror rotation shaft 315. When the main mirror 311 is in an oblique state, the sub mirror 321 is also in an oblique state in which the sub mirror 321 is obliquely provided in the subject light beam. The subject luminous flux that has passed through the AF optical system 42 enters the AF sensor 43. The AF sensor 43 detects a phase difference signal from the received subject light beam. The sub mirror 321 retracts from the subject light beam in conjunction with the main mirror 311 when the main mirror 311 retracts from the subject light beam.

  A focal plane shutter 44 and an image sensor 45 are arranged along the optical axis 11 behind the oblique main mirror 311. When the subject image is guided to the image sensor 45 side, the main mirror 311 is retracted from the subject light beam. The focal plane shutter 44 is opened when the main mirror 311 and the sub mirror 321 do not block the subject light beam, and is blocked at other times. The imaging element 45 is a photoelectric conversion element such as a CMOS sensor, for example, and converts the subject image formed on the light receiving surface into an electrical signal.

  The electrical signal photoelectrically converted by the image sensor 45 is processed into image data by an image processing unit 47 which is a DSP mounted on the main board 46. In addition to the image processing unit 47, a camera system control unit 48, which is an MPU that integrally controls the system of the camera body 30, is mounted on the main board 46. The camera system control unit 48 manages the camera sequence accompanied by the operations of the mirror units around the main mirror 311 and the sub mirror 321 and plays a role of controlling the focal plane shutter 44 as an exposure control unit. Further, the camera system control unit 48 performs input / output processing of each component, such as performing focusing control from the phase difference signal output from the AF sensor 43.

  A display unit 49 such as a liquid crystal monitor is disposed on the back of the camera body 30, and the subject image processed by the image processing unit 47 is displayed. The display unit 49 displays not only a still image after shooting, but also an EVF image as a viewfinder, various menu information, shooting information, and the like. Further, the camera body 30 accommodates a detachable secondary battery 50 and supplies power not only to the camera body 30 but also to the lens unit 20.

  FIG. 2 is a perspective view of the vicinity of the mirror box 61 when the main mirror 311 is obliquely installed in the subject light beam. Although the mirror box 61 is shown on the two side surfaces for convenience in the drawing, the mirror box 61 is actually constituted by side surfaces surrounding the main mirror 311 holding the main mirror 311 and the sub mirror holding frame 322 holding the sub mirror 321 around the subject light flux. Is done. The mirror box 61 is made of a highly rigid mold member or magnesium alloy having a light shielding line formed on the surface thereof to prevent stray light. A main mirror rotating shaft 313 formed integrally with the main mirror holding frame 312 is pivotally supported from the outside of the mirror box 61, and the main mirror holding frame 312 rotates around the main mirror rotating shaft 313. The sub mirror holding frame 322 is supported by a sub mirror rotation shaft 315 and rotates around the sub mirror rotation shaft 315. The abutting portion 62 is formed to protrude from the side surface of the mirror box 61 toward the inside of the mirror box 61. In FIG. 2, the side surface of the mirror box 61 on the left side of the drawing is omitted, but in actuality, the left abutting portion is located on the left side surface of the mirror box 61 at a position facing the abutting portion 62. It is formed so as to protrude from the inside toward the inside.

  The main mirror holding frame 312 has an edge 314. The edge 314 is formed so as to surround a part of the outer periphery of the main mirror 311. The edge portion 314 is formed to protrude in the left-right direction of the main mirror near the tip of the main mirror holding frame 312 on the side farther from the main mirror rotation shaft 313. The edge 314 is formed thicker than the plate thickness of the main mirror 311. That is, the edge 314 protrudes toward the focus plate 36 from the reflecting surface of the main mirror 311.

  FIG. 3 is a perspective view of the vicinity of the mirror box 61 when the main mirror 311 is retracted from the subject light beam. When the main mirror holding frame 312 rotates from the oblique state to the retracted state around the main mirror rotation shaft 313, the sub mirror holding frame 322 is also retracted from the subject light beam in conjunction with the main mirror holding frame 312. For example, in one shooting operation, a transition is made from an oblique state in which the user can observe the subject image formed on the focusing screen 36 to a retracted state in which the subject image is exposed on the light receiving surface of the image sensor 45, and is determined in advance. After the elapse of the exposure time, the main mirror holding frame 312 and the sub mirror holding frame 322 are rotated so as to return to the oblique state again. Therefore, this operation is repeatedly executed during continuous shooting.

  The rotating operation between the oblique state and the retracted state includes, for example, an actuator that lifts the retracted state against the biasing spring that biases to the oblique state, and a biasing spring that releases the operating force of the actuator. It is realized by a release mechanism that releases The secondary battery 50 supplies electric power to the actuator, and the camera system control unit 48 controls the actuator and the release mechanism.

  The down positioning pin 34 abuts against the back surface of the main mirror holding frame 312 when shifting from the retracted state to the oblique state, thereby receiving an impact that stops the rotation and accurately guiding the subject light flux to the focus plate 36. The main mirror 311 is settled at a proper angle.

  The abutting portion 62 causes the edge portion 314 to abut against the abutting portion 62 and rebound when the main mirror holding frame 312 shifts from the oblique state to the retracted state. The abutting portion 62 positions the main mirror holding frame 312 in the retracted state.

  In the mirror holding mechanism of a general single-lens reflex camera, when the main mirror holding frame shifts from the oblique state to the retracted state, the main mirror holding frame is abutted against an abutting portion formed in the mirror box. When the main mirror holding frame hits the abutting portion, an impact absorbing member such as a malt plane is attached to the abutting portion in order to suppress the bounce of the main mirror holding frame. In the mirror holding mechanism as described above, the impact absorbing member absorbs an impact when the main mirror holding frame hits the abutting portion. Therefore, even if the reflecting surface of the main mirror supported by the main mirror holding frame is directly abutted against the abutting portion, the main mirror was not damaged.

  However, according to the mirror holding mechanism of the present embodiment, the main mirror holding frame 312 hits the abutting portion 62 and rebounds. Therefore, in the present embodiment, an impact absorbing member such as a malt plane is not provided in the abutting portion 62 in order to absorb the impact. Therefore, when the main mirror holding frame 312 first hits the abutting portion 62 when the main mirror holding frame 312 shifts from the oblique state to the retracted state, the main mirror holding frame 312 hits the abutting portion 62. rebound. Therefore, the main mirror 311 is damaged by an impact when the main mirror 311 directly hits the abutting portion 62 as in the above-described general mirror holding mechanism.

  In order to prevent the main mirror 311 from being damaged due to the main mirror 311 hitting the abutting portion 62, the edge portion 314 hits the abutting portion 62. In the present embodiment, the edge portions 314 are provided on the left and right of the front end of the main mirror holding frame 312. When the edge portion 314 is provided further to the front side of the tip of the main mirror holding frame 312, the dimension of the main mirror holding frame 312 in the optical axis direction is increased. However, according to the present embodiment, since the edge portions 314 are provided on the left and right of the tip of the main mirror 311, the size of the main mirror holding frame 312 in the optical axis direction does not increase. That is, the dimension of the main mirror holding frame 312 in the optical axis direction can be substantially the same as the dimension of the main mirror 311 in the optical axis direction. Therefore, the dimension of the camera body 30 in the optical axis direction is reduced.

  The state of the operation in which the main mirror unit 310 and the sub mirror unit 320 shift from the oblique installation state to the retracted state will be described with reference to FIGS. For the purpose of simplifying the drawings, in FIGS. 4 to 9, the main mirror holding frame 312, the sub mirror holding frame 322, the toggle spring 39 and the abutting portion 62 are extracted and their positional relationships are shown. 4 to 9, (a) shows a state seen from the side indicated by an arrow P in FIG. 2, and (b) shows a state seen from the side indicated by an arrow Q in FIG. The main mirror holding frame 312 and the sub mirror holding frame 322 are moved from the oblique state to the retracted state, that is, in the clockwise direction in FIGS. 4 to 9 and in the counterclockwise direction in (b). Is defined as the retreat direction. Similarly, the main mirror holding frame 312 and the sub mirror holding frame 322 are moved from the retracted state to the obliquely arranged state, that is, in the counterclockwise direction in FIGS. 4 to 9A and in the clockwise direction in FIG. The direction is defined as the oblique direction.

  FIG. 4 is a diagram illustrating the oblique installation state. The sub mirror rotation shaft 315 is formed on the main mirror holding frame 312. As will be described in detail later, the sub mirror holding frame 322 swings in conjunction with the main mirror holding frame 312 and further rotates around the sub mirror rotation shaft 315. The toggle spring 39 is an urging spring attached between the main mirror holding frame 312 and the sub mirror holding frame 322. One end of the toggle spring 39 is supported by the main mirror holding frame 312. The other end of the toggle spring 39 biases a biasing surface 323 provided on the sub mirror holding frame 322.

  As shown in FIG. 4A, the biasing surface 323 is positioned on the left side of the sub mirror rotation shaft 315 in the oblique state. The toggle spring 39 urges the urging surface 323 in the direction of arrow A in FIG. Therefore, a counterclockwise rotational moment is generated in the sub mirror holding frame 322 in FIG.

  The restricting portion 316 is provided so as to protrude from the main mirror holding frame 312 to the front side of the sheet. The sub mirror holding frame 322 has a restricting portion 324 on the side opposite to the urging surface 323 across the sub mirror rotation shaft 315. The restricting portion 324 abuts against the restricting portion 316 provided on the main mirror holding frame 312 and restricts the counterclockwise rotation in FIG. 4A by the toggle spring 39.

  An impact absorbing member 319 such as a malt plane is provided on the back surface of the main mirror holding frame 312, that is, the surface on which the subject light beam does not strike. The shock absorbing member 319 is provided at a contact location between the main mirror holding frame 312 and the sub mirror holding frame 322 in the retracted state. The shock absorbing member 319 is fixed to the back surface of the main mirror holding frame 312 by, for example, adhesion.

  In the present embodiment, the shock absorbing member 319 is provided on the main mirror holding frame 312, but may be provided on the sub mirror holding frame 322. Further, the shock absorbing member 319 may be provided on both the main mirror holding frame 312 and the sub mirror holding frame 322.

  As shown in FIG. 4B, the sub mirror holding frame 322 has a first cam surface 325 and a second cam surface 326. The turning pin 63 is provided on the side surface of the mirror box 61. The turning pin 63 is provided so as to protrude from the side surface of the mirror box 61 in the direction of arrow Q in FIG. That is, in FIG. 4B, the turning pin 63 is provided so as to protrude from the front side of the paper to the back side of the paper.

  The turning pin 63 is configured by an eccentric pin. The turning pin 63 is supported so as to be rotatable with respect to the side surface of the mirror box 61. When the turning pin 63 is rotated, the turning pin 63 can adjust the timing for switching the urging surface 323 to the right side or the left side across the sub mirror rotation shaft 315. By adjusting the position of the turning pin 63, the timing of the first contact between the main mirror holding frame 312 and the sub mirror holding frame 322 can be adjusted. In the oblique state, the turning pin 63 is not in contact with either the first cam surface 325 or the second cam surface 326. As will be described in detail later, the first cam surface 325 contacts the turning pin 63 when the main mirror holding frame 312 shifts from the oblique state to the retracted state.

  The adjusting mechanism for the turning pin 63 that reverses the biasing direction of the toggle spring 39 is not limited to the eccentric pin. For example, the turning pin 63 may be supported by a long hole provided in the side surface of the mirror box 61 via a support member. The turning pin 63 is supported so that the arrangement position in the elongated hole can be adjusted by the support member. Therefore, even with such a configuration, the toggle spring 39 can adjust the timing for reversing the direction in which the biasing surface 323 is biased.

  FIG. 5 is a diagram illustrating a state in which the main mirror holding frame 312 is in the middle of the transition from the oblique state to the retracted state. In FIG. 5, the turning pin 63 is in a state before the urging direction of the toggle spring 39 is reversed. That is, the urging direction of the toggle spring 39 is the same as the urging direction shown in FIG.

  As shown in FIG. 5A, the urging surface 323 is located on the left side of the sub mirror rotation shaft 315. The toggle spring 39 urges the urging surface 323 in the arrow B direction. Therefore, a counterclockwise rotational moment is generated in the sub mirror holding frame 322 in FIG. The main mirror holding frame 312 is rotated in the retracting direction about the main mirror rotation shaft 313 by an actuator. The sub mirror holding frame 322 rotates in the retracting direction in conjunction with the rotation of the main mirror holding frame 312 in the retracting direction.

  In FIG. 5B, the turning pin 63 does not contact the first cam surface 325 for a while, but contacts the first cam surface 325 as the rotation of the main mirror holding frame 312 in the retracting direction proceeds. The driving force in the retracting direction of the main mirror holding frame 312 by the actuator is larger than the urging force of the toggle spring 39. Therefore, when the main mirror holding frame 312 further rotates in the retracting direction, the first cam surface 325 and the turning pin 63 come into contact with each other, and the sub mirror holding frame 322 rotates in the retracting direction.

  The sub mirror holding frame 322 revolves in conjunction with the rotation of the main mirror holding frame 312 until the first cam surface 325 and the turning pin 63 come into contact with each other. After the first cam surface 325 and the turning pin 63 come into contact, the first cam surface 325 is pushed by the turning pin 63, so that the toggle spring 39 reverses the urging direction. Therefore, after the biasing direction of the toggle spring 39 is reversed, the sub mirror holding frame 322 rotates around the sub mirror rotation shaft 315 while revolving in conjunction with the rotation of the main mirror holding frame 312. Therefore, after the first cam surface 325 and the turning pin 63 contact, the rotation amount of the sub mirror holding frame 322 is larger than the rotation amount of the main mirror holding frame 312.

  FIG. 6 is a diagram illustrating a state in which the main mirror holding frame 312 has abutted against the abutting portion 62. When the main mirror holding frame 312 hits the abutting portion 62, the tip of the sub mirror holding frame 322 is not yet in contact with the main mirror holding frame 312.

  As shown in FIG. 6A, the urging surface 323 is located on the right side of the sub mirror rotation shaft 315. The toggle spring 39 urges the urging surface 323 in the arrow C direction. Therefore, a clockwise rotating moment is generated in the sub mirror holding frame 322 in FIG. Therefore, the sub mirror holding frame 322 is rotated in the retracting direction around the sub mirror rotation shaft 315 by the toggle spring 39.

  In FIG. 6B, the sub mirror holding frame 322 rotates in the retracting direction by the urging force of the toggle spring 39. Therefore, the first cam surface 325 is separated from the turning pin 63. When the main mirror holding frame 312 is in contact with the abutting portion 62, the main mirror holding frame 312 does not rotate. Therefore, the sub mirror holding frame 322 cannot move in conjunction with the main mirror holding frame 312. That is, the first cam surface 325 is not pushed by the turning pin 63. Therefore, the position of the urging surface 323 is switched from the left side to the right side with the sub-mirror rotation shaft 315 sandwiched by the turning pin 63 until the main mirror holding frame 312 rotates in the retracting direction and hits the abutting portion 62.

  FIG. 7 is a view showing a state in which the main mirror holding frame 312 hits the abutting portion 62 and rebounds. Since the abutting portion 62 is a rigid body, the main mirror holding frame 312 abuts against the abutting portion 62 and rebounds in an oblique direction.

  As shown in FIG. 7A, the urging surface 323 is located on the right side of the sub mirror rotation shaft 315. The toggle spring 39 urges the urging surface 323 in the arrow D direction. Therefore, a clockwise rotating moment is generated in the sub mirror holding frame 322 in FIG. Therefore, the sub mirror holding frame 322 is rotated in the retracting direction around the sub mirror rotation shaft 315 by the toggle spring 39.

  In FIG. 7B, the sub mirror holding frame 322 rotates in the retracting direction by the urging force of the toggle spring 39. Therefore, the first cam surface 325 is separated from the turning pin 63.

  FIG. 8 is a diagram illustrating a state in which the front end portion of the sub mirror holding frame 322 first contacts the main mirror holding frame 312. At the timing when the main mirror holding frame 312 hits and strikes the abutting portion 62 and moves in the oblique direction, the tip of the sub mirror holding frame 322 first contacts the main mirror holding frame 312. The tip of the sub-mirror holding frame 322 first comes into contact with the main mirror holding frame 312 outside the subject light beam.

  As shown in FIG. 8A, the urging surface 323 is located on the right side of the sub mirror rotation shaft 315. The toggle spring 39 urges the urging surface 323 in the direction of arrow E. Therefore, a clockwise rotating moment is generated in the sub mirror holding frame 322 in FIG. Therefore, the sub mirror holding frame 322 is rotated in the retracting direction around the sub mirror rotation shaft 315 by the toggle spring 39.

  When the tip of the sub mirror holding frame 322 contacts the main mirror holding frame 312, the shock absorbing member 319 suppresses the generation of contact sound due to the contact between the main mirror holding frame 312 and the tip of the sub mirror holding frame 322. Further, the shock absorbing member 319 prevents the main mirror holding frame 312 and the front end portions of the sub mirror holding frame 322 from being damaged by the contact between the main mirror holding frame 312 and the front end portions of the sub mirror holding frame 322.

  In FIG. 8B, the sub mirror holding frame 322 rotates in the retracting direction by the urging force of the toggle spring 39. Therefore, the first cam surface 325 is separated from the turning pin 63. The main mirror unit 310 has an angular momentum toward the oblique direction, and the sub-mirror unit 320 has an angular momentum toward the retracting direction. Therefore, by bringing the main mirror holding frame 312 and the sub mirror holding frame 322 into contact with each other, the mutual angular momentum is canceled.

  The angular momentum in the retracting direction of the sub mirror unit 320 is adjusted to be slightly larger than the angular momentum in the oblique direction of the main mirror unit 310. The angular momentum of the main mirror unit 310 includes the mass of the main mirror holding frame 312, the position of the center of gravity of the main mirror holding frame 312, the driving speed of the actuator to drive the main mirror holding frame 312 in the retracting direction, and the coefficient of restitution of the abutting unit 62. It is determined by the mass of the main mirror 311 and the like.

  The angular momentum of the sub mirror unit 320 depends on the mass of the sub mirror holding frame 322, the position of the center of gravity of the sub mirror holding frame 322, the biasing force of the toggle spring 39, the timing at which the turning pin 63 reverses the biasing direction of the toggle spring 39, the mass of the sub mirror 321, etc. Determined. The various parameters described above can be experimentally determined in advance so that the angular momentum of the sub mirror unit 320 is slightly larger than the angular momentum of the main mirror unit 310. However, due to component variation and assembly variation, after the mirror holding mechanism 300 is assembled, the mutual angular momentum of the main mirror unit 310 and the sub mirror unit 320 may not satisfy the predetermined mutual relationship of angular momentum. . Specifically, in a state after the mirror holding mechanism 300 is assembled, for example, the angular momentum in the oblique direction of the main mirror unit 310 is larger than the angular momentum in the retracting direction of the sub mirror unit 320. There is. Therefore, it is preferable that the angular momentum of the main mirror unit 310 and the sub mirror unit 320 can be adjusted.

  The mass of the main mirror holding frame 312 is adjusted by adjusting the injection mold. For example, when it is experimentally known in advance that the amount of rebound at the abutting portion 62 is small, the main mirror holding frame 312 may be molded with the tip end side of the main mirror holding frame 312 thickened. Furthermore, only by adjustment with the injection molding die, when the plurality of mirror holding mechanisms 300 are assembled, the predetermined angular momentum may not be satisfied due to individual component variations. In such a case, for example, a plurality of weights may be prepared in advance, and appropriate weights may be attached experimentally during assembly.

  The angular momentum of the sub mirror holding frame 322 can be adjusted by the spring force of the toggle spring 39, the mass of the sub mirror holding frame 322, and the like. The spring force of the toggle spring 39 can be adjusted, for example, by changing the wire diameter and the number of turns. In order to make the angular momentum in the retracting direction of the sub mirror part 320 slightly larger than the angular momentum in the oblique direction of the main mirror part 310, the mass of the sub mirror holding frame 322 is adjusted by adjusting the mold of injection molding. . For example, the sub mirror holding frame 322 may be molded with the tip side of the sub mirror holding frame 322 being thick. Furthermore, only by adjustment with the injection molding die, when the plurality of mirror holding mechanisms 300 are assembled, the predetermined angular momentum may not be satisfied due to individual component variations. In such a case, for example, a plurality of weights may be prepared in advance, and appropriate weights may be attached experimentally during assembly.

  As described above, according to the present embodiment, the angular momentum of the main mirror part 310 that strikes the abutting part 62 and rebounds in the oblique direction is canceled out by the angular momentum of the sub mirror part 320 toward the retracting direction. Thereby, the angular momentum of the main mirror part 310 bounced off at the abutting part 62 decreases. Therefore, the main mirror part 310 bounced off at the abutting part 62 can be converged earlier. More preferably, when the front end portion of the sub mirror holding frame 322 comes into contact with the main mirror holding frame 312 for the first time, the main mirror portion 310 and the sub mirror portion 320 are substantially offset in mutual angular momentum. And adjust the angular momentum of the sub mirror. Further, the angular momentum in the retracting direction of the sub mirror unit 320 is set slightly larger than the angular momentum in the oblique direction of the main mirror unit 310. Therefore, when the front end portion of the sub mirror holding frame 322 first contacts the main mirror holding frame 312, the main mirror holding frame 312 is on the oblique installation direction side from the position where the main mirror holding frame 312 first contacts the front end portion of the sub mirror holding frame 322. Does not rotate. That is, when the tip of the sub mirror holding frame 322 first contacts the main mirror holding frame 312, the sub mirror holding frame 322 can rotate in the retracting direction together with the main mirror holding frame 312. Therefore, the main mirror holding frame 312 and the sub mirror holding frame 322 do not block the subject light beam after the tip of the sub mirror holding frame 322 first contacts the main mirror holding frame 312. In addition, since the mutual angular momentum of the main mirror part 310 and the sub mirror part 320 is substantially canceled by the first contact, the main mirror holding frame 312 and the sub mirror holding frame 322 do not make a second or subsequent contact.

  The camera system control unit 48 can start exposure of the image sensor in synchronization with the initial contact between the main mirror holding frame 312 and the sub mirror holding frame 322. Specifically, the camera system control unit 48 starts running the front curtain of the focal plane shutter 44 when the sub mirror holding frame 322 first contacts the main mirror holding frame 312. The time until the first contact between the main mirror holding frame 312 and the sub mirror holding frame 322 may be experimentally determined in advance.

  FIG. 9 is a diagram illustrating a retracted state. After first contacting the main mirror holding frame 312, the sub mirror holding frame 322 is displaced to the retracted state integrally with the main mirror holding frame 312 by the driving force of the actuator to drive the main mirror holding frame 312 in the retracting direction. .

  As shown in FIG. 9A, the urging surface 323 is located on the right side of the sub mirror rotation shaft 315. The toggle spring 39 urges the urging surface 323 in the direction of arrow F. Therefore, a clockwise rotating moment is generated in the sub mirror holding frame 322 in FIG. Therefore, the sub mirror holding frame 322 rotates in the retracting direction around the sub mirror rotation shaft 315. The sub mirror holding frame 322 is disposed in a retracted state integrally with the main mirror holding frame 312. Since the angular momentum of the main mirror holding frame 312 and the sub mirror holding frame 322 is substantially canceled by the initial contact between the main mirror holding frame 312 and the sub mirror holding frame 322, the main mirror holding frame 312 is gently abutted. Contact the part 62. That is, the main mirror holding frame 312 has almost no angular momentum in the retracting direction. Therefore, even if the main mirror holding frame 312 hits the abutting portion 62, it does not rebound again.

  Since FIG. 9B is a view seen from the side opposite to the side shown in FIG. 9A as described above, the directions of the arrows indicating the rotation direction of the sub mirror holding frame 322 are opposite. The sub mirror holding frame 322 rotates in the retracting direction by the urging force of the toggle spring 39. The turning pin 63 is separated from the first cam surface 325.

  Note that if the angular momentum of each other is canceled by the first contact between the main mirror holding frame 312 and the sub mirror holding frame 322, the main mirror holding frame 312 and the sub mirror holding frame 322 are displaced to the abutting portion 62 after the first contact. Even if not, it may be adjusted so as to stop at the position of the first contact. In this case, the abutting part 62 may not be provided. Even in this case, the main mirror holding frame 312 and the sub mirror holding frame 322 are in contact with each other outside the subject light flux. Therefore, the camera system control unit 48 can start exposure.

  According to the present embodiment, the main mirror holding frame 312 that hits the abutting portion 62 and rebounds and goes in the oblique direction and the sub mirror holding frame 322 that goes in the retracting direction first contact each other outside the subject light flux. Furthermore, by adjusting in advance the angular momentum in the oblique direction of the main mirror holding frame 312 and the angular momentum in the retracting direction of the sub mirror holding frame 322, the mutual angular momentum is canceled at the first contact. Therefore, the main mirror holding frame 312 and the sub mirror holding frame 322 do not block the subject luminous flux after the first contact. Then, exposure can be started in synchronization with the first contact between the main mirror holding frame 312 and the sub mirror holding frame 322. Therefore, according to the mirror holding mechanism 300 of this embodiment, the start of exposure can be accelerated without increasing the number of parts and without further complicating the mechanism. In particular, the frame speed can be increased during continuous shooting.

  Note that the mirror holding mechanism 300 in the present embodiment can also be applied to a camera having a shutter that does not have a front curtain. In this case, when the sub mirror holding frame 322 first comes into contact with the main mirror holding frame 312, the image sensor 45 starts charge accumulation and starts exposure. As a result, as in the case of a camera equipped with a focal plane shutter 44, an effect that the start of exposure can be accelerated is obtained.

  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.

10 SLR camera, 11 optical axis, 20 lens unit, 21 lens group, 22 lens mount, 30 camera body, 34 down positioning pin, 36 focus plate, 39 toggle spring, 300 mirror holding mechanism, 310 main mirror unit, 311 main mirror , 312 Main mirror holding frame, 313 Main mirror rotating shaft, 314 Edge, 315 Sub mirror rotating shaft, 316 Restricting portion, 319 Shock absorbing member, 320 Sub mirror portion, 321 Sub mirror, 322 Sub mirror holding frame, 323 Energizing surface, 324 Restricting , 325 1st cam surface, 326 2nd cam surface, 40 penta prism, 41 eyepiece optical system, 42 AF optical system, 43 AF sensor, 44 focal plane shutter, 45 image sensor, 46 main board, 47 image processing unit, 48 La system control unit, 49 display unit, 50 battery, 52 camera mount, 61 a mirror box, 62 abutting portions, 63 turning pin

Claims (7)

A mirror holding mechanism installed in the camera body,
A main mirror that rotates between a first state obliquely provided in the subject luminous flux and a second state retracted from the subject luminous flux;
A sub-mirror part that swings in conjunction with the main mirror part, is obliquely installed in the subject light beam in the first state, and is retracted from the subject light beam in the second state;
In the operation of displacing from the first state to the second state, the sub-mirror portion that is displaced in the retracting direction is the timing at which the main mirror portion rebounds at the end and is displaced in the oblique direction. Mirror holding mechanism that makes the first contact with.   The mirror holding mechanism according to claim 1, wherein the contact is performed outside the subject light flux.   The mirror holding mechanism according to claim 1, wherein an impact absorbing member is provided at a contact location between the main mirror portion and the sub mirror portion.   The mirror holding mechanism according to any one of claims 1 to 3, wherein the end portion where the main mirror portion bounces is not an elastic body.   The mirror holding mechanism according to any one of claims 1 to 4, further comprising an attaching portion attached to at least one of the main mirror portion and the sub mirror portion. A toggle spring that urges the main mirror portion by switching the sub mirror portion between the oblique direction and the retracting direction;
A turning pin that reverses the biasing direction of the toggle spring,
The mirror holding mechanism according to claim 1, wherein the turning pin has an adjustment mechanism that adjusts a timing of reversing the biasing direction. The mirror holding mechanism according to any one of claims 1 to 6,
An image sensor;
An imaging apparatus comprising: an exposure control unit that starts exposure of the imaging element in synchronization with the contact.

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