JP5919761B2 - Camera movable mirror shock absorption mechanism - Google Patents

Description

  The present invention relates to a drive device for a movable mirror provided in a single-lens reflex camera, and more particularly to an impact absorbing mechanism for the movable mirror.

  Inside the single-lens reflex camera, a finder light guide position (down position) that is inserted in the photographic optical path and reflects the subject light to the finder optical system, and a retracted position that evacuates from the photographic optical path and passes the subject light to the shutter side. A movable mirror (quick return mirror) that can be turned up and down is provided at (up position). If the movable mirror bounces (vibrates) due to an impact when it reaches the rotation end such as the finder light guide position or the retracted position, the observation image of the finder is not stable and adversely affects the observation performance. Also, with a camera that uses a movable mirror to direct the subject light to a distance measuring sensor or a photometric sensor, accurate distance measurement or photometry cannot be performed while the movable mirror is bouncing. Copy performance is limited. For this reason, there has been proposed an impact absorbing mechanism that absorbs an impact when the movable mirror rotates and suppresses a bounce.

JP 2000-131755 A

  In order to improve the continuous shooting performance of the camera, both the rotation of the movable mirror to the finder light guide position (mirror down operation) and the rotation to the retracted position (mirror up operation) perform shock absorption and mirror It is desirable to suppress bounce. Therefore, an impact absorbing mechanism including a buffer member for suppressing bounce at the finder light guide position of the movable mirror and a buffer member for suppressing bounce at the retracted position is known. However, if the buffer members that function at each position of the movable mirror are individually prepared, there is a problem that the manufacturing cost increases.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide a movable mirror shock absorbing mechanism for a camera that can be manufactured at a low cost with a simple structure and contributes to improving continuous shooting performance. .

The present invention rotates between a finder light guide position that is located on the photographing optical path and reflects subject light to the observation optical system, and a retreat position that is retracted from the photographing optical path and allows the subject light to pass to the imaging light receiving medium side. This is related to the shock absorbing mechanism of the movable mirror of the camera that is movably supported. The movable mirror is supported so that it can move straight in the direction intersecting the trajectory of the movable mirror. A first buffer member that is pressed and moved by a pressing portion that moves along with the rotation of the movable mirror and absorbs the impact of the movable mirror, and can move straight in a direction that intersects with the rotation locus of the movable mirror. and supported by the movable mirror and the second buffer member for impact absorption of the movable mirror is pressed and moved by the pressing portion when pivoted to the retracted position from the finder light position, the first buffer member and the second Urges the衝部material each comprise a biasing member for holding the buffer waiting position to advance on a moving locus of the pressing portion, that the first buffer member and the second cushioning member made of cushioning members common specifications It is a feature.

The urging member urges the first buffer member and the second buffer member to move away from the rotation center of the movable mirror , and the first buffer member and the second buffer member It is good to make it press and move by a press part in the direction opposite to a urging direction.

  The buffer member of the common specification has an asymmetric shape with respect to a virtual center line in which the surface pressed by the pressing portion is parallel to the linearly moving direction of each buffer member and passes through the center in the width direction. By supporting the second buffer member with the front and back reversed, it becomes easy to set the optimum bounce suppressing performance for each buffer member.

  The buffer member of the common specification is connected to both sides of the outer edge cam surface located on the outer edge portion far from the rotation center of the movable mirror, and gradually approaches the rotation center of the movable mirror as the distance from the outer edge cam surface increases. It can be set as the shape which has a pair of inclination cam surface which inclines in the direction to do. When the first buffer member and the second buffer member are held at the respective buffer standby positions, the outer edge cam surface and the pair of inclined cam surfaces advance on the movement locus of the pressing portion. When the movable mirror rotates from the retracted position to the finder light guide position, the pressing portion presses one inclined cam surface and the outer edge cam surface of the first buffer member to move from the buffer standby position, and the movable mirror guides the finder. When the light position is reached, the pressing portion is opposed to the other inclined cam surface, and the first buffer member returns to the buffer standby position. Conversely, when the movable mirror rotates from the finder light guide position to the retracted position, the pressing portion presses one inclined cam surface and the outer edge cam surface of the second buffer member to move from the buffer standby position, and the movable mirror When the position reaches the retracted position, the pressing portion faces the other inclined cam surface, and the second buffer member returns to the buffer standby position.

  The pressing portion is preferably a rotation contact portion that is provided on the side of the mirror support member that holds the movable mirror so as to be rotatable about an axis parallel to the rotation center of the movable mirror.

  According to the movable mirror shock absorbing mechanism of the present invention, the first buffer member that absorbs shock when the movable mirror rotates from the retracted position to the finder light guiding position, and the movable mirror from the finder light guiding position to the retracted position. By providing the second buffer member that absorbs the shock when rotating, it is possible to improve the continuous shooting performance by suppressing the bounce of the movable mirror at both the finder light guide position and the retracted position. Furthermore, since the first buffer member and the second buffer member are made to have a common buffer member, the structure can be simplified and the manufacturing cost can be reduced.

It is a figure which shows the outline of the optical system of the single-lens reflex camera to which this invention is applied. It is a front perspective view of the mirror box in a mirror down state. It is a front perspective view of the mirror box in a mirror up state. It is a back perspective view of a mirror box in a mirror down state. It is a back perspective view of a mirror box in a mirror down state. It is a back perspective view of a mirror box in a mirror up state. It is a perspective view of the mirror shock absorption mechanism in a state where the contact portion of the mirror sheet is in contact with the down absorption member. It is a perspective view of the mirror shock absorbing mechanism in a state where the contact portion of the mirror sheet is in contact with the up-absorbing member. It is a left view of the mirror box in the state where the presser plate is removed and the mirror shock absorbing mechanism is exposed. It is a side view of the mirror impact absorption mechanism in a mirror-down state. It is a side view of the mirror impact absorbing mechanism in a state where the movable mirror is rotating from the down position to the up position. It is a side view of the mirror impact absorbing mechanism in a state where the movable mirror is rotating from the down position to the up position. It is a side view of the mirror impact absorbing mechanism in the mirror up state. It is a side view of the mirror impact absorbing mechanism in a state where the movable mirror is rotating from the up position to the down position. It is a side view of the mirror impact absorbing mechanism in a state where the movable mirror is rotating from the up position to the down position. It is a figure of the state which piled up the slide member of the common specification which comprises a down absorption member and an up absorption member upside down.

  A single-lens reflex camera (hereinafter referred to as a camera) 10 shown in FIG. 1 has a lens mount 13 for attaching and detaching an interchangeable lens barrel 12 on the front surface of a camera body 11, and a mirror box 14 is provided on the inside thereof. .

  A movable mirror (quick return mirror) 15 is provided in the mirror box 14. The movable mirror 15 has a structure in which the main mirror 15 a is fixedly supported on the mirror sheet 16, and the sub mirror 17 is rotatably supported on the back side of the mirror sheet 16, and protrudes on both sides of the mirror sheet 16. A pair of mirror sheet hinges 16 x are pivotally supported on both side walls of the mirror box 14. A focal plane shutter (hereinafter referred to as shutter) 18 is provided behind the movable mirror 15, and an image sensor (imaging light receiving medium) 19 is provided behind the shutter 18. Note that the camera 10 of the present embodiment is a digital camera that uses the image sensor 19 as an imaging light-receiving medium, but the present invention can also be applied to a camera that uses a silver salt film as the imaging light-receiving medium.

  The movable mirror 15 is inclined down at an angle of about 45 degrees on the photographing optical path from the photographing lens 12a in the lens barrel 12 to the image sensor 19 with the mirror sheet hinge 16x as an axis (finder light guide position: 1 between the solid line in FIG. 1, FIG. 2, FIG. 4, FIG. 5, and FIG. 10) and the up position retracted upward from the imaging optical path (retracted position: two-dot chain line in FIG. 1, FIG. 3, FIG. Is reciprocally rotated. As shown in FIGS. 4 and 6, a down positioning dowel 20 protrudes from the inner surface of one of both side walls of the mirror box 14 positioned with the movable mirror 15 interposed therebetween. The mirror sheet 16 is opposed to the down positioning dowel 20. The down position of the movable mirror 15 is determined by abutting a stopper portion 16a (FIGS. 7 and 8) provided on one side portion of the movable mirror 15. The down positioning dowel 20 can finely adjust the mounting position with respect to the mirror box 14. Also, an upper stopper 21 is provided in the mirror box 14 so that the upper surface of the mirror sheet 16 can come into contact when the movable mirror 15 is rotated to the up position. A finder optical system 22 composed of a pentaprism, an eyepiece, or the like is provided above the movable mirror 15.

  When the movable mirror 15 is in the down position, subject light that enters the mirror box 14 through the photographing lens 12a in the lens barrel 12 with the lens barrel 12 mounted on the lens mount 13 is the main mirror of the movable mirror 15. The object image can be observed through the finder window 22a on the rear side of the camera body 11 after being reflected by the lens 15a and entering the finder optical system 22. In this state, photometry can be performed by the photometry unit 23 provided behind the pentaprism constituting the finder optical system 22. In the down position of the movable mirror 15, the sub mirror 17 protrudes obliquely downward with respect to the mirror sheet 16, and part of the subject light is guided to the distance measuring unit 24 below the mirror box 14 by the sub mirror 17, The distance can be detected. On the other hand, when the movable mirror 15 is in the up position, the subject light incident into the mirror box 14 through the photographing lens 12a is not reflected by the movable mirror 15 but proceeds to the shutter 18 side, and the shutter 18 is opened to open the image sensor 19. Light can be incident on the light receiving surface. At the up position of the movable mirror 15, the sub mirror 17 is stored on the back side of the mirror sheet 16. The LCD monitor 25 provided on the rear surface of the camera body 11 can display an electronic image of the subject obtained by the image sensor 19 and various types of information other than the electronic image.

  As shown in FIGS. 3 and 5, a mirror drive mechanism 30 that moves the movable mirror 15 up and down is provided on one side (the left side when viewed from the front) of the mirror box 14. The mirror drive mechanism 30 includes a motor 31, a reduction gear train 32 that transmits a drive force of the motor 31, a cam gear 33 that receives a rotational drive force from the reduction gear train 32 via a planetary gear mechanism, and a cam gear 33. A mirror drive lever 34 whose rotation position is controlled is provided. The mirror drive lever 34 is supported by the mirror box 14 so as to be reciprocally rotatable about an axis 34x substantially parallel to the axis of the mirror sheet hinge 16x, and holds a mirror sheet boss 16b provided on the side of the mirror sheet 16. doing. The holding portion by the mirror driving lever 34 presses the mirror sheet boss 16b downward to rotate the movable mirror 15 toward the down position, and presses the mirror sheet boss 16b upward to move the movable mirror 15 to the up position. Rotate toward The mirror drive lever 34 is urged to rotate in a direction to press the movable mirror 15 to the down position, and when the cam gear 33 is in a specific rotation position, a mirror control cam (peripheral cam) formed on the cam gear 33. Thus, the mirror drive lever 34 is pressed and rotated in the mirror up direction against the urging force. Specifically, the cam gear 33 is a one-rotation cam gear that is rotated only in one direction from the initial position. When the cam gear 33 is in the initial position, the mirror control cam of the cam gear 33 does not press the mirror drive lever 34, and the mirror drive. The movable mirror 15 is held in the down position by the urging force acting on the lever 34. When the cam gear 33 is rotated from the initial position to the middle, the mirror control cam of the cam gear 33 presses and rotates the mirror drive lever 34, and the mirror drive lever 34 rotates the movable mirror 15 to the up position. From this midway position until the cam gear 33 returns to the initial position, the mirror control cam of the cam gear 33 releases the pressure on the mirror drive lever 34, and the movable mirror 15 is returned to the down position.

  A shutter charge lever 35 for charging the shutter 18 is further provided on one side of the mirror box 14. The cam gear 33 has a shutter charge cam that controls the operation of the shutter charge lever 35 in addition to the above-described mirror drive cam, and rotates the shutter charge lever 35 reciprocally by rotating once from the initial position to charge the shutter. Let it be done. Since the shutter charge mechanism is not related to the features of the present invention, detailed description thereof is omitted.

  The other side of the mirror box 14 (the side on the right side when viewed from the front) absorbs an impact when the movable mirror 15 rotates to the down position and the up position, thereby suppressing the bounce (vibration) of the movable mirror 15. A mirror shock absorbing mechanism 40 is provided. The mirror impact absorbing mechanism 40 includes a down absorbing member (first buffer member) 41, a down absorbing spring (biasing member) 42, an up absorbing member (second buffer member) 43, and an up absorbing spring (biasing member) 44. Each of these members is held so as not to drop off by a pressing plate 45 (FIG. 4) fixed to the side of the mirror box 14. 6 and 9 show a state in which the pressing plate 45 is removed.

The down absorption member 41 performs shock absorption and bounce suppression when the movable mirror 15 rotates to the down position, and the up absorption member 43 performs shock absorption and bounce suppression when the movable mirror 15 rotates to the up position. The down absorption member 41 and the up absorption member 43 are composed of a slide member 50 having a common specification, and can be properly used by attaching the slide member 50 to the mirror box 14 with the front and back sides reversed. As shown in FIG. 16, the slide member 50 has a shape in which a pair of wing parts 51 and 52 are bridged by an intermediate bridge part 53, and guide holes 54 and 55 are formed in the wing part 51 and the wing part 52, respectively. Is formed. The guide hole 54 and the guide hole 55 are parallel long holes. A spring accommodating portion 56 is formed in a part of the intermediate bridging portion 53. A cylindrical storage space having one end opened is formed in the spring storage portion 56, and a spring support protrusion 57 is formed inside the storage space.

  The slide member 50 has a first cam surface (inclined cam surface) C1 and a second cam surface (inclined cam) on the outer edge portion on the side where the distance from the mirror seat hinge 16x is long when assembled to the mirror box 14 described later. Surface) C2 and a third cam surface (outer edge cam surface) C3 are formed. In the following description, the side far from the mirror seat hinge 16x in the state where the slide member 50 is assembled to the mirror box 14 is referred to as an outer diameter side, and the closer side is referred to as an inner diameter side. The first cam surface C1 is an outer diameter side edge portion of the wing portion 51, the second cam surface C2 is an outer diameter side edge portion of the wing portion 52, and the third cam surface C3 is an outer diameter side edge portion of the intermediate bridge portion 53. Is formed. The third cam surface C3 is a surface positioned on the outermost diameter side, and the first cam surface C1 and the second cam surface C2 are surfaces having an inclination component toward the inner diameter side as the distance from the third cam surface C3 increases. . Further, on the outer diameter side edge portion of the wing portion 51, a gentle slope K1 having a gentle inclination angle toward the inner diameter direction from the first cam surface C1 is formed in a region extending from the first cam surface C1 to the side surface of the wing portion 51. In the outer diameter side edge of the wing portion 52, a gentle slope K2 having a gentle inclination angle toward the inner diameter direction from the second cam surface C2 is formed in a region extending from the second cam surface C2 to the side surface of the wing portion 52. Is formed.

  An edge on the outer diameter side of the slide member 50 on which the cam surfaces C1, C2, and C3 are formed is an imaginary center that passes through the center in the width direction in parallel with the linearly moving direction of the down absorbent member 41 and the up absorbent member 43 described later. It has an asymmetric shape with respect to the line G (FIGS. 10 and 16). As can be seen from FIG. 16 in which the two slide members 50 are overlapped with each other upside down, the first cam surface C1 and the second cam surface C2, and the gentle slope K1 and the gentle slope K2 are asymmetric, respectively. The surface C3 is also asymmetric on both sides of the virtual center line G. In the third cam surface C3, the boundary portion with the first cam surface C1 protrudes slightly toward the outer diameter side from the boundary portion with the second cam surface C2, and the second cam surface C3 is second from the first cam surface C1 side. As it moves toward the cam surface C2, it gradually approaches the inner diameter side. The second cam surface C2 continuing to one end of the third cam surface C3 is formed longer in the inner diameter direction than the first cam surface C1 continuing to the other end of the third cam surface C3. The gentle slope K2 is located closer to the inner diameter than the gentle slope K1.

Four guide pins 14a, 14b, 14c and 14d are provided on the side surface of the mirror box 14 at predetermined intervals along the rotation direction of the movable mirror 15. Four guide pins 14a, 14b, 14c and 14d are provided. Are equal in radial distance about the mirror seat hinge 16x. Further, the distance between the guide pins 14 a and 14 b in the rotation direction of the movable mirror 15 is equal to the distance between the guide pins 14 c and 14 d, and the distance between the guide pins forming a pair is the guide hole 54 in the slide member 50. And the distance between the guide holes 55. On the side surface of the mirror box 14, there are further provided a spring support protrusion 14e positioned between the guide pin 14a and the guide pin 14b, and a spring support protrusion 14f positioned between the guide pin 14c and the guide pin 14d.

  The slide member 50 used as the down-absorbing member 41 has the cam surfaces C1, C2, and C3 facing in the outer diameter direction far from the mirror seat hinge 16x, and the guide hole 54 and the guide pin 14b with respect to the guide pin 14a. The guide hole 55 is inserted and assembled. The slide member 50 used as the up-absorbing member 43 is arranged so that the cam surfaces C1, C2 and C3 face in the outer diameter direction far from the mirror seat hinge 16x, and the guide hole 55 and the guide pin 14d with respect to the guide pin 14c. The guide hole 54 is inserted and assembled. In other words, the down absorption member 41 and the up absorption member 43 are supported on the side surface of the mirror box 14 with the common specification slide member 50 turned upside down, and the wings 52 are opposed to each other in the rotational direction of the movable mirror 15. Arrangement.

  The down-absorbing member 41 receives the guides of the pair of guide pins 14a and 14b through the pair of guide holes 54 and 55, thereby centering the mirror sheet hinge 16x in a plane perpendicular to the axis of the mirror sheet hinge 16x. The movable mirror 15 is supported so as to be able to move straight in the rotational radius direction. The moving direction of the down absorption member 41 is obliquely downward with respect to the horizontal direction with the camera 10 held horizontally.

  The down absorption spring 42 is inserted into the storage space of the spring storage portion 56 in the down absorption member 41. The storage space of the spring storage portion 56 is opened to the inner diameter side opposite to the third cam surface C3. The down absorption spring 42 is a compression spring, and is housed in a state in which one end is brought into contact with the bottom surface of the housing space of the spring housing 56 and the other end is exposed to the opening side of the housing space. The exposed side end of the down absorption spring 42 abuts on the spring support protrusion 14e when the down absorption member 41 is supported by the mirror box 14. The down absorption spring 42 is prevented from buckling by the inner peripheral surface of the storage space of the spring storage portion 56 and the spring support protrusion 57, and can be expanded and contracted in the axial direction. The down absorption spring 42 is compressed in the assembled state of the down absorption member 41 shown in FIGS. 9 to 15, and the down absorption member 41 is moved and urged away from the mirror seat hinge 16x by the restoring force. The movement of the down absorbing member 41 in the urging direction by the down absorbing spring 42 is regulated by bringing one end of the guide holes 54 and 55 into contact with the guide pins 14a and 14b. The moving end in the urging direction is the buffer standby position of the down absorbing member 41.

  Like the down absorbing member 41, the up absorbing member 43 receives the guides of the pair of guide pins 14 d and 14 c through the pair of guide holes 54 and 55, so that the mirror in the plane perpendicular to the axis of the mirror sheet hinge 16 x is obtained. The movable mirror 15 around the seat hinge 16x is supported so as to be able to move straight in the rotational radius direction. The movement direction of the up-absorbing member 43 is substantially horizontal when the camera 10 is held horizontally.

The up absorption spring 44 is inserted into the storage space of the spring storage portion 56 in the up absorption member 43. The up absorption spring 44 is a compression spring having the same specifications as the down absorption spring 42, and has one end abutted against the bottom surface of the storage space of the spring storage portion 56 and the other end exposed at the opening of the storage space. When the up-absorbing member 43 is supported by the mirror box 14, the exposed end of the up-absorbing spring 44 comes into contact with the spring support protrusion 14f. The up absorption spring 44 is prevented from buckling by the inner peripheral surface of the storage space of the spring storage portion 56 and the spring support protrusion 57, and can be expanded and contracted in the axial direction. The up-absorbing spring 44 is compressed in the assembled state of the up-absorbing member 43 shown in FIGS. 9 to 15, and the up-absorbing member 43 is urged to move in the outer diameter direction away from the mirror seat hinge 16x by the restoring force. The movement of the up absorbing member 43 in the urging direction by the up absorbing spring 44 is regulated by bringing one end portion of the guide holes 54 and 55 into contact with the guide pins 14d and 14c. The moving end in the urging direction is a buffer standby position of the up absorbing member 43.

  As shown in FIG. 7 and FIG. 8, a base shaft portion 16c projects from the side portion near the tip of the mirror sheet 16, and a roller (pressing portion, rotation contact portion) 60 is supported on the base shaft portion 16c. Has been. The roller 60 has a small diameter portion 60a having the same diameter as the base shaft portion 16c and a large diameter portion 60b positioned at the tip of the small diameter portion 60a, and is parallel to the axis of the mirror sheet hinge 16x with respect to the base shaft portion 16c. It is supported so as to be rotatable about an axis. The large diameter portion 60 b of the roller 60 has a cylindrical outer surface centering on the rotation axis of the roller 60. A through-hole 14g through which the base shaft portion 16c and the small-diameter portion 60a of the roller 60 are inserted is formed on the side surface of the mirror box 14. The through-hole 14g is an arc-shaped long hole along the movement locus of the base shaft portion 16c and the small-diameter portion 60a of the roller 60 when the movable mirror 15 is rotated, and the movable range of the movable mirror 15 from the down position to the up position. Therefore, the movement of the base shaft portion 16c and the roller 60 is not hindered. As shown in FIG. 6, the large-diameter portion 60 b of the roller 60 protrudes from the side surface of the mirror box 14 with the base shaft portion 16 c and the small-diameter portion 60 a inserted through the through-hole 14 g, and the movable mirror 15 is rotated. Accordingly, it is possible to abut against the first cam surface C1, the second cam surface C2, and the third cam surface C3 of the down absorption member 41 and the up absorption member 43.

  The operation of the mirror shock absorbing mechanism 40 will be described with reference to FIG. FIG. 10 shows a state where the movable mirror 15 is in the down position. At this time, the mirror sheet boss 16 b is pressed downward by the mirror drive lever 34 constituting the mirror drive mechanism 30, and the movable mirror 15 is held in the down position by the stopper portion 16 a of the mirror sheet 16 contacting the down positioning dowel 20. (FIG. 1). The down absorbing member 41 and the up absorbing member 43 are held at the buffer standby position by the urging forces of the down absorbing spring 42 and the up absorbing spring 44, respectively. As can be seen from FIG. 16, the gentle slope K1 is positioned in the outer diameter direction than the gentle slope K2, and when the movable mirror 15 is in the down position, it is down with respect to the large diameter portion 60b of the roller 60 provided on the mirror sheet 16. The first cam surface C1 of the absorbing member 41 and the gentle slope K1 are in contact with each other. The first cam surface C1 of the down absorbing member 41 in the mirror down state in FIG. 10 is an inclined surface in a direction in which resistance is provided via the roller 60 with respect to the rotation of the movable mirror 15 in the up position direction. The bounce of the movable mirror 15 from the position is limited.

  When the movable mirror 15 is rotated from the down position to the up position by the mirror drive lever 34 of the mirror drive mechanism 30, the large-diameter portion 60b of the roller 60 rolls on the first cam surface C1 in the initial stage. Then, the down absorbing member 41 is pressed, and the down absorbing member 41 is pressed and moved in the inner diameter direction from the buffer standby position of FIG. 10 against the urging force of the down absorbing spring 42. At this time, since the large diameter portion 60b of the roller 60 that rolls over the first cam surface C1 that is a slanted surface, the mirror driving mechanism does not cause a catch between the roller 60 and the down absorbing member 41. 30, the movable mirror 15 can be smoothly rotated from the down position to the up position. As the movable mirror 15 rotates in the up position direction, the large-diameter portion 60b of the roller 60 gets over the third cam surface C3 from the first cam surface C1 to the opposite position to the second cam surface C2 and the gentle slope K2. If it passes, the pressing state by the roller 60 will be cancelled | released and the down absorption member 41 will return to a buffer standby position with the urging | biasing force of the down absorption spring 42. FIG.

  When the movable mirror 15 approaches the up position, the large diameter portion 60b of the roller 60 of the mirror sheet 16 contacts the second cam surface C2 of the up absorbing member 43 as shown in FIG. Since the gentle slope K2 located in front of the second cam surface C2 is located on the inner diameter side of the gentle slope K1, the up-absorbing member before the large-diameter portion 60b of the roller 60 abuts against the second cam surface C2. There is no possibility that rotation of the movable mirror 15 is hindered by contacting the side surface of the wing part 52 of 43. At the time of FIG. 11, the movable mirror 15 has not reached the up position, and when the movable mirror 15 is further rotated toward the up position, the large diameter portion 60b of the roller 60 is moved to the second cam surface C2 as shown in FIG. Then, while rolling on the third cam surface C3, the up absorbing member 43 is pressed and moved from the buffer standby position to the inner diameter direction (direction approaching the mirror seat hinge 16x) against the urging force of the up absorbing spring 44. While the up absorbing member 43 is pressed from the buffer standby position by the roller 60, the load of the up absorbing spring 44 acts on the rotation of the movable mirror 15, and the movable mirror 15 includes the up absorbing member 43 and the up absorbing spring. It rotates while absorbing the shock by 44. The third cam surface C3 of the up-absorbing member 43 has a shape that gradually increases the protruding amount toward the outer diameter side with respect to the traveling direction of the roller 60 when the mirror is raised. While rolling while pressing the three cam surfaces C3, the load on the movable mirror 15 gradually increases, and immediately before the large diameter portion 60b of the roller 60 gets over the third cam surface C3 to the first cam surface C1 side. Maximum load.

  When the movable mirror 15 is rotated to the up position in FIG. 13, the upper surface of the mirror sheet 16 contacts the upper stopper 21, and further upward rotation is restricted (FIG. 1). In this mirror-up state, the large-diameter portion 60b of the roller 60 passes over the third cam surface C3 of the up-absorbing member 43 and reaches a position facing the first cam surface C1 and the gentle slope K1, and is pressed by the roller 60. The up-absorbing member 43 released from is returned to the buffer standby position by the urging force of the up-absorbing spring 44. Here, when a force that reverses the movable mirror 15 that has reached the up position in the down position direction is applied, the first cam surface C1 of the up absorbing member 43 and the large diameter portion of the roller 60 that have returned to the buffer standby position. Movement resistance acts by the contact relationship with 60b. In order for the movable mirror 15 to further rotate in the down position direction, it is necessary to press and move the up absorbing member 43 against the urging force of the up absorbing spring 44, but this is due to the driving force of the mirror driving mechanism 30. In contrast, in the bounce of the movable mirror 15 after reaching the up position, a force sufficient to move the energized up absorption member 43 is not applied, so the up absorption member 43 functions as a stopper that suppresses the mirror bounce.

  As described above, when the movable mirror 15 rotates from the down position to the up position, the load of the up absorption spring 44 is applied to the movable mirror 15 while the roller 60 pushes the up absorption member 43 from the buffer standby position. Acts and absorbs shock. And the repulsion rotation to the down position direction after the movable mirror 15 reaches an up position is restrict | limited by the up absorption member 43 which returned to the buffer standby position. Therefore, the bounce of the movable mirror 15 can be reliably suppressed and held in the up position by the up absorbing member 43 which is a single buffer member.

  Contrary to the mirror up operation described above, when the movable mirror 15 is rotated from the up position to the down position in FIG. 13 by the mirror drive lever 34 of the mirror drive mechanism 30, the large-diameter portion of the roller 60 at the initial stage. 60b presses the up absorbing member 43 while rolling on the first cam surface C1. Similarly to the down absorption member 41 in the initial stage of the mirror up operation, the up absorption member 43 whose first cam surface C1 is pressed by the large-diameter portion 60b of the roller 60 resists the urging force of the up absorption spring 44 and is buffered. Moved from position. Unlike when the mirror bounce occurs after reaching the up position as described above, a driving force in the down position direction by the mirror drive mechanism 30 acts on the movable mirror 15, so the movable mirror 15 presses and moves the up absorbing member 43. Rotate without stopping at the load.

  When the movable mirror 15 approaches the down position, the large diameter portion 60b of the roller 60 of the mirror sheet 16 abuts against the second cam surface C2 of the down absorbing member 41 as shown in FIG. Since the gentle slope K2 located in front of the second cam surface C2 is located on the inner diameter side of the gentle slope K1, the down-absorbing member before the large-diameter portion 60b of the roller 60 contacts the second cam surface C2. There is no possibility that rotation of the movable mirror 15 will be hindered by contacting the side surface of the wing part 52 of 41. At the time of FIG. 14, the movable mirror 15 has not reached the down position, and when the movable mirror 15 is further rotated toward the down position, the large-diameter portion 60b of the roller 60 is moved to the second cam surface C2 as shown in FIG. Then, while rolling on the third cam surface C3, the down absorbing member 41 is pressed and moved from the buffer standby position toward the mirror seat hinge 16x against the urging force of the down absorbing spring 42. While the down absorbing member 41 is pressed from the buffer standby position, the load of the down absorbing spring 42 acts on the rotation of the movable mirror 15, and the movable mirror 15 is impacted by the down absorbing member 41 and the down absorbing spring 42. It rotates while being absorbed. The third cam surface C3 of the down-absorbing member 41 has a shape that gradually increases the protruding amount toward the outer diameter side with respect to the traveling direction of the roller 60 when the mirror is down. While rolling while pressing the three cam surfaces C3, the load on the movable mirror 15 gradually increases, and immediately before the large diameter portion 60b of the roller 60 gets over the third cam surface C3 to the first cam surface C1 side. Maximum load.

  When the movable mirror 15 is rotated to the down position in FIG. 10, the stopper portion 16a contacts the down positioning dowel 20, and further downward rotation is restricted (FIG. 1). In this mirror-down state, the large-diameter portion 60b of the roller 60 passes over the third cam surface C3 of the down absorbing member 41 and reaches the position facing the first cam surface C1 and the gentle slope K1, and is pressed by the roller 60. The down-absorbing member 41 released from is returned to the buffer standby position by the urging force of the down-absorbing spring 42. Here, when a force is applied to reverse the movable mirror 15 that has reached the down position in the up position direction, the first cam surface C1 of the down absorbing member 41 and the large diameter portion of the roller 60 that have returned to the buffer standby position. Movement resistance acts by the contact relationship with 60b. In order for the bounced movable mirror 15 to further rotate in the up position direction, it is necessary to press and move the down absorbing member 41 against the urging force of the down absorbing spring 42, but due to the driving force of the mirror driving mechanism 30. Unlike the above, the bounce of the movable mirror 15 after reaching the down position does not apply a force enough to move the urged down absorption member 41, so the down absorption member 41 functions as a stopper that suppresses the mirror bounce. .

  As described above, when the movable mirror 15 rotates from the up position to the down position, the load of the down absorption spring 42 is applied to the movable mirror 15 while the down absorption member 41 is pressed and moved from the buffer standby position by the roller 60. Acts and absorbs shock. And the repulsion rotation to the up position direction after the movable mirror 15 reaches a down position is restrict | limited by the down absorption member 41 which returned to the buffer standby position. Accordingly, the bounce of the movable mirror 15 can be reliably suppressed and held in the down position by the down absorbing member 41 which is a single buffer member.

  As described above, in the mirror impact absorbing mechanism 40 of the camera 10 according to the present embodiment, the down absorbing member 41 that suppresses the bounce of the movable mirror 15 when the mirror is down, and the up absorber that suppresses the bounce of the movable mirror 15 when the mirror is up. Reference numeral 43 denotes a slide member 50 having a common specification. Further, the down absorption spring 42 and the up absorption spring 44 that urge the down absorption member 41 and the up absorption member 43 are also constituted by compression springs of common specifications. Therefore, it is possible to achieve a reduction in manufacturing cost by sharing parts while reliably suppressing the bounce of the movable mirror 15 at both the down position and the up position to improve continuous shooting performance.

  In the slide member 50, the surfaces (cam surfaces C 1, C 2 and C 3, gentle slopes K 1, K 2) pressed by the large-diameter portion 60 b of the roller 60 on the movable mirror 15 side are asymmetric with respect to the virtual center line G in the width direction. It is a simple shape and is assembled with the front and back reversed when used as the down absorbent member 41 and when used as the up absorbent member 43. As a result, when the movable mirror 15 is in contact with the large diameter portion 60b of the roller 60 in the middle of rotation, when the movable mirror 15 is pressed and moved in the inner diameter direction by the large diameter portion 60b of the roller 60, the movable mirror 15 rotates. Both the down absorbing member 41 and the up absorbing member 43 have the same specifications while optimizing the load characteristics when holding the large-diameter portion 60b of the roller 60 in the state of reaching the down position or the up position as the moving end. The slide member 50 can be used.

  Moreover, the smooth operation | movement is implement | achieved by using the roller 60 which can rotate the site | part by the side of the movable mirror 15 which contact | abuts the down absorption member 41 or the up absorption member 43. FIG.

  Note that, unlike the configuration described above, the third cam surface C3 of the slide member 50 can be set to a symmetrical shape with respect to the virtual center line G. Specifically, the third cam surface C3 can be formed as an arc-shaped surface having a constant radius centered on the axis of the mirror sheet hinge 16x. In this case, the load applied to the roller 60 is always equal while the large-diameter portion 60b of the roller 60 is moving on the third cam surface C3. Further, the shapes of the first cam surface C1 and the second cam surface C2 can be different from the configurations described above. For example, in the illustrated configuration, the first cam surface C1 and the second cam surface C2 are formed as surfaces having substantially the same inclination angle in the forward and reverse directions with respect to the virtual center line G of the slide member 50 (see FIG. 16). It is also possible to make the inclination angles of the first cam surface C1 and the second cam surface C2 different from each other. Since the load on the roller 60 changes according to the inclination angle of the cam surface, the setting that the inclination angle of the first cam surface C1 is increased with an emphasis on the bounce suppression effect of the movable mirror 15 after mirror up or after mirror down, Further, the setting may be made such that the inclination angle of the second cam surface C2 is increased with emphasis on the buffering performance in the middle of the mirror up operation or the mirror down operation. That is, the shapes of the cam surfaces C1, C2, and C3 in the slide member 50 can be appropriately selected according to the intended load setting for the movable mirror 15.

  As mentioned above, although demonstrated based on illustration embodiment, this invention is not limited to this. For example, in the mirror impact absorbing mechanism 40 of the illustrated embodiment, the roller 60 provided on the mirror sheet 16 constituting the movable mirror 15 is configured to abut against the down absorbing member 41 and the up absorbing member 43. Alternatively, it is also possible to provide a driven member that moves following the rotation of the movable mirror 15, and this driven member is brought into contact with the down absorbing member 41 or the up absorbing member 43. In this case, the driven member constitutes a pressing portion on the movable mirror 15 side.

  Further, the pressing part on the movable mirror 15 side is preferably the rotatable roller 60 as described above, but it is also possible to bring the non-rotating part into contact with the down absorbing member 41 or the up absorbing member 43.

DESCRIPTION OF SYMBOLS 10 Single-lens reflex camera 11 Camera body 12 Lens barrel 13 Lens mount 14 Mirror box 14a 14b 14c 14d Guide pin 14e 14f Spring support protrusion 14g Through-hole 15 Movable mirror (quick return mirror)
15a Main mirror 16 Mirror sheet 16a Stopper portion 16b Mirror sheet boss 16c Base shaft portion 16x Mirror sheet hinge (rotating shaft of movable mirror)
17 Sub-mirror 18 Focal plane shutter 19 Image sensor (light-receiving medium for imaging)
20 Down positioning dowel 21 Upper stopper 22 Viewfinder optical system 22a Viewfinder window 23 Metering unit 24 Distance measuring unit 25 LCD monitor 30 Mirror drive mechanism 31 Motor 32 Reduction gear train 33 Cam gear 34 Mirror drive lever 34x Mirror drive lever shaft 35 Shutter charge lever 40 Mirror shock absorbing mechanism 41 Down absorbing member (first buffer member)
42 Down absorption spring (biasing member)
43 Up absorption member (second buffer member)
44 Up absorption spring (biasing member)
45 Holding plate 50 Slide member (buffer member with common specifications)
51 52 Wings 53 Intermediate bridge 54 55 Guide hole 56 Spring storage 57 Spring support protrusion 60 Roller (pressing part, rotating contact part)
60a Small diameter portion 60b Large diameter portion C1 First cam surface (inclined cam surface)
C2 Second cam surface (inclined cam surface)
C3 3rd cam surface (outer edge cam surface)
K1 gentle slope K2 gentle slope

Claims (5)

A finder light guide position that is located on the photographing optical path and reflects the subject light to the observation optical system, and a retreat position that is retracted from the photographing optical path and allows the subject light to pass to the imaging light receiving medium side is supported rotatably. In a camera with a movable mirror,
A pressure that is supported so as to be able to move straight in a direction crossing the rotation trajectory of the movable mirror, and that moves with the rotation of the movable mirror when the movable mirror rotates from the retracted position to the finder light guide position. A first buffer member that is pressed and moved by the unit to absorb the impact of the movable mirror;
The movable mirror is supported so as to be able to move straight in a direction intersecting the rotation locus of the movable mirror. When the movable mirror is rotated from the finder light guide position to the retracted position, it is pressed and moved by the pressing portion to impact the movable mirror. A second buffer member for absorbing ;
An urging member that urges the first buffer member and the second buffer member to hold the buffer member in a buffer standby position that advances on the movement locus of the pressing portion ;
A movable mirror shock absorbing mechanism for a camera, wherein the first buffer member and the second buffer member are made of a buffer member having a common specification. 2. The movable mirror shock absorbing mechanism for a camera according to claim 1, wherein the biasing member moves and biases the first buffer member and the second buffer member in a direction away from a rotation center of the movable mirror. The first buffer member and the second buffer member are movable mirror shock absorbing mechanisms of a camera that are pressed and moved by the pressing portion in a direction opposite to the moving biasing direction. 3. The movable mirror shock absorbing mechanism for a camera according to claim 2, wherein the buffer member of the common specification is asymmetric with respect to a virtual center line passing through the center in the width direction in which the surface pressed by the pressing portion is parallel to the linear movement direction. A movable mirror shock absorbing mechanism for a camera having a shape and supported by the first buffer member and the second buffer member with the front and back reversed. 4. The movable mirror shock absorbing mechanism for a camera according to claim 2, wherein the buffer member of the common specification is an outer edge cam surface located at an outer edge portion far from a rotation center of the movable mirror, and on both sides of the outer edge cam surface. Having a pair of inclined cam surfaces that incline in a direction that gradually approaches the rotational center of the movable mirror as it is connected and away from the outer edge cam surface;
When the first buffer member and the second buffer member are held at the respective buffer standby positions, the outer edge cam surface and the pair of inclined cam surfaces advance on the movement locus of the pressing portion,
When the movable mirror rotates from the retracted position to the finder light guide position, the pressing portion presses one of the inclined cam surface and the outer edge cam surface of the first buffer member to move from the buffer standby position. When the movable mirror reaches the finder light guide position, the pressing portion is opposed to the other inclined cam surface, and the first buffer member returns to the buffer standby position.
When the movable mirror rotates from the finder light guide position to the retracted position, the pressing portion presses one of the inclined cam surface and the outer edge cam surface of the second buffer member to move from the buffer standby position. When the movable mirror is moved and the movable mirror reaches the retracted position, the movable mirror shock absorbing mechanism of the camera in which the second buffer member returns to the buffer standby position with the pressing portion facing the other inclined cam surface. 5. The movable mirror shock absorbing mechanism for a camera according to claim 1, wherein the pressing portion has an axis parallel to a rotation center of the movable mirror on a side portion of a mirror support member that holds the movable mirror. A movable mirror shock absorbing mechanism for a camera, which is composed of a rotating contact portion provided rotatably at the center.

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