JP4477891B2 - Pop-up strobe - Google Patents

Description

  The present invention relates to a pop-up strobe of a camera.

  In general, in a camera, if the light emitting part of the strobe is too close to the photographic optical axis or too far behind the optical axis, the part located in front of the light emitting part (lens barrel, lens hood, conversion lens) May cause vignetting of strobe light. For example, various cameras have pop-up type strobes that can move the light-emitting part between the position stored in the camera body and the protruding position. However, it is easy to be restricted by the camera body. On the other hand, giving priority to the optical performance of the strobe may increase the size of the camera or affect the camera design.

  Further, the pop-up strobe is generally spring-biased in the protruding direction, and the storing operation is performed manually against the spring. There is a demand to improve the operability of manual storage as much as possible.

  An object of the present invention is to provide a pop-up strobe that can effectively prevent vignetting of strobe light and has excellent operability during storage.

The pop-up strobe of the present invention is a slide member supported on the camera body so as to be able to advance and retract between an advancing position approaching the subject and a retracting position retracting; a storage position accommodated in the camera body on the slide member; A light emitting unit supported rotatably at a protruding position protruding from the camera body ; a roller provided on the camera body and rotatable about an axis substantially parallel to the rotation axis of the light emitting unit; A roller contact surface provided on the light emitting section unit so as to be decentered from the rotating shaft , and the light emitting section unit is directed from the protruding position to the storage position in a state where the slide member is in the advanced position. is rotated Te, and characterized in that the roller abutment surface abuts against the roller, the guiding of the roller contact surface and roller, the light emitting section unit and the slide member is moved to the retracted position direction To have.

  The roller contact surface preferably includes a curved surface at least partially. Specifically, the roller contact surface may be constituted by a concave curved surface and a convex curved surface that are continuous in the radial direction about the rotation axis of the light emitting unit.

  The light emitting unit has a support arm having one end pivotally supported by the slide member and the other end having a light emitting unit, and the roller contact surface is provided near the end of the support arm on the light emitting unit side. Preferably it is.

  A pair of roller contact surfaces and rollers may be provided corresponding to both sides of the light emitting section.

  The pop-up strobe of the present invention further includes a slide member urging unit that urges the slide member toward the advanced position, a light emitting unit urging unit that urges the light emitting unit toward the protruding position, the slide member urging unit, It is preferable that a locking mechanism is provided that holds the slide member in the retracted position and holds the light emitting unit in the retracted position against the light emitting unit urging means.

  According to the present invention described above, it is possible to effectively prevent vignetting of the strobe light and to obtain a pop-up strobe excellent in operability during storage.

  Hereinafter, the present invention will be described based on illustrated embodiments. The digital camera 10 has a camera body 11 having a photographing optical system. The camera body 11 has a box (square tube) shape that is long in the direction along the optical axis O of the photographic optical system, and its outer surfaces are a body front end surface 11a and a body rear end surface 11b that are substantially orthogonal to the optical axis O. The front end surface 11a and the body rear end surface 11b are connected to each other to form a body upper surface 11c, a body lower surface 11d, a body right side surface 11e, and a body left side surface 11f that surround the optical axis O. In the present embodiment, the vertical direction in FIGS. 3, 11, and 12 is the vertical direction in the digital camera 10, and the horizontal direction is the horizontal direction. More specifically, the right-hand direction when the viewpoint is positioned on the body rear end surface 11b side with respect to the digital camera 10 (state in FIG. 3) is defined as right, and the left-hand direction is defined as left. Further, a direction parallel to the optical axis O (hereinafter referred to as an optical axis direction) is defined as a front-rear direction in the digital camera 10, and the body front end surface 11a side is defined as the front and the body rear end surface 11b side is defined as the rear.

  A front lens LF located closest to the subject in the photographic optical system is exposed on the body front end surface 11 a of the camera body 11. The front lens LF may be a single lens or a lens group. A filter screw 12 to which accessories such as a filter can be attached is provided around the front lens LF. The photographing optical system is a zoom lens system, and includes a plurality of lens groups in addition to the front lens LF (not shown). The photographing optical system is an inner zoom and inner focus type photographing optical system in which the lens barrel is not extended during zooming and focusing, and the front lens LF does not move forward from the illustrated position.

  Operation-related buttons such as a power button 13, a mode dial 14, a playback button 15, a menu button 16, and a multi-directional button 17 are provided on the body upper surface 11c of the camera body 11 in a region close to the body rear end surface 11b. . The power button 13 is an operation member for turning on and off the main switch of the digital camera 10, the mode dial 14 is an operation member for selecting various shooting modes, and the playback button 15 is used to display a recorded image on a liquid crystal display (liquid crystal panel, image). This is an operation member for displaying (reproducing) on the (display surface) 32. Further, when the menu button 16 is operated, various setting modes are entered, and the function can be selected and set by operating the multi-directional button 17. The multidirectional button 17 is also used for switching images to be reproduced. Setting items by the menu button 16 are a recording screen size, image quality, white balance, sensitivity, and the like, but are not limited thereto. The multi-directional button 17 is a momentary switch that can be operated in a plurality of directions. For example, the multi-directional button 17 can be pressed in two orthogonal axes (four directions) and pressed at the intersection of the two axes. A pop-up strobe 18 is disposed in front of these buttons. The pop-up strobe 18 can be switched between a pop-up state in which the light-emitting portion projects upward from the camera body 11 and a storage state in which the light-emitting portion is housed in the body upper surface 11c. Indicates the state. A memory card lid 19 is provided in the vicinity of the ridgeline between the body upper surface 11c and the body right side surface 11e. When the memory card cover 19 is opened, an opening of a memory card slot (not shown) is exposed, and a memory card for recording image data can be inserted into and removed from the memory card slot.

  On the left side surface 11f of the body 11 of the camera body 11, a strobe mode button 20, a self-continuous shooting button 21, Focus mode buttons 22 are arranged at substantially equal intervals in the optical axis direction. The strobe mode button 20 is an operation member used for controlling the light emitting unit of the pop-up strobe 18 and can switch between strobe related modes such as forced light emission, light emission stop, and red-eye prevention light emission mode. The self-continuous shooting button 21 is an operation member for selecting a drive mode at the time of shooting. In addition to a normal drive mode (only one shot is taken simultaneously with the shutter release operation), a self-timer shooting mode, an auto bracket mode, etc. Can be selected. The focus mode button 22 is an operation member for selecting a focus mode, and can select a macro shooting mode, an infinity shooting mode, a manual focus mode, and the like in addition to a normal autofocus mode. In addition, a speaker opening 23 is formed slightly forward of the strobe mode button 20 on the left side surface 11f of the body, and an external connector cover 24 is provided below the speaker opening 23. The external connector cover 24 can be opened and closed (or detached) with respect to the left side surface 11f.

  On the body rear end surface 11b side of the camera body 11, a liquid crystal monitor block (image display unit) 25 is supported via a hinge portion 26 provided at a ridge (boundary) portion between the body rear end surface 11b and the body upper surface 11c. ing. The hinge portion 26 includes a pair of support arms 27 provided on the camera body 11 side so as to be separated in the left-right direction, an intermediate support portion 28 that is sandwiched between the pair of support arms 27 and supports the liquid crystal monitor block 25, and an intermediate support. A pair of shaft pins 29 projecting from the portion 28 in the left-right direction and rotatably inserted into the shaft holes in the respective support arms 27 are provided, and the support arm 27 and the intermediate support portion 28 are rotated relative to each other via the shaft pins 29. It is possible to move. The axis X1 of the axis pin 29 is directed in the left-right direction of the camera orthogonal to the optical axis O, and the liquid crystal monitor block 25 is on the rearward extension of the optical axis O and adjacent to the body rear end surface 11b. It is possible to rotate between the storage position (FIGS. 4 and 9) to be performed and the standing position (FIG. 8) in which the edge on the opposite side of the intermediate support portion 28 is lifted to a position higher than the hinge portion 26. In the storage position, the liquid crystal display unit 32 of the liquid crystal monitor block 25 is positioned in a plane substantially orthogonal to the optical axis O. Further, the position indicated by a two-dot chain line in FIG. 8 is the maximum standing position of the liquid crystal monitor block 25. The rotation angle between the storage position and the maximum standing position in the liquid crystal monitor block 25 is preferably 180 degrees or more, and is set to about 210 degrees in this embodiment.

  The liquid crystal monitor block 25 is also supported by the intermediate support portion 28 so as to be rotatable about an axis X2 orthogonal to the axis X1. Specifically, a shaft pin 30 is provided in the frame portion 25a of the liquid crystal monitor block 25 in the direction of the axis X2, and a shaft hole into which the shaft pin 30 is rotatably inserted is formed in the intermediate support portion 28. Has been. Accordingly, the liquid crystal monitor block 25 can rotate around the axis X1 and rotate around the axis X2 with respect to the camera body 11. In addition, the relationship between the shaft pin and the shaft hole in the hinge portion 26 can be reversed from the above description. That is, in the relationship between the support arm 27 (camera body 11) and the intermediate support portion 28, a shaft pin may be provided on the support arm 27 side, and a shaft hole may be formed on the intermediate support portion 28 side. In relation to the intermediate support portion 28, a shaft pin may be provided on the intermediate support portion 28 side and a shaft hole may be formed on the liquid crystal monitor block 25 side.

  The frame portion 25a of the liquid crystal monitor block 25 has four side edges that surround the rectangular liquid crystal display portion 32, and the liquid crystal monitor block 25 is adjacent to the body rear end face 11b as shown in FIGS. In the stowed position, the edges and sides of the three sides excluding the edge in contact with the intermediate support portion 28 are sized and shaped so as to be substantially flush with the body lower surface 11d, the body right side surface 11e, and the body left side surface 11f, respectively ( 3 to 9).

  When the liquid crystal display unit 32 is rotated from the state of FIG. 4 where the liquid crystal display unit 32 is opposed to the body rear end surface 11b about the axis X1 and is erected as shown in FIG. 8, the liquid crystal display unit 32 brings the photographer up. It becomes possible to use (view) the liquid crystal display unit 32 as a monitor. FIG. 8 shows the state in which the liquid crystal monitor block 25 is raised about 180 degrees and the aforementioned maximum standing position, but the hinge portion 26 can stop the liquid crystal monitor block 25 at any other angular position. Equipped with a simple friction (or click) mechanism.

  In addition, as shown in FIG. 10, the liquid crystal display block 32 can be directed forward by rotating the standing liquid crystal monitor block 25 about the axis X2. The state in which the liquid crystal display unit 32 is directed forward is suitable for face-to-face photography in which the photographer uses himself as a subject. Further, when the liquid crystal monitor block 25 is rotated in the storage direction about the axis X1 in the face-to-face shooting state, and the liquid crystal display unit 32 is at an angle that is substantially parallel to the body upper surface 11c of the camera body 11, the waist level shooting is performed. It will be in a suitable state. Further, when the liquid crystal monitor block 25 is rotated from this state toward the body rear end surface 11b about the axis X1, the liquid crystal display unit 32 is not opposed to the body rear end surface 11b, contrary to FIG. The state shown in FIG. 9 exposed at the rear end of the liquid crystal display unit 32 can be seen without the liquid crystal monitor block 25 protruding (standing) from the camera body 11. 8 and 9, the top-and-bottom direction on the display screen of the liquid crystal display unit 32 is reversed, but the digital camera 10 includes detection means for detecting a change in the position state of the liquid crystal monitor block 25, and Image control means for displaying an image in an appropriate state (correct in the vertical direction as viewed from the photographer) on the liquid crystal display unit 32 based on the detection means. When the digital camera 10 is transported or the like, it is preferable to protect the liquid crystal display unit 32 by making the liquid crystal display unit 32 face the body rear end face 11b as shown in FIG.

  A grip 40 for gripping is provided on the body right side surface 11 e side of the camera body 11. The grip 40 has an elongated box shape (square tube) like the camera body 11, and its outer surface is substantially orthogonal to both grip end surfaces 40a and 40b that are spaced apart in the longitudinal direction, and the grip end surfaces 40a and 40b. And four longitudinal surfaces 40c, 40d, 40e, and 40f extending in the longitudinal direction. Among these surfaces, the set of both grip end surfaces 40a and 40b, the set of longitudinal surfaces 40c and 40d, and the set of longitudinal surfaces 40e and 40f are in a substantially parallel relationship. A storage chamber (battery storage chamber) for a battery 42 (FIG. 1), which is a driving power source for the digital camera 10, is formed in the grip 40, and a battery lid 43 capable of opening and closing the battery storage chamber is formed on the grip end surface 40a side. It is said.

  The grip 40 is supported to be rotatable with respect to the camera body 11 via a grip rotation shaft 41. The grip rotation shaft 41 is provided so as to connect the body right side surface 11e and the longitudinal surface 40f, which are opposed surfaces of the camera body 11 and the grip 40, and an axis line X3 thereof is an axis pin of the hinge portion 26. 29 is substantially parallel to the axis X1. The position of the grip rotation shaft 41 (axis line X3) in the longitudinal direction of the grip 40 is set eccentrically in the vicinity of the grip end surface 40b. Therefore, the grip 40 has a grip end surface 40a (as shown in FIGS. 4 to 7). The end on the battery lid 43 side is rotated so as to draw an arcuate locus centering on the axis X3.

  4 and 5 show one (storage end) and the other (projecting end) of the rotation end of the grip 40, both of which have a longitudinal direction of the grip 40 and a longitudinal direction (optical axis direction) of the camera body 11. Although they are substantially parallel, the orientations of the grip end faces 40a and 40b are reversed. 4, the grip end surface 40a (battery cover 43) faces forward, and the outer shape of the grip 40 is within the contour of the right side surface 11e of the body in the front-rear direction and the vertical direction of the camera. In other words, in the state of FIG. 4, the entire length in the longitudinal direction of the grip 40 is within the longitudinal width (position in the optical axis direction) of the camera body 11, and the lateral width (longitudinal surface 40c, 40d) is within the vertical width of the camera body 11, and the grip 40 does not protrude in the front-rear direction and the vertical direction with respect to the camera body 11. That is, the grip 40 and the camera main body 11 form a continuous box-like body, and are in a storage state that is easy to carry. Further, since the grip 40 does not protrude downward, the camera can be stably placed on a floor or a desk, and is suitable for photographing in such a placed state. In particular, at the storage end, the longitudinal surface 40d (lower surface) of the grip 40 is substantially flush with the body lower surface 11d of the camera body 11 (see FIGS. 3 and 11), and the body lower surface 11d faces downward. Stability is improved when the digital camera 10 is placed.

  When photographing, the grip 40 may be rotated clockwise from the storage end in FIG. The grip rotation shaft 41 includes a friction (or click) mechanism that can stop the grip 40 at an arbitrary angle up to the protruding end of FIG. 5 in which the grip end surface 40a (battery cover 43) faces rearward. 40 angular positions can be determined by the photographer's preference. As described above, the angle of the liquid crystal monitor block 25 can be adjusted around the axis line X1 and the axis line X2, and the angle of the grip 40 can also be adjusted independently of the axis line X3 so that the degree of freedom is high. A shooting posture can be obtained. In particular, the rotation center (axis line X1) of the liquid crystal monitor block 25 and the rotation center (axis line X3) of the grip 40 are made parallel to the left-right direction of the camera, so that the holding performance and the visibility of the monitor are not impaired. It is possible to freely change the height position of the camera and the elevation angle (vertical angle) of the camera.

Further, as shown in FIGS. 11 and 12, the grip rotation shaft 41 is configured so that the grip 40 can be brought into and out of contact with the camera body 11 in the direction along the axis X3 (left-right direction). This contact / separation operation can be performed independently of the rotation about the axis X3. For example, when the grip 40 is at the storage end in FIG. 11 (state shown in FIG. 11), the projecting amount of the grip 40 from the camera body 11 can be reduced to a compact state. On the other hand, at the time of shooting for gripping the grip 40, the grip 40 is slid and separated from the camera main body 11 by a predetermined amount as shown in FIG. The interference of the surface 11e) is avoided and the holding performance is improved. FIG. 12 shows a state in which the longitudinal direction of the grip 40 is substantially parallel to the longitudinal direction of the camera body 11. From this state, the grip 40 is rotated about the axis X 3 and set to an arbitrary angle. Can do.

As described above, the grip 40 is a box-like body having three pairs of plane portions (both grip end surfaces 40a and 40b and longitudinal surfaces 40c, 40d, 40e, and 40f) on the outer surface. is there. In this grip 40, an inclined surface 40g connecting the grip end surface 40b and the longitudinal direction surface 40c is further formed on the outer surface in the vicinity of the grip end surface 40b on the side close to the grip rotation shaft 41. ridge portions in contact with the direction plane 40 d is chamfered arcuate surface 40h is formed. The inclined surface 40g, the grip end surfaces 40a and 40b (the arcuate surface 40h), and the longitudinal surfaces 40c and 40d constitute a surrounding surface that is substantially parallel to the axis X3 of the grip rotation shaft 41 and surrounds the axis X3. . The inclined surface 40g is a plane that is not parallel to any of the other outer surfaces of the grip 40. A shutter button (first operation member, operation member for image recording) 45 is provided on the inclined surface 40g, and an annular zoom operation lever 46 surrounding the shutter button 45 is provided. The arcuate surface 40h is a curved surface having a positive curvature toward the outside of the grip 40, and a recording button (second operation member, operation member for image recording) 47 is provided on the arcuate surface 40h. Yes. The shutter button 45 is an operation member for taking a still image, and can perform photometry and distance measurement by half-pressing the button, and shutter release (still image taking) can be performed by fully pressing the button. The shooting mode and the like at this time are appropriately set by the above-described operation members. On the other hand, the recording button 47 is an operation member for shooting a moving image. When the recording button 47 is pressed, recording of the moving image is started, and when the pressing is released, the recording is stopped. Both still images and moving images are recorded on the memory card as electronic image data through processing by the image processing means.

  As shown in FIG. 4, the inclined surface 40g is formed so as to be non-parallel and non-orthogonal with respect to the longitudinal line S of the grip 40 passing through the middle between the longitudinal surfaces 40c and 40d. The inclination angle K1 of the inclined surface 40g with respect to the longitudinal direction line S may be between 15 degrees and 75 degrees, more preferably between 30 degrees and 60 degrees. The shutter button 45 provided on the inclined surface 40g faces the front (front) of the camera at the angular position of FIG. 6 where the grip end surface 40a (battery cover 43) of the grip 40 faces obliquely downward and rearward. In a general photographing posture in which the digital camera 10 is held at or near the eye level of the photographer, it is assumed that the grip 40 is located within a predetermined range of forward and reverse angles with the angular position in FIG. 6 as the center. . In consideration of the shape of the human hand, if the shutter button 45 is facing substantially the front of the camera in a state where the grip 40 faces obliquely downward and rearward, it becomes easier to perform a pressing operation with the index finger.

  Since the recording button 47 is provided on the grip end surface 40b adjacent to the inclined surface 40g in a non-orthogonal relationship, when the grip 40 is at the angular position in FIG. When the direction and the forefinger are put on the shutter button 45, the recording button 47 naturally corresponds to the position of the thumb. Here, the recording button 47 is provided on an arcuate surface 40h that is further chamfered (having a positive curvature) also on the grip end surface 40b, and as shown in FIG. With respect to the longitudinal direction line S of the grip 40 passing through the middle, the grip 40 protrudes in a direction substantially opposite to the shutter button 45. By tilting the recording button 47 in this way, the photographer's thumb comes into contact with the recording button 47 more naturally, and the operability is further improved. The inclination angle K2 of the recording button 47 with respect to the longitudinal direction line S is preferably about the same as the inclination angle K1 of the shutter button 45 (inclined surface 40g).

  Therefore, when the grip 40 is at an angular position in FIG. 6 where the grip 40 faces obliquely downward, or at an angular position within a predetermined range before and after the grip 40, the shutter button 45 faces substantially in front of the camera and the recording button 47 faces substantially upward. When the index finger is put on the shutter button 45, the recording button 47 naturally corresponds to the position of the thumb. That is, in the grip 40, the shutter button 45 and the recording button 47 are provided at positions where a pressing operation can be easily performed when the grip 40 is rotated to the use position in the photographing state.

  The angle of the grip 40 in the shooting state is not limited to FIGS. For example, in a shooting posture with the camera placed above the head, the grip 40 may be positioned at an angle in which the grip end surface 40a (battery cover 43) is directed in a substantially vertical direction as shown in FIG. In this case, since the photographer's arm extends substantially parallel to the longitudinal direction of the grip 40, the index finger and the thumb are naturally applied to the shutter button 45 and the recording button 47, respectively, as in FIG. It can be done without difficulty.

  The grip 40 is supported by the grip rotation shaft 41 at a position eccentric to the one end 40b side in the longitudinal direction. On the other hand, the shutter button 45 and the recording button 47 are arranged eccentrically at positions relatively close to the grip rotation shaft 41 in the radial direction around the grip rotation shaft 41 (axis line X3). The positional displacement with respect to the camera body 11 when the grip 40 is rotated is small, and the operability is not easily lost. Further, the shutter button 45 and the recording button 47 are located on substantially the same circumferential surface with the grip rotation shaft 41 (axis line X3) as the center, and even if the grip 40 is rotated, the shutter button 45 and the recording button 47 are separated from the grip rotation shaft 41. Each distance does not change. This also makes it difficult for the operability to be impaired.

  As described above, the shutter button 45 and the recording button 47 are arranged to be easily operated at any angular position of the grip 40.

  A tripod screw hole 48 opened downward is formed in the lower body surface 11d of the camera body 11 (see FIG. 4). Since the liquid crystal monitor block 25 and the grip 40 are supported on the body rear end surface 11b and the body right side surface 11e, respectively, the liquid crystal monitor block 25 and the grip 40 do not overlap the lower surface 11d of the body even if they rotate. The tripod screw hole 48 is not blocked. Therefore, it is possible to perform photographing using a tripod without any trouble while providing the rotating type grip 40 and the liquid crystal monitor block 25. Further, as described above, if the grip 40 is rotated to the storage end, the camera can be stably supported without a tripod. That is, the digital camera 10 of the present embodiment is compatible with various shooting modes other than hand-held.

  When handheld shooting is performed with the digital camera 10 having the pivotable grip 40 as described above, a general shooting posture is to hold the camera body 11 with the left hand while holding the grip 40 with the right hand. At this time, the left hand supports the lower surface 11d of the body with the palm and puts the thumb along the left side surface 11f of the body. Here, since the operation member is not provided on the lower body surface 11d having the largest contact area with the left hand, there is no possibility of erroneous operation. Further, on the left side surface 11f of the body along with the left thumb, there are provided operation members for image recording setting that are frequently used in the shooting state, such as a strobe mode button 20, a self-continuous shooting button 21, and a focus mode button 22. The image recording can be set without changing the shooting posture.

  Further, when the recorded still image or moving image is reproduced on the liquid crystal display unit 32, a use posture in which a finger is mainly applied to the body upper surface 11c of the camera main body unit 11 is assumed. Correspondingly, operation members for image reproduction such as the reproduction button 15 and the multi-directional button 17 are provided on the body upper surface 11c, and it is easy to operate while holding the camera body 11 in the above posture. It has become. Note that when the image is reproduced, the grip 40 may be positioned at the storage end and the right hand may hold the camera body 11.

  FIGS. 13 to 16 show the arrangement of the electrical system in the camera body 11. A holding frame 50 that supports the photographing optical system is provided in the camera body 11. The holding frame 50 is formed of a cylindrical body whose axis is directed in the optical axis direction, an opening 50a for supporting the front lens LF is formed at the front end, and the CCD 51 is held via the CCD substrate 52 on the rear end side. Yes. In this embodiment, an integral member called the holding frame 50 is used to make the position of the photographing optical system easy to understand. However, the support member of the photographing optical system may not be such an integral member.

The CCD 51 constitutes a photographing optical system together with the front lens LF and the like. The CCD substrate 52 is located between the rear end portion of the holding frame 50 and the body rear end surface 11b, and is arranged in a planar shape substantially orthogonal to the optical axis O. Between the holding frame 50 and the body upper surface 11c, a first switch substrate 53 having a planar shape substantially parallel to the body upper surface 11c is disposed. The first switch board 53 is provided with contacts of the power button 13, the mode dial 14, the playback button 15, the menu button 16, and the multidirectional button 17. Between the holding frame 50 and the body left side surface 11f, a second switch substrate 54 having a planar shape substantially parallel to the body left side surface 11f is disposed. The second switch board 54 is provided with contacts of the strobe mode button 20, the self-continuous shooting button 21, and the focus mode button 22. Between the holding frame 50 and the body lower surface 11d, a jack substrate 55 having a planar shape substantially parallel to the body lower surface 11d is disposed. The jack board 55 is provided with a PC jack 56 used for connection with a personal computer and an adapter jack 57 to which a power adapter is connected. The PC jack 56 and the adapter jack 57 face the body left side surface 11 f of the camera body 11, and are exposed to the outer surface side of the digital camera 10 by opening the external connector cover 24. A main board 58 having a planar shape substantially parallel to the body right side surface 11e is disposed between the holding frame 50 and the body right side surface 11e. The main board 58 is provided with a microcomputer for controlling the entire digital camera 10 and a circuit for image processing. The main board 58 is longer in the optical axis direction than the first switch board 53, the second switch board 54, and the jack board 55. It is a member. The CCD substrate 52 and the first switch substrate 53 are connected to the main substrate 58 via FPCs 59 and 60, respectively. The second switch board 54 is connected to the first switch board 53 by the FPC 61, and sends a signal to the main board 58 via the first switch board 53. The jack board 55 is connected to the main board 58 via the connector 62.

  As can be seen from FIGS. 13 to 16, the photographing optical system (holding frame 50) of the digital camera 10 is in a space surrounded by a circuit board composed of the CCD board 52, the first switch board 53, the jack board 55, and the main board 58. Has been placed. More specifically, the photographing optical system of the present embodiment is a type in which the lens barrel is not extended during zooming and focusing, and is always within the camera body 11 without protruding forward. The above-described substrates are arranged inside the camera body 11 so as to surround the photographing optical system. This circuit arrangement improves the space efficiency of the electrical system and contributes to the miniaturization of the camera and the improvement of design freedom. In particular, in the present embodiment, the camera body 11 has a box shape (square tube) that is long in the optical axis direction, and a first switch board 53, a second switch board 54, a jack board 55, It is effective to arrange the main board 58.

  In the present embodiment, a rotatable grip 40 is disposed on the body right side surface 11e side of the camera body 11. On the surface on which the movable member such as the grip 40 is provided, switches and terminals (jacks) exposed on the outer surface of the camera may not be arranged to avoid being covered or interfered with the movable member. preferable. Therefore, the first switch board 53, the second switch board 54 provided with switch contacts, and the jack board 55 provided with terminals are provided on the inner surfaces of the body upper surface 11c, the body lower surface 11d, and the body left side surface 11f other than the body right side surface 11e. Are arranged along. The main board 58 that does not need to be connected to the outer surface of the camera is disposed on the inner surface side of the right side surface 11e by utilizing the fact that switches and terminals are not (cannot) be disposed on the right side surface 11e side. Like to do. As can be seen from FIGS. 14 and 15, the space on the inner surface of the right side surface 11e of the body is entirely allocated to the main board 58, and the main board 58 having a shape substantially equal to the entire length of the holding frame 50 in the optical axis direction is employed. It is possible.

  Also, no switches or terminals are provided on the body rear end surface 11b side which supports the liquid crystal monitor block 25 which is a movable member similar to the grip 40, and the main board is disposed on the inner surface side of the body rear end surface 11b. Similar to 58, a CCD substrate 52 that does not require connection with the camera outer surface side is disposed. Since the space on the inner surface side of the rear end surface 11b of the body faces the rearmost end portion of the photographing optical system, it is most preferable to arrange the CCD substrate 52 in the space from the viewpoint of space and circuit efficiency.

  As can be seen from the above description, in the digital camera 10 of the present embodiment, the liquid crystal monitor block 25 and the grip 40 can be individually rotated, so that the degree of freedom of the shooting posture is increased and the operability is improved. . Further, the shutter button 45 and the recording button 47 are easy to operate regardless of the rotation position of the grip 40 (at any angular position).

  In the digital camera 10 according to the embodiment, the circuit arrangement in the camera body 11 and the arrangement of the operation members on the outer surface of the camera body 11 are devised as described above, and the functionality as the camera body 11 is high. .

  Next, the pop-up flash 18 will be described with reference to FIG. 17 and 18 show the internal structure of the upper half of the camera body 11 with the exterior parts removed. A body member 33 is provided in the camera body 11, and a strobe storage portion 33a is formed on the upper surface side of the body member 33 (see FIGS. 19 to 21). The pop-up strobe 18 includes a light emitting unit 34 that can be accommodated in the strobe accommodating portion 33a, and a slide member 35 that supports the light emitting unit 34 and is supported on the body member 33 so as to be able to advance and retreat.

  The body member 33 is provided with a slide guide shaft 65 having a uniform cross section that faces the front-rear direction of the camera body 11 (direction substantially parallel to the optical axis O). As shown in FIG. 19, both end portions of the slide guide shaft 65 are fixed to the body member 33, and below the slide guide shaft 65 are similarly sub guide shafts 66 whose both end portions are fixed to the body member 33. Is provided. The sub guide shaft 66 is parallel to the slide guide shaft 65. The slide member 35 is slidably fitted to the slide guide shaft 65 and the sub guide shaft 66. Due to this sliding relationship, the slide member 35 moves in the front-rear direction of the camera body 11, that is, the advancing position approaching the subject. It can advance and retreat to and away from the retracted position. The forward and backward movement ends (advance position and reverse position) of the slide member 35 are regulated by a front wall 33b and a first rear wall 33c formed on the body member 33. The slide member 35 has a sleeve-like portion 35 a that protrudes rearward along the slide guide shaft 65, and a compression provided between the rear end portion of the sleeve-like portion 35 a and the second rear wall 33 d of the body member 33. The slide member 35 is urged to move forward by a coil spring (slide member urging means) 67.

  The light emitting unit 34 has a pair of support arms 70 and 71 that are separated in the left-right direction of the camera, and a circular shaft hole is formed at one end (base end) of each of the support arm 70 and the support arm 71. . A pop-up rotation shaft 72 is inserted into the circular shaft hole so as to be relatively rotatable. The pop-up rotation shaft 72 is inserted and supported in a shaft hole formed in the slide member 35 so that the axis thereof is substantially orthogonal to the optical axis O and is directed in the left-right direction of the camera. Therefore, the light emitting unit 34 (support arms 70 and 71) can rotate between the storage position shown in FIG. 20 and the protruding position shown in FIG. 21 around the axis of the pop-up rotation shaft 72. The light emitting unit 34 is biased toward the protruding position by a pop-up biasing spring (light emitting unit biasing means) 73. The pop-up biasing spring 73 is a torsion spring, and has one end engaged with the support arm 70 and the other end engaged with the slide member 35.

  A strobe light emitting portion 74 is supported on the other end portions (tip portions) of the support arm 70 and the support arm 71. The strobe light emitting unit 74 supports a strobe lens 76 on the front surface of a strobe body 75 fixed to (or integrally formed with) the support arms 70 and 71, and a xenon tube 77 and a reflector 78 behind the strobe lens 76. It has a supported structure. A pair of guide fins 79 project from both sides of the strobe body 75. Each guide fin 79 is formed as a roller guide surface (storage guide mechanism, roller contact surface) 80 having a corrugated surface facing the strobe irradiation direction. Specifically, the roller guide surface 80 has a shape in which a concave curved surface portion 80a and a convex curved surface portion 80b are continuous, and the convex curved surface portion 80b is on the tip side of the light emitting unit 34 (support arms 70 and 71). The concave curved surface portion 80a is positioned on the proximal end side of the light emitting unit 34 (support arms 70 and 71). The shape of the roller guide surface 80 is common to the left and right guide fins 79. For convenience of explanation, the concave curved surface portion 80a and the convex curved surface portion 80b are separated, but there is no step in the middle of the roller guide surface 80, and the surface is a continuous surface.

  The body member 33 is provided with a guide roller (storage guide mechanism) 81 that is positioned on the movement locus of the roller guide surface 80 when the light emitting unit 34 is rotated. The guide roller 81 is installed at a position where it comes into contact with the concave curved surface portion 80a when the light emitting unit 34 is rotated in the storage direction in a state where the slide member 35 is located at the forward movement end (FIG. 21). 22). The guide roller 81 can be rotated by a rotation shaft parallel to the pop-up rotation shaft 72, and has a cylindrical outer peripheral surface concentric with the rotation shaft.

  The light emitting unit 34 and the body member 33 are connected by a link mechanism. The link mechanism includes a first link 82 whose one end is pivotally attached to the body member 33 by a link rotation shaft 82a, and a second link 83 that is movable toward and away from the first link 82 in the longitudinal direction. ing. The first link 82 includes a pair of long holes 82b facing in the longitudinal direction, and the slide projections 83a of the second link 83 are slidably engaged with the long holes 82b. The second link 83 has another slide projection 83b at one end facing in the direction opposite to the link rotation shaft 82a, and the slide projection 83b is formed with respect to a long hole 70a formed in the longitudinal direction of the support arm 70. It is slidably engaged. The link mechanism including the first link 82 and the second link 83 determines the protruding position of the light emitting unit 34 with respect to the body member 33. That is, the total length of the link mechanism (the interval between the link rotation shaft 82a and the slide protrusion 83b) is changed by the sliding contact relationship between the long hole 82b and the slide protrusion 83a, and the link mechanism is at the longest at the angular position in FIG. Further, the rotation of the light emitting unit 34 in the further protruding direction is restricted. The first link 82 and the second link 83 are centered on a link rotation shaft 82a in FIGS. 20 and 21 by a link biasing spring (light emitting unit biasing means) 84 corresponding to the protruding direction of the light emitting unit 34. Counterclockwise).

  A locking hole (locking mechanism) 85 is formed in the support arm 70. The locking hole 85 is a rectangular hole opened toward the side of the support arm 70, and is positioned near the strobe light emitting unit 74 in the longitudinal direction of the support arm 70. As shown in FIG. 20, the locking hole 85 is positioned in front of the pop-up rotation shaft 72 when the light emitting unit 34 is stored. The body member 33 is provided with a stopper (locking mechanism) 86 that can be engaged with and disengaged from the locking hole 85 in the stored state. The stopper 86 can be rotated around a stopper rotation shaft 86a whose axis is directed in the vertical direction of the camera orthogonal to the pop-up rotation shaft 72. It has a locking arm 86b that enters or leaves. The locking arm 86b has an L-shape that extends upward substantially parallel to the stopper rotation shaft 86a and is bent at a substantially right angle toward the back side of the plane of FIG. 20 and FIG. In a state in which the bent tip portion of the locking arm 86b enters the locking hole 85, the light emitting unit in the protruding direction depends on the engagement relationship between the bent tip portion and the inner surface 85a (FIG. 21) of the locking hole 85. The rotation of 34 is restricted. Further, in the engaged state between the bent tip portion of the locking arm 86b and the locking hole 85, the optical axis direction depends on the engagement relationship between the bent tip portion and another inner surface 85b (FIG. 21) of the locking hole 85. The movement of the light emitting unit 34 to the front is restricted. In other words, in a state where the locking arm 86 b of the stopper 86 is engaged with the locking hole 85, the strobe light emitting portion 74 is restricted from rotating to the protruding position, and is also restricted from moving forward together with the slide member 35. . The body member 33 is provided with a stopper urging spring 87 that urges the stopper 86 at an engagement position with the locking hole 85. A pop-up operation button 88 (FIG. 17) is provided on the outer surface of the camera body 11, and when the pop-up operation button 88 is pressed, the disengagement direction with the locking hole 85 against the stopper biasing spring 87. The stopper 86 can be rotated to the front side of the paper in FIGS.

  The position of the stopper 86 in the axial direction of the stopper rotation shaft 86a can be adjusted by a washer 86c (FIGS. 20 and 21) provided between the stopper 86 and the body member 33. With this position adjustment, the light emitting unit 34 can be reliably positioned at the storage position by changing the height of the bent tip of the locking arm 86b. 20 and 21, the washer 86c is disposed on the upper side of the shaft portion of the stopper 86, but can be provided on the lower side of the shaft portion.

  The operation of the pop-up flash 18 having the above structure will be described. 19 and 20 show the stowed state of the pop-up flash 18. The longitudinal directions of the support arm 70 and the support arm 71 are substantially parallel to the axial direction of the slide guide shaft 65 and the sub guide shaft 66, and the entire light emitting unit 34 is stored in the strobe storage portion 33 a of the body member 33. Has been. At this time, the light emitting unit 34 has the strobe lens 76 facing the bottom surface side of the strobe housing portion 33 a, and the vicinity of the end of the convex curved surface portion 80 b of the roller guide surface 80 is in contact with the guide roller 81. Further, the link mechanism including the first link 82 and the second link 83 has the maximum length, and the slide protrusion 83b is in contact with the end portion on the side far from the pop-up rotation shaft 72 in the long hole 70a. Although the urging force in the protruding direction is acting on the light emitting unit 34 by the pop-up urging spring 73 and the link urging spring 84, the engaging hole 85 and the stopper 86 are engaged to rotate in the protruding direction. Be regulated.

  As shown in FIG. 19, in the housed state, the slide member 35 is located in the vicinity of the rearward movement end (retracted position) regulated by the first rear wall 33c. A forward urging force is applied to the slide member 35 by the compression coil spring 67, but the forward movement of the light emitting unit 34 coupled to the slide member 35 via the pop-up rotation shaft 72 is locked. Since it is regulated by the engagement between the hole 85 and the stopper 86, the slide member 35 remains at the position shown in FIG. 20 against the urging force of the compression coil spring 67.

  If the pop-up operation button 88 is pressed to release the engagement between the locking hole 85 and the stopper 86, both the rotation of the light emitting unit 34 in the protruding direction and the forward movement of the slide member 35 are permitted. The pop-up state of FIG. 21 is obtained by the urging force of each spring charged in the housed state. The slide member 35 is moved to the front moving end (advance position) that contacts the front wall 33 b by the biasing force of the compression coil spring 67. While the light emitting unit 34 moves forward together with the slide member 35, the light emitting unit 34 rotates in a direction in which the strobe light emitting unit 74 protrudes about the pop-up rotation shaft 72 by the urging force of the pop-up urging spring 73 and the link urging spring 84. Start moving. At this time, in the link mechanism that supports the light emitting unit 34, the slide protrusion 83 a is slid in the long hole 82 b until the middle of the rotation in the protruding direction, and both ends (the link rotation shaft 82 a and the slide protrusion 83 b). The slide projection 83b is moved closer to the other end (the end closer to the pop-up rotation shaft 72) in the long hole 70a while shortening the length between them. When the intermediate point is passed, the expansion / contraction relationship is reversed, and the link mechanism again separates the distance between both ends (the link rotation shaft 82a and the slide protrusion 83b), and the slide protrusion 83b is rotated pop-up within the long hole 70a. Move to the end far from the shaft 72. As described above, when the light emitting unit 34 rotates to the position shown in FIG. 21, the length of the link mechanism is maximized, and further rotation of the light emitting unit 34 is restricted.

  As described above, when the light emitting unit 34 is popped up together with the slide member 35, the strobe light emitting unit 74 becomes closer to the subject as compared with the case where the light emitting unit 34 is rotated at a fixed position. Generation of light vignetting can be effectively prevented.

  When the pop-up strobe 18 is returned from the pop-up state to the stowed position, the reverse operation is performed. Although detailed description is omitted in order to avoid duplication, the light emitting unit 34 is rotated in the storage direction and the light emitting unit 34 and the slide member 35 are slid rearward. However, while the pop-up operation is automatically performed by the spring biasing force, the storing operation is performed manually, the pop-up strobe 18 includes two different components, that is, rotation in the storing direction and sliding backward. The operability in the storing operation is taken into consideration. When the light emitting unit 34 is pushed in the storage direction (counterclockwise) from the state of FIG. 21, as shown in FIG. 22 at a timing (angular position) before the left and right support arms 70 and 71 become horizontal. In addition, the concave curved surface portion 80 a of the roller guide surface 80 comes into contact with the guide roller 81. More specifically, the guide roller 81 abuts near the end of the concave curved surface portion 80a opposite to the convex curved surface portion 80b. Then, the contact angle of the concave curved surface portion 80a with respect to the guide roller 81 at this time (the angular position of the light emitting unit 34 around the pop-up rotation shaft 72) and the shape of the concave curved surface portion 80a itself in the contact region ( When a downward pressing force in FIG. 22 is applied to the light emitting unit 34 due to the relationship with the curvature and the inclination angle, a backward moving component force is generated. By this backward component force, it is possible to smoothly shift from an operation state in which the light emitting unit 34 is rotated in the storage direction to an operation state in which the light emitting unit 34 is also moved backward. That is, since the operator can be recognized as a series of operations in the storage direction without being aware of the two-step operation system of closing the strobe and then sliding it, the operability is excellent. In particular, the position where the roller guide surface 80 and the guide roller 81 are brought into contact with each other is set on the distal end side farthest from the pop-up rotation shaft 72 in the light emitting unit 34, so that the backward movement component force is more effectively generated. ing. In addition, since the contact portion on the body member 33 side is the guide roller 81 that is a rotating member, a smoother operational feeling can be obtained.

  If the operation in the storing direction is further continued from the state of FIG. 22, the contact position on the roller guide surface 80 side with respect to the guide roller 81 is displaced from the concave curved surface portion 80a to the convex curved surface portion 80b. The convex curved surface portion 80b has its most protruding portion abutted against the guide roller 81 immediately before the storage position in FIG. 20, and thereafter the light emitting unit 34 is moved downward (approaching the body member 33) due to the relationship with the guide roller 81. The light emitting unit 34 can be reliably moved to the storage position with a light force at the final stage of the storage operation. Further, as can be seen from FIG. 20, when a forward moving force is applied to the light emitting unit 34 in the housed state, the inclination of the concave curved surface portion 80a acts to urge the light emitting unit 34 to move upward. Therefore, the roller guide surface 80 and the guide roller 81 also function as an assist for the protruding operation of the light emitting unit 34 at the time of pop-up.

  As described above, in the pop-up strobe 18 of the present embodiment, vignetting of strobe light hardly occurs in the pop-up state, and good optical performance can be obtained. In addition, the operability during the storing operation is also excellent.

  The pop-up strobe 18 further includes a speed change mechanism that adjusts the moving speed of the light emitting unit 34 during the pop-up operation. As shown in FIGS. 18, 23, and 24, the pop-up rotation shaft 72 includes a shaft gear 72 a at the end protruding to the support arm 71 side. The shaft gear 72 a meshes with the first gear 90 a of the reduction gear train 90 provided on the side surface of the support arm 71. The reduction gear train 90 is composed of a first gear 90 a, a second gear 90 b, a third gear 90 c, and a fourth gear 90 d that mesh with each other in order, and the final fourth gear 90 d meshes with the cam gear 91. Each gear of the reduction gear train 90 and the gear rotation shafts 90x1, 90x2, 90x3, 90x4 and 91x of the cam gear 91 are parallel to the axis of the pop-up rotation shaft 72, and the gear rotation shafts 90x1 to 91x are connected to the support arm 71. They are provided at predetermined intervals on a straight line extending in the longitudinal direction. A cam 92 having a triangular cross section is provided on the extension of the gear rotation shaft 91 x of the cam gear 91, and a free end 93 a of a leaf spring 93 is provided at a position facing the peripheral surface of the cam 92. The leaf spring 93 is curved in an S shape, and a fixed end 93 b opposite to the free end is fixed to the support arm 71.

  As described above, the pop-up rotation shaft 72 having the shaft gear 72a is supported by the slide member 35. Therefore, when the light emitting unit 34 rotates with respect to the slide member 35, the pop-up rotation shaft 72 is engaged by the meshing relationship with the shaft gear 72a. One gear 90a rotates. The rotation of the first gear 90a is transmitted through the second gear 90b, the third gear 90c, and the fourth gear 90d to rotate the cam gear 91. When the cam gear 91 rotates, the cam 92 provided on the same axis also rotates, and the positional relationship with the leaf spring 93 changes. FIG. 24A shows the housed state of the light emitting unit 34, and the free end 93 a of the leaf spring 93 faces along the linear portion 92 a of the triangular cam 92. When the light emitting unit 34 is rotated in the protruding direction from this storage position, the cam gear 91 and the cam 92 are rotated counterclockwise in FIG. Then, the apex portion 92 b adjacent to the linear portion 92 a in the cam 92 comes into contact with the free end portion 93 a of the leaf spring 93. The distance connecting the axis of the gear rotation shaft 91x and the apex portion 92b is the distance connecting the linear portion 92a and the axis of the gear rotation shaft 91x (the perpendicular passing through the axis of the gear rotation shaft 91x and orthogonal to the linear portion 92a). Therefore, the apex portion 92b pushes up the free end portion 93a away from the fixed end portion 93b to elastically deform the leaf spring 93. The rotation of the cam gear 91 is decelerated by the resistance of the leaf spring 93 at this time, and the decelerated state is transmitted to the first gear 90a via the fourth gear 90d, the third gear 90c, and the second gear 90b, and the light emitting unit The movement of 34 in the protruding direction is decelerated. FIG. 24B shows an intermediate angle between the storage position and the protruding position of the light emitting unit 34, and in this state, the pressing amount of the cam 92 (vertex portion 92b) against the free end 93a is maximized, and as a result, The resistance of the leaf spring 93 is the maximum.

  When the light emitting unit 34 is rotated in the protruding direction past the state of FIG. 24B, the apex 92b gradually retracts from the free end 93a of the leaf spring 93, and in the state of FIG. The leaf spring 93 that has been charged to the maximum (elastically deformed) is restored in a direction in which the free end portion 93a approaches the fixed end portion 93b. This spring restoring force acts as an auxiliary force that increases the rotational torque of the cam gear 91. That is, the leaf spring 93 eliminates the deceleration action on the light emitting unit 34 and conversely assists the protrusion of the light emitting unit 34. The assist action by the leaf spring 93 continues until just before the light emitting unit 34 reaches the protruding position. FIG. 24C shows a state in which the light emitting unit 34 has been rotated to the protruding position, and the linear portion 92 c following the apex portion 92 b of the cam 92 faces the free end portion 93 a of the leaf spring 93. However, the linear portion 92c and the free end portion 93a are slightly separated from each other. That is, in the state of FIG. 24C, the restoration of the leaf spring 93 is completed, and no force from the leaf spring 93 acts on the cam gear 91.

  As described above, in the pop-up strobe 18 of the present embodiment, the moving speed is decelerated at the initial stage of the pop-up operation of the light emitting unit 34, and the decelerating is canceled and auxiliary force in the protruding direction is applied when approaching the protruding position. Is provided. The pop-up urging spring 73 and the link urging spring 84 that urge the light-emitting unit 34 in the pop-up direction have the maximum charge amount (deflection amount) in the housed state of the light-emitting unit 34, and the light-emitting unit 34 is in the protruding position. As it approaches, the restoring force gradually attenuates. On the other hand, pop-up strobes that hold a protruding position by a spring force generally require a force in the protruding direction to be surely applied without deviation until reaching the protruding position. Therefore, the above transmission mechanism is effective. In a region near the storage position where the charge amount of the pop-up urging spring 73 and the link urging spring 84 is maximum, a force in the deceleration direction is exerted by the speed change mechanism, and the protrusion direction force by the pop-up urging spring 73 is reduced. In the region closer to the position, the protrusion operation is assisted by the action of the speed change mechanism, so that the light emitting unit 34 can be operated smoothly and reliably until the protrusion position is reached.

  Although only one leaf spring 93 is shown in the figure, a plurality of leaf springs may be provided. By changing the number of leaf springs, the degree of the effect by the speed change mechanism can be changed.

  While the present invention has been described with reference to the illustrated embodiment, the present invention is not limited to the illustrated embodiment. For example, in the camera of the embodiment, the grip 40 and the liquid crystal monitor block 25 rotate with respect to the camera main body 11, but the present invention can also be applied to a camera that does not have such a rotating unit. Further, the present invention can be applied not only to the digital camera as in the embodiment but also to a silver salt film camera.

In addition, the roller guide surface of the embodiment has a corrugated curved shape, but a linear contact surface is not limited to a curved surface as long as an appropriate component force can be generated.

It is a front perspective view showing one embodiment of a digital camera to which the present invention is applied. It is the front perspective view which looked at the digital camera from the direction different from FIG. It is a rear view of the digital camera. It is the side view which looked at the digital camera from the grip side. It is a side view which shows the state which rotated the grip in the digital camera. It is a side view which shows the angle position from which a grip differs in the digital camera. It is a side view which shows the further different angular position of a grip in the digital camera. It is a side view which shows the standing state of the liquid crystal monitor block in the digital camera. FIG. 5 is a side view showing a state in which the liquid crystal monitor block is reversed from FIG. 4 in the digital camera. It is a front perspective view which shows the standing state of the liquid crystal monitor block in the digital camera. FIG. 2 is a front view of the digital camera in a state where a grip is close to the camera body. FIG. 3 is a front view of the digital camera in a state where a grip is separated from a camera body. It is a front view which shows the outline of the circuit structure inside the digital camera. It is a top view which shows the outline of the circuit structure. It is a side view which shows the outline of the circuit configuration. It is the side view seen from the opposite side to Drawing 15 showing the outline of the circuit composition. It is the front perspective view which removed the exterior of the camera body upper surface side, and showed the pop-up strobe. It is the front perspective view seen from the direction different from FIG. It is a longitudinal cross-sectional view of the pop-up strobe stored. It is a side view of the storage state of the pop-up strobe. It is a side view of the pop-up state (protrusion state) of the pop-up strobe. It is a side view which shows the contact relationship between a roller guide surface and a guide roller when the pop-up strobe is rotated from the pop-up state in the storage direction. It is a side view which shows the speed change mechanism in the other side of the pop-up strobe. It is a side view for demonstrating the operating state of the transmission mechanism.

Explanation of symbols

K1 Inclination angle of shutter button (inclined surface) K2 Inclination angle of recording button LF Front lens O Optical axis S Grip longitudinal line X1 X2 X3 Axis 10 Digital camera 11 111 Camera body 11a Body front end surface 11b 111b Body rear end surface 11c Body upper surface 11d Body lower surface 11e Body right side surface 11f Body left side surface 12 Filter screw 13 Power button 14 Mode dial 15 Play button 16 Menu button 17 Multi-directional button 18 Pop-up flash 19 Memory card cover 20 Strobe mode button 21 Self-continuous shooting button 22 Focus mode button 23 Speaker opening 24 External connector cover 25 125 LCD monitor block 25a 125a Frame portion 26 126 Hinge portion 27 127 Support arm 28 128 Intermediate support portion 29 Axis pin 0 shaft pin 32 liquid crystal display section 33 body member 33a strobe housing section 33b front wall 33c first rear wall 33d second rear wall 34 light emitting section unit 35 slide member 35a sleeve-like section 40 140 grip 40a 40b 140a grip end face 40c 40d 40e 40f Longitudinal surface 40g Inclined surface 40h Arc-shaped surface 41 Grip rotating shaft 42 Battery 43 Battery cover 45 145 Shutter button 46 Zoom operation lever 47 Recording button 48 Tripod screw hole 50 Holding frame 50a of the taking optical system Opening 51 CCD
52 CCD board 53 First switch board 54 Second switch board 55 Jack board 56 PC jack 57 Adapter jack 58 Main board 59 60 61 FPC
65 Slide guide shaft 66 Sub guide shaft 67 Compression coil spring (sliding member biasing means)
70 71 Support arm 70a Long hole 72 Pop-up rotation shaft 72a Shaft gear 73 Pop-up urging spring (light emitting portion urging means)
74 Strobe light emitting unit 75 Strobe body 76 Strobe lens 77 Xenon tube 78 Reflector 79 Guide fin 80 Roller guide surface (storage guide mechanism, roller contact surface)
80a concave curved surface portion 80b convex curved surface portion 81 guide roller (storage guide mechanism)
82 First link 82a Link rotation shaft 82b Long hole 83 Second link 83a 83b Slide protrusion 84 Link biasing spring (light emitting portion biasing means)
85 Locking hole (Locking mechanism)
85a 85b Inner surface 86 of locking hole Stopper (locking mechanism)
86a Stopper rotation shaft 86b Locking arm 87 Stopper biasing spring 88 Pop-up operation button 90 Reduction gear train 90a First gear 90b Second gear 90c Third gear 90d Fourth gear 90x1 90x2 90x3 90x4 Gear rotation shaft 91 Cam gear 91x Gear Rotating shaft 92 Cam 92a 92c Linear portion 92b Vertex portion 93 Leaf spring 93a Free end portion 93b Fixed end portion

Claims (6)

A slide member supported on the camera body so as to be movable back and forth between an advance position approaching the subject and a retract position retracted;
A light emitting unit supported by the slide member so as to be rotatable between a storage position stored in the camera body and a protruding position protruding from the camera body ;
A roller provided on the camera body and rotatable about an axis substantially parallel to the rotation axis of the light emitting unit; and
A roller contact surface that is provided on the light emitting section unit so as to be eccentric from the rotation shaft;
With
When the slide member is rotated toward the light emitting unit in a state in the advanced position to the storage position from the projected position, the roller abutment surface abuts against the roller, the roller abutment surface and the roller A pop-up strobe in which the light emitting unit and the slide member are moved in the direction of the retracted position by the guide . In the pop-up flash according to claim 1, the pop-up flash the roller abutment surface that includes a curved surface at least in part. 3. The pop-up strobe according to claim 2, wherein the roller contact surface is formed of a concave curved surface and a convex curved surface that are continuous in a radial direction around the rotation axis of the light emitting unit. The pop-up strobe according to any one of claims 1 to 3 , wherein the light emitting unit has a support arm having one end supported on a slide member by the rotating shaft and having a light emitting unit at the other end. The roller contact surface is a pop-up strobe provided in the vicinity of the light emitting portion side end portion of the support arm. 5. The pop-up strobe according to claim 4 , wherein a pair of the roller contact surfaces are provided on both sides of the light emitting portion, and the camera body includes a pair of rollers corresponding to the pair of roller contact surfaces. In the pop-up flash according to any one of claims 1 to 5, and the slide member biasing means for biasing toward the slide member to the advanced position, the light emitting portion biasing means for urging toward the light emitting unit to the extended position And a pop-up strobe having a locking mechanism for holding the slide member in the retracted position and holding the light emitting unit in the retracted position against the slide member urging means and the light emitting portion urging means.

Images