JP2012133181A - Imaging apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce the number of components and achieve down-sizing by integrating substrates related to operation members and substrates related to light emission without deteriorating assemblability.SOLUTION: On a stroboscope operation board 43, a strobe circuit and switches corresponding to operation members on the top face are mounted. In a temporary unit 20, the stroboscope operation board 43 is positioned relative to a battery storage member 71 in an optical axis direction and a longitudinal direction by a positioning hole 43a engaging a positioning section 71d. At the same time, the stroboscope operation board 43 is disposed to cover a connecting section 41a and an engaged section 71a in an engaging state with a play from above, and the rear edge of the stroboscope operation board 43 is sandwiched in the vertical direction by a hook section 71e with a prescribed gap. A light emission section holder 41 and the battery storage member 71, integrated into the temporary unit 20, are respectively positioned and fixed relative to a front cover 3.

Description

  The present invention relates to an imaging device in which a light emitting unit holder and a battery housing member are both fixed to an attached member.

  Conventionally, for example, a digital camera as an imaging device is currently required to be reduced in cost and size. In order to reduce the cost, it is effective to consolidate circuit board configurations in the camera. Usually, a digital camera is equipped with a strobe board on which a strobe light emitting circuit is mounted, a switch corresponding to operation members such as a shutter button and a zoom lever, and a top operation board on which an accompanying electric circuit is mounted.

  Patent Document 1 discloses a strobe unit in which a strobe wiring board on which a strobe light emitting circuit is mounted is attached to a strobe light emitting unit to form a unit. Also shown is a top operation board on which a release switch for a shutter button, a power button, a light emitting diode for AF auxiliary light, and a mode dial are mounted. The strobe wiring board is provided with a connection connector, and is electrically connected to a main wiring board on which a CPU, a memory, an image processing LSI, a power supply circuit, and the like are mounted via an upper surface operation board. By attaching a strobe wiring board on which a strobe light emitting circuit is mounted to the strobe light emitting unit to form a unit, some cost reduction is achieved.

JP 2010-49175 A

  However, in the prior art disclosed in the above-mentioned Patent Document 1, there are two boards because a connection connector is provided on the strobe wiring board and each signal line is relayed to the upper operation board. For this reason, a connection connector and a locking member for locking each substrate are required, and the number of parts is large, which hinders cost reduction and miniaturization. By the way, in assembling a plurality of components, it is necessary to avoid a decrease in assembling ability.

  The present invention has been made to solve the above-described problems of the prior art, and its object is to reduce the number of parts and reduce the number of parts by consolidating the operation member-related and light-emitting related boards without degrading the assemblability. It is to plan.

  In order to achieve the above object, the present invention provides a light emitting unit holder for holding a light emitting unit, an electronic component for causing the light emitting unit to emit light, a substrate attached to the light emitting unit holder, and a battery. And a battery housing member attached to a unit in which the light emitting unit holder and the substrate are integrated. The battery housing member includes a positioning unit for positioning the substrate and the unit. An engaging portion that engages with an engaging portion of the light emitting portion holder is formed, and when the substrate of the unit is positioned by the positioning portion, the engaging portion is free to play in the engaged portion. It is characterized by engaging.

  According to the present invention, it is possible to reduce the number of components and reduce the size by consolidating the operation member-related and light emission-related substrates without degrading the assembling property.

1 is a perspective view of an imaging apparatus according to an embodiment of the present invention. It is a disassembled perspective view which shows the structure of a digital camera. It is a disassembled perspective view and front view which show the structure of a strobe unit. It is sectional drawing which follows the AA line of FIG.3 (b), and an expansion perspective view of an engaging part. It is the front view and perspective view of a battery accommodating part unit. It is an enlarged view of the engaged part vicinity of a battery accommodating part unit, and a perspective view of a battery accommodating part unit. It is a perspective view which shows the inner side (back side) of a front cover, and a perspective view which shows an upper surface operation unit. It is sectional drawing which follows the BB line of FIG.7 (b), and the perspective view of the front side which shows the completion state of a temporary unit. It is the figure which shows the assembly process of a temporary unit, and the figure which expanded the engaging part vicinity. It is a perspective view which shows the process of assembling a temporary unit to a front cover, and the assembly process of a lens-barrel and a main wiring board. It is a figure which shows the assembly process of an operation flexible and a liquid crystal unit, and the assembly process of an upper surface operation unit. It is a perspective view which shows the assembly process of a back cover unit and a battery cover.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 is a perspective view of an imaging apparatus according to an embodiment of the present invention. 1A is an oblique front view, and FIG. 1B is a perspective view viewed from an oblique rear surface. This imaging apparatus is configured as a digital camera 100.

  As shown in FIG. 1A, the lens barrel 1 is in the front center of the digital camera 100. The lens barrel 1 includes a lens barrel (not shown), and the symmetric axis of the photographing lens is the optical axis 2. An upper surface operation unit 50 is disposed on the upper part of the digital camera 100. Hereinafter, the optical axis direction (the direction along the optical axis 2) is the front-rear direction, and in particular, the subject side is the front side or the front side. As for the vertical direction, as shown in FIGS. 1A and 1B, the upper surface operation unit 50 is referred to as being positioned upward. Further, the direction perpendicular to both the optical axis direction and the up-down direction is the left-right direction, and the left and right are referred to as directions viewed from the operator. For example, the upper surface operation unit 50 is disposed on the right side in the upper part of the digital camera 100.

  As shown in FIG. 1A, a surface perpendicular to the optical axis 2 on the front surface of the digital camera 100 is covered with a front cover 3 as a “attached member”. The periphery of the front cover 3 is cut off with a large curved surface for design consideration. However, the dimensions of the main part are controlled in a plane perpendicular to the optical axis 2. A strobe light emission window 4 is located at the upper left of the lens barrel 1. The strobe light emission window 4 is placed on a large curved surface for design considerations, but the optical performance is managed in accordance with the optical axis 2.

  The upper right portion of the digital camera 100 is covered with the upper surface cover 5 of the upper surface operation unit 50. The upper surface cover 5 is provided with a power button 51, a shutter button 52, a zoom lever 53, and a mode dial 54 as upper surface operation members.

  When the power button 51 is pressed, the digital camera 100 comes out of the resting state, and the lens barrel 1 changes from the retracted state shown in FIG. When the power button 51 is pressed in this state, the digital camera 100 returns from a state where photographing can be performed to a retracted state where the photographing lens is retracted. When the retracted state is restored, the digital camera 100 enters a power saving state in which it does not react other than the operation of the power button 51. When the power button 51 is pressed and shooting is possible, shooting is performed when the shutter button 52 is pressed.

  The mode dial 54 switches modes such as a shooting mode and a playback mode. The rotational position of the mode dial 54 is configured such that an electrical contact specific to the position enters. Therefore, even if it moves in a state where it can be photographed or moves in a resting state, the position change of the mode dial 54 is accepted, and in the resting state, the next time the power button 51 is pressed, the mode corresponding to that position is changed. It has been switched.

  The direction in which the power button 51 and the shutter button 52 are pressed is the downward direction, that is, the direction perpendicular to the upper surface of the digital camera 100. Since the upper surface of the digital camera 100 is parallel to the optical axis 2, the direction in which the power button 51 and the shutter button 52 are pressed is also perpendicular to the optical axis 2. The rotation axes of the zoom lever 53 and the mode dial 54 are along the vertical direction. Accordingly, the rotation axes of the zoom lever 53 and the mode dial 54 are also perpendicular to the optical axis 2.

  Similar to the front cover 3, the periphery of the upper surface cover 5 constituting a part of the upper surface of the digital camera 100 is scraped off with a large curved surface for design consideration. However, the dimensions of the main part are controlled in a plane parallel to the optical axis 2.

  As shown in FIG. 1B, the surface perpendicular to the optical axis 2 on the back surface of the digital camera 100 is covered with the rear cover 6. A liquid crystal display window 61 is arranged from the rear left side to the center of the rear cover 6. A liquid crystal display 8 (see FIG. 2) is provided on the inner side (front side) of the liquid crystal display window 61. In the digital camera 100 having no optical viewfinder, the light taken from the taking lens is imaged on the image sensor 12 (see FIG. 2) and converted into an electrical signal. Then, the electrical signal is converted into a digital signal, and then displayed on the liquid crystal display 8, and is used for confirming a subject image to be captured and for reproducing and displaying the captured image.

  On the right side of the liquid crystal display window 61, an operation button group 62 is provided. The operation button group 62 also includes a center cross key. The operation button group 62 is used when, for example, instructing the digital camera 100 of functions such as changing shooting conditions, changing the liquid crystal display mode, and switching to a playback screen.

  Next, the configuration of the digital camera 100 will be described.

  FIG. 2 is an exploded perspective view showing the configuration of the digital camera 100. Each unit of the digital camera 100 is assembled to the front cover 3. These units include the upper surface operation unit 50, the strobe unit 40, the battery housing unit 70, the lens barrel 1, the liquid crystal unit 80, and the rear cover unit 60. In addition, as will be described later, the strobe unit 40 and the battery housing unit 70 are fixed to the front cover 3 in a state where the strobe unit 40 and the temporary unit 20 are integrated. In the temporary unit 20, the strobe unit 40 and the battery storage unit 70 are arranged in the left-right direction, and the strobe unit 40 is located on the left side.

  FIG. 3A is an exploded perspective view showing the configuration of the strobe unit 40. FIG. 3B is a front view of the strobe unit 40. FIG. 4A is a cross-sectional view taken along the line AA in FIG.

  As shown in FIG. 3B, the strobe unit 40 has a substantially U-shape that covers the strobe light emitting unit 410, the light emitting unit holder 41 that houses the strobe light emitting unit 410, the strobe operation substrate 43, and the strobe light emitting unit 410 from the top. The light emitting unit cover 44 and the speaker 45 are configured. The strobe unit 40 is an integrated unit. On the front surface of the light emitting unit holder 41, a positioning unit 41d and a screw hole 41e for being attached to the front cover 3 are provided. As shown in FIG. 4A, the strobe light emitting unit 410 includes a reflective shade 411, an arc tube 412, a strobe light emission window 4, a main capacitor 414, and the like. The strobe light emitting unit 410 is assembled to the light emitting unit holder 41.

  The strobe light emitting unit 410 needs to maintain the positional relationship with the optical axis 2 in order to irradiate the photographing range of the photographing lens of the lens barrel 1. Therefore, it is desirable that the strobe light emitting unit 410 is positioned and attached to a surface parallel to the surface to which the lens barrel 1 is attached and perpendicular to the optical axis.

  The strobe unit 40 is assembled as follows. First, as shown in FIG. 3A, the strobe light emitting section 410 and the strobe operation board 43 are fixed to a jig (not shown), and the lead wire 42 is soldered in this state. Each lead wire 42 is electrically coupled to a strobe circuit mounted on the strobe operation board 43, a light emitting tube 412 incorporated in the light emitting unit holder 41, a reflective shade 411 that transmits a trigger signal, and a main capacitor 414. As a result, the positional relationship between the two parts of the light emitting unit holder 41 and the strobe operation board 43 is determined, and flexibility (can be moved a little) between each other.

  The light emitting unit cover 44 is fastened to the light emitting unit holder 41 with a snap fit 44 a so as to sandwich the strobe operation substrate 43 from above and below in cooperation with the light emitting unit holder 41. Thereafter, the strobe unit 40 is completed by adhering and fixing the speaker 45 to the light emitting unit cover 44 with double-sided tape. With this configuration, the strobe unit 40 can check the strobe function by emitting light in the unit state. Therefore, it is advantageous for measuring the strobe characteristics (light distribution characteristics, guide number, etc.) and ensuring the unit.

  In the unit state, the strobe operation substrate 43 is configured to be sandwiched between the light emitting unit holder 41 and the light emitting unit cover 44 with a predetermined gap. That is, even if the strobe operation board 43 is greatly deformed in a direction perpendicular to the upper surface of the digital camera 100, an abnormal force is not applied to the lead wire 42 connecting the strobe light emitting unit 410 and the strobe operation board 43. In addition, the light emitting unit cover 44 covers the trigger coil 413 and the strobe electrical component 431 mounted on the strobe operation board 43 in the unit state, thereby reducing static electricity from the outside of the camera.

  On the strobe operation board 43, a strobe circuit, a switch for an upper surface operation member, and the like are attached. That is, it corresponds to a strobe circuit such as a strobe electric component 431 that is an electronic component for causing the strobe light emitting unit 410 to emit light on one strobe operation board 43 and a top operation member such as a power button 51 of the top operation unit 50. Switches are implemented. As a result, the operation member-related and light emission-related substrates are integrated into one.

  In the strobe unit 40 in the unit state, the strobe operation board 43 is attached to the light emitting unit holder 41 by the lead wire 42 without positioning. Therefore, as described above, the light emitting unit holder 41 and the strobe operation substrate 43 have flexibility to move relative to each other.

  A connecting portion of the strobe operation board 43 to the main wiring board 11 (FIG. 2) is provided near the positioning hole (positioning corresponding part) 43a. Further, the strobe operation board 43 and the main wiring board 11 are both positioned with respect to the battery housing member 71 (FIG. 5A) of the battery housing unit 70, so that the displacement of the connecting portion is less likely to occur. It has become.

  As shown in FIG. 3A, an engaging portion 41 a is provided at the upper right portion of the light emitting portion holder 41. The engaging portion 41 a is formed so as to protrude from the battery housing member 71 side (right side) in the temporary unit 20.

  FIG. 4B is an enlarged perspective view of the engaging portion 41 a provided in the light emitting portion holder 41. Each of the engaging portions 41a includes a rib-like first extending portion 41b and a second extending portion 41c, and has an L-shaped saddle shape in plan view (viewed from above). The first extending portion 41 b extends from the upper left portion of the light emitting portion holder 41 to the right (battery housing member 71 side). And the 2nd extension part 41c is extended from the front-end | tip part of the 1st extension part 41b to back. The extending direction of the first extending part 41b is perpendicular to the extending direction of the second extending part 41c.

  FIG. 5A is a front view showing the battery storage unit 70. The battery housing member 71 is for housing and holding a power battery (not shown). As shown in FIG. 5A, a positioning part 71 f and a screw hole 71 g for attaching to the front cover 3 are provided on the front surface of the battery housing member 71. In addition, one screw hole 71h used to clamp the upper surface cover 5 by sandwiching the upper surface cover 5 between the battery housing member 71 and the front cover 3 is provided.

  FIG. 5B is a perspective view of the battery housing unit 70 as viewed obliquely from the upper rear. On the rear surface of the battery housing member 71, a positioning portion 71i, a screw seat 71j, a positioning portion 71k, and a screw seat 71m are provided. The upper surface of the battery housing member 71 is a surface (horizontal plane) parallel to the optical axis 2, and a positioning portion 71 d for positioning the strobe operation board 43 is provided on the upper surface, in addition to the hook portion 71 e and the engaged portion 71 a. It has been.

  6A is an enlarged view of the vicinity of the engaged portion 71a on the upper surface of the battery housing unit 70. FIG. FIG. 6B is a perspective view of the battery housing unit 70 as viewed obliquely from the lower rear.

  As shown in FIG. 6A, the engaged portion 71a is provided corresponding to the engaging portion 41a of the light emitting portion holder 41 (FIG. 4B). The engaged portion 71a is formed as a concave portion having a shape fitting to the engaging portion 41a, and has an L-shaped saddle shape in plan view. That is, the engaged portion 71a has the first space 71b and the second space 71c for the first extending portion 41b and the second extending portion 41c of the engaging portion 41a to enter. Yes. However, the dimensions of the engaging portion 41a and the engaged portion 71a are designed so as to fit with play. By engaging the engaging portion 41a and the engaged portion 71a in the fitted state, the front-rear and left-right movements of the light-emitting portion holder 41 and the battery housing member 71 are restricted to predetermined ranges having play respectively. The

  The positioning portion 71d for positioning the strobe operation board 43 also serves as a positioning for the upper surface cover 5. The hook portion 71e is provided at the rear portion of the upper surface of the battery housing member 71, opens forward, and is formed in an L-shaped bowl shape in a side view. When the rear edge of the strobe operation board 43 is engaged with the hook portion 71e, the strobe operation board 43 is sandwiched between the upper surface of the battery housing member 71 and the lower surface of the hook portion 71e. Thereby, the vertical movement of the strobe operation board 43 with respect to the battery housing member 71 can be restricted. However, the relationship between the position of the lower surface of the hook portion 71e where the strobe operation board 43 is sandwiched and the thickness of the strobe operation board 43 is managed with respect to each other, so that a predetermined gap is formed during clamping. Yes. The strobe operation board 43 is movable up and down with respect to the battery housing member 71 within the predetermined gap.

  As shown in FIG. 6 (b), an opening 711 for taking in and out a power supply battery (not shown) is provided at the lower part of the battery housing member 71. A battery discharge spring 712 that is urged in a direction (downward) for discharging the stored battery is engaged with the upper part of the battery storage member 71. In the opening 711 of the battery housing member, as a battery lock mechanism, in addition to the lock member 713, a shaft 714 shown in FIG. 5B and a drive member 715 made of a high-sliding polymer material (for example, POM) A biasing member 716 made of a compression coil spring or the like is attached.

  In addition, a tripod seat 717 exposed to the outside of the digital camera 100 and a guide hole 718 that pivotally supports the battery lid 10 (see FIG. 2) are integrally formed at the lower portion of the battery housing member 71. Thus, the battery housing member 71 is formed of PC (polycarbonate) containing glass fibers because there are many portions that require relatively high strength.

  FIG. 7A is a perspective view showing the inside (rear side) of the front cover 3. A strobe screw seat 3a for attaching the light emitting unit holder 41 of the strobe unit 40 and a battery screw seat 3b for attaching the battery storage member 71 of the battery storage unit 70 are provided inside the front cover 3. In addition, a lens barrel screw seat 3c for attaching the lens barrel 1 and an upper surface cover screw seat 3d for calling and attaching the upper surface cover 5 of the upper surface operation unit 50 incorporating the upper surface operation member are provided.

  The seat surfaces of the flash screw seat 3a, the battery screw seat 3b, the lens barrel screw seat 3c, and the top cover screw seat 3d are surfaces perpendicular to the optical axis. A strobe positioning unit 3e, a battery positioning unit 3f, and a lens barrel positioning unit 3g are provided in proximity to the two screw seats 3a, 3b, and 3c. A screw hole 41e (FIG. 3A) and a screw hole 71g (FIG. 5A) correspond to the screw seats 3a and 3b, respectively. In the upper left portion of the front cover 3, a light emitting portion hole 3 h is provided corresponding to the strobe light emitting window 4.

  FIG. 7B is a perspective view showing the upper surface operation unit 50. Fig.8 (a) is sectional drawing which follows the BB line of FIG.7 (b). On the lower surface of the upper cover 5, there are two positioning holes 5 a for positioning and attaching the upper cover 5 to the battery housing member 71. The upper surface cover 5 has a standing wall portion extending downward, and a mounting hole 5 b is provided at the tip of the upper surface cover 5 so as to penetrate in a direction parallel to the optical axis 2.

  The upper surface operation unit 50 is assembled to the front cover 3. Then, the screw hole 71h (FIG. 5A) of the battery housing member 71 and the mounting hole 5b for attaching the top cover 5 with the strobe operation board 43 sandwiched between the top cover 5 and the battery housing member 71 The top cover screw seat 3d (FIG. 7A) of the front cover 3 is fastened together. A mounting hole 5b is interposed between the screw hole 71h and the upper surface cover screw seat 3d. By adopting such a configuration, the strobe operation board 43 is fixed, and the digital camera 100 can obtain high rigidity. Further, with such a configuration, the strobe operation board 43 is positioned on a plane parallel to the optical axis 2 and perpendicular to the pressing direction of the shutter button 52. Thereby, the positional relationship between the upper surface operation members and the switches on the strobe operation board 43 corresponding to them becomes accurate.

  Next, the configuration of the lens barrel 1, the liquid crystal unit 80, the rear cover unit 60, and the battery lid 10 will be described with reference to FIG.

  The front surface (front side) of the lens barrel 1 is provided with a positioning shape and a mounting hole (not shown). The lens barrel 1 is assembled to the front cover 3 in the optical axis direction so that it can be fixed with screws. It has become. On the back surface (rear side) of the lens barrel 1, a sensor flexible wiring board 13 to which an image sensor 12 is attached is disposed. Hereinafter, “flexible wiring board” is abbreviated as “flexible”. On the main wiring board 11, a CPU, a memory, an image processing LSI, a power supply circuit, and the like are mounted in addition to a connection connector that connects connection portions extending from various flexible cables.

  In the liquid crystal unit 80, the liquid crystal reinforcing plate 81 is formed in a shape that covers the four sides of the liquid crystal display 8. A liquid crystal flexible wiring board (not shown) connected to the ACF (Anisotropic Conductive Film) is connected to the liquid crystal display 8 from a substantially central portion near the main wiring board 11. I'm out. The extended liquid crystal FPC is assembled so as to pass through a hole formed in a part of the liquid crystal reinforcing plate 81. The liquid crystal display 8 and the liquid crystal reinforcing plate 81 are bonded and fixed by a double-sided tape affixed to the diaphragm-shaped portion provided on the liquid crystal reinforcing plate 81, and the liquid crystal unit 80 is completed.

  The standing wall portion formed to cover the four side portions of the liquid crystal display 8 in the liquid crystal reinforcing plate 81 is formed slightly higher than the thickness of the liquid crystal display 8. Thereby, the external force applied to the rear cover 6 is transmitted to the liquid crystal reinforcing plate 81 instead of the liquid crystal display 8. The liquid crystal reinforcing plate 81 also serves as a cradle for the operation flexible board 14. The operation flex 14 is provided with switches for the operation button group 62 of the rear cover unit 60.

  In the rear cover unit 60, the rear cover 6 is provided with a large rectangular hole, and a substantially colorless and transparent liquid crystal display window 61 is bonded and fixed with a double-sided tape so as to close the rectangular hole from the outside of the rear cover. . The back surface of the liquid crystal display window 61 is subjected to blind printing in a frame shape, and a double-sided tape is pasted on the blind-printed portion in a square shape, and then adhered and fixed to the rear cover 6. The operation button group 62 is fixed by being attached to the end of a spring-like beam (not shown) extending from the button. Therefore, the button does not fall off and can move in the direction of the optical axis 2. A tip of the operation button group 62 has a protrusion shape, and a switch mounted on the operation flexible board 14 can be pressed.

  Further, a jack cover 63 for covering the external power supply connector and the USB connector mounted on the main wiring board 11 is provided on the side of the rear cover 6. The jack cover 63 is formed of a relatively soft resin, and the hinge portion thereof is configured to be easily bent. Thus, the rear cover unit 60 is configured.

  An opening / closing shaft 101 is formed on the battery lid 10. The opening / closing shaft 101 engages with the guide hole 718 (FIG. 6B) of the battery housing member 71 to form a hinge portion of the battery cover 10, and the battery cover 10 moves and rotates along the guide hole 718. Is possible.

  Next, a method for assembling the digital camera 100 will be described with reference to FIGS. 2 and 9 to 12. First, the configuration and assembly of the temporary unit 20 will be described with reference to FIGS. 8B and 9.

  FIG. 8B is a front perspective view showing the completed state of the temporary unit 20. The temporary unit 20 is a unit in which the strobe unit 40, the battery housing unit 70, and the strobe operation board 43 are integrated in a temporarily fixed state.

  Here, when the temporary unit 20 is assembled to the front cover 3, the strobe unit 40 and the battery storage unit 70 are each positioned and fixed to the front cover 3. As for the strobe unit 40, the positioning portion 41d (FIG. 3A, FIG. 8B) of the light emitting unit holder 41 is inserted into the strobe positioning portion 3e of the front cover 3 (FIG. 7A). In this state, the strobe unit 40 is screwed through the strobe screw seat 3a (FIG. 7 (a)) and the screw hole 41e (FIG. 3 (a), FIG. 8 (b)), whereby the strobe unit 40 is moved to the front cover 3. Fixed against.

  On the other hand, the strobe operation board 43 enters the positioning portion 71d (FIGS. 5B and 8B) in which the positioning hole 43a (FIG. 3A) is provided on the upper surface of the battery housing member 71 and is positioned. The The positioning part 71d is a pin extending vertically upward from the upper surface of the digital camera 100.

  In this way, the two parts (light emitting unit holder 41 and strobe operation board 43) existing in one unit are positioned in different directions. Therefore, the strobe unit 40 and the battery housing unit 70 cannot be assembled straight in the optical axis direction (simply moved only in the optical axis direction). Therefore, it is necessary to assemble the strobe unit 40 and the battery housing unit 70 as a state of the temporary unit 20 in which the positioning portion 71d is inserted and engaged with the positioning hole 43a.

  FIG. 9A is a diagram illustrating an assembly process of the temporary unit 20. FIG. 9B is an enlarged view of the vicinity of the engaging portion 41a with the strobe operation board 43 hidden for convenience.

  As shown in FIG. 9A, the rear edge portion of the strobe operation board 43 is inserted into the hook portion 71e of the battery housing member 71 in a state where the front edge portion of the strobe operation board 43 is inclined slightly higher. Direction of arrow A). After that, the strobe operation board 43 is assembled so that the positioning hole 43a enters the positioning portion 71d while rotating the front edge of the strobe operation substrate 43 in the direction of lowering (the rotation direction of the arrow B). In parallel with this, as shown in FIG. 9B, the first extending portion 41 b and the second extending portion 41 c of the engaging portion 41 a of the light emitting portion holder 41 are connected to the battery housing member 71. It fits in the 1st space 71b and the 2nd space 71c of the joint part 71a (refer also to Fig.6 (a) and FIG.4 (b)).

  Here, the second extending portion 41c extends from the extending end of the first extending portion 41b in the direction in which the hook portion 71e is formed. That is, the extending direction of the second extending portion 41c is the direction (rear) on the side where the hook portion 71e is provided in the optical axis direction. Thereby, the space which the to-be-engaged part 71a occupies can be minimized.

  The strobe operation board 43 is restrained from moving in all directions with respect to the battery housing member 71 by the positioning hole 43a entering the positioning portion 71d and being further sandwiched by the hook portion 71e in the vertical direction. However, as described above, only the vertical direction is movable within a predetermined gap.

  As described above, due to the engagement between the engaging portion 41a and the engaged portion 71a, the movement of the light emitting portion holder 41 and the battery housing member 71 other than the vertical direction is restricted within a predetermined range. Moreover, the strobe operation board 43 is disposed so as to cover (engage the lid) the engaging portion 41a and the engaged portion 71a in the engaged state from above. Accordingly, the relative movement in the vertical direction of the light emitting unit holder 41 and the battery housing member 71 is also restricted through the strobe operation board 43. However, since the hook portion 71e holds the strobe operation substrate 43 with a gap therebetween, the strobe operation substrate 43 comes into contact with or close to the engaging portion 41a and the engaged portion 71a. Accordingly, the light emitting unit holder 41 and the battery housing member 71 are allowed to move somewhat in the vertical direction.

  Thus, since the light emitting unit holder 41 and the battery housing member 71 are temporarily fixed with appropriate play, the two do not move more than necessary and do not easily separate from each other. It becomes a certain temporary unit 20.

  Next, the assembly process of the digital camera 100 after the temporary unit 20 is assembled will be described with reference to FIGS.

  FIG. 10A is a perspective view showing a process of assembling the temporary unit 20 to the front cover 3. The temporary unit 20 is assembled to the front cover 3 in the optical axis direction. The front cover 3 is placed on a cradle (not shown) with the back side (back side) facing up, and the temporary unit 20 is assembled. Therefore, the direction of the optical axis is the direction in which gravity works. When assembling the temporary unit 20, in order not to reduce the reliability of the circuit on the strobe operation board 43, it is desirable to avoid directly touching the strobe operation board 43 even if gloves or finger sack are worn. Therefore, as a work form, the light emitting unit holder 41 is grasped with the left hand, and the entire temporary unit 20 is dropped into the front cover 3.

  Thus, when the temporary unit 20 is assembled, the battery housing unit 70 generates a moment due to gravity by having the light emitting unit holder 41. However, here, the hook portion 71 e provided on the upper surface of the battery housing member 71 acts so as to be supported by the strobe operation substrate 43. That is, the hook portion 71e is located farther from the light emitting portion holder 41 than the engaged portion 71a in the direction perpendicular to both the optical axis direction and the vertical direction (left and right direction) of the rear edge portion of the strobe operation board 43. It is provided at a position where the (right side) position can be sandwiched (FIG. 5B). As a result, even when the front side of the temporary unit 20 faces downward and the light emitting unit holder 41 is gripped, the strobe operation substrate 43 is supported through the hook portion 71e against the moment. Therefore, the temporary unit 20 can be assembled without breaking.

  By the way, since the strobe light emission window 4 (FIG. 1A) of the strobe unit 40 is an exterior part of the digital camera 100, if the strobe light emission window 4 is damaged, the value of the digital camera 100 as a product is impaired. When the temporary unit 20 is dropped onto the front cover 3 by holding the light emitting unit holder 41 with the left hand as described above, a slight twist is applied to the left hand, and the strobe light emission window 4 of the light emitting unit holder 41 is attached to the bottom of the light emitting unit holder 41. It will be incorporated in a form that is lower than.

  At that time, first, the strobe light emission window 4 enters the light emitting portion hole 3h of the front cover 3, and the strobe positioning portion 41d enters the positioning portion 3e of the front cover 3. Then, the battery positioning portion 71f (FIG. 8B) enters the positioning portion 3f of the front cover 3. Thereafter, the two screws are screwed in the direction of the optical axis 2 through the screw hole 41e and the strobe screw seat 3a. In parallel with this, two screws are screwed in the direction of the optical axis 2 through the screw hole 71g and the battery screw seat 3b. Thereby, the light emission part holder 41 and the battery storage member 71 are fixed to the front cover 3 (main fixing). At this time, as described above, since the light emitting unit holder 41 and the battery housing member 71 have movable ranges in the vertical and horizontal directions and the optical axis direction, there is no hindrance to positioning of both of them relative to the front cover 3. Further, there is no double fitting. In this way, the strobe unit 40 and the battery storage unit 70 are assembled to the front cover 3.

  FIG. 10B is a perspective view showing an assembly process of the lens barrel 1 and the main wiring board 11. The sensor flexible board 13 arranged on the rear side of the lens barrel 1 is inserted into the connection portion of the main wiring board 11. Thereafter, the lens barrel 1 and the main wiring board 11 are moved in the optical axis direction so as to be simultaneously dropped into an assembly (FIG. 10A) in which the strobe unit 40 and the battery housing unit 70 are assembled to the front cover 3. Assemble and screw in the optical axis direction and fix.

  Since both the lens barrel 1 and the strobe unit 40 are incorporated into the front cover 3 from the optical axis direction, optical accuracy is maintained. A positioning portion 71i (FIGS. 5B and 10B) of the battery housing member 71 enters the positioning hole 11a of the main wiring board 11, and is screwed using a screw seat 71j (FIG. 5B). To do.

  FIG. 11A is a perspective view showing an assembly process of the operation flexible 14 and the liquid crystal unit 80. The operation flexible board 14 is inserted into a connection portion provided on the main wiring board 11 and the strobe operation board 43. Thereafter, when the liquid crystal unit 80 is assembled, the connected operation flexible 14 is temporarily retracted to the upper surface side of the digital camera 100, so that the liquid crystal unit 80 can be assembled straight.

  Next, the liquid crystal display 8 is assembled in the optical axis direction as a liquid crystal unit 80 fixed to the liquid crystal reinforcing plate 81. A positioning portion 71k (FIGS. 5B and 11A) of the battery housing member 71 is inserted into the positioning hole 81a of the liquid crystal reinforcing plate 81, and the liquid crystal FPC extended from the liquid crystal display 8 is connected to the main wiring. Insert into the connector of the board 11.

  Thereafter, screws are fastened in the optical axis direction via the screw seats 41f of the light emitting unit holder 41, and the optical axes are fastened together with the main wiring board 11 to the screw seats 71m (FIG. 5B) of the battery housing member 71. Screw in the direction. By fastening together, the metal parts of the liquid crystal display 8 and the liquid crystal reinforcing plate 81 are grounded to the ground line.

  The liquid crystal reinforcing plate 81 is provided with an extending portion (not shown) that is electrically connected to the speaker 45 (FIG. 3A) incorporated in the light emitting portion cover 44. As a result, the speaker 45 is connected to the main GND of the digital camera 100, and static electricity from the outside of the camera can be reduced. After that, the operation flexible 14 that has been temporarily retracted is placed on a cradle provided on the liquid crystal reinforcing plate 81 to be positioned and fixed.

  FIG. 11B is a diagram illustrating an assembly process of the upper surface operation unit 50. In FIG. 11B, it is shown upright for convenience. This is because the strobe operation board 43 and the upper surface operation unit 50 are located above the battery housing member 71, and only the upper surface operation unit 50 is assembled in a direction perpendicular to the optical axis 2. However, in practice, as in FIG. 11 (a), the operation is performed with the front surface of the front cover 3 kept downward.

  Therefore, the upper surface operation unit 50 is assembled from the side. The upper surface operation unit 50 is fastened together with the battery housing member 71 together with the front cover 3 while being pressed against the battery housing member 71 with the strobe operation board 43 interposed therebetween. At that time, the screw is screwed in the optical axis direction through a screw hole 71h (FIG. 5A), a mounting hole 5b (FIG. 8A), and a top cover screw seat 3d (FIG. 7A). . A dedicated fastening member is not used for the strobe operation board 43.

  FIG. 12 is a perspective view showing an assembly process of the rear cover unit 60 and the battery lid 10. The rear cover unit 60 and the battery cover 10 are attached to the assembly assembled in FIG. 11B, and the digital camera 100 is completed. Since the rear cover 6 is an exterior part that affects the design, the screw is screwed not in the optical axis direction but in a direction perpendicular to the optical axis, that is, in the lateral direction or the lower direction of the digital camera 100.

  According to the present embodiment, the strobe operation board 43 is mounted with a strobe circuit and switches corresponding to the upper surface operation member, and the operation member-related and light emission-related boards are integrated into one. This contributes to miniaturization and requires fewer locking and connecting members.

  Further, since the flash unit 40 and the battery housing unit 70 are integrated into the temporary cover 20 and then assembled to the front cover 3, it is easy to handle as a single unit and the workability is good. In particular, the temporary unit 20 is integrated and is not easily separated, and the strobe unit 40 and the battery storage unit 70 are individually movable when permanently fixed to the front cover 3. Each can be positioned and is not double-fixed, but also has high assembly accuracy.

  That is, in the temporary unit 20, the positioning hole 43 a of the strobe operation board 43 is engaged with the positioning portion 71 d of the battery storage member 71, so that the strobe operation board 43 with respect to the battery storage member 71 in the optical axis direction and the left-right direction Positioned. At the same time, the strobe operation board 43 is disposed so as to cover the engaged portion 41a and the engaged portion 71a in the engaged state from above, and the strobe operation substrate 43 is sandwiched from above and below by the hook portion 71e. And the light emission part holder 41 and the battery storage member 71 are each positioned and fixed with respect to the front cover 3 in the state which was the temporary unit 20 united. Here, since the engaging portion 41a and the engaged portion 71a are engaged with play, the engaging portion 41a and the engaged portion 71a are regulated so as to move within a predetermined range in the optical axis direction and the left-right direction. Further, since the strobe operation board 43 is held by the hook portion 71e with a predetermined gap, the strobe operation board 43 is restricted so that it can move within a predetermined range in the vertical direction. With such a configuration, the rigidity for maintaining an integral state as the temporary unit 20 is ensured.

  Therefore, it is possible to reduce the number of parts and reduce the size by consolidating the operation member-related and light emission-related substrates without degrading the assemblability.

  In addition, the hook portion 71e is provided at a position where a position farther from the light emitting portion holder 41 than the engaged portion 71a in the left-right direction can be sandwiched among the rear edge portions of the strobe operation board 43. Accordingly, even in a normally assumed work mode in which the light emitting unit holder 41 is held and the temporary unit 20 is slightly tilted, the battery housing member 71 is appropriately supported by the strobe operation substrate 43 via the hook portion 71e. Therefore, the temporary unit 20 is difficult to be separated and easy to handle.

  By the way, although the engaging part 41a and the to-be-engaged part 71a were made into the L-shaped hook shape, it is not restricted to such a shape. That is, it suffices if the relative movement in the horizontal direction (optical axis direction and left-right direction) between the light emitting unit holder 41 and the battery housing member 71 can be restricted within a predetermined range, and the relationship between the male type and the female type may be reversed. . For example, as an example of the engaging portion 41a, a T shape or a cross shape may be used. Alternatively, instead of the second extending portion 41c, a portion (circular shape, square shape, etc.) wider in the front-rear direction than the first extending portion 41b may be formed at the tip of the first extending portion 41b. Good. Further, the positioning hole 43a and the positioning portion 71d are not limited in shape, and the relationship between the male type and the female type may be reversed.

  By the way, although the front cover 3 is shown as the “attached member” to which the light emitting unit holder 41 and the battery housing member 71 are fixed, it is not limited thereto. For example, when a member fixed to the front cover 3 is interposed on the rear side of the front cover 3, the interposed member may be used.

  Note that the imaging apparatus to which the present invention is applied is not limited to a digital still camera, and may be, for example, a video camera.

  Although the present invention has been described in detail based on preferred embodiments thereof, the present invention is not limited to these specific embodiments, and various forms within the scope of the present invention are also included in the present invention. included.

3 Front cover 20 Temporary unit 41 Light emitting part holder 41a Engaging part 43 Strobe operation board 43a Positioning hole 71 Battery housing member 71a Engaged part 71d Positioning part 71e Hook part

Claims (6)

A light emitting unit holder for holding the light emitting unit;
An electronic component for causing the light emitting unit to emit light is mounted, and a substrate attached to the light emitting unit holder;
A battery is housed and a battery housing member attached to a unit in which the light emitting unit holder and the substrate are integrated,
The battery housing member is formed with a positioning part for positioning with the substrate of the unit and an engaged part for engaging with an engaging part of the light emitting part holder of the unit,
The imaging apparatus according to claim 1, wherein when the substrate of the unit is positioned by the positioning portion, the engaging portion engages with the engaged portion with play.   The battery housing member is formed with a hook portion for sandwiching the edge of the substrate in the unit, and when the battery housing member is attached to the unit, the edge of the substrate in the unit is sandwiched between the hook portion. And the engagement portion is engaged before the substrate is positioned at the positioning portion of the battery housing member, and the board of the unit is positioned at the positioning portion of the battery housing member. The imaging apparatus according to claim 1, wherein the imaging unit is engaged with play.   The hook portion regulates the substrate in a vertical direction with respect to the battery housing member, and the positioning portion has a direction perpendicular to both the optical axis direction and the optical axis direction and the vertical direction with respect to the battery housing member. The engaged portion restricts the engaging portion with respect to the battery housing member in an optical axis direction and a direction perpendicular to both the optical axis direction and the vertical direction. 2. The imaging device according to 2.   4. The engagement portion according to claim 1, wherein the engagement portion is formed in an L-shaped bowl shape, and the engaged portion is a recess having a shape fitting to the engagement portion. The imaging apparatus of Claim 1.   The engaging portion includes a first extension portion extending in the direction of the battery housing member in a direction perpendicular to both the optical axis direction and the vertical direction, and a tip portion of the first extension portion. The imaging apparatus according to claim 4, further comprising: a second extension portion extending at a right angle with respect to the first extension portion. The imaging apparatus according to claim 5, wherein an extending direction of the second extending portion is a direction on a side where the hook portion is provided in an optical axis direction.

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