JP4493265B2 - Lens barrel - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a structure of a lens barrel.
[0002]
[Prior art]
Conventionally, a subject image acquisition means in which a subject image formed based on a light beam incident on a photographing optical system composed of a plurality of lens groups is arranged at a predetermined position, for example, an image sensor such as a charge coupled device (CCD), or Cameras configured to acquire desired subject image information or subject images by forming an image on a light-receiving surface of a photosensitive material such as a photographic film are widely spread and put into practical use. .
[0003]
In such a camera, further downsizing, in particular, downsizing in the thickness direction of the camera is desired. For that purpose, downsizing of the lens barrel including the photographing optical system is indispensable.
[0004]
As a lens barrel used for the camera or the like, for example, a reflecting member made of a reflecting mirror or the like is arranged in a photographing optical path having a plurality of lens groups and the like, and the photographing optical axis is bent in a predetermined direction, so-called A device for reducing the size of the apparatus by applying a bending optical system has been proposed.
[0005]
Patent Document 1 proposes a lens barrel to which the above bending optical system is applied. In this lens barrel, a subject light is taken in by a prism, and a photographing optical axis is bent by the prism, thereby a plurality of lenses. A structure in which the subject light is incident on an optical system composed of a group is employed. Note that the optical axis incident on the prism is the first optical axis, and the optical axes of the plurality of lens groups after bending are the second optical axes.
[0006]
By the way, the lens barrel as described above incorporates a light amount adjusting device such as a shutter and an aperture unit for adjusting the light amount according to the luminance of the subject, and a lens driving mechanism for focusing and zooming. It is common.
[0007]
Also in the lens barrel disclosed in Patent Document 1, the diaphragm unit is disposed between the plurality of lens groups, and the diaphragm blades of the diaphragm unit are parallel to the first optical axis by a diaphragm unit drive source. The amount of light is adjusted by displacing in any direction. Further, the zoom motor and the focus motor perform focus adjustment drive and variable power drive in the second optical axis direction of the plurality of lens groups. The aperture unit drive source, the zoom motor, and the focus motor are disposed at each corner of the rectangular parallelepiped with the first optical axis as the center.
[0008]
[Patent Document 1]
Patent Document 1 is Japanese Patent Laid-Open No. 11-84209 (paragraph numbers 0017 to 0023).
[0009]
[Problems to be solved by the invention]
However, in the lens barrel disclosed in Patent Document 1, the driving direction of the diaphragm blade that is the light amount adjusting device is parallel to the incident optical axis (first optical axis) of the subject light to the prism. The structure is not necessarily suitable for reducing the thickness of the lens barrel along the first optical axis direction. In order to achieve a sufficiently thin lens barrel and to realize a compact camera, the driving direction of the light amount adjusting device is taken into consideration, and at the same time, a driving source for the light amount adjusting device and a lens group for advancing and retracting driving. It is necessary to consider the arrangement of the drive source.
[0010]
In view of the above reasons, the present invention considers the driving direction of the light amount adjusting device, and at the same time, considers the arrangement of the driving source for the light amount adjusting device driving and the lens driving, and the thickness direction of the lens barrel, that is, An object of the present invention is to provide a lens barrel that is thin in a direction parallel to the incident optical axis (first optical axis) of subject light and that enables further miniaturization of the camera.
[0011]
[Means for Solving the Problems]
The lens barrel of the present invention is a lens barrel having a variable magnification optical system composed of a plurality of lens groups, and a second light beam incident from a subject along the first optical axis intersects the first optical axis. A reflecting optical member that reflects the light along the second optical axis, first and second movable lens groups disposed along the second optical axis, and the first movable lens group as the second light. A first movable holding frame that holds the second movable lens group so as to be displaceable along an axis; a second movable holding frame that holds the second movable lens group so that it can be displaced along the second optical axis; The first movable holding frame is displaced along the optical axis of the first movable holding frame, and the shield is movable between a position where the exposure opening is shielded and a position where the exposure opening is opened within a plane substantially perpendicular to the second optical axis. a shutter means having a member, a shutter driving source for driving the shielding member, the first movable holding A lens driving unit for displacing the first movable holding frame and the second movable holding frame along a second optical axis, and a position for entering and retracting into the photographing optical path in a plane orthogonal to the second optical axis. And a filter drive source for driving the ND filter, wherein the shielding member is on a plane including the first optical axis and the second optical axis. The ND filter moves in a direction substantially orthogonal to each other, and the ND filter moves in a direction substantially orthogonal to a plane including the first optical axis and the second optical axis, and the shutter drive source and the filter drive source. Is arranged in parallel in the first optical axis direction, and the lens drive unit is displaced substantially linearly in the second optical axis direction with respect to the shutter drive source and the filter drive source. It is characterized by being arranged in.
[0021]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is an exploded perspective view of an electronic camera incorporating a lens barrel that is an embodiment of the present invention.
[0022]
In the following description, as shown in FIG. 1, the direction along the first optical axis O1, which is the incident direction of the subject luminous flux, is the Z direction, and the Z (+) direction in the subject side direction of the electronic camera is the front, The Z (−) direction in the direction of the camera rear side is the rear. In the direction perpendicular to the Z direction, the vertical direction is the Y direction, the Y (+) direction is the upward direction, and the Y (−) direction is the downward direction. When the camera is viewed from the subject side, the X (+) direction is the right direction and the X (−) direction is the right direction.
[0023]
As shown in FIG. 1, the electronic camera 1 of the present embodiment is a so-called digital camera, and has a front cover 2 and a rear cover 3 that are exterior members, and is housed in the front cover 2 and the rear cover 3. The lens barrel 10, the electric substrate unit 5, the power supply unit 6, the strobe unit 7, the strobe charging capacitor 8, the LCD unit 9 as a display unit, and the base frame 24 are provided as constituent units. Do it.
[0024]
The front cover 2 is provided with a photographing window portion 2a for taking in a subject light flux and a strobe light emission window portion 2b on the front surface portion thereof.
[0025]
The rear cover 3 is provided with a two-stage release button 26 and a power button 27 for turning on / off the power on the upper surface, and an LCD opening 3a on the back. A transparent plate 4 which is a transparent member is fixed to the back surface of the rear cover 3 so as to cover the LCD opening 3a.
[0026]
The lens barrel 10 has a substantially rectangular parallelepiped outer shape having a front surface portion along the X and Y planes when mounted on the camera, the longitudinal direction being the Y direction, and a relatively thin thickness in the Z direction. A prism 33 of a reflecting optical member that forms a bending optical system for taking in a subject light beam along the first optical axis O1 (Z direction) is accommodated in the upper part. An inclined surface 31c (FIG. 3) is formed on the rear upper surface of the lens barrel.
[0027]
In the lens barrel 10, the subject light flux in the direction of the first optical axis O1 taken in by the prism 33 is reflected in the direction of the second optical axis O2, and the CCD 55, which is an image pickup device, passes through a photographing lens system described later. The image is formed on the imaging surface of the image and converted into an imaging signal of the subject image. The detailed structure will be described later.
[0028]
The electric board unit 5 is disposed on the side of the lens barrel 10 and has three printed boards 18, 19, and 20 on which control elements of an electric circuit of an electronic camera to be described later are mounted. A recording media slot 21 is mounted inside the substrate 20. The printed circuit boards 18, 19, and 20 are connected and connected by flexible printed circuit boards (hereinafter referred to as FPCs) 22 and 23, and are housed in a stacked state in the direction of the optical axis O1.
[0029]
The power supply unit 6 is disposed on the side of the lens barrel 10 and includes a battery case 11 and a camera power supply battery 12 that is inserted into and stored in the battery case 11 and has a flat surface extending in the XY plane. A rectangular parallelepiped shape having a relatively small thickness in the Z direction.
[0030]
The strobe unit 7 includes a strobe main body 13 and a strobe arc tube 14 supported inside the reflector umbrella of the strobe main body 13.
[0031]
The LCD unit 9 includes an LCD display plate 15 that is a liquid crystal display plate having display surfaces along X and Y planes, an LCD illumination light source 16 that is disposed at an upper position of the LCD display plate 15 and extends in the X direction, And a light guide plate 17 covering the side opposite to the display surface of the LCD display plate 15. The light guide plate 17 is a member whose thickness changes in the Y direction, and is formed with a thick upper portion on the light source side and a thin lower portion.
[0032]
The housing state of each of the constituent units in the front and rear covers 2 and 3 will be described. First, the front portion of the lens barrel 10 is formed at the center of a base frame 24 formed of a metal plate and having a flat surface extending on the XY plane. (Second outer wall 32j) is applied and fastened with screws 25. The printed circuit board 20 side of the electric circuit board unit 5 is fastened and fixed together with the media slot 21 by screws 25 in a state adjacent to the lens barrel 10 on the left side of the base frame 24. Further, the power supply unit 6 is fastened by screws 25 in a state adjacent to the lens barrel 10 on the right side of the base frame 24, and the lens barrel 10, the electric board unit 5, and the power supply unit 6 are integrated. Further, the strobe unit 7 is fixed to the upper part of the power supply unit 6, and the strobe charging capacitor 8 is fixed in a state of entering from the rear of the strobe unit 7 to the rear of the upper inclined surface 31 c of the lens barrel 10.
[0033]
On the other hand, the LCD unit 9 is fixedly arranged inside the rear cover 3 with the display surface of the LCD display plate 15 facing the opening 3a.
[0034]
A base frame 24 to which the lens barrel 10, the electric board unit 5, and the power supply unit 6 are attached is housed in a state of being sandwiched between the front cover 2 and the rear cover 3, and the front cover 2 and the rear cover 3. And the electronic camera 1 is completed.
[0035]
In the storage state, the incident opening of the prism 33 of the lens barrel 10 is arranged to face the photographing window 2a of the front cover 2, and the light emitting part of the strobe unit 7 is arranged behind the strobe light emitting window 2b. . Further, the LCD unit 9 is positioned so as to overlap the battery unit 6 and the lens barrel 10, and is positioned to face the LCD opening 3 a of the rear cover 3.
[0036]
Further, the thickness in the Z direction of the lens barrel 10, the power supply unit 6 and the LCD unit 9 in the stored state is substantially equal to the thickness (occupied space) of the electric board unit 5 in the Z direction. The heights in the Y direction of the lens barrel 10 and the LCD unit 9 are substantially equal.
[0037]
Here, the electric circuit of the electronic camera 1 of the present embodiment will be described with reference to the block diagram of FIG.
The electronic camera 1 of the present embodiment incorporates a CPU 170 that is a control means, and the CPU 170 controls the entire control elements of the electronic camera 1.
[0038]
First, an image of a subject that has passed through the photographing optical system 111 is converted into an electrical signal by the CCD 55 that is an image pickup device under the control of the CPU 170. The electrical signal converted by the CCD 55 is converted to an analog image signal by the imaging circuit 113 and then converted to a digital image signal by the A / D conversion circuit 114. The digital image signal is recorded via an interface (I / F) 121 on a recording medium card (memory card) 120 as a recording medium such as a removable flash memory card or smart memory card that is an external memory. Is done. The recording media card 120 is detachable from the media slot 21.
[0039]
Further, the electric circuit of the electronic camera 1 is provided with a built-in memory 130 and an image processing circuit 140 having a high processing speed. For example, a random access memory (RAM) is applied to the built-in memory 130, and each image is displayed. It is used as a working memory in processing or as a high-speed buffer for temporary image storage means. The image processing circuit 140 performs processing such as conversion to RGB signals, conversion of the number of pixels, data compression, and decompression based on the image data digitized by the A / D conversion circuit 114.
[0040]
Further, the above-described image display LCD display panel 15 (liquid crystal display device) is mounted on the electronic camera 1, and the LCD display panel 15 is used for confirming an image recorded on the memory card 120 and photographing. A subject image to be displayed is displayed. The image displayed on the LCD display board 15 is an image displayed after the image information from the built-in memory 130 is once taken into the video memory 151 and converted into a video image by the video output circuit 152. The video output circuit 152 can also output a video image to an external display device via the video output external terminal 153.
[0041]
The CPU 170 takes in a shooting start signal by operating the release button 26 and takes an image with the CCD 55, or takes in setting signals for various modes of the operation unit 173 by operating a mode setting button (not shown) to set the shooting mode. . The setting mode is displayed on the mode LCD 172. Further, based on the control of the CPU 170, when the amount of light at the time of imaging of the subject is insufficient, the strobe light emitting tube 14 of the strobe unit 7 is turned on and strobe shooting is performed.
[0042]
Further, the CPU 170 is connected with first and second step motors 53 and 54, which are lens drive sources for performing focus drive and zoom drive of the photographing optical system, via a driver 171, and the lens is driven by the motor. Is called.
[0043]
The CPU 170 is connected to a subject light quantity adjusting device, which is an ND filter solenoid 51 for driving the ND filter unit and a shutter solenoid 52 for driving the shutter unit via a driver 171. Light amount adjustment driving is performed by the solenoid.
[0044]
The CPU 170 is connected to photo reflectors (hereinafter referred to as PR) 58 and 59 which are detection means for detecting the reset position of the forward / backward movement of the photographing optical system. The reset position is detected when the photographing lens system 111 is reset.
[0045]
An external interface (external I / F) 161 is connected to the external input / output terminal 160 and inputs / outputs data to / from an external device. For example, a personal computer or the like is connected to the external input / output terminal 160, and an image in the memory card 120 is transferred to the personal computer or the like, and image data is taken in from the personal computer or the like.
[0046]
Further, each control element of the electronic camera 1 is supplied with power from the battery 12 of the power supply unit 6 via the power supply unit 180 and is driven. The battery 12 can be charged under the control of the power supply unit 180.
[0047]
Next, the detailed structure of the lens barrel 10 will be described with reference to FIGS.
3 and 4 are exploded perspective views of the lens barrel as seen from the back side. FIG. 5 is a longitudinal sectional view of the lens barrel in a wide state when viewed from the front side. FIG. 6 is a longitudinal sectional view of the lens barrel in the tele state as viewed from the front side. 7 is a cross-sectional view taken along line AA in FIG. 5, FIG. 8 is a cross-sectional view taken along line DD in FIG. 6, and FIG. 9 is a cross-sectional view taken along line BB in FIG. FIG. 10 is an exploded perspective view around the first group frame portion (ND filter unit portion) of the lens barrel. FIG. 11 is a view taken in the direction of arrow C in FIG. 5 and shows a rotation range of the shutter drive arm. FIG. 12 is an exploded perspective view around the shutter unit. FIG. 13A is a view taken along the line E-E in FIG. 12 and shows a shutter open state. FIG. 13B is an EE arrow view of FIG. 12 and shows a shutter closed state. FIG. 14A is an enlarged cross-sectional view of the shutter drive arm. FIG. 14B is an enlarged cross-sectional view showing a state in which the shutter drive arm and the shaft portion are mounted on the shaft portion adhesive fixing jig. FIG. 15 is a perspective view of the lens barrel with the connected FPC mounted as viewed from the front side, and FIG. 16 is a perspective view of the lens barrel with the connected FPC mounted as viewed from the back side.
[0048]
The lens barrel 10 includes a first group frame 31 that is a first holding frame and a fixed frame 32 that is a frame member as shown in FIG. 5 and the like, and is incorporated in the first group frame 31. The members are a prism 33 as a reflective optical member, a first group lens 34, an ND filter unit 47 as a light amount adjusting means, an ND filter rotary solenoid (hereinafter referred to as a solenoid) 51 as a filter drive source, and a shutter. For example, a shutter solenoid 52 that is a drive source (sector drive source). Further, members provided inside the fixed frame 32 are a shutter unit 48 which is a light amount adjusting means (shutter means) along the optical axis O2, and a second holding frame (first movable holding) which can be moved forward and backward. The second group lens 35 of the zoom lens group held by the second group frame 38, which is a frame), and the third group frame 39, which is a third holding frame (second movable holding frame) that can be advanced and retracted. Mounted on the CCD substrate 56 and the third group lens 36 of the zoom and focus lens group, the fourth group lens 37 held in the lower opening 32b of the fixed frame 32, and the imaging located at the imaging position of the subject luminous flux The element CCDs 55 are arranged in order. Further, a zoom shaft for advancing and retracting the second group frame 38 and a suspension shaft 41 and a rotation stop shaft 42 whose both ends are fixedly held by the fixed frame 32 on the left and right along the second optical axis O2 (that is, the Y direction). The first step motor 53 of the first lens drive source constituting the motor unit and the second lens drive source constituting the motor unit for zoom and focus drive for advancing and retreating the third group frame 39. A second step motor 54 and a compression spring 46 inserted between the second group frame 38 and the third group frame 39 are also provided. A fixed lid 89 made of a metal plate is mounted and fixed on the back side of the fixed frame 32. On the front side of the fixed frame 32, an FPC 86 on which electrical connection portions such as connection terminals and sensors of the respective drive sources are mounted is disposed.
[0049]
The first holding frame 31 includes a rectangular parallelepiped outer shape portion and a triangular prism-shaped outer shape portion having an inclined surface 31c along the outer shape of the prism 33 housed in a part on the rear surface side and the axial direction being the X direction. The prism, the first group lens, the ND filter unit, the solenoid and the like are accommodated and fastened and coupled to the upper side of the fixed frame 32 by a screw insertion hole 31f and a screw screw hole 32f. .
[0050]
The prism 33 is inserted and fixed in the front opening 31 a of the first group frame 31. The subject luminous flux incident along the optical axis O1 is bent at an angle of 90 ° by the prism 33, and reflected toward the lower opening 31b along the second optical axis O2 (Y direction).
[0051]
The first group lens 34 is inserted and held on the lower side of the lower opening 31 b of the first group frame 31.
[0052]
The ND filter unit 47 is incorporated on the lower surface side of the first group frame 31, and is a light amount adjusting member that is movable in a direction substantially orthogonal to the optical axis plane including the optical axis O1 and the optical axis O2 in order to adjust the subject light amount. An ND filter 67 is provided. Details of the structure will be described later.
[0053]
The ND filter solenoid 51 and the shutter solenoid 52 are arranged in parallel along the first optical axis O1 on the left side of the prism 33 in the first group frame 31 in a united state. The respective output shafts 51a and 52a are arranged so as to protrude in the direction of the optical axis O2 below the first group frame 31 (FIG. 10). A pinion 61 is fixed to the output shaft 51 a of the ND filter solenoid 51. On the other hand, a shutter driving arm 71 as a driving force transmitting member is fixed to the output shaft 52 a of the shutter solenoid 52. A shaft portion 72 formed of a hollow shaft member having a predetermined length corresponding to the forward / backward movement position of the second group lens is fixed to the tip of the arm portion of the shutter drive arm 71. The output shafts 51a and 52a are rotationally driven by driving the solenoid forward and backward, whereby the pinion 61 or the shutter drive arm 71 is rotated twice in an open position and a closed position, respectively. It is rotationally driven to the moving position. Operations of the ND filter unit and the shutter unit by the pinion 61 and the shaft portion 72 will be described later.
[0054]
The second group frame 38 has an opening 38a at the center upper portion, two guide holes 38c penetrating along the Y direction, a rotation stop notch 38g on the opposite side of the guide hole 38c, and a lead screw insertion notch 38d. The lever rotation shaft hole 38e, the four stepped pins 38b, and the locking projections 38f and the like are provided on both end surfaces in the Z direction (FIG. 12). In addition to the second group lens 35 serving as a zoom lens, the shutter unit 48 is disposed on the upper surface on the opening 38a side in the second group frame 38, and the sector drive lever 43 is rotatable in the lever shaft hole 38e. Inserted. The second group frame 38 is supported so as to be movable back and forth along the optical axis O2 by a suspension shaft 41 and a rotation stop shaft 42 which are slidably fitted into the guide hole 38c and the notch 38g, respectively.
[0055]
The shutter unit 48 has first and second sectors 74 and 76 that are two shielding members that can be opened and closed in a direction perpendicular to the optical axis plane including the optical axis O1 and the optical axis O2. Details of the structure will be described later.
[0056]
The third group frame 39 has two guide holes 39b penetrating along the Y direction, a rotation stop notch 39c facing the guide hole 39b, and a lead screw insertion notch 39d. In addition, a third group lens 36 serving as a zoom and focus lens is mounted.
[0057]
The first step motor 53 includes a motor body, a rotor portion 53c to which the lead screw shaft 81 is fixed, a coil portion 53b in which a bearing portion 53a for supporting another shaft is provided at a tip portion thereof, and four pieces. And a connection terminal 53d (FIGS. 5 and 9).
[0058]
The second step motor 54 includes a motor main body, a rotor portion 54c to which the lead screw shaft 83 is fixed, a coil portion 54b in which a bearing portion 54a for supporting another shaft is provided at a tip portion thereof, and four pieces. Connection terminal 54d (FIGS. 5 and 9).
[0059]
The first and second step motors 53 and 54 are fixedly supported on the inner side of the left side wall portion 32k, which is the first outer wall of the fixed frame 32, via a motor mounting plate 85 as shown in FIGS. That is, the first and second step motors 53 and 54 are on the left side of the position where the second and third group frames 38 and 39 of the fixed frame 32 are disposed, and below the solenoids 51 and 52. The lead screw shafts are opposed to each other below and above the linear region parallel to the rotor portion 53c and the coil portion 53b, and the rotor portion 54c and the coil portion 54b are placed on the optical axis plane including the optical axis O1 and the optical axis O2. The stepping motor is mounted by attaching the motor mounting plate 85 to the upper and lower ends of the motor mounting plate 85 along the line, positioning the motor mounting plate 85 on the positioning pin 32p, and fixing the motor mounting plate 85 to the inside of the left side wall portion 32k with screws 49.
[0060]
In the step motor mounting support state, the first step motor 53 is positioned with the lead screw shaft 81 facing upward, the second step motor 54 is positioned with the lead screw shaft 83 facing downward, and The leading end portions of the lead screw shafts 81 and 83 are supported by being rotatably fitted in bearing portions 54a and 53a of the other step motors 54 and 53, respectively.
[0061]
Accordingly, the lead screw shafts 81 and 83 are arranged in a state parallel to the optical axis plane including the optical axis O1 and the optical axis O2 and in a state parallel to the optical axis O2 with the step motors 53 and 54 attached. The The lead screw shafts 81 and 83 are arranged in parallel in the direction of the optical axis O2. Further, the solenoids 51 and 52 and the step motors 53 and 54 are arranged on one linear region parallel to the side of the optical axis O2.
[0062]
A second group frame drive nut 82 is screwed and fitted to the lead screw shaft 81, and a third group frame drive nut 84 is screwed and fitted to the lead screw shaft 83. The upper surface 38 h (FIG. 12) of the notch 38 d of the second group frame 38 inserted across the lead screw shaft 81 is applied to the lower surface of the screwed second group frame drive nut 82 by the urging force of the compression spring 46. It touches and is energized upward. Further, the lower surface portion 39h of the notch 39d of the third group frame 39 inserted across the lead screw shaft 83 is brought into contact with the upper surface of the screwed third group frame drive nut 84 by the urging force of the compression spring 46, It is urged downward.
[0063]
As described above, the second and third group frames 38 and 39 are driven forward and backward by the movement of the drive nuts 82 and 84, and the screwing backlash between the drive nuts 82 and 84 and the lead screw shafts 81 and 83 is one. The direction is approached.
[0064]
Therefore, when the lead screw shaft 81 is rotated by the step motor 53, the second group frame 38 moves between the wide position (reset position) and the tele position in FIG. 5 along the optical axis O2 via the second group frame drive nut 82. It is driven back and forth. Similarly, when the lead screw shaft 83 is rotated by the step motor 54, the third group frame 39 is moved along the optical axis O2 from the wide position (reset position) in FIG. 5 to the tele position in FIG. It is driven back and forth between. During the reset processing operation of the step motors 53 and 54, when the second group frame 38 and the third group frame 39 move in the reset direction and reach the reset positions, a photo reflector (hereinafter referred to as PR), which will be described later, is used. (Description) The arrival of the reset position is detected by 58 and 59 (FIGS. 7 and 15).
[0065]
As described above, during zooming, the step motors 53 and 54 are driven to hold the second group lens 35 that is a zoom lens, and the third group frame 39 that holds the third group lens 36 that is used for zooming and focusing. Drive. At this time, the driving amount of the second group frame 38 and the third group frame 39 can be determined from the number of driving steps of the step motors 53 and 54 with the reset position detected by the PRs 58 and 59 as a reference. The zoom state of the system is calculated.
[0066]
Focus driving is performed by driving the driving step motor 54 to displace the third group frame 39 in the direction of the optical axis O2.
[0067]
The ND filter unit 47 is disposed between the lower surface of the first group frame 31 and the upper surface of the fixed frame 32, and as shown in an exploded perspective view of FIG. 10, an idle gear 62 that meshes with the output pinion 61 of the ND filter solenoid 51. The ND filter drive gear 63 meshing with the idle gear 62, the ground plate 64 attached to the first group frame 31 and holding the gear, the filter drive arm 65 provided with pin holes 65a and 65b at both ends, and the central opening 66a, a pin hole 66b, an ND filter scratch preventing sheet 66 provided with an X-direction long hole 66c, an ND filter 67 provided with a pin hole 67b, an X-direction long hole 67c, and a caulking pin 68. .
[0068]
The pin hole 65 a at one end of the filter drive arm 65 is fitted into the drive pin 63 a of the filter drive gear 63 and is integrally supported by the filter drive gear 63. The caulking pin 68 is caulked and fixed to the pin hole 65b of the filter drive arm 65 in a state of being rotatably fitted in the pin hole 67b of the ND filter 67 and the pin hole 66b of the ND filter scratch preventing sheet 66. . Further, the ND filter scratch preventing sheet 66 and the ND filter 67 are supported by their long holes 66c and 67c being slidably fitted into the guide pins 31e of the first group frame 31. A support sheet 78 (FIGS. 3 and 4) with an ND filter protection sheet 79 having a central opening is disposed on the opening 32a side of the fixed frame 32 on the lower surface of the ND filter 67. It is arranged on a plane orthogonal to the optical axis O2, and can be slid along the plane in the X direction.
[0069]
In the light amount adjustment operation by the ND filter unit 47 having the above-described configuration, when the ND filter solenoid 51 is driven to rotate clockwise as viewed from below in FIG. 10, the filter drive arm 65 is moved via the filter drive gear 63. 10 is rotated clockwise as viewed from the bottom of FIG. 10 (ND filter entry drive direction). The ND filter scratch preventing sheet 66 and the ND filter 67 are integrally slid in the X (+) direction (that is, the optical axis plane including the optical axis O1 and the optical axis O2, that is, the direction orthogonal to the YZ plane), The ND filter 67 moves from the position retracted from the opening 32a of the fixed frame 32 to the approach position covering the opening 32a, and the reduced subject light quantity enters the second group lens 35 side. Conversely, when the ND filter solenoid 51 is driven to rotate counterclockwise as viewed from the bottom of FIG. 10, the ND filter scratch prevention sheet 66 and the ND filter 67 are in a direction opposite to the moving direction ( (X (−) direction), the ND filter 67 moves to the retracted position retracted from the opening 32a of the fixed frame 32, and the total incident light quantity of the subject light beam is emitted to the second group lens 35 side.
[0070]
As shown in FIG. 12, the shutter unit 48 is a unit mounted on the upper part of the second group frame 38. The shutter unit 48 includes a central opening 73a, four support holes 73b, a relief arc groove 73c, and opposing folding portions. A shutter lid 73 provided with a stop hole 73d, a straight guide long hole 74b in the X direction, an engagement long hole 74c that is an engagement hole in the Z direction, a first sector 74 provided with a shielding portion, and a shutter opening diameter A first blade sheet 75 provided with an opening 75a, a mounting long hole 75b, a relief arc groove 75c, a linear guide long hole 76b in the X direction, an engagement long hole 76c which is an engagement hole in the Z direction, and A second sector 76 provided with a shielding part, a second blade sheet 77 provided with an opening 77a having a larger diameter than the opening 75a, a mounting long hole 77b, and a relief arc groove 77c, and along the Y direction Rotating shaft portions 43a, made and a sector drive lever 43 of the sector drive member driven elongated hole 43 b, 2 pieces of the sector drive pin 43c is engaged shaft, 43d are provided.
[0071]
Note that one of the long mounting holes 75b and 77b provided in the first and second blade sheets 74 and 75 is fitted to the stepped pin 38b as a positioning, and the other has a slight backlash. It is formed.
[0072]
The sector drive lever 43 has the pivot shaft 43a penetrated through the shutter lever pivot shaft hole 38e of the second group frame 38, and the retaining ring 45 for retaining the stopper is locked to the tip of the shaft portion. When the sector drive lever 43 is mounted, the second blade sheet 77, the second sector 76, the first blade sheet 75, and the first sector 74 are arranged in this order from the upper side of the second group frame 38 to the stepped pin 38b of the second group frame 38. Insert it. At that time, one sector drive pin 43c of the sector drive lever 43 is inserted into the escape arc grooves 77c and 75c and the engagement long hole 74c in order from the bottom, and at the same time, the other sector drive pin 43d is inserted into the engagement long hole 76c. Let Finally, the shutter lid 73 is covered from above, and the locking holes 73d are engaged with the locking projections 38f of the second group frame 38 so that the shutter unit 48 is mounted. In this state, the sector drive pin 43c is inserted into the escape arc groove 73c. Since a shaft portion 72 of a shutter drive arm 71, which will be described later, is slidably fitted into the driven slot 43b of the sector drive lever 43, the sector drive lever 43 is rotationally driven by the shutter drive arm 71, and the shutter The sectors 74 and 76 of the unit 48 are slid and driven.
[0073]
The shaft 72 is fixed to the shutter drive arm 71 in a state extending in a direction parallel to the optical axis O2 at a position spaced apart from the center of the rotation axis of the shutter drive arm 71 by a predetermined distance. Thus, even when the second group frame 38 is moved back and forth in the direction of the optical axis O2, the length is set such that the shaft portion 72 is always engaged with the driven long hole 43b of the sector drive lever 43.
[0074]
As shown in FIG. 14A, which is an enlarged cross-sectional view of the shutter drive arm and the shaft portion, the shaft portion 72 is inserted into the shaft hole 71a at the tip of the arm 71, and an adhesive is injected into the fitting gap. To be fixed. As shown in FIG. 14B, when the shutter drive arm 71 and the shaft portion 72 are bonded, the shutter drive arm 71 is attached to the holding frame 91a formed on the bonding fixing jig 91, and the shaft portion 72 is fixed to the jig. The shaft is held in the shaft holding hole 91b 91 and is inserted into the shaft hole 71a. The shaft hole 71a and the shaft portion 72 have a gap in which the positional accuracy can be adjusted, and the shaft portion 72 is supported in a state of being separated from the shutter drive arm 71 by a predetermined distance and in parallel. In this supported state, an adhesive is injected into the shaft hole 71 a, and the shaft portion 72 is bonded and fixed to the shutter drive arm 71. When the shutter drive arm 71 is incorporated in the fixed frame 32, the shaft is separated from the shutter drive arm 71 by a predetermined distance and is supported in a state parallel to the optical axis O2.
[0075]
The shutter drive arm 71 is in substantially the same region on a plane orthogonal to the optical axis O2 where the second step motor 54 is located in the assembled state, but the second step motor 54 avoids the swing locus of the shaft portion 72. Placed in a different position. At the same time, the swing trajectory of the shaft portion 72 is in a region where the position of the suspension shaft 41 is avoided.
[0076]
The opening / closing rotational position of the shutter drive arm 71 is defined by the restricting projection of the opening 32g of the fixed frame 32 as shown in FIG. That is, the shutter drive arm 71 is inserted through the opening 32g having the two restricting protrusions 32i and 32h of the fixed frame 32, and the shutter drive arm 71 is rotated in the opening direction (clockwise in FIG. 11). The distal end of the shutter abuts against the restricting projection 32i to define the opening rotation position of the shutter drive arm 71. Further, when the shutter drive arm 71 rotates in the closing direction (counterclockwise in FIG. 11), the tip of the shutter drive arm 71 comes into contact with the restricting projection 32h to define the closing rotation position of the shutter drive arm 71.
[0077]
The shutter unit 48 is disposed along the upper surface of the second group frame 38, and moves forward and backward in the direction of the optical axis O2 integrally with the second group frame 38. Therefore, the first and second sectors 74 and 76 are always held along a plane perpendicular to the optical axis O2, and slide on the plane.
[0078]
In the shutter opening / closing operation of the shutter unit 48 having the above-described configuration, when the shutter closed state shown in FIG. 13B is changed to the shutter open state shown in FIG. 13A, the output shaft 52a of the shutter solenoid 52 is rotated counterclockwise. When driven (upward in FIG. 13B), the sector drive lever 43 is driven to rotate clockwise via the shaft portion 72 of the shutter drive arm 71. As shown in FIG. 13A, when the sector driving lever 43 is rotated clockwise, the first sector 74 and the second sector 76 are moved in the X (+) and X (−) directions by the sector driving pins 43c and 43d, respectively. That is, the shutter is driven to slide in the direction perpendicular to the optical axis plane including the optical axis O1 and the optical axis O2, and the shutter is opened (maximum opening diameter) to open the opening 75a of the blade sheet.
[0079]
When the shutter open state shown in FIG. 13A is changed to the shutter closed state, when the output shaft 52a of the shutter solenoid 52 is driven clockwise (upward in FIG. 13A), the shaft portion of the shutter drive arm 71 is driven. The sector drive lever 43 is driven to rotate counterclockwise via 72. As shown in FIG. 13B, the sector drive lever 43 rotates counterclockwise so that the first sector 74 and the second sector 76 are moved in the X (−) direction and X (+) by the sector drive pins 43c and 43d, respectively. ) Direction (that is, the direction orthogonal to the optical axis plane including the optical axis O1 and the optical axis O2), and the shutter is closed to close the opening 75a of the blade sheet.
[0080]
In the lens barrel 10, when assembling each component such as a lens group and a step motor, the lens group, the step motor and the like are inserted through an opening 32 g provided on the back side of the fixed frame 32 and assembled. Is done. After the assembly is completed, a fixed lid 89 made of a metal plate is attached to the opening 32g, screws are inserted into the screw insertion holes 89d and 89e, and screwed into the fixing frame side screw holes 32d and 32e to seal the fixing frame 32. State (FIG. 3).
[0081]
As shown in FIG. 15, the fixed frame 32 of the lens barrel 10 has the above-mentioned 2, 3 on the front side wall portion 32j which is the second outer wall along the plane (XY plane) perpendicular to the thickness direction of the fixed frame cuboid. Insertion holes 32r and 32s into which the group frame reset position detection PR58 and PR59 can be inserted are provided. The positions of the insertion holes 32r and 32s are positions where the detection surfaces face each other when the second and third group frames 38 and 39 are at the reset position on the movement locus.
[0082]
Also, as shown in FIG. 16, the left (right in FIG. 16, right) wall 32k of the first outer wall adjacent to the front side wall 32j of the fixed frame 32 and along the thickness direction of the rectangular parallelepiped. Terminal insertion holes 32m and 32n are provided at the lower and upper positions. The four motor terminals 53d and 54d of the first step motor 53 and the second step motor 54 are inserted into the terminal insertion holes 32m and 32n, and are exposed to the outside of the fixed frame. Further, the two lead wires 51b of the ND filter solenoid 51 and the two lead wires 52b of the shutter solenoid 52 are arranged from the left side (the right side in FIG. 16) of the first holding frame 31 as shown in FIG. Derived and guided to the upper part of the front side wall part 32j.
[0083]
An ND filter solenoid lead wire connection land 86e and a shutter solenoid lead wire connection land 86f are provided above the connection FPC 86, and the surface mount type PR58 and 59 are mounted at the center. ing. Further, the two protrusions 86a and 86b of the connection FPC 86 are bent and pasted from the surface of the front wall portion 32j of the fixed frame 32 to the surface of the left wall portion 32k. The projections 86a and 86b are provided with a first step motor terminal connection land 86c and a second step motor terminal connection land 86d.
[0084]
When the connection FPC 86 is attached to the lens barrel 10, the connection FPC 86 is attached to the surface of the front side wall portion 32j of the fixed frame 32, and the mounted PR 58 and 59 are respectively inserted into the insertion holes 32r and 32s of the fixed frame 32. insert. On the other hand, the protrusions 86a and 86b of the connection FPC 86 are bent from the surface side of the front wall 32j of the fixed frame 32 and attached to the left wall 32k, and the motor terminals 53d and 54d are soldered to the motor terminal connection lands 86c and 86d. . Further, the lead wires 51 b and 52 b of the solenoids 51 and 52 are soldered to the solenoid lead wire connection lands 86 e and 86 f of the connection FPC 86. The connection FPC 86 is led out to the electric board side on the electric board unit 5 side, and is connected to the connector.
[0085]
Next, a photographing operation by the camera 1 of the present embodiment having the above-described configuration will be described.
When the user operates the power button 27 on the rear cover, the power switch is turned on and the memory card 120 is inserted into the card slot 21. When a mode setting button 27 (not shown) is operated, the CPU 170 selects and sets the shooting mode.
[0086]
Subsequently, when shooting is performed, the image of the subject light beam captured via the prism 33 and the first to fourth lens groups 34 to 37 is converted into an electrical imaging signal by the CCD 55 under the control of the CPU 170, and the built-in memory. 130 is captured as a video signal. The video signal is displayed on the LCD display board 15 as a subject image. When the user performs an operation such as zooming to determine a subject to be photographed and a shooting angle of view and presses the first release button of the release button 26, the CPU 170 controls the image signal based on the contrast information. Thus, the focusing drive of the third group lens 36 is performed. In this focus drive and the zoom drive, the first and second step motors 53 and 54 are driven and controlled, and the second group frame 38 and the third group frame 39 are moved to the forward and backward positions along the respective optical axes O2. It is done by moving. On the other hand, photometry of subject light is performed based on the captured video signal. When the subject brightness is higher than a predetermined value in the photometric data, the ND filter solenoid 51 is driven, and the ND filter 67 enters and moves to a position covering the fixed frame opening 32a.
[0087]
Next, a shooting start signal is captured by pressing the release button 26 at the second stage, and after the shutter opening time has elapsed based on the photometric data, the shutter solenoid 52 is driven to close the first and second sectors 74 and 76. It moves to the position and the shutter is closed.
[0088]
During the shutter opening period, the subject luminous flux taken in via the prism 33 passes through the photographing lens system, forms an image on the imaging surface of the CCD 55, and exposure is performed. Under the control of the CPU 170, an imaging signal within the exposure time is output from the CCD 55 and converted into a video signal. The video signal is once recorded in the built-in memory 130, then subjected to a predetermined process by the image processing circuit 140, recorded in the memory card 120, and shooting is completed.
[0089]
As described above, according to the lens barrel 10 incorporated in the camera of the present embodiment, first, when adjusting the amount of light, the ND filter 67 of the ND filter unit is moved substantially in the X direction (that is, the optical axis O1 and Since the slide movement is performed in a direction orthogonal to the optical axis plane including the optical axis O2, the thickness of the lens barrel 10 in the optical axis O1 direction (Z direction) can be reduced.
[0090]
Similarly, the sectors 74 and 76 of the shutter unit can be similarly opened and closed by sliding in the X direction, and the thickness of the lens barrel 10 in the optical axis O1 direction (Z direction) can be reduced. it can.
[0091]
Further, the ND filter unit 47 and the shutter unit 48 are arranged in different plane areas in the optical axis O2 direction. That is, the ND filter unit 47 is disposed in the lower part on the first group frame 31 side, and the shutter unit 48 is disposed on the upper surface part of the second group frame 38 disposed so as to be able to advance and retract. Therefore, the arrangement of the lens barrel in the optical axis O2 direction is simplified, and the height of the lens barrel 10 in the Y direction can be reduced.
[0092]
An ND filter driving solenoid 51 and a sector driving solenoid 52 arranged on the left side of the prism 33 of the first group frame 31 are arranged in parallel along the optical axis O1, and further below the solenoid portion. First and second step motors 53 and 54 for advancing and retracting the second and third group frames are arranged on the left side of the optical axis O2 of the fixed frame 32. That is, the solenoids 51 and 52 and the step motors 53 and 54 are arranged in a straight line region on the left side parallel to the optical axis O2 at the side where the shutter unit 48 and the second and third group frames 38 and 39 are disposed. Therefore, the dead space in the lens barrel 10 is extremely reduced. Further, since the bearing portions and the rotor portions of the step motors 53 and 54 are arranged in parallel in the direction of the optical axis O1, and are arranged at positions shifted from each other in the direction of the optical axis O2, the output shaft of the step motor is provided. The lead screw shafts 81 and 83 can be efficiently arranged in a state of being kept parallel along the optical axis O2. Therefore, the lens barrel 10 can be made compact as a whole, and downsizing can be realized.
[0093]
Further, the shaft portion 72 fixed to the swinging end portion of the shutter drive arm 71 moves in a rotation region that avoids the suspension shaft 41, and the second step motor is arranged outside the rotation region of the shaft portion. Therefore, the lens barrel 10 can be compactly assembled from this point.
[0094]
The shaft 72 fixed to the swinging end of the shutter drive arm 71 is provided with a relatively long extension in the direction of the optical axis O2, but is formed of a hollow shaft. Therefore, the moment of inertia around the center of the rotation axis of the shutter drive arm 71 does not become excessive, and the first and second sectors 74 and 76 can be driven at high speed via the shaft portion 72, so that the high-speed shutter can be opened and closed. It becomes possible.
[0095]
Here, a modified example of the ND filter unit 47 applied to the lens barrel 10 will be described using a plan view of the modified ND filter unit in FIG.
The ND filter unit 101 according to the modification includes an ND filter frame 102 that can slide and an ND filter 103 that is held by the ND filter frame 102.
[0096]
The ND filter frame 102 has a shape whose longitudinal direction is the X direction, and the ND filter 103 is held on the right side thereof. Furthermore, the ND filter frame 102 includes linear guide grooves 102b and 102c that extend in the Z direction along both sides of the ND filter 103 and are displaced in the Z direction, and a rack that extends along one end surface on the Z side. 102d.
[0097]
In the guide grooves 102b and 102c, guide pins 31g and 31h that are spaced apart in the Z direction and displaced in the X direction on the first group frame 31 side are slidably fitted. The rack 102d meshes with the output pinion 61 of the ND filter solenoid 51.
[0098]
In the ND filter unit 101, when the output pinion 61 of the ND filter solenoid 51 is rotated in the filter entry direction, the ND filter frame 102 moves in the X (+) direction (that is, light including the optical axis O1 and the optical axis O2). The ND filter unit 103 moves to an approach position that covers the fixed frame opening 32a. Conversely, when the output pinion 61 is rotated in the filter retracting direction, the ND filter frame 102 slides in the X (−) direction, and the ND filter 103 moves to a position retracted from the fixed frame opening 32a.
[0099]
When the ND filter unit 101 of the above modification is applied, a lens barrel that has a small number of constituent members including a driving unit, a small occupied space, and can be made inexpensive and compact can be provided.
[0100]
【The invention's effect】
As described above , according to the present invention , in the lens barrel having the variable magnification optical system, the movable lens group is disposed along the second optical axis, and the exposure opening is within a plane orthogonal to the second optical axis. And a shutter member that opens and closes the shutter, and further moves the shielding member of the shutter unit in a direction substantially orthogonal to the optical axis plane including the first optical axis and the second optical axis, thereby reducing the thickness of the lens barrel. Can be thinned.
Furthermore, by adopting a configuration in which the ND filter is moved in a direction substantially orthogonal to the optical axis plane including the first optical axis and the second optical axis, the thickness of the lens barrel can be further reduced. .
Further, the shutter drive source and the filter drive source are arranged in parallel in the first optical axis direction, the first and second lens drive sources are arranged in parallel in the first optical axis, and the second optical axis direction is arranged. Further, the lens barrel can be further reduced in size and thickness by being disposed at a position displaced substantially linearly.
[Brief description of the drawings]
FIG. 1 is an exploded perspective view of an electronic camera including a lens barrel that is an embodiment of the present invention.
FIG. 2 is a block configuration diagram of an electric circuit of the electronic camera of FIG.
3 is an exploded perspective view of the lens barrel of the electronic camera shown in FIG. 1 as viewed from the back side.
4 is an exploded perspective view of the lens barrel of the electronic camera shown in FIG. 1 as viewed from the back side.
5 is a longitudinal sectional view of the lens barrel of FIG. 3 in a wide state when viewed from the front side.
6 is a longitudinal sectional view of the lens barrel of FIG. 3 in a tele state as viewed from the front side.
7 is a cross-sectional view taken along the line AA in FIG.
8 is a cross-sectional view taken along the line DD of FIG.
9 is a cross-sectional view taken along the line BB of FIG.
10 is an exploded perspective view around the first group frame portion (ND filter unit portion) of the lens barrel in FIG. 3; FIG.
11 is a view as seen from the direction of the arrow C in FIG. 5 and shows a rotation range of the shutter drive arm. FIG.
12 is an exploded perspective view around the shutter unit portion of the lens barrel of FIG. 3; FIG.
FIGS. 13A and 13B are views taken along the line E-E in FIG. 12, in which FIG. 13A shows the shutter open state, and FIG. 13B shows the shutter closed state.
14 is a diagram showing a shape of a shutter drive arm applied to the lens barrel of FIG. 3 and a state of attaching an adhesive fixing die, and FIG. 14 (A) is an enlarged sectional view of the shutter drive arm. FIG. 14B is an enlarged cross-sectional view showing a state where the shutter drive arm and the shaft portion are attached to and bonded to an adhesive fixing jig.
15 is a perspective view of a state in which a connection FPC is mounted on the lens barrel of FIG. 3 as viewed from the front side.
16 is a perspective view of a state in which a connection FPC is mounted on the lens barrel of FIG. 3 as viewed from the back side.
17 is a plan view of a modified example of the ND filter unit applied to the lens barrel of FIG. 3; FIG.
[Explanation of symbols]
33 ... Prism (reflection optical member)
35 ... 2 group lens (lens group, variable magnification optical system)
36 ... 3 group lens (lens group, variable magnification optical system)
38 ... 2 group frame (holding frame, first movable holding frame)
39 ... 3 group frame (holding frame, second movable holding frame)
48 ... Shutter unit (light quantity adjusting member, shutter means)
51 ... Solenoid for ND filter (drive source, drive source for filter)
52. Shutter solenoid (drive source, shutter drive source)
53 .. First step motor (lens drive source)
54 ... Second step motor (lens drive source)
67 .. ND filter (light quantity adjusting member)
74 ... 1st sector (light quantity adjustment member, shielding member)
76 ... 2nd sector (light quantity adjustment member, shielding member)
O1 ... first optical axis O2 ... second optical axis

Claims (4)

In a lens barrel having a variable magnification optical system composed of a plurality of lens groups,
A reflective optical member that reflects a light beam incident from a subject along a first optical axis so as to be along a second optical axis that intersects the first optical axis;
First and second movable lens groups disposed along the second optical axis;
A first movable holding frame that holds the first movable lens group so as to be displaceable along the second optical axis;
A second movable holding frame that holds the second movable lens group so as to be displaceable along the second optical axis;
It is displaced along the second optical axis integrally with the first movable holding frame, and moves to a position where the exposure opening is shielded and opened in a plane substantially perpendicular to the second optical axis. Shutter means having a possible shielding member;
A shutter drive source for driving the shielding member;
A lens driving unit for displacing the first movable holding frame and the second movable holding frame along the second optical axis;
An ND filter that is movable in a plane perpendicular to the second optical axis to a position that enters the imaging optical path and a position that retreats;
A filter drive source for driving the ND filter;
Comprising
The shielding member moves in a direction substantially orthogonal to a plane including the first optical axis and the second optical axis;
The ND filter moves in a direction substantially orthogonal to a plane including the first optical axis and the second optical axis,
The shutter drive source and the filter drive source are arranged in parallel in the first optical axis direction,
The lens driving unit is disposed at a position substantially linearly displaced in the second optical axis direction with respect to the shutter driving source and the filter driving source.
A lens barrel characterized by that . The lens barrel according to claim 1, wherein the shutter drive source and the filter drive source are solenoids.   The lens barrel according to claim 1, wherein the lens driving unit is arranged in parallel with the first optical axis.   A third lens group frame that holds the third lens group in a displaceable manner along the second optical axis;
  2. The lens barrel according to claim 1, wherein the third lens group frame is displaced in a direction of the second optical axis to perform focus driving. 3.

Images