JP4949089B2 - Lens device - Google Patents

Description

  The present invention relates to a lens apparatus, and more particularly to a lens apparatus provided in a portable video imaging apparatus.

  The lens apparatus is provided with a plurality of photographing lenses that move in the optical axis direction, such as a focus lens and a zoom lens (see, for example, Patent Document 1). Usually, such a movable photographic lens has its holding frame engaged with two guide bars, one guide bar acting as the main guide in the optical axis direction, and the other guide bar holding the lens. Acts as a detent for the frame. That is, the lens holding frame is provided with a guide portion that is slidably engaged with the guide bar of the main guide, and a detent portion that engages with the detent guide bar and restricts movement in the rotational direction. It is done. The guide part has a predetermined length in the axial direction to prevent the lens holding frame from rattling, and the lens holding frame moves in the optical axis direction when the guide part slides on the guide bar. Is done.

By the way, when a plurality of movable photographing lenses are provided, a common guide bar is used in the lens holding frame of each photographing lens. For example, in a lens apparatus including a zoom lens and a focus lens, a guide bar on the zoom lens side and a guide portion on the focus lens side are engaged with a guide bar serving as a main guide, and the zoom lens is mounted on a guide bar for rotation prevention. The anti-rotation part on the side and the anti-rotation part on the focus lens side are engaged. Accordingly, a common guide bar can be used for a plurality of photographing lenses, and the number of parts can be reduced to reduce the cost.
JP 2005-114811 A

  However, when the guide bar is shared by a plurality of photographing lenses, there arises a problem that the lens device cannot be reduced in size. That is, since the guide portion requires a predetermined length in the axial direction, when a plurality of guide portions are engaged with one guide bar, a large space is required in the axial direction, and the lens device is in the axial direction. The problem of increasing the size arises.

  Therefore, a method of arranging a plurality of guide portions in two guide bars can be considered. For example, the zoom lens side guide portion is engaged with the first guide bar to be the main guide on the zoom lens side, while the focus lens side guide portion is engaged with the second guide bar to be the focus lens side. The main guide. At that time, the first guide bar is engaged with the anti-rotation portion on the focus lens side, and the second guide bar is engaged with the anti-rotation portion on the zoom lens side. As a result, the two guide portions are divided and arranged in two guide bars, so that the lens device can be miniaturized.

  However, in the above case, since the two guide bars are respectively the main guides, the two guide bars must be attached in parallel to the optical axis with a high degree of accuracy, and much labor is required for assembly work. There was a problem that would be necessary.

  In addition, each guide bar is preferably selected as a selected part according to the processing accuracy of the guide hole of the guide part or for each rod of the guide bar or the guide part, but both of the two guide bars are used as the main guide. In this case, in order to maintain a high degree of parallelism with the optical axis, the design must be changed every time the guide bar is changed, and there is a problem that the guide bar cannot be a selected part. .

  Due to such a problem, conventionally, two guide bars cannot be used as a main guide.

  The present invention has been made in view of such circumstances, and provides a lens device that allows a lens holding frame to be engaged with a plurality of guide bars and that each guide bar can be used as a main guide of the lens holding frame. For the purpose.

In order to achieve the above object, the invention according to claim 1 is engaged with the lens barrel body, a plurality of guide bars supported by the lens barrel body in the optical axis direction, and the plurality of guide bars. And a plurality of lens holding frames supported so as to be movable in the optical axis direction, the lens barrel main body has an opening larger than one end of the guide bar. The one end of the guide bar is inserted into the opening, and the one end of the plurality of guide bars is inserted into the optical axis in the gap between the guide bar and the opening. A pressing member that presses all of the orthogonal directions in the same direction is provided , the opening is a square hole, the pressing member is formed in a triangular prism shape, and the pressing member is inserted into a corner portion of the square hole. Of the guide bar And an end portion of the rectangular side is pressed against the corner portion opposite to the pressing member.

  According to the invention of claim 1, since the end portions of the plurality of guide bars are all pressed and fixed in the same direction by the pressing member, the plurality of guide bars are assembled to the lens device with high parallelism. Thereby, each of the plurality of guide bars can be used as a main guide of the lens holding frame, and the lens device can be downsized.

According to the first aspect of the present invention, since the end portion of the guide bar is inserted and attached to an opening larger than the guide bar, even a guide bar having a different diameter can be fixed to the lens barrel. Therefore, the guide bar can be a selected part. Further, according to the first aspect of the invention, since the end portion of the guide bar is pressed against the corner portion of the square hole, the end portion of the guide bar can be accurately positioned and fixed.

According to a second aspect of the present invention, in the first aspect of the present invention, the pressing member is formed in a shape having a hollow portion by an elastic material.

According to the invention of claim 2 , since the pressing member is an elastic material having a hollow portion, it is easily elastically deformed and can be elastically deformed following the end portion of the guide bar. Therefore, the end portion of the guide bar can be reliably pressed.

According to a third aspect of the present invention, in the first or second aspect of the present invention, the pressing member and the lens barrel main body are provided with positioning means for positioning the pressing member inside the hole. .

According to the invention of claim 3 , since the pressing member and the lens barrel main body can be positioned and fixed, the plurality of guide bars can be pressed and fixed in the exact same direction.

According to a fourth aspect of the present invention, in any one of the first to third aspects, the lens holding frame is slidably engaged with one of the plurality of guide bars. And a non-rotating portion that is engaged with another guide bar of the guide bars and restricts the movement in the rotational direction, and the plurality of lens holding frames are engaged with guide bars with different guide portions. It is characterized by being.

According to the invention of claim 4, a guide bar having a plurality of different lens holding frames is used as the main guide. The present invention is particularly effective when a plurality of guide bars are used as the main guide.

The invention according to claim 5 is the invention according to any one of claims 1 to 4 , wherein the lens barrel main body is formed with a press-fitting opening into which the other end of the guide bar is press-fitted, The wall surface forming the press-fitting opening is formed such that the wall surface pressed by the pressing member is thicker than the wall surface opposite to the pressed side.

According to the invention of claim 5 , since the wall surface of the press-fit opening is thick on the side pressed by the pressing member and is formed thin on the opposite side, the wall surface on the pressed side is not deformed, and the opposite side The wall of the wall is deformed. Therefore, when the end portion of the guide bar is press-fitted into the press-fit opening, the opposite wall surface is elastically deformed, and the end portion of the guide bar is pressed and fixed to the pressed side. At this time, since the pressed wall surface is thick and does not elastically deform, the guide bar can be accurately positioned and fixed with reference to this wall surface. Thus, the guide bar can be fixed parallel to the optical axis by fixing the other end of the guide bar in accordance with the pressing direction of the one end of the guide bar.

  According to the present invention, since the end portions of the guide bar are all pressed in the same direction and fixed by the pressing member, the plurality of guide bars can be assembled to the lens device with high parallelism, and the plurality of guide bars are respectively It can be used as a main guide, and thus the lens device can be miniaturized.

  A preferred embodiment of a lens apparatus according to the present invention will be described in detail below with reference to the accompanying drawings.

  FIG. 1 shows a side sectional view of a lens apparatus 10 according to the embodiment. The lens device 10 includes a first lens group 12, a second lens group 14, a third lens group 16, and a fourth lens group from the front side of the photographing optical axis (subject side) to the rear side of the photographing optical axis (imaging side). The object light that has passed through the first to fourth lens groups 12 to 18 is composed of R, G, B of the color separation prism 20 via the color separation prism 20 constituting the color separation optical system. The image is formed on the image pickup devices 22, 24, and 26 provided at the respective emission ends. A camera body (not shown) equipped with the lens device 10 is subjected to predetermined processing (white balance, γ correction, etc.) on the imaging signals obtained from the imaging elements 22, 24, and 26 in a predetermined format. A signal processing circuit (not shown) for generating a video signal is mounted.

  The first lens group 12 is a so-called front lens, the second lens group 14 is a variator lens that changes the focal length, and the third lens group 16 is an anti-vibration lens that is driven in a direction that cancels vibration caused by camera shake or the like. The fourth lens group 18 is a focus lens that adjusts the focal point.

  These first to fourth lens groups 12 to 18 are held in the lens barrel body 11. In addition, a pair of guide bars 28 and 30 (see FIG. 4) parallel to the optical axis are inserted into the lens barrel main body 11, and a holding frame for the second lens group 14 is disposed on the guide bars 28 and 30. 32 and the holding frame 34 of the fourth lens group 18 are slidably supported, and the housing 36 of the third lens group 16 is fixed to the guide bars 28 and 30. The housing 36 may be directly fixed to the lens barrel body 11.

  The second lens group 14 is provided with a nut (not shown) that constitutes a screw feed device, and a feed screw (not shown) that also constitutes a screw feed device is screwed and connected to the nut. The feed screw is disposed in parallel with the optical axis, and its end is connected to the output shaft of a zoom stepping motor (not shown). When a zoom signal is output from the camera body side to a zoom driver circuit (not shown) of the zoom stepping motor, the zoom stepping motor rotationally drives the feed screw in a direction corresponding to the signal. As a result, the second lens group 14 is moved back and forth in the optical axis direction along the guide bars 28 and 30 and adjusted to a desired focal length.

  Similarly, the fourth lens group 18 is also provided with a nut (not shown) constituting a screw feed device, and a feed screw (not shown) constituting the screw feed device is screwed and connected to the nut. The feed screw is disposed in parallel with the optical axis, and its end is connected to the output shaft of a focusing stepping motor (not shown). When a focus signal is output from the camera body side to a focus driver circuit (not shown) of the focus stepping motor, the focus stepping motor rotationally drives the feed screw in a direction corresponding to the signal. As a result, the fourth lens group 18 is moved back and forth in the optical axis direction along the guide bars 28 and 30 to be focused.

  Next, the structure of the vibration isolation mechanism will be described.

  2 is a perspective view of the housing 36 equipped with the vibration-proof lens 16 as viewed from the rear, and FIG. 3 is a perspective view of the housing 36 shown in FIG.

  As shown in these drawings, a third lens group (here, referred to as an anti-vibration lens for convenience) 16 is held by a lens holding frame 50, and this lens holding frame 50 is within a plane orthogonal to the photographing optical axis L. It is supported so as to be movable in two different directions. Hereinafter, the moving direction of the anti-vibration lens 16 is defined as an X direction (horizontal direction in FIGS. 2 and 3) and a Y direction (vertical direction in FIGS. 2 and 3). Further, a mechanism for moving the image stabilizing lens 16 in the X direction is referred to as an X movement mechanism, and a mechanism for moving in the Y direction is referred to as a Y movement mechanism.

  First, the X movement mechanism will be described.

  A movement guide bar 52 is fixed to the lens holding frame 50. The movement guide bar 52 is disposed in the Y direction, and the slider 54 is engaged with the movement guide bar 52. The slider 54 is formed in an L shape composed of an upper side portion and a left side portion, and two guide portions 56, 56 are formed on the left side portion so as to protrude in the optical axis direction. Guide holes (not shown) are formed in each guide portion 56 in the Y direction, and the moving guide bar 52 is inserted through these guide holes. Thereby, the slider 54 is engaged along the movement guide bar 52 so as to be slidable in the Y direction. Therefore, the lens holding frame 50 is supported by the slider 54 so as to be slidable in the Y direction. Further, the movement of the lens holding frame 50 in the X direction is restricted by the slider 54, and when the slider 54 is moved in the X direction, the lens holding frame 50 is also moved in the X direction.

  Note that the lower end portion 52A of the movement guide bar 52 in the drawing is engaged with the X-direction long hole 58 formed in the housing 36, whereby the lens holding frame 50 falls (inclination with respect to the optical axis direction). Is prevented.

  A guide hole (not shown) in the X direction is formed on the upper side of the slider 54, and the fixed guide bar 60 is inserted into the guide hole. The fixed guide bar 60 is disposed in the X direction, and both ends thereof are fixed to the housing 36. Accordingly, the slider 54 is supported so as to be slidable in the X direction along the fixed guide bar 60. By sliding the slider 54 in the X direction, the lens holding frame 50 engaged with the left side portion of the slider 54 via the moving guide bar 52 is slid in the X direction.

  A planar motor coil (trade name “Fine Pattern Coil” (registered trademark)) 62 is fixed to the upper side of the slider 54, and a flexible printed circuit board (hereinafter referred to as “flexible”) is provided on the lower surface of the motor coil 62. 64 output ends are bonded and fixed. The motor coil 62 is disposed in the X direction around the outer side of the vibration-proof lens 16, and a position sensor 66 such as a Hall element is positioned and fixed to the flex 64.

  The flex 64 is drawn out from the motor coil 62 in the X direction, and is drawn out of the housing 36 through the side opening 68 of the housing 36. The flex 64 drawn to the outside is bent outward, and after a V-shaped (or U-shaped) bent portion is formed, the lens barrel main body from a predetermined position of the lens barrel main body 11 (see FIG. 1). 11 to the outside. The extracted flexible cable 64 is connected to a unit that performs power supply and operation control of the image stabilizing lens 16. The side opening 68 of the housing 36 communicates with the end surface of the housing 36 through a slit 70, and the flexible 64 is disposed inside the side opening 68 by passing the flexible 64 through the slit 70.

  A magnet 72 is disposed outside the motor coil 62 so as to face the motor coil 62. The magnet 72 is formed in a rectangular plate shape, and is arranged so that the S pole 72A and the N pole 72B are arranged in the X direction. The position sensor 66 described above is disposed opposite to the boundary between the S pole 72A and the N pole 72B of the magnet 72, detects a change in the magnetic field, and outputs the detected signal to the unit via the flex 64. .

  A metal plate (not shown) serving as a yoke is provided outside the magnet 72. The metal plate is attracted to the magnet 72 by the magnetic force of the magnet 72. Further, the metal plate is formed in a rectangular shape larger than the magnet 72, and is attached in a state where the edge portion protrudes from the magnet 72. A recess having a size of a metal plate is formed on the outer surface of the housing 36, and an opening 74 having a size of a magnet 72 is formed on the inside thereof. The metal plate is stored in the recess of the housing 36, A magnet 72 is accommodated in the opening 74.

  Inside the motor coil 62, a metal plate 76 serving as a yoke is disposed in the X direction so as to face the motor coil 62. One end of the metal plate 76 is inserted into the slit 70, and the other end is inserted into a groove 78 formed in the housing 36, so that the metal plate 76 is fixed to the housing 36.

  In the X moving mechanism configured as described above, since the motor coil 62 is disposed in the magnetic field formed by the magnet 72 and the two metal plates (one not shown) 76, the motor coil 62 is energized. Thus, the motor coil 62 and the slider 54 that supports the motor coil 62 receive a force in the X direction. Accordingly, the slider 54 and the lens holding frame 50 are moved in the X direction, and accordingly, the image stabilizing lens 16 is moved in the X direction. The above is the structure of the vibration isolation mechanism.

  Next, the Y moving mechanism will be described.

  A movement guide bar 82 is fixed to the lens holding frame 50. The movement guide bar 82 is disposed in the X direction, and a slider 84 is engaged with the movement guide bar 82. The slider 84 is formed in an L shape composed of a lower side portion and a right side portion, and two guide portions 86, 86 are formed on the lower side portion so as to protrude in the optical axis direction. Guide holes (not shown) are formed in each guide portion 86 in the X direction, and the moving guide bar 82 is inserted through these guide holes. Thereby, the slider 84 is engaged along the movement guide bar 82 so as to be slidable in the X direction. Accordingly, the lens holding frame 50 is supported by the slider 84 so as to be slidable in the X direction. The movement of the lens holding frame 50 in the Y direction is restricted by the slider 84, and when the slider 84 is moved in the Y direction, the lens holding frame 50 is also moved in the Y direction.

  A Y-direction guide hole (not shown) is formed in the right side portion of the slider 84, and the fixed guide bar 90 is inserted into the guide hole. The fixed guide bar 90 is disposed in the Y direction, and both ends thereof are fixed to the housing 36. Accordingly, the slider 84 is supported so as to be slidable in the Y direction along the fixed guide bar 90. By sliding the slider 84 in the Y direction, the lens holding frame 50 engaged with the lower side portion of the slider 84 via the moving guide bar 82 is slid in the Y direction.

  A flat motor coil (trade name “Fine Pattern Coil” (registered trademark)) 92 is fixed to the right side of the slider 84, and a flexible printed circuit board (hereinafter referred to as “flexible”) is provided on the left surface of the motor coil 92. The output end of 94 is bonded and fixed. The motor coil 92 is disposed in the Y direction around the outer side of the anti-vibration lens 16, and a position sensor 96 such as a Hall element is positioned and fixed to the flex 94.

  The flex 94 is drawn out from the motor coil 92 in the Y direction, and is drawn out of the housing 36 through the side opening 98 of the housing 36. The flex 94 pulled out to the outside is bent outward, and after a V-shaped (or U-shaped) bent portion is formed, the lens barrel main body from a predetermined position of the lens barrel main body 11 (see FIG. 1). 11 to the outside. The extracted flexible cable 94 is connected to a unit that performs power supply and operation control of the image stabilizing lens 16. The side opening 98 of the housing 36 is communicated with the end surface of the housing 36 through the slit 100, and the flex 94 is disposed inside the side opening 98 by passing the flexible wire 94 through the slit 100.

  A magnet 102 is disposed outside the motor coil 92 so as to face the motor coil 92. The magnet 102 is formed in a rectangular plate shape, and is disposed so that the S pole 102A and the N pole 102B are arranged in the Y direction. The position sensor 96 described above is disposed opposite to the boundary between the S pole 102A and the N pole 102B of the magnet 102, detects a change in the magnetic field, and outputs the detected signal to the unit via the flex 94. .

  A metal plate (not shown) serving as a yoke is provided outside the magnet 102. The metal plate is attracted to the magnet 102 by the magnetic force of the magnet 102. Further, the metal plate is formed in a rectangular shape larger than the magnet 102, and is attached in a state where the edge portion protrudes from the magnet 102. A recess having a size of a metal plate is formed on the outer surface of the housing 36, and an opening 104 having a size of the magnet 102 is formed on the inside thereof. The metal plate is stored in the recess of the housing 36, The magnet 102 is accommodated in the opening 104.

  Inside the motor coil 92, a metal plate 106 serving as a yoke is disposed in the Y direction so as to face the motor coil 92. One end of the metal plate 106 is inserted into the slit 100, and the other end is inserted into a groove 108 formed in the housing 36, so that the metal plate 106 is fixed to the housing 36.

  In the Y moving mechanism configured as described above, since the motor coil 92 is disposed in the magnetic field formed by the magnet 102 and the two metal plates (one is not shown) 106, the motor coil 92 is energized. Thus, the motor coil 92 and the slider 84 that supports the motor coil 92 receive a force in the Y direction. Accordingly, the slider 84 and the lens holding frame 50 are moved in the Y direction, and accordingly, the image stabilizing lens 16 is moved in the Y direction. The above is the structure of the vibration isolation mechanism.

  Next, the attachment mechanism of the guide bars 28 and 30 which is a characteristic part of the present invention will be described. FIG. 4 is a plan view showing the lens apparatus 10 in a state where each component is incorporated in the lens barrel main body 11, and FIG. 5 is a perspective view showing a state in which the guide bars 28 and 30 are incorporated in the lens barrel main body 11. FIG.

  As shown in these drawings, two guide bars 28 and 30 are arranged in the lens barrel body 11 in parallel with the optical axis L. In addition, a holding frame 32 for the second lens group 14, a housing 36 for the third lens group 16, and a holding frame 34 for the fourth lens group 18 are provided inside the lens barrel main body 11. The frame 32, the holding frame 34, and the housing 36 are engaged with the two guide bars 28 and 300.

  The holding frame 32 is integrally formed with a guide part 110 and an anti-rotation part 112. The guide part 110 is elongated in the direction of the optical axis L, and includes guide holes (not shown) through which the guide bar 28 is inserted at both end parts 110A and 110B. The guide hole has substantially the same dimensions as the guide bar 28, and the guide bar 28 is slidably inserted therethrough. Thereby, the guide part 110, that is, the holding frame 32 is slidably supported along the guide bar 28. In addition, in order to prevent the guide part 110 from rattling with the guide bar 28, it is necessary to widen the space | interval of both ends 110A and 110B (namely, guide hole) to the optical axis L direction, and it is elongated in the optical axis L direction. Yes. On the other hand, a groove (not shown) is formed in the rotation stopper 112 from the outside (the lower side in FIG. 4), and the guide frame 30 is engaged with the groove, whereby the holding frame 32 is moved to the guide bar. Rotation about 28 is prevented.

  Similarly to the holding frame 32 described above, the holding frame 34 is integrally formed with a guide portion 114 and a rotation preventing portion 116. The guide portion 114 is elongated in the direction of the optical axis L, and has guide holes (not shown) through which the guide bar 30 is inserted at both end portions 114A and 114B. The guide hole has substantially the same dimensions as the guide bar 30, and the guide bar 30 is slidably inserted therethrough. As a result, the guide portion 114, that is, the holding frame 34 is slidably supported along the guide bar 30. In addition, in order to prevent the guide part 114 from rattling with the guide bar 30, it is necessary to widen the space | interval of both ends 114A and 114B (namely, guide hole) to the optical axis L direction, and it is formed long and thin in the optical axis L direction. Yes. On the other hand, a groove (not shown) is formed in the rotation stopper 116 from the outside (upper side in FIG. 4), and the guide frame 28 is engaged with the groove, whereby the holding frame 34 is moved to the guide bar 30. Rotation around the center is prevented.

  Similarly to the holding frames 32 and 34, the housing 36 is also integrally formed with a guide portion 120 and a rotation preventing portion 122. The guide part 120 is formed elongated in the direction of the optical axis L, and is provided with guide holes (not shown) through which the guide bar 30 is inserted at both end parts 120A and 120B. The guide hole has substantially the same dimensions as the guide bar 30, and the guide bar 30 is slidably inserted therethrough. Thereby, the guide part 120, that is, the housing 36 is slidably supported along the guide bar 30. In addition, in order to prevent the guide part 120 from rattling with the guide bar 30, it is necessary to widen the space | interval of both ends 120A and 120B (namely, guide hole) to the optical axis L direction, and it is elongated in the optical axis L direction. Yes. On the other hand, a groove (not shown) is formed in the rotation stopper 122 from the outside (the upper side in FIG. 4), and the guide bar 28 is engaged with the groove, whereby the housing 36 is guided to the guide bar 30. Rotation around the center is prevented. A concave portion (not shown) is formed on the side surface of the guide portion 120, and the convex portion of the lens barrel body 11 is engaged with the concave portion, thereby positioning in the optical axis L direction. Thereby, the housing 36 is fixed to the lens barrel body 11.

  As described above, the guide portion 28 of the holding frame 32 is engaged with the guide bar 28, and the guide bar 28 functions as the main guide of the second lens group 14. On the other hand, a guide portion 114 of the holding frame 34 is engaged with the guide bar 30, and the guide bar 30 functions as a main guide for the fourth lens group 18. For this reason, the guide bars 28 and 30 are required to have a high degree of parallelism with the optical axis L.

  Incidentally, as shown in FIG. 5, the guide bar 28 has one end 28B press-fitted into a hole (corresponding to a press-fit opening) 124 of the lens barrel body 11 and is fixed, and the other end 28A is fixed. After being loosely inserted into a hole (corresponding to an opening) 128 of the lens barrel main body 11, the lens barrel main body 11 is fixed to the lens barrel main body 11 by a pressing member 132. Similarly, one end 30B of the guide bar 30 is fixed by being press-fitted into a hole (corresponding to a press-fitting opening) 126 of the lens barrel main body 11, and the other end 30A of the lens barrel main body 11 is fixed. After loose insertion in the hole (corresponding to the opening) 130, the lens barrel main body 11 is fixed by the pressing member 134.

  Next, the fixing mechanism of the end portion 28A of the guide bar 28 will be described in detail. FIG. 6 is a perspective view showing the hole 128 of the lens barrel body 11 in a state where the end portion 28A of the guide bar 28 is inserted. 7 is a perspective view showing the pressing member 132 and the end portion 28A of the guide bar 28, and FIG. 8 is a perspective view of the pressing member 132 and the guide bar 28 as viewed from the rear side in FIG.

  As shown in these drawings, the hole 128 of the lens barrel body 11 is a square hole formed in the direction of the optical axis L, and is opened larger than the end portion 28 </ b> A of the guide bar 28. The guide bar 28 is inserted from the front side of the lens barrel main body 11 through the hole 128 and is disposed inside the lens barrel main body 11.

  A stepped portion 136 is formed in the upper portion inside the hole 128 as positioning means for the pressing member 132, and the stepped portion 138 of the pressing member 132 is engaged with the stepped portion 136. Here, of the side surfaces forming the holes 128, the lower surface in FIG. 6 is the surface 128a, the left side surface is the surface 128b, the upper surface is the surface 128c, and the right side surface is the surface 128d.

  On the other hand, the holding member 132 is formed in a substantially triangular prism shape as a whole, and has a size that can be press-fitted into the hole 128 of the lens barrel body 11. The pressing member 132 is formed of a material having a large elastic force such as polyacetal, and a through hole 140 is formed at the center thereof, and has a shape in which a large elastic force acts. Therefore, when the pressing member 132 is press-fitted into the hole 128 of the lens barrel main body 11, the pressing member 132 is fixed to the hole 128 by the large elastic force of the pressing member 132 itself, and the oblique pressing portion 132 x of the pressing member 132 is used. The end 28A of the guide bar 28 can be pressed. The pressing member 132 is formed so that the lower end portion 132a and the left end portion 132b of FIG. 6 protrude, and when the pressing member 132 is press-fitted into the hole 128 of the lens barrel body 11, the lower end portion 132a and the left end portion 132b. Respectively press the surface 128a and the surface 128b of the hole 128, and the pressing member 132 is fixed to the hole 128.

  The pressing member 132 is provided with a stepped portion 138 that is engaged with the stepped portion 136 of the lens barrel main body 11, and the stepped portion 138 is brought into contact with the stepped portion 136 of the lens barrel main body 11. Accordingly, the position of the pressing member 132 in the optical axis L direction is positioned inside the hole 128. Note that the pressing member 132 does not completely enter the hole 128 when the stepped portion 136 and the stepped portion 138 are not aligned.

  As shown in FIG. 6, the pressing member 132 configured as described above is inserted into the upper right corner portion of the hole 128 in a state where the end portion 28 </ b> A of the guide bar 28 is disposed in the lower left corner portion of the hole 128. . At that time, the pressing member 132 is inserted so that the stepped portion 138 of the holding member 132 is aligned with the position of the stepped portion 136 of the hole 128 (that is, the stepped portion 138 is located upward). Thereby, the end portion 28A of the guide bar 28 is pressed and fixed to the lower left corner portion of the hole 128 (that is, to the surfaces 128a and 128b of the hole 128) by the elastic force of the pressing member 132.

  The above is the description of the fixing mechanism of the end portion 28A of the guide bar 28. The fixing mechanism of the end portion 30A of the guide bar 30 is also configured similarly to the fixing mechanism of the end portion 28A of the guide bar 28 described above. That is, the hole 130 of the lens barrel main body 11 is a square hole formed in the direction of the optical axis L, and is opened larger than the end portion 30 </ b> A of the guide bar 30. The guide bar 30 is inserted from the front side of the lens barrel body 11 through the hole 130 and is disposed inside the lens barrel body 11. Further, a stepped portion (not shown) is formed as a positioning means for the pressing member 134 at the upper part inside the hole 130, and the stepped portion (not shown) of the pressing member 134 is engaged with the stepped portion. The step portion of the hole 130 is formed in the same positional relationship as the step portion 136 of the hole 128 described above (that is, the upper side in FIGS. 5 and 6).

  On the other hand, the holding member 134 is made of the same material and has the same shape, and the description thereof is omitted. The pressing member 132 and the pressing member 134 may be common parts. As shown in FIG. 5, the pressing member 134 is inserted into the upper right corner of the hole 130 in a state where the end 30 </ b> A of the guide bar 30 is disposed at the lower left corner of the hole 130. As a result, the end 30A of the guide bar 30 is pressed and fixed to the lower left corner of the hole 130 (ie, to the left and lower surfaces of the hole 130) by the elastic force of the pressing member 134.

  As described above, the end 28A of the guide bar 28 is pressed and fixed to the lower left corner of FIGS. 5 and 6 by the pressing member 132, and similarly, the end 30A of the guide bar 30 is fixed to the pressing member. It is pressed and fixed to the lower left corner of 134. Therefore, the end 28A of the guide bar 28 and the end 30A of the guide bar 30 are pressed and fixed in the same direction.

  In this way, by pressing and fixing the two guide bars 28 and 30 in the same direction, the two guide bars 28 and 30 always have the same plane (the lower side and the left side in FIG. 5) as the reference plane. Therefore, the guide bar 28 and the guide bar 30 can always be fixed with high parallelism.

  Next, the fixing mechanism of the end portion 28B of the guide bar 28 will be described in detail. 9 is a perspective view of the hole 124 into which the end portion 28B of the guide bar 28 is press-fitted, as viewed from the rear, and FIG. 10 is a perspective view of the hole 124 as seen from a different direction from FIG. 11A and 11B are longitudinal sectional views for explaining a fixed state of the end portion 28B of the guide bar 28. FIG.

  As shown in these drawings, the hole 124 of the lens barrel body 11 is a square hole formed in the direction of the optical axis L, and one side thereof is approximately the same size as the diameter of the end portion 28B of the guide bar 28 or slightly. It is formed with small dimensions.

  Of the four side surfaces forming the hole 124, the lower surface in FIGS. 9 and 10 is the surface 124a, the right side surface 124b, the upper surface is the surface 124c, and the left side surface is the surface 124d. 6 and 9 are opposite because the viewing direction is different, the surface 124b of the hole 124 in FIG. 9 and the surface 128b of the hole 128 in FIG. 6 are arranged on the same side, and the surface 124d and the surface 128d Are located on the same side. Further, the vertical relationship is the same, the surface 124a in FIG. 9 and the surface 128a in FIG. 6 are arranged on the same side, and the surface 124c and the surface 128c are arranged on the same side.

  The hole 124 in FIG. 9 is processed with reference to the surfaces 124a and 124b. Specifically, the surfaces 124a and 124b of the hole 124 are processed so as to have the same positional relationship with respect to the optical axis L as the surfaces 128a and 128b of the hole 128 in FIG.

  By the way, the side walls forming the holes 124 are formed such that the surfaces 124a and 124b are thick and the surfaces 124c and 124d are thin. That is, the wall in the pressing direction by the pressing members 132 and 134 described above is thick and the opposite wall is thin. Therefore, the side walls on the surfaces 124a and 124b side of the hole 124 are not easily deformed, and the side walls on the surfaces 124c and 124d side are easily deformed. Therefore, when the end portion 28B of the guide bar 28 is press-fitted into the hole 124, the side walls on the surfaces 124c and 124d side of the hole 124 are elastically deformed, and the end portion 28B of the guide bar 28 is elastically deformed to the surfaces 124a and 124b of the hole 124. Pressed and fixed. At that time, since the side walls of the surfaces 124a and 124b of the hole 124 are formed thick, the surfaces 124a and 124b of the hole 124 are not deformed. For example, as shown in FIGS. 11A and 11B, when the end 28B of the guide bar 28 is press-fitted into the hole 124, the side wall of the surface 124c is deformed to release the stress, while the side wall of the surface 124a is Without being deformed, the guide bar 28 is positioned and fixed in the vertical direction with the surface 124a as a reference. Similarly, the side wall of the surface 124d is deformed to release stress, while the side wall of the surface 124b is not deformed, and the guide bar 28 is positioned and fixed in the left-right direction with reference to the surface 124b.

  Thus, by forming the side walls forming the surfaces 124a and 124b of the hole 124 to be thicker than the side walls of the surfaces 124c and 124d, the end portion 28B of the guide bar 28 can be fixed using the surfaces 124a and 124b as reference surfaces. As a result, both end portions 28A and 28B of the guide bar 28 are fixed with reference to the same side surfaces (that is, the surface 124a, the surface 124b, and the surfaces 128a and 128b), so that the guide bar 28 is parallel to the optical axis L. Can be fixed.

  The above is the description of the fixing mechanism of the end portion 28B of the guide bar 28. The fixing mechanism of the end portion 30B of the guide bar 30 is also configured similarly to the fixing mechanism of the end portion 28B of the guide bar 28 described above. That is, the hole 126 of the lens barrel body 11 is a square hole formed in the direction of the optical axis L, and one side thereof is formed with a dimension that is substantially the same as or slightly smaller than the diameter of the end 30B of the guide bar 30. . The holes 126 are processed with reference to the lower and left surfaces (not shown) in FIG. Specifically, the lower and left surfaces of the hole 126 are processed so as to have the same positional relationship with respect to the optical axis L as the lower and left surfaces (not shown) of the hole 130.

  In FIG. 5, the side wall forming the hole 126 is formed such that the lower side wall and the left side surface are thicker than the upper side and the right side wall. That is, the wall in the pressing direction by the pressing members 132 and 134 described above is thick and the opposite wall is thin. Therefore, the hole 126 is configured such that the side walls forming the lower and left surfaces are not easily deformed, and the side walls forming the upper and right surfaces are easily deformed. Therefore, when the end portion 30B of the guide bar 30 is press-fitted into the hole 126, the side walls forming the upper and right surfaces of the hole 126 are elastically deformed, and the end portion 30B of the guide bar 30 is below the hole 126 by the elastic force. It is pressed and fixed to the left surface. At this time, since the sidewalls forming the lower and left surfaces of the hole 126 are formed thick, the sidewalls forming the lower and left surfaces of the hole 126 are not deformed. Therefore, the end 30B of the guide bar 30 can be fixed using the lower and left surfaces of the hole 126 as a reference surface. As a result, both end portions 30A and 30B of the guide bar 30 are fixed on the same side surface (that is, the lower side and the left side surface in FIG. 5), so that the guide bar 30 is fixed in parallel to the optical axis L. can do.

  As described above, according to the present embodiment, the end 28A of the guide bar 28 is pressed and fixed to the lower and left surfaces (in FIG. 5) in the hole 128 by the pressing member 132, and similarly. The end 30A of the guide bar 30 is pressed and fixed to the lower and left surfaces (in FIG. 5) in the hole 130 by the pressing member 134. Further, the end portion 28B of the guide bar 28 is positioned and fixed to the lower and left side surfaces (in FIG. 5) in the hole 126, and similarly, the end portion 30B of the guide bar 30 is in the hole 128 (in FIG. 5). ) Positioned and fixed on the lower and left surfaces. Therefore, since the two end portions 28A, 28B, 30A, and 30B are pressed and fixed in the same direction, the two guide bars 28 and 30 are fixed in parallel to each other and the optical axis. It can be fixed parallel to L. Therefore, even when the guide bars 28 and 30 are selected parts, the guide bars 28 and 30 can always be fixed parallel to the optical axis L.

  For example, the guide bars 28 and 30 may be changed to pins having slightly different outer diameters depending on the accuracy when the guide holes of the guide portions 110 and 114 of the holding frames 32 and 34 are processed. In addition, since both ends of the guide bars 28 and 30 are pressed and fixed to the same surface of the holes 128 and 130, the guide bars 28 and 30 can be fixed in parallel to the optical axis L. Therefore, when both of the guide bars 28 and 30 are used as the main guide (for example, when the guide bar 28 is used as the main guide of the holding frame 32 and the guide bar 30 is used as the main guide of the holding frame 34 as in the present embodiment). In addition, high optical performance can be obtained.

  In addition, according to the present embodiment, since the two guide bars 28 and 30 can be used as main guides, the guide part 110 of the holding frame 32 and the guide part 114 of the holding frame 34 are provided as separate guide bars. 28, 30. Thus, it is necessary to secure a large installation space for the guide portions 110 and 114 in the optical axis L direction by arranging the guide portions 110 and 114 that are long in the optical axis L direction separately in the two guide bars 28 and 30. Thus, the lens device 10 can be downsized in the optical axis L direction.

  Further, according to the present embodiment, since the holes 128 and 130 of the lens barrel main body 11 are opened larger than the end portions 28A and 30A of the guide bars 28 and 30, the diameters of the guide bars 28 and 30 are changed. The guide bars 28 and 30 can be selected parts.

  Further, in the present embodiment, since the through hole 140 is formed in the pressing member 132 (or 134), the pressing portion 132x is elastically deformed following the end portion 28A (or 30A) of the guide bar 28 (or 30). Therefore, the end portion 28A (or 30A) of the guide bar 28 (or 30) can be reliably pressed by the pressing portion 132x.

  In the above-described embodiment, the end portions 28A and 30A of the guide bars 28 and 30 are each pressed against the lower left corner portion of FIG. 5, but the pressing direction is not limited to this, and the guide is not limited to this. Any direction may be used as long as the bars 28 and 30 are pressed in the same direction. However, it is preferable that the end portions 28B and 30B of the guide bars 28 and 30 are also fixed with reference to the surface in the direction.

  In the above-described embodiment, the holes 128 and 130 of the lens barrel main body 11 are square holes and the pressing members 132 and 134 are formed in a substantially triangular cylindrical shape. However, the shapes of the holes 128 and 130 and the pressing members 132 and 134 are the same. However, the present invention is not limited to this, and any configuration may be used as long as the end portions 28A and 30A of the guide bars 28 and 30 are pressed in the same direction.

  Furthermore, although embodiment mentioned above demonstrated in the example which provided the two guide bars 28 and 30, it is applicable also when providing three or more guide bars. Also in this case, all the guide bars can be fixed with high parallelism by pressing and fixing all the guide bars in the same direction.

Sectional drawing which shows the lens apparatus which concerns on embodiment Perspective view from the rear of the chassis equipped with anti-vibration lens The perspective view which removed the actuator from the housing | casing of FIG. The top view which shows the lens apparatus of the state which incorporated each component in the lens barrel main body The perspective view which shows the state which incorporated the guide bar in the lens barrel main body The perspective view which shows the hole of the lens barrel main body of the state in which the edge part of the guide bar was penetrated The perspective view which shows the edge part of a holding member and a guide bar The perspective view which shows the pressing member and guide bar seen from the back side of FIG. A perspective view of the hole into which the end of the guide bar is press-fitted as viewed from the rear It is a perspective view of the hole seen from the direction different from FIG. Longitudinal sectional view explaining the fixed state of the end of the guide bar

Explanation of symbols

  DESCRIPTION OF SYMBOLS 10 ... Lens apparatus, 11 ... Lens barrel main body, 12 ... 1st lens group, 14 ... 2nd lens group, 16 ... 3rd lens group, 18 ... 4th lens group, 28 ... Guide bar, 30 ... Guide bar, 32 ... Holding frame, 34 ... Holding frame, 36 ... Housing, 110 ... Guide part, 112 ... Anti-rotation part, 114 ... Guide part, 116 ... Anti-rotation part, 120 ... Guide part, 122 ... Anti-rotation part, 128, 130 ... hole, 132, 134 ... pressing member, 136,138 ... stepped portion

Claims (5)

A lens barrel body, a plurality of guide bars supported by the lens barrel body in the optical axis direction, and a plurality of lenses supported to be movable in the optical axis direction by being engaged with the plurality of guide bars In a lens device including a holding frame,
The lens barrel main body is formed with an opening larger than the one end of the guide bar, and the one end of the guide bar is inserted into the opening.
In the gap between the guide bar and the opening, there is provided a pressing member that presses one end of the plurality of guide bars in the same direction perpendicular to the optical axis .
The opening is a square hole, the pressing member is formed in a triangular prism shape, and when the pressing member is inserted into a corner portion of the square hole, one end of the guide bar is connected to the pressing member. A lens device, wherein the lens device is pressed against opposing corner portions . The lens device according to claim 1, wherein the pressing member is formed in a shape having a hollow portion by an elastic material. Wherein the pressing member and the lens barrel body, a lens device according to claim 1 or 2, characterized in that positioning means for positioning said holding member within said bore is provided. The lens holding frame is
A guide portion slidably engaged with one of the plurality of guide bars;
A detent portion engaged with another guide bar of the guide bars to restrict movement in the rotational direction, and
Wherein the plurality of lens holding frame, a lens apparatus according to any one of claims 1-3, characterized in that said guide portion is engaged with the different guide bar. The lens barrel body is formed with a press-fit opening into which the other end of the guide bar is press-fitted,
Walls forming the piezoelectric necessity openings, one wall surface of the side that is pressed by the pressing member, according to claim 1-4, characterized in that it is thicker than the wall surface opposite to the side to be the pressing Or the lens device according to claim 1.

Images