JP2011033684A - Lens barrel and imaging apparatus having the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a lens barrel for effectively preventing adherence of dust to a distance information display member and a part viewed from the outside being a distance information observation window, and facilitating miniaturization of the lens barrel. <P>SOLUTION: The lens barrel includes: a first cylinder for providing the distance information observation window on the periphery; a drive part for driving a lens holding frame holding a lens; a rotation member rotated by being interlocked with the drive part; and a distance information display member for displaying a position of the lens holding frame provided on the periphery of the rotation member as distance information. The lens barrel observes the distance information of the distance information display member through the distance information observation window. The distance information display member is wound on a circular cylinder of one circumference or more on the periphery of the rotation member to cover the outer periphery of the drive part with a rectangular sheet member displaying the distance information on one face. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a lens barrel suitable for observing distance information in the optical axis direction of a lens displayed on a distance information display member through a distance information observation window provided in a part of a fixed cylinder, and relates to a digital camera and a video camera. It is suitable for an imaging device (camera) such as the above.

  2. Description of the Related Art Conventionally, as a distance information display device that indicates distance information between a camera (imaging device) and a subject, a configuration in which a distance information display member is interlocked with a drive unit that drives a focus lens is known. Specifically, distance information at each position in the optical axis direction of the focus lens is described (formed) on a distance information display member. The distance information formed on the distance information display member can be observed through a transparent window part attached to the exterior of the lens barrel (Patent Documents 1 and 2). Patent Document 1 discloses a lens barrel including an optical member made of a cylindrical lens in a window portion in order to improve the visibility of a distance information display member. Patent Document 2 discloses a lens barrel having a configuration in which a distance information display member bulges to the outer diameter side and the distance information display member is brought close to a window portion.

JP 2005-266675 A JP 2000-056204 A

  If there is a lens driving unit inside the lens barrel, dust is generated as the driving unit is driven. Such dust may adhere to parts such as a distance information display member and a distance information observation window (observation window) that can be seen from the outside. From the viewpoint of dust adhesion, the lens barrel disclosed in Patent Document 1 tends to deposit dust on the distance information display member and the observation window. The lens barrel of Patent Document 1 does not have an overlap structure or a structure for catching dust from a rotor, a stator driving unit, and a distance information display member, which are considered to be main sources of dust (such as wear powder). For this reason, the dust generated in the drive unit can easily reach the distance information display member and the observation window. In the lens barrel of Patent Document 2, the distance information display member and the observation window are separated from the drive unit, which is advantageous from the viewpoint of dust adhesion. However, there is a layout restriction that a part cannot be interposed between the distance information display member and the window, and it is difficult to reduce the size of the lens barrel. In addition, when moving image shooting is performed, it is necessary to perform focus adjustment at a lower speed than still image shooting. Therefore, even with the same defocus amount, the driving time becomes longer or the shooting time itself becomes longer. For this reason, such a lens barrel has a large amount of dust generated from the drive unit, and some measures against dust are required.

  An object of the present invention is to provide a lens barrel that can effectively prevent dust from adhering to a portion visible from the outside, such as a distance information display member and a distance information observation window, and can easily reduce the size of the lens barrel. .

  The lens barrel of the present invention includes a first tube having a distance information observation window on the circumference, a driving unit that drives a lens holding frame that holds the lens, and a rotation that rotates in conjunction with the driving unit. And a distance information display member that displays the position of the lens holding frame provided on the circumference of the rotating member as distance information, and the distance information of the distance information display member via the distance information observation window In the lens barrel configured to be observable, the distance information display member has a rectangular sheet member on which the distance information is displayed on one surface at least once on the periphery of the rotating member so as to cover the outer periphery of the driving unit. It is characterized by being wound in a cylindrical shape.

  According to the present invention, it is possible to effectively prevent dust from adhering to externally visible parts such as a distance information display member and a distance information observation window, and a lens barrel that can be easily downsized is obtained.

Sectional drawing of Example 1 when the lens barrel of this invention is applied to a lens interchangeable digital single-lens reflex camera Sectional view of the focus unit 108 of FIG. 1 is a perspective view of the focus unit 108 of FIG. 1 is a development view of the distance information display member 108a in FIG. Overall view (A) and enlarged view (B) of distance information display member 108a and rotating member 108b in FIG. Sectional drawing of the focus unit 108 in Example 2 of this invention.

  Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The lens barrel of the present invention has a first cylinder (front frame) 28 provided with a distance information observation window (observation window) 44 on the circumference. A driving unit 108 h that drives the lens holding frame (second group barrel) 32 that holds the lens (lens unit) 102 is provided. Further, a rotation member 108b that rotates in conjunction with the drive unit 108h, and a distance information display member 108a that displays the position of the lens holding frame 32 provided on the circumference of the rotation member 108b as distance information are provided. The distance information display member 108a is configured to be able to observe the distance information through the distance information observation window 44. The distance information display member 108 a is configured by winding a rectangular sheet member 108 aa on which distance information is displayed on one surface A in a cylindrical shape at least once around the rotation member 108 a so as to cover the outer periphery of the drive unit 108 h. Yes. At one end 108a-5 of the sheet member 108aa, one or more reference lines 108a-2 serving as a reference when being bonded to the other end side are formed.

  FIG. 1 is a cross-sectional view of a main part when a lens barrel according to an embodiment of the present invention is applied to a lens interchangeable digital single-lens reflex camera (imaging device). In FIG. 1, the direction of the lens optical axis (imaging optical axis) AXL is the Z direction, the direction orthogonal to the lens optical axis AXL, and the horizontal direction of the two directions parallel to the imaging surface 6 is the X direction, The vertical direction is the Y direction. Reference numeral 1 denotes a camera body (hereinafter simply referred to as a camera). An interchangeable lens 2 is detachably attached to the camera 1. First, the structure of the camera 1 will be described. In the state shown in FIG. 1, the main mirror 3 is disposed on the optical path of the light beam from the interchangeable lens 2, reflects a part of the light beam, guides it to the finder optical system FO (7, 8), and the remaining light beam. Permeate. A sub-mirror 4 is arranged behind the main mirror 3 (image side), and reflects the light beam that has passed through the main mirror 3 to guide it to the focus detection unit 5. The main mirror 3 and the sub mirror 4 can be integrally retracted from the optical path by a drive mechanism (not shown).

  The focus detection unit 5 has a function of performing focus detection (detection of the focus state of the interchangeable lens 2) by a so-called known phase difference detection method. The focus detection unit 5 includes a separator lens that divides an incident light beam into two light beams, and two lenses that re-image a subject image with the divided light beams. Furthermore, it is composed of a line sensor such as a CCD sensor that photoelectrically converts two formed subject images. The line sensor is arranged in a cross shape so as to detect the image position of the subject in the vertical direction (Y direction) and the horizontal direction (X direction). Reference numeral 6 denotes an image sensor constituted by a CCD sensor or a CMOS sensor, and an object image (image) by a light beam from the interchangeable lens 2 is formed on the light receiving surface (image pickup surface) of the image sensor 6. The imaging element 6 photoelectrically converts the formed subject image and outputs an imaging signal. The exposure amount of the image sensor 6 is controlled by an electronically controlled focal plane shutter (not shown).

  The finder optical system FO includes a pentaprism 7 as an image reversing unit and an eyepiece lens 8. Reference numeral 9 denotes a display panel, which has a function of displaying an image output from a signal processing unit (not shown) that receives a signal from the image sensor 6 and various other shooting information. The interchangeable lens 2 includes a first lens unit 101 as a fixed lens, a second lens unit 102 as a focus lens, and a third lens unit 103 as a fixed lens in order from the subject side to the image side. Furthermore, it has a fourth lens unit 104 as a focus lens, a fifth lens unit 105 as an anti-vibration lens, and a sixth lens unit 106 as a fixed lens. The aperture unit 107 is disposed on the front side (object side) of the third lens unit 103, and adjusts the amount of light that passes through the interchangeable lens 2 and reaches the camera 1 side. The lens units 101 to 106 and the diaphragm unit 107 constitute a part of the photographing optical system.

  The second lens unit 102 and the fourth lens unit 104 receive a driving force from the focus unit 108 and move on the optical axis AXL to perform focus adjustment. The interchangeable lens 2 of the present embodiment is a photographic lens having a single focal length, but may be a zoom lens having a zoom function. The focus unit 108 includes a rotating member 108b that rotates in conjunction with the drive unit 108h, and a distance information display member 108a provided on the rotating member 108b. The distance information of the distance information display member 108a can be observed from the outside through a distance information display window (distance information observation window) 44 attached to the front frame (first cylinder) 28.

  Next, the structure of the lens barrel of the interchangeable lens 2 will be described. Reference numeral 21 denotes a fixed cylinder, an attachment part 21a of the guide cylinder 22, an attachment part (not shown) of the exterior ring 30, an attachment part (not shown) of the shake correction lens driving device 39, and an attachment part of the sixth group lens barrel 36. 21b, an attachment portion (not shown) for attaching the circuit board 42, and the like. In addition, in the attachment part 21a of the fixed cylinder 21, it is fixed to the guide cylinder 22 by a method such as fastening. In addition, the fixed cylinder 21 is fixed to the mount 40 via the outer ring 30 by a method such as fastening at an outer ring mounting portion (not shown). Further, since the shake correction lens drive device mounting portion (not shown) and the shake correction lens drive device 39 are fixed via a roller (not shown), the eccentric cylinder is used to fix the lens to the fixed cylinder 21. The inclination of the five lens unit 105 can be adjusted. In the sixth group barrel attachment portion 21b, the sixth group barrel 36 is fixed by a method such as fastening.

  Reference numeral 22 denotes a guide cylinder (second cylinder), a first rectilinear groove (guide groove) 22a, a second rectilinear groove (guide groove) 22b, an attachment part 22c for the fixed cylinder 21 and an attachment part for the front fixed cylinder 23. 22d. Further, the mounting portion 22e of a member on which a sensor for detecting angular velocity and acceleration is mounted has a mounting portion (not shown) for the focus unit 108 and a mounting portion (not shown) for the third group barrel 33. Further, a bayonet portion 22f for restricting movement of the cam tube 24 in the thrust direction (optical axis direction) is provided with a groove portion provided on the second tube 22 with a plurality of notches in the circumferential direction. The first rectilinear groove 22a guides the second group lens barrel 32 for focusing, and the second rectilinear groove 22b guides the fourth group lens barrel 34 for focusing. The third group barrel mounting portion (not shown) and the third group barrel 33 are fixed via a roller (not shown). The guide tube 22 has a notch (not shown) offset from the locus of a focus roller (not shown) attached to the cam tube 24. In addition, a holding plate mounting portion (not shown) for holding a flexible printed circuit board that supplies power to a diaphragm unit 107 described later is provided.

  Reference numeral 23 denotes a front fixed cylinder, which has an attachment part 23 a for the guide cylinder 22, an attachment part 23 b for the front frame 28, and an attachment part (not shown) for the first group barrel 31. The first group barrel mounting portion includes a restricting portion that restricts the movement of the first group barrel 31 in the optical axis direction and a contact portion of the roller. The first group barrel, that is, the first lens unit 101 is configured to be adjustable in eccentricity with respect to the front fixed barrel 23. Reference numeral 24 denotes a cam cylinder (first cylinder) having a first cam groove (cam groove) 24a, a second cam groove 24b, and an attachment portion (not shown) for a focus roller (not shown). In addition, a plurality of protrusions 24 c are provided in the circumferential direction of the first tube 24 that engages with the bayonet portion 22 f of the guide tube 22. The cam cylinder 24 is disposed inside the guide cylinder 22 and is diameter-fitted at two locations, the front and rear ends.

  Reference numerals 25 and 26 denote a first cam follower and a second cam follower, respectively. The first cam follower 25 fixed to the second group barrel 32 engages with the first cam groove 24a of the cam barrel 24 and the first rectilinear groove (first guide groove) 22a of the guide barrel 22. The second cam follower 26 fixed to the fourth group lens barrel 34 engages with the second cam groove 24 b of the cam cylinder 24 and the second rectilinear groove (second guide groove) 22 b of the guide cylinder 22. When the focus unit 108 is driven, a key unit (not shown) that is an output unit of the focus unit 108 rotates around the optical axis. Further, a focus roller (not shown) is engaged with the key portion, and the rotation is transmitted to the cam cylinder 24 which is a mounting member for the focus roller. By rotation of the cam barrel 24, the second group barrel 32 moves in the optical axis direction via the first cam follower 25 while following the relative relationship between the first rectilinear groove 22a and the first cam groove 24a. Similarly, the fourth group barrel 34 moves in the optical axis direction through the second cam follower 26 while following the relative relationship between the second rectilinear groove 22b and the second cam groove 24b. The above is the function of the cam followers 25 and 26.

  Reference numeral 27 denotes a focus ring, which has a guide groove portion 27a that engages with a roller (not shown) fixed to the focus unit 108 to restrict movement in the optical axis direction and hold it rotatably. Further, it has a groove 27 b that engages with a protrusion (not shown) of the focus unit 108 of the focus ring 27 and transmits the rotation of the focus ring 27 to the focus unit 108. The focus unit 108 includes a drive source (not shown), a key portion (not shown), and a projection (not shown) that engages with the focus ring 27. The drive source and the electric circuit board 42 are connected by a flexible printed circuit board or the like, and the drive source is driven by a drive signal from the electric circuit board 42. Reference numeral 28 denotes a front frame, which attaches the attachment portion 28a of the front fixed cylinder 23, the screw portion 28b for attaching accessories such as a filter, the flange portion 28c for attaching accessories such as a hood, and the distance information display window 44. Part (not shown). Reference numeral 29 denotes a decorative ring, which is screwed and fixed to the screw portion 28b of the front frame 28.

  Reference numeral 30 denotes an exterior ring, which is a cover member that covers internal parts for decoration. Between the fixed cylinder 21 and the mount member 40, it has an attachment part (not shown) fixed by fastening together. Further, an operation member (not shown) for switching the focus and the image stabilization function is attached. Reference numeral 31 denotes a first group barrel, which has a contact portion with the front fixed barrel 23 and an attachment portion (not shown) for fixing a roller (not shown). Reference numeral 32 denotes a second group lens barrel (lens holding frame) for focusing, which has a seat portion 32a for fixing the first cam follower 25 and a guide portion 32b for engaging with the arm portion 38c of the sub-aperture device 38. Reference numeral 33 denotes a fixed third group barrel, which has an attachment portion (not shown) fixed to the guide cylinder 22 via a roller (not shown). Further, it has a shape that surrounds an attachment portion (not shown) of the diaphragm unit 107 and a drive portion (not shown) of the main diaphragm device 37. Reference numeral 34 denotes a fourth group lens barrel (lens holding frame) for focusing, and has a seat portion 34 a for fixing the second cam follower 26.

  Reference numeral 35 denotes a fifth lens barrel for image stabilization, which has a function of performing camera shake correction by shifting in a plane parallel to the optical axis by the drive unit 39a of the lens drive device 39 for shake correction. Reference numeral 36 denotes a fixed sixth group lens barrel, which has an attachment portion 36 a fixed to the fixed cylinder 21. The first group barrel 31 to the sixth group barrel 36 are components of the first lens unit 101 to the sixth lens unit 106, respectively. Reference numeral 37 denotes a main diaphragm device, which is disposed on the object side of the third group barrel 33 and includes a plurality of diaphragm blades 37a, a drive member (not shown), and a cover member (not shown). A flexible printed circuit board (not shown) has one end connected to the main diaphragm 37 and the other connected to the electric circuit board 42. The diaphragm blade 37a is driven by the drive signal from the electric circuit board 42 to restrict the passing light beam. The main aperture unit 37 and the sub aperture unit 38 constitute the aperture unit 107. A sub diaphragm 38 is arranged on the object side of the main diaphragm 37, and includes a plurality of diaphragm blades 38a and a rotating member 38b that rotates to open and close the diaphragm blades 38a. Further, the arm portion 38 c extending from the rotating member 38 b is engaged with the guide portion 32 b of the second group barrel 32. The structure is such that the diaphragm blade 38a is opened and closed by rotating the arm portion 38c, that is, the rotating member 38b by the rectilinear movement of the second group lens barrel 32 when focusing.

  The shake correction lens driving device 39 includes a fifth group barrel 35 (movable portion) that corrects camera shake by shifting in a plane perpendicular to the optical axis, and a drive unit 39a that drives the fifth group barrel 35. Have. Furthermore, the flexible printed circuit board (not shown) has one end connected to the drive unit 39a of the shake correction lens driving device 39 and the other connected to the electric circuit board 42. The fifth lens barrel 35 is driven by a drive signal from the electric circuit board 42. Reference numeral 40 denotes a mount member, which includes an opening 40a, a flange 40b for attaching to the camera body, and a seat (not shown) for fastening to the fixed cylinder 21. Further, a back cover 43 is attached to the opening of the mount member 40, and the inner diameter portion of the back cover 43 is subjected to flocking treatment for preventing reflection. Reference numeral 41 denotes a contact member, which has a contact portion 41a having one end connected to the electric circuit board 42, and contacts the contact portion of the camera body when attached to the camera body to transmit information to the camera body. It has become. The electric circuit board 42 performs various driving operations and information transmission processing with the camera in the lens. In a lens barrel having such a configuration, when a release button (not shown) is operated, after the autofocus and exposure determination operations, the image sensor is exposed and the acquired image is recorded. The above is description of each member. Next, the interrelationships of main components related to the lens barrel of the present embodiment will be described.

[Example 1]
The configuration of the lens barrel according to the first embodiment of the present invention will be described below with reference to FIGS. 2 to 5 are explanatory views of a part of the lens barrel 2 shown in FIG. 2 to 5 show an enlarged view, a perspective view, a developed view of the distance information display member 108a, and a schematic view of the distance information display member 108, respectively, of the focus unit 108 described above. The drive mechanism of the focus unit 108 will be described with reference to FIG. The distance information display member 108a is formed of a rectangular sheet member 108aa as shown in FIG. 4, and distance information 108a-1 is described on the A surface side (outer diameter side), and along the outer peripheral surface of the cylindrical rotating member 108b. By sticking them together, they are cylindrical and integrated with the rotating member 108b. A fixed member 108e is provided with a rotation angle detector (not shown) that detects the rotation of the rotating member 108b. The rotating member 108b rotatably holds the rollers 108i (three places) shown in FIG. 3, and the connecting ring 108f connected to the focus ring 27 and the rotor 108c are provided with contact surfaces with the rollers 108i. The roller 108i is sandwiched between the contact surfaces. Reference numeral 108d denotes a stator, and the rotor 108c, the roller 108i, and the connecting ring 108f are pressed against the fixed member 108e by the pressing member 108g. When vibration is generated in the stator 108d by a piezoelectric element (not shown), the rotor 108c is rotated by vibration waves generated on the contact surface between the stator 108d and the rotor 108c. The focus lens drive unit 108h includes a rotor 108c and a stator 108d, and corresponds to a drive unit that drives the focus lens 102.

  When the rotor 108c rotates, the rotating member 108b rotates with respect to the fixed member 108e by the rolling of the roller 108i. In this embodiment, the rotating member 108b is interlocked so as to make a half rotation with respect to one rotation of the rotor 108c. When the focus ring 27 is manually operated, the connecting ring 108f rotates and the roller 108i rolls, whereby the rotating member 108b rotates with respect to the fixed member 108e. The cam cylinder 24 is rotated through a focus key (not shown) fixed to the rotating member 108b by the rotation of the rotating member 108b, and the second and fourth lens units 102 and 104 are driven straightly. The focus adjustment is performed by moving the focus lens by moving the second and fourth lens units 102 and 104 as described above. This completes the description of the drive mechanism of the focus unit 108. Hereinafter, features of the present embodiment will be described. In the present embodiment, the distance information display member 108a is provided on the entire outer diameter side so as to cover the drive unit 108h. This makes it difficult for dust generated in the driving unit 108h to adhere to the information display surface A and the distance information display window (distance information observation window) 44 of the distance information display member 108a. The reason why it is provided on the outer diameter side so as to cover the drive unit 108h is that when the distance information display member 108a has only a part of the phase, the dust generated in the drive unit 108h from the part other than the phase of the front frame 28 Adhere to the inner diameter side. This is because it can be considered to adhere to the surface A on the outer diameter side of the distance information display member 108a.

  In addition, by providing an adhesive such as double-sided tape or glue on the inner surface B of the distance information display member 108a, it is easy to adhere and fix to the rotating member 108b and to remove dust. In the present embodiment, the adhesive is provided on the surface B. However, the adhesive may be provided on both sides of the surface A where the information is not observed through the display window 44. Removing dust with an adhesive not only reduces the amount of dust adhering to parts visible from the outside, such as the distance information display member 108a and the distance information display window 44, but also means that dust enters the lens barrel 2. There is also an effect to prevent. FIG. 4 is a development view of the distance information display member 108a. In FIG. 4, the sheet member 108aa includes distance information 108a-1 and a plurality of reference lines 108a-2. A positioning groove 108a-4 is provided at one end 108a-5 of the distance information display member 108a, and positioning with the positioning protrusion (not shown) of the rotating member 108b is performed. One or more reference lines 108a-2 are provided in the vicinity of one end 108a-5. Thereby, when winding around the rotation member 108b, the shape after winding is obtained by pasting so that the one side 108a-3 of the other end of the distance information display member 108a is parallel to one or more reference lines 108a-2. Can be close to a cylinder. Further, one or more (a plurality of) reference lines are provided in consideration of elongation due to tension at the time of winding. Thereby, even when the sheet member 108aa is wound around the rotating member 108b, it is not necessary to take an unnecessary clearance, so that the rotating member 108b can be easily downsized. This leads to reduction of unnecessary gaps and is effective from the viewpoint of preventing entry of dust.

  Next, the reason why the distance information display member 108a is originally configured by winding a sheet member instead of a ring-shaped member will be described. As described above, it is advantageous to provide an adhesive on the inner surface B of the distance information display member 108a from the viewpoint of preventing the adhesion of dust. When originally a ring-shaped (cylindrical) member is used, a ring-shaped component having an inner diameter with an adhesive is incorporated while being inserted in the optical axis direction of the lens. Compared with this, it is easier to assemble a sheet member having an adhesive on its inner diameter. Further, since there is no need to take unnecessary clearance because of the concern that the adhesive is attached at the time of incorporation, the lens barrel can be easily downsized. FIG. 5 shows an overall view (A) of only the distance information display member 108a and the rotating member 108b as viewed from the subject side, and an enlarged view (B) of the two-dot chain line portion. In the range in which the sheet member 108aa of the distance information display member 108a is overlapped and pasted (corresponding to the position where the sheet member 108aa is overlapped and pasted), the rotating member 108b is shaped as shown in FIG. That is, a step 108b-1 having the same level as the thickness of the sheet member 108aa of the distance information display member 108a is provided on the rotating member 108b (corresponding to the member to be adhered). As described above, in this embodiment, the region where the sheet member 108aa on the circumference of the rotating member 108b is overlapped and bonded is provided with a step corresponding to the thickness of the sheet member 108aa. This prevents the surface (A) on the outer diameter side of the distance information display member 108a from protruding. As a result, it is possible to prevent dust from entering from unnecessary gaps, and further facilitate the downsizing of the lens barrel.

[Example 2]
FIG. 6 is a schematic view of a main part of a lens barrel according to the second embodiment of the present invention. In this embodiment, a cylindrical member 45 is further added to the lens barrel of the first embodiment. Specifically, a cylindrical member 45 is added between the drive unit 108h of the focus unit 108 and the distance information display member 108a. This makes it difficult for dust generated in the driving unit 108h to adhere to the distance information display member 108a and the distance information display window 44. Moreover, by providing (providing) an adhesive to at least one of the inner and outer diameters of the area where the information of the surface A shown in FIG. 6 is not observed through the display window, the surface B, the surface C, and the surface D. More effective garbage prevention is possible. In this embodiment, the cylindrical member 45 is added as a new part, but it may be made of the same member as the front frame 28 and in the same shape. Further, the cylindrical member 45 may be formed by winding a sheet member in the same manner as the distance information display member 108a. As described above, according to the present embodiment, the distance information display member 108a in which the sheet member 108aa is wound in a cylindrical shape is disposed on the outer diameter side so as to cover the drive unit 108h. Accordingly, dust generated from the drive unit 108h hardly reaches the front surface side (outer diameter side) A of the distance information display member 108a, and adhesion of dust such as wear powder can be prevented. Further, at least one reference line is provided at a place where the sheet member 108aa is overlapped and bonded. As a result, the shape after winding can be made closer to a cylinder, so there is no need to take unnecessary clearance from the counterpart part (rotating member), making it easier to reduce the size of the lens barrel and preventing entry of dust. It becomes easy.

108: Focus unit, 108a: Distance information display member, 108h: Focus lens driving unit, 21: Fixed tube, 22: Guide tube, 23: Front fixed tube, 24: Cam tube, 25: First cam follower, 26: Second Cam follower, 27: focus ring, 28: front frame, 32: second group barrel, 33: third group barrel, 34: fourth group barrel, 35: fifth group barrel, 36: sixth group mirror Tube 44: Distance information display window, 108aa: Sheet member, 108a-2: Reference line, 108b: Rotating member, 108h: Drive unit, 108a: Distance information display member

Claims (6)

  A first cylinder provided with a distance information observation window on the circumference; a driving unit that drives a lens holding frame that holds the lens; a rotating member that rotates in conjunction with the driving unit; and a circumference of the rotating member A distance information display member that displays the position of the lens holding frame provided above as distance information; and a lens barrel configured to allow the distance information of the distance information display member to be observed through the distance information observation window The distance information display member is formed by winding a rectangular sheet member having the distance information displayed on one surface thereof in a cylindrical shape at least once around the periphery of the rotating member so as to cover the outer periphery of the driving unit. A lens barrel characterized by having   The lens barrel according to claim 1, wherein at least one reference line serving as a reference when the sheet member is bonded to the other end side is formed at one end of the sheet member.   The lens barrel according to claim 1, wherein an adhesive is provided on a surface or a back surface of the sheet member on which the distance information is displayed.   4. The lens mirror according to claim 1, wherein a region corresponding to the thickness of the sheet member is provided in an area where the sheet member on the circumference of the rotating member is overlapped and bonded. Tube.   A cylindrical member is disposed between the distance information display member and the drive unit, and an adhesive is provided on at least one of the distance information display member or the inner and outer diameters of the cylindrical member. Item 5. The lens barrel according to any one of Items 1 to 4.   An imaging apparatus comprising the lens barrel according to claim 1.