JP2013083694A - Lens barrel and imaging apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a lens barrel having excellent optical performance and an imaging apparatus.SOLUTION: A lens barrel 20 includes a diaphragm member 200 and a lens frame F4 arranged along an optical axis OA in order from an object side and a drive force transmission member 140 transmitting a diaphragm drive force from a camera body 10 to the diaphragm member 200. The drive force transmission member 140 includes an engagement part 110 to which the diaphragm drive force is transmitted from the camera body 10, when the lens barrel 20 is attached to the camera body 10, a mount side arm part 112 extending from the engagement part 110 to an object side, an object side arm part 231 extending from the diaphragm member 200 to a mount side, a relay arm part 141 for relaying between the object side arm part 231 and the mount side arm part 112, to transmit the diaphragm drive force, and a shaft part 143 provided on the relay arm part 141 and serves as the rotation center of the relay arm part 141. The shaft part 143 is configured so as not to transmit a vibration to the lens frame F4.

Description

  The present invention relates to a lens barrel and an imaging apparatus.

  In a high magnification zoom lens barrel, the amount of movement of the aperture during zooming is large. When the aperture is controlled mechanically from the camera body, the transmission system for transmitting the aperture driving force from the camera body to the aperture becomes longer. For this reason, there is a conventional one in which a relay member is provided on a moving lens group located in the middle of the transmission system, and the diaphragm drive from the camera body is relayed by the relay member (for example, see Patent Document 1).

JP-A-5-119367

However, when the aperture is driven, a load is directly applied to the moving lens group that holds the relay member, so that the moving lens group may vibrate and optical performance may be deteriorated.
The subject of this invention is providing the lens-barrel and imaging device which have favorable optical performance.

  The present invention solves the above problems by the following means. In addition, in order to make an understanding easy, although the code | symbol corresponding to embodiment of this invention is attached | subjected and demonstrated, it is not limited to this.

In the first aspect of the present invention, the diaphragm member (200) and the lens frame (F4) arranged in order from the subject side along the optical axis (OA), and the diaphragm driving force from the camera body (10), the diaphragm member. A lens barrel (20) having a driving force transmission member (140) for transmitting to (200), wherein the lens barrel (20) is a camera body (10). An engagement portion (110) to which the diaphragm driving force is transmitted from the camera body (10) and a mount side arm portion (112) extending from the engagement portion (110) toward the subject side The subject driving arm (231) extending from the aperture member (200) to the mount side, and the subject side arm (231) and the mount side arm (112) are relayed to transmit the aperture driving force. A relay arm part (141) for transmission; And a shaft portion (143) serving as a rotation center of the relay arm portion (141). The shaft portion (143) is disposed on the lens frame (F4). Thus, the lens barrel (20) is provided so as not to transmit vibration.
The invention according to claim 2 is the lens barrel (20) according to claim 1, further comprising an annular shaft holding frame (142) for holding the shaft portion (143). The frame (142) is a lens barrel (20) characterized in that vibration is not transmitted to the lens frame (F4).
The invention according to claim 3 is the lens barrel (20) according to claim 2, wherein an elastic member (144, 302,...) Is provided between the shaft holding frame (142) and the lens frame (F4). 303) is arranged, which is a lens barrel (20).
The invention according to claim 4 is the lens barrel (20) according to claim 2 or 3, wherein the shaft holding frame (142) and the lens frame (F4) are provided on the outer peripheral surface. A cylindrical member having a pin (142P) and having a groove (22S) in which the guide pin (142P) of the shaft holding frame (142) and the guide pin (41) of the lens frame (F4) are engaged ( 22). A lens barrel (20).
A fifth aspect of the present invention is the lens barrel (20) according to the second or third aspect, wherein the lens barrel (20) extends along the optical axis (OA), and the shaft holding frame (142) and the lens frame ( A lens barrel (20) including a guide bar (150) for guiding the straight movement of F4).
The invention according to claim 6 is the lens barrel (20) according to claim 4, wherein two guide bars (150) are provided, and the lens frame (F4) and the shaft holding frame ( 142) includes two holes, a through hole (42A, 142Aa) and a loose insertion hole (142Ba, 43A) that can move in the radial direction, and the through hole (42A, 142Aa) is provided. The thickness of the portion in the optical axis (OA) direction is thicker than the portion where the loose insertion holes (142Ba, 43A) are provided, and one of the guide bars (150) has a through hole of the lens frame (F4). (42A, 142Aa) and the loose insertion holes (142Ba, 43A) of the shaft holding frame (142) are inserted, and the other of the guide bar (150) is inserted into the loose insertion holes (142Ba, 142A, 142) of the lens frame (F4). 43A) and the shaft holding frame (1 The through hole (42A in 2), 142Aa) is inserted, a lens barrel, wherein (20).
The invention according to claim 7 is the lens barrel (20) according to any one of claims 1 to 6, wherein the lens barrel (20) is a zoom lens mirror capable of changing a focal length. The cylinder (20) is characterized in that a relative positional relationship among the subject side arm portion (231), the relay arm portion (141), and the mount side arm portion (112) changes according to a focal length. The lens barrel (20).
Invention of Claim 8 is an imaging device (1) provided with the lens-barrel (20) of any one of Claims 1-7.
Note that the configuration described with reference numerals may be modified as appropriate, and at least a part of the configuration may be replaced with another component.

  According to the present invention, it is possible to provide a lens barrel and an imaging apparatus having good optical performance.

1 is a diagram schematically illustrating a camera to which an embodiment of the present invention is applied, in a state where a focal length of a lens barrel is at a wide angle end. FIG. It is a figure which shows the state which the focal distance of the lens-barrel changed to the telephoto side from the figure. It is a conceptual perspective view explaining the structure of the aperture mechanism in 1st Embodiment. FIG. 2 is an enlarged view of a diaphragm mechanism portion in FIG. 1. It is a top view explaining the effect | action of the aperture mechanism in 1st Embodiment. It is an enlarged view of the aperture mechanism part in 2nd Embodiment. It is a figure which shows a vibration suppression connection member. It is a conceptual perspective view explaining the structure of the aperture mechanism which concerns on 2nd Embodiment. It is a conceptual perspective view explaining the structure of the aperture mechanism which concerns on 3rd Embodiment. It is a conceptual perspective view explaining the structure of the aperture mechanism which concerns on 4th Embodiment.

(First embodiment)
Embodiments of the present invention will be described below with reference to the drawings and the like.
1 and 2 are diagrams schematically showing a camera 1 to which an embodiment of a lens barrel and an imaging apparatus according to the present invention is applied. FIG. 1 shows a state in which the focal length of the lens barrel 20 is at the wide-angle end, and FIG. 2 shows a state in which the focal length of the lens barrel 20 has changed to the telephoto side.

  Each drawing described below is provided with an XYZ orthogonal coordinate system for ease of explanation and understanding. In this coordinate system, when the photographer shoots a horizontally long image with the optical axis OA being horizontal, the direction toward the left side as viewed from the photographer at the position of the camera 1 (hereinafter referred to as a positive position) is the X axis plus direction, the positive direction. A direction toward the upper side at the position is a Y-axis plus direction, and a direction toward the subject at the positive position is a Z-axis plus direction. In the following description, the direction parallel to the optical axis OA is referred to as “front-rear”, the subject side is referred to as “front side”, and the other end side is referred to as “back side”.

The camera 1 includes a camera body 10 and a lens barrel 20.
The camera body 10 includes an image sensor 11 that converts an optical image of a subject into an electrical signal, a body side interlocking unit 12 that sets a diaphragm, and a drive unit 13 that drives the body side interlocking unit 12.

The lens barrel 20 is an interchangeable lens that can be attached to and detached from the camera body 10. In the present embodiment, the lens barrel 20 is an interchangeable lens. However, the lens barrel 20 is not limited to this and may be a lens barrel integrated with the camera body.
The lens barrel 20 is a so-called zoom lens having a variable focal length. The lens barrel 20 includes a plurality of lens groups (a first lens group L1, a second lens group L2, a third lens group L3, a fourth lens) constituting an imaging optical system inside an outer cylinder 21 that forms an outer shape. A group L4) and a diaphragm mechanism 100 for adjusting the aperture diameter of the imaging optical system.

Inside the outer cylinder 21, a fixed cylinder 22 and a cam cylinder 23 are arranged concentrically.
A flange portion 21A having a small diameter is formed at the base end portion (end portion on the back side) of the outer cylinder 21, and the outer lens mount 24 and the inner fixing ring are sandwiched between the flange portion 21A and the flange portion 21A. 25 is fastened together. The lens mount 24 is a member that couples the lens barrel 20 to the camera body 10. A zoom operation ring 26 is rotatably mounted on the outer periphery of the outer cylinder 21.

The fixed cylinder 22 has a base end coupled to a fixing ring 25 and is fixed so as not to rotate relative to the outer cylinder 21.
The cam cylinder 23 is rotatably fitted to the inner periphery of the fixed cylinder 22. The cam cylinder 23 is connected to the zoom operation ring 26 via an interlocking mechanism (not shown), and rotates in conjunction with the rotation of the zoom operation ring 26.

  Each lens group L1, L2, L3, L4 constituting the imaging optical system is held by a lens frame (first lens frame F1, second lens frame F2, third lens frame F3, fourth lens frame F4), respectively. And is arranged on the inner periphery of the cam cylinder 23 via the lens frames F1, F2, F3, and F4.

  The first lens group L1 and the second lens group L2 are zooming and focusing lens groups, and a detailed description of the zoom operation ring 26 provided on the outer periphery of the outer cylinder 21 and a focusing motor (not shown) is omitted. They are linked via a linkage mechanism, and are moved in a predetermined relationship in the direction of the optical axis OA by the rotation operation of the zoom operation ring 26 and the rotation of the focusing motor.

The third lens group L3 and the fourth lens group L4 are zooming lens groups, and move in a predetermined relationship in the direction of the optical axis OA by the rotation of the cam cylinder 23 by the rotation operation of the zoom operation ring 26.
That is, the follower pin 31 is implanted in the outer periphery of the third lens frame F 3, and the follower pin 31 is fitted into and penetrates the cam groove 23 A formed in the cam cylinder 23, and the tip thereof is in the fixed cylinder 22. It is fitted in a rectilinear groove 22S parallel to the formed optical axis OA. The fourth lens frame F4 has a follower pin 41 planted on the outer periphery thereof. The follower pin 41 is fitted into and penetrates a cam groove 23B formed in the cam cylinder 23, and the tip thereof is attached to the fixed cylinder 22. It fits in the formed rectilinear groove 22S.

  The cam grooves 22A and 23B formed in the cam cylinder 23 are formed in a substantially spiral shape in which the position in the optical axis OA direction in the circumferential direction changes in a predetermined relationship. Accordingly, the third lens group L3 and the fourth lens group L4 (the third lens frame F3 and the fourth lens frame F4) are respectively in a predetermined relationship by the rotation of the cam cylinder 23 that is interlocked with the rotation of the zoom operation ring 26. It is driven to move in the direction of the optical axis OA. For example, three follower pins 31 and 41 are provided at 120 ° intervals in the circumferential direction. In this case, three cam grooves 23C and rectilinear grooves 22S are also provided in the circumferential direction.

  As described above, the lens groups L1, L2, L3, and L4 constituting the imaging optical system are relatively displaced in the direction of the optical axis OA in a predetermined relationship by the rotation operation of the zoom operation ring 26. The composite focal length of the optical system changes (zooming). FIG. 1 shows the wide-angle end with the shortest focal length, and FIG. 2 shows the long focal side (telephoto side) where the third lens unit L3 and the fourth lens unit L4 are moved to the front side (Z-axis plus side) by the zoom operation. Show.

The aperture mechanism 100 includes an aperture operation ring 110 and an opening limiting plate 120 disposed at the base end portion (inside the lens mount 24) of the outer cylinder 21, and an aperture unit disposed on the front side of the third lens frame F3. 200 and the interlocking mechanism 140 provided in the 4th lens frame F4 located between both.
The aperture mechanism 100 adjusts the aperture diameter by operating the camera body 10 and adjusts the aperture aperture diameter according to the zoom operation of the lens barrel 20. The diaphragm mechanism 100 will be described in detail later.

  The lens barrel 20 configured as described above is attached to the camera body 10 via the lens mount 24, and causes the subject image to be formed on the image sensor 11 by the lens groups L1, L2, L3, and L4. The focal length of the lens barrel 20 changes by rotating the zoom operation ring 26 to move the lens groups L1, L2, L3, and L4 in the direction of the optical axis OA. That is, from the wide-angle end where the focal length shown in FIG. 1 is the shortest, the third lens unit L3 and the fourth lens unit L4 are moved to the front side (Z-axis plus side) by the zoom operation, and the long focal side shown in FIG. Telephoto side).

  Then, as described above, the camera 1 constituted by the camera body 10 and the lens barrel 20 converts the subject light image formed by the lens barrel 20 into an electrical signal by the image pickup device 11, and images Information is recorded in a memory (not shown).

Next, referring to FIGS. 3 to 5 in addition to FIGS. 1 and 2 described above, the diaphragm mechanism 100 which is a feature of this configuration will be described in detail.
FIG. 3 is a conceptual perspective view illustrating the configuration of the diaphragm mechanism 100. FIG. 4 is an enlarged view of the aperture mechanism 100 portion in FIG. FIG. 5 is a plan view for explaining the operation of the aperture mechanism 100.

As described above, the diaphragm mechanism 100 includes the diaphragm operation ring 110, the opening restriction plate 120, the diaphragm unit 200, and the interlocking mechanism 140.
The aperture operation ring 110 is an annular member that is driven in accordance with the aperture operation on the camera body 10 side, and is rotatably mounted inside the lens mount 24 fixed to the base end portion of the lens barrel 20. ing. The aperture operation ring 110 is urged to rotate in a direction to open an aperture blade 220 in an aperture unit 200 described later by an aperture operation ring urging spring (not shown).

The aperture operation ring 110 includes a lens side interlocking unit 111 and is connected to the aperture operation arm 112.
The lens-side interlocking unit 111 protrudes from the rear side (camera body 10 side) of the aperture operation ring 110. The lens side interlocking unit 111 corresponds to the body side interlocking unit 12 provided in the camera body 10, the lens side interlocking unit 111 is pressed by the body side interlocking unit 12, and the aperture operation ring 110 is coupled to the body side interlocking. It rotates in conjunction with the part 12.

  The aperture operation arm 112 extends on the front side (the aperture unit 200 side) of the aperture operation ring 110 with a predetermined length. The aperture operation arm 112 has a plate shape with a predetermined width and a predetermined thickness, and is positioned parallel to the optical axis OA with its plate surface facing the optical axis OA. An engagement slit 113 is formed in the aperture operation arm 112 along the extending direction. The engagement slit 113 is engaged with an engagement protrusion 141A of an interlocking lever 141 in an interlocking mechanism 140 described later, whereby the rotation of the aperture operation ring 110 is transmitted to the interlocking lever 141.

  The open limit plate 120 is a flat plate member having a predetermined width, and is fixed to the lens barrel 20 at the base end portion and disposed in parallel with the optical axis OA. An end edge of the aperture limiting plate 120 that faces the rotation direction of the aperture unit 200 toward the aperture opening side is a correction gradient surface having a predetermined angle, and this correction gradient surface is a second operation protrusion 232 in the aperture unit 200 described later. The aperture diameter of the aperture unit 200 is defined by abutting the aperture.

  The aperture unit 200 includes a holding member 210, an aperture blade 220, an aperture operation member 230, and a fixed frame 240. 3 and 5, the fixed frame 240 is omitted. The aperture unit 200 is mounted on the front side of the third lens frame F3 that holds the third lens unit L3, and moves in the direction of the optical axis OA integrally with the third lens frame F3.

The holding member 210 is a disk-like member that constitutes the skeleton of the aperture unit 200, and is attached to the front side of the third lens frame F3.
A diaphragm blade 220 and a diaphragm operation member 230 are mounted on the front side of the holding member 210.
The aperture blade 220 includes a plurality of arcuate unit blade members that form an aperture opening between the holding member 210 and the aperture operation member 230. The unit blade member includes a pivot pin 221 that is pivotally supported by the holding member 210, and a cam pin 222 that is operated by the aperture operation member 230.

  The diaphragm operating member 230 is an annular member having an opening at the center, and includes a cam groove 223 in which a cam pin 222 of a unit blade member in the diaphragm blade 220 is slidably fitted, and is rotatable by a fixed frame 240. It is supported by. As the diaphragm operating member 230 rotates, the cam groove 223 swings the diaphragm blade 220 to change the aperture diameter of the diaphragm formed by the diaphragm blade 220. The aperture operation member 230 is urged in a direction to open the aperture blades 220 by an urging spring (not shown).

  The aperture operation member 230 includes a first operation protrusion 231 and a second operation protrusion 232. Each of the first operation protrusion 231 and the second operation protrusion 232 has a plate shape with a predetermined width, and has a posture in which the plate surface faces the optical axis OA from the outer peripheral edge portion of the aperture operation member 230 toward the back surface side. A predetermined length is extended in parallel with the optical axis OA.

The first operation protrusion 231 corresponds to the aperture operation arm 112 in the aperture operation ring 110. An operation slit 233 having a predetermined width is formed along the extending direction of the first operation protrusion 231 (FIGS. 1 and 2). An engagement protrusion 141B of an interlocking lever 141 in the interlocking mechanism 140 described later is fitted in the operation slit 233, whereby the first operation protrusion 231 (that is, the aperture operation member 230) is interposed via the interlocking lever 141. The diaphragm operating ring 110 is connected.
The second operation protrusion 232 corresponds to the operation plate portion 122 of the opening restriction plate 120 and is engaged with the operation plate portion 122 by the rotation of the diaphragm operation member 230 toward the aperture opening side.

The interlocking mechanism 140 includes an interlocking lever 141, a lever holding frame 142, a vibration blocking member 144, and the like.
The interlocking lever 141 is a plate having a predetermined thickness and is formed in a predetermined length, and has an engagement protrusion 141A at one end and an engagement protrusion 141B at the other end. The interlocking lever 141 is swingably mounted on the outer peripheral surface of the lever holding frame 142 by a pivot shaft 143 at the center thereof.

  The lever holding frame 142 has an L-shaped cross section and is formed in an annular shape. However, the shape is not limited to the ring, and may be a shape in which a part of the ring is missing. The lever holding frame 142 is externally attached to a small diameter portion on the front side of the fourth lens frame F4 that holds the fourth lens unit L4. FIG. 3 is a conceptual diagram and does not show an extrapolation structure of the lever holding frame 142 to the fourth lens frame F4.

A vibration blocking member 144 is interposed between the front surface of the fourth lens frame F4 and the back surface of the lever holding frame 142.
The vibration isolation member 144 is formed in an annular shape with a rectangular cross section by an elastic material such as rubber having a predetermined elasticity, and is fixed to the fourth lens frame F4 and the lever holding frame on both sides thereof by adhesion or the like. Yes. Accordingly, the vibration blocking member 144 elastically connects the fourth lens frame F4 and the lever holding frame, and allows the displacement in the direction of the optical axis OA by the buffering action to block the transmission of vibration. Acts as follows.

The central axis of the pivot shaft 143 that pivotally supports the interlocking lever 141 is set in the radial direction of the lens barrel 20, whereby the interlocking lever 141 swings in a plane parallel to the optical axis OA. It is like that.
The engagement protrusion 141A at the rear side (right side in FIG. 4) of the interlocking lever 141 is provided on the outer peripheral side, and is fitted into the slit 113 of the aperture operation arm 112 in the aperture operation ring 110 as described above. ing.
Further, the engaging protrusion 141B on the front side (left side in FIG. 4) end of the interlocking lever 141 is provided to protrude on the inner peripheral side, and as described above, the first operation protrusion of the diaphragm operating member 230 in the diaphragm unit 200. 231 is fitted in the operation slit 233.

  In the interlocking mechanism 140 configured as described above, as shown in FIG. 5, the rotation of the diaphragm operating ring 110 swings the interlocking lever 141 via the diaphragm operating arm 112, and the interlocking lever 141 swings. The aperture operation member 230 in the aperture unit 200 is rotated through the first operation protrusion 231.

  When the third lens frame F3 to which the aperture unit 200 is attached and the fourth lens frame F4 to which the interlocking lever 141 is attached are moved relative to each other by a zooming operation, the engagement protrusions 141A and 141B on the interlocking lever 141 are controlled by the aperture operation. This is permitted by moving within the engagement slit 113 of the arm 112 or the operation slit 233 of the first operation protrusion 231 of the aperture operation member 230. Further, the displacement of the engagement protrusions 141A and 141B due to the swinging of the interlocking lever 141 is allowed by changing the fitting position with the engagement slit 113 or the slit 231A.

  That is, in the interlocking mechanism 140, the interlocking lever 141 pivotally attached to the fourth lens frame F4 has the optical axes of the third lens frame F3 (third lens group L3) and the fourth lens frame F4 (fourth lens group L4). The aperture operation ring 110 and the aperture operation member 230 in the aperture unit 200 are interlocked while allowing relative displacement in the OA direction.

In the diaphragm mechanism 100 configured as described above, during the diaphragm operation, the rotation of the diaphragm operation ring 110 is transmitted to the diaphragm unit 200 via the interlocking lever 141, and the diaphragm blade 220 is operated so that the predetermined diaphragm opening is obtained. Set. During the aperture operation, the operating force and the operating vibration act on the fourth lens frame F4 that supports the interlocking lever 141. The operating force and the operating vibration are applied to the fourth lens frame F4, the lever holding frame 142, and the like. Is blocked without being transmitted to the fourth lens frame F4 by the vibration blocking member 144 interposed therebetween.
Thereby, it is possible to suppress the deterioration of the optical performance due to the vibration of the interlocking lever 141 during the diaphragm operation being transmitted to the fourth lens frame F4 (fourth lens unit L4).

(Second Embodiment)
Next, a second embodiment of the present invention shown in FIGS. 6 to 8 will be described. FIG. 6 is an enlarged view of a portion of the diaphragm mechanism 102 in the second embodiment, and corresponds to FIG. 4 in the first embodiment described above. FIG. 7 is an enlarged view showing the vibration suppressing connecting member 300. FIG. 8 is a conceptual perspective view illustrating the configuration of the diaphragm mechanism 102 according to the second embodiment.
The basic configuration and operation of the camera and lens barrel to which the second embodiment is applied are the same as those of the first embodiment described above, and the same reference numerals are given to the components having the same functions. Omitted.

In the interlocking mechanism 140 in the second embodiment, a lever holding frame 142 that supports the interlocking lever 141 is mounted on the front side of the third lens frame F3 via a vibration suppression connecting member 300.
The lever holding frame 142 is formed in an annular shape, and an interlocking lever 141 is pivotally attached to the outer periphery thereof by a pivot shaft 143.

The lever holding frame 142 includes a follower pin 142P that fits in the rectilinear groove 22S of the fixed cylinder 22 on the outer periphery thereof. The follower pin 142 </ b> P is set so as to fit only in the rectilinear groove 22 </ b> S and not protrude to the outer peripheral side of the fixed cylinder 22.
Accordingly, the lever holding frame 142 is provided so as to be movable in the direction of the optical axis OA along the rectilinear groove 22S in a state where movement in the direction orthogonal to the optical axis OA is restricted.
In the second embodiment, unlike the above-described first embodiment, the fixed cylinder 22 is located on the inner peripheral side of the cam cylinder 23.

As shown in the enlarged view of FIG. 8A, the vibration suppression connecting member 300 includes a stud bolt 310, a pair of O-rings 301 and 302, a spring 303, and the like.
The stud bolt 310 has a large-diameter head 311 formed at one end of a shaft having a predetermined diameter, and a male screw portion 312 formed at the other end.
The O-rings 301 and 302 are formed in an annular shape with a circular cross section having a predetermined diameter by a material having predetermined elasticity such as rubber.

The stud bolt 310 penetrates the lever holding frame 142 from the front side, and is fastened to the front side of the fourth lens frame F4 by the male screw portion 312.
An O-ring 301 is interposed between the head 311 of the stud bolt 310 and the front surface of the lever holding frame 142. Further, an O-ring 301 and a spring 303 are interposed between the back surface of the lever holding frame 142 and the front surface of the fourth lens frame F4 with a washer 304 interposed therebetween.
The vibration suppressing connecting member 300 having such a configuration is disposed, for example, at three locations at 120 ° intervals in the circumferential direction.

Accordingly, the lever holding frame 142 is elastically supported in the direction of the optical axis OA by the fourth lens frame F4 by the action of the O-rings 301 and 302 and the spring 303 in the vibration suppressing coupling member 30.
Further, the lever holding frame 142 includes a follower pin 142P provided in the lever holding frame 142 and is fitted in the rectilinear groove 22S of the fixed cylinder 22, so that the direction orthogonal to the optical axis OA (radial direction) with the rectilinear movement of the fourth lens frame F4. Move without blurring.

In the second embodiment, the operation force and the operation vibration that act on the lever holding frame 142 via the interlocking lever 141 during the diaphragm operation are blocked by the vibration suppression connecting member 300.
Thereby, it is possible to suppress the deterioration of the optical performance due to the vibration of the interlocking lever 141 during the diaphragm operation being transmitted to the fourth lens frame F4 (fourth lens unit L4).
Further, in this configuration, the lever holding frame 142 is less affected by the vibration of the interlocking lever 141 because the follower pin 142P is fitted into the rectilinear groove 22S of the fixed cylinder 22 and the movement in the radial direction and the circumferential direction is restricted. it can.

Note that the vibration suppression connecting member may have a configuration in which the spring 303 is omitted as in the vibration suppression connecting member 300 ′ shown in FIG.
That is, in the vibration suppression connecting member 300 ′ shown in FIG. 7B, the stud bolt 310 ′ includes a large-diameter portion 311 with a male screw portion 312 protruding and a support shaft portion 313 extending from the large-diameter portion 311. And a set screw 314 at the tip of the support shaft portion 313. The stud bolt 310 ′ is fastened and fixed to the lever holding frame 142 by the male screw portion 312, and the lever holding frame 142 is supported by the nut 305 fastened to the tip of the support shaft portion 313 via the washer 306 so as not to fall off. Yes. An O-ring 302 is interposed between the large diameter portion 311 and the lever holding frame 142, and an O-ring 301 is interposed between the lever holding frame 142 and the washer 306.

(Third embodiment)
Next, a third embodiment of the present invention will be described. FIG. 9 is a conceptual perspective view illustrating the configuration of the diaphragm mechanism 103 according to the third embodiment.
Note that the basic configuration and operation of the camera and lens barrel to which the third embodiment is applied are the same as those of the first embodiment described above, and components having the same functions are denoted by the same reference numerals. Is omitted.

In the third embodiment, the lever holding frame 142 that supports the interlocking lever 141 of the interlocking mechanism 140 is not connected to the fourth lens frame F4 and is configured independently. In the third embodiment, a pair of guide bars 150 (first guide bars) that guide the straight movement of the third lens group L3 (third lens frame F3) and the fourth lens group L4 (fourth lens frame F4). 151, a second guide bar 152).
The pair of guide bars 150 (151 and 152) are disposed in parallel with the optical axis OA at substantially symmetrical positions with the optical axis OA interposed therebetween.

  The third lens frame F3, the fourth lens frame F4, and the lever holding frame 142 each include a bearing portion (42, 43, 142A, 142B) that is slidably fitted to the guide bar 150 on the outer periphery. Guided by the guide bar 150, it is configured to move straight in parallel with the optical axis OA. In FIG. 9, the bearing portion of the third lens frame F3 is omitted for the sake of simplicity, but includes a bearing portion similar to the fourth lens frame F4 described below.

The fourth lens frame F4 includes a main bearing 42 fitted to the first guide bar 151 and a secondary bearing 43 fitted to the second guide bar 152 on the outer periphery thereof.
The main bearing 42 is provided with a round bearing hole 42 </ b> A that is slidably movable without rattling on the first guide bar 151, and is set to a predetermined fitting width in the axial direction.
The sub-bearing 43 has a plate shape with a predetermined thickness in the axial direction, and has a U-shaped fitting groove 43 </ b> A that is open to the outer periphery side so as to be slidably movable without rattling the second guide bar 152. It has.
As a result, the main bearing 42 and the first guide bar 151 exclusively guide the movement of the fourth lens frame F4 (fourth lens group L4), and the slave bearing 43 and the second guide bar 152 absorb errors between the bearings. And function as a detent for the fourth lens frame F4.

The lever holding frame 142 includes, on the outer periphery thereof, a main bearing 142A that fits with the second guide bar 152 and a slave bearing 142B that fits with the first guide bar 151.
The main bearing 142 </ b> A includes a round bearing hole 142 </ b> Aa that is slidably movable without rattling on the second guide bar 152, and is set to a predetermined fitting width in the axial direction.
The sub-bearing 142B has a plate shape with a predetermined thickness in the axial direction, and has a U-shaped fitting groove 142Ba opened to the outer peripheral side that is slidably fitted without rattling on the first guide bar 151. It has.
As a result, the main bearing 142A and the second guide bar 152 exclusively guide the movement of the lever holding frame 142, and the slave bearing 43 and the first guide bar 151 absorb errors between the bearings and prevent the lever holding frame 142 from rotating. It is supposed to function.

That is, the role of the first guide bar 151 and the second guide bar 152 is set to be reversed between the fourth lens frame F4 and the lever holding frame 142.
According to the configuration of the third embodiment, the lever holding frame 142 that supports the interlocking lever 141 of the interlocking mechanism 140 is independent without being connected to the fourth lens frame F4. When driving, the operation vibration of the interlocking lever 141 is not transmitted to the fourth lens frame F4. Further, the fourth lens frame F4 (the same applies to the third lens frame F3) and the lever holding frame 142 are configured such that their main bearings 42 and 142A are fitted to different guide bars 151 and 152 and are guided to move. Therefore, the transmission of the operating force and the operating vibration acting on the lever holding frame 142 to the fourth lens frame F4 via the guide bar 150 can be suppressed. As a result, it is possible to suppress the deterioration of the optical performance due to the vibration of the fourth lens group 14 due to the operation force and the operation vibration acting on the lever holding frame 142 via the interlocking lever 141 during the diaphragm operation.

Furthermore, by using the guide bar 150 for moving and guiding the fourth lens frame F4 for moving and guiding the lever holding frame 142, space efficiency can be improved and the entire diaphragm mechanism 103 can be made compact.
In this configuration, the third lens frame F3, the fourth lens frame F4, and the fourth lens frame F4 are not driven for movement in the cam groove formed in the cam cylinder as in the first embodiment, although not shown. What is necessary is just to comprise so that it may carry out by the fitted follower pin.

(Fourth embodiment)
FIG. 10 is a conceptual perspective view illustrating the configuration of the diaphragm mechanism 104 according to the fourth embodiment of the present invention.
The diaphragm mechanism 104 shown in FIG. 10 drives the fourth lens frame F4 and the lever holding frame 142 by the same cam groove 22B, for example, with respect to the linear guide structure by the guide bar in the third embodiment described above.

  That is, in the diaphragm mechanism 104 in this configuration, the follower pin 142P ′ planted on the outer periphery of the lever holding frame 142 has the same cam groove 23B (fitting the follower pin 41 planted on the outer periphery of the fourth lens frame F4. It is fitted to a cam cylinder (not shown). As a result, the fourth lens frame F4 and the lever holding frame 142 move in a straight line in synchronization with the rotation of a cam cylinder (not shown).

  According to the configuration of the fourth embodiment, the lever holding frame 142 that supports the interlocking lever 141 of the interlocking mechanism 140 is independent without being connected to the fourth lens frame F4. At this time, the operation vibration of the interlocking lever 141 is not transmitted to the fourth lens frame F4. Thereby, it is possible to suppress degradation of optical performance due to the fourth lens group 14 vibrating due to the operating force and the operating vibration acting on the lever holding frame 142 via the interlocking lever 141 during the aperture operation.

  Further, since the lever holding frame 142 is moved and driven by the same cam groove 23B that moves and drives the fourth lens frame F4, space efficiency is improved and the entire diaphragm mechanism 103 can be configured compactly.

As described above, this embodiment has the following effects.
In the diaphragm mechanisms 100, 102, 103, and 104, during the diaphragm operation, the rotation of the diaphragm operation ring 110 is transmitted to the diaphragm unit 200 via the interlocking lever 141, and the diaphragm blades 220 are operated to set a predetermined diaphragm opening. During the aperture operation, the transmission of the operating force and the operation vibration acting on the interlocking lever 141 to the fourth lens frame F4 can be suppressed, whereby the vibration of the interlocking lever 141 during the aperture operation causes the fourth lens frame to vibrate. Degradation of optical performance due to transmission to F4 (fourth lens unit L4) can be suppressed.

(Deformation)
The present invention is not limited to the above-described embodiment, and various modifications and changes as described below are possible, and these are also within the scope of the present invention.
In this embodiment, the present invention is applied to a lens barrel that can have four lens groups. However, the lens configuration is not limited to this, and may be more or less, and can be changed as appropriate.

  DESCRIPTION OF SYMBOLS 1: Camera, 10: Camera body, 11: Image sensor, 12: Body side interlocking part, 13: Drive part, 20: Lens barrel, 22: Fixed cylinder, 22S: Straight groove, 23: Cam cylinder, 23B: Cam Groove, F3: third lens frame, 31: follower pin, 41: follower pin, 42: main bearing, 43: slave bearing, 100, 102, 103, 104: aperture mechanism, 110: aperture operation ring, 112: aperture operation arm, 140: interlocking mechanism, 141: interlocking lever, 142: lever holding frame, 142A: main bearing, 142B: slave bearing, 142P, 142P ′: follower pin, 143: pivot shaft, 144: vibration isolating member, 150: guide bar, 151: First guide bar, 152: Second guide bar, 200: Diaphragm unit, 220: Diaphragm blade, 230: Diaphragm operation member, 231: First operation protrusion, 300, 00 ': vibration suppression connecting member, 301, 302: O-ring, 303: spring, F3: third lens frame, F4: fourth lens frame, L3: third lens group, L4: fourth lens group, OA: light axis

Claims (8)

A diaphragm member and a lens frame arranged in order from the subject side along the optical axis;
A driving force transmission member that transmits a diaphragm driving force from the camera body to the diaphragm member, and a lens barrel,
The driving force transmission member is
When the lens barrel is attached to the camera body, an engagement portion that transmits the diaphragm driving force from the camera body;
A mount side arm extending from the engagement portion toward the subject,
A subject-side arm extending from the aperture member toward the mount;
A relay arm that relays between the subject side arm and the mount side arm to transmit the aperture driving force;
A shaft portion provided on the relay arm portion and serving as a rotation center of the relay arm portion;
Have
The lens barrel, wherein the shaft portion is provided so as not to transmit vibration to the lens frame. The lens barrel according to claim 1,
Having an annular shaft holding frame for holding the shaft portion;
The lens barrel, wherein the shaft holding frame is provided so that vibration is not transmitted to the lens frame. The lens barrel according to claim 2,
An elastic member is disposed between the shaft holding frame and the lens frame;
A lens barrel characterized by The lens barrel according to claim 2 or 3,
The shaft holding frame and the lens frame each include a guide pin provided on an outer peripheral surface,
Comprising a cylindrical member formed with a groove portion for engaging the guide pin of the shaft holding frame and the guide pin of the lens frame;
A lens barrel characterized by The lens barrel according to claim 2 or 3,
A guide bar that extends along the optical axis and guides linear movement of the shaft holding frame and the lens frame;
A lens barrel characterized by The lens barrel according to claim 4,
Two guide bars are provided,
The lens frame and the shaft holding frame each include two holes, a through hole and a loose insertion hole capable of radial movement,
The thickness in the optical axis direction of the portion where the through hole is provided is thicker than the portion where the loose insertion hole is provided,
In one of the guide bars, a through hole of the lens frame and a loose insertion hole of the shaft holding frame are inserted,
On the other side of the guide bar, a loose insertion hole of the lens frame and a through hole of the shaft holding frame are inserted,
A lens barrel characterized by The lens barrel according to any one of claims 1 to 6,
The lens barrel is a zoom lens barrel capable of changing a focal length,
The lens barrel according to claim 1, wherein a relative positional relationship among the subject side arm portion, the relay arm portion, and the mount side arm portion changes according to a focal length.   An imaging device comprising the lens barrel according to any one of claims 1 to 7.

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