JP2017026977A - Lens barrel and optical device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a lens barrel whose adjusted tilt posture is fixed regardless of a position of a cam part.SOLUTION: A lens barrel 1 comprises: a first barrel 27 having a straight advance groove 27a with a fixed inclination angle around an optical axis OA; a second barrel 23 having a cam groove 23a whose inclination angle around the optical axis OA varies, and being relatively rotatable with respect to the first barrel 27 with the optical axis OA as a center; a lens frame 53 disposed inside the first barrel 27 and the second barrel 23, for holding a lens; a straight advance part 30 attached so that a relative position with the lens frame 53 is adjustable in a direction in which the straight advance groove 27a is formed and moving with the lens frame 53 by moving along the straight advance groove 27a; and a cam part 40 having a cam groove engagement part engaged with the cam groove 23a and moving with the lens frame 53 while a position with respect to the straight advance part 30 is fixed.SELECTED DRAWING: Figure 7

Description

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

Conventionally, in a lens barrel, a plurality of cam portions that engage with a rectilinear groove extending in the optical axis direction formed in the fixed cylinder and a curved cam groove formed in a rotating cylinder rotating around the optical axis, Some lens groups are provided on the outer periphery of the lens group so that the lens group can be cam-driven.
In such a lens group, there is one in which tilt adjustment is performed by decentering the engaging portion of the cam portion with the rectilinear groove and the engaging portion of the cam groove and rotating the cam portion. (For example, refer to Patent Document 1).

  However, the conventional adjustment mechanism has a problem that the adjusted tilt posture changes depending on the position of the cam portion in the cam groove.

JP 2008-46439 A

The lens barrel of the present invention has a first tube having a straight groove having a constant inclination angle around the optical axis, and a cam groove in which the inclination angle around the optical axis changes, A second cylinder that is rotatable relative to the optical axis; a lens frame that is disposed inside the first cylinder and the second cylinder and that holds the lens; and the lens frame in a direction in which the rectilinear groove is formed. Are mounted so as to be adjustable, and have a rectilinear portion that moves along with the lens frame by moving along the rectilinear groove, and a cam groove engaging portion that engages with the cam groove, with respect to the rectilinear portion. And a cam portion that moves with the lens frame with a fixed position.
Moreover, the optical apparatus of the present invention is configured to include the lens barrel.

It is a schematic side view of the lens barrel of the first embodiment. It is the A section enlarged view of FIG. 1, and is a figure which shows the part of the blurring correction apparatus of a lens barrel. It is the perspective view which looked at the coil peripheral part of the blurring correction apparatus from the to-be-photographed object side. It is the perspective view which looked at the coil peripheral part of the blurring correction apparatus in the 1st comparison form from the to-be-photographed object side. It is a disassembled perspective view of the 3rd lens frame of 1st Embodiment, a rear fixed cylinder, and a 2nd cam cylinder. It is an enlarged view of the B section of FIG. It is a perspective view of the part of a tilt adjustment mechanism, (a) is an exploded view, (b) is an assembly drawing. FIG. 5A is a perspective view of a rectilinear portion, FIG. 5A is a view seen from the outer diameter side, and FIG. 5B is a view seen from the inner diameter side. (A) is the top view which looked at the cam part from the internal diameter side, (b) is the perspective view which looked at the cam part from the internal diameter side. FIGS. 9A to 9C are diagrams corresponding to FIG. 6 and illustrating the tilt adjustment by the tilt adjustment mechanism. (A) to (c) is a diagram corresponding to FIG. 10, illustrating a cam member of the tilt adjustment mechanism. It is a figure explaining a comparison form. It is a figure corresponding to 1st Embodiment which showed 2nd Embodiment. It is sectional drawing of the tilt adjustment mechanism of 2nd Embodiment. It is a figure corresponding to 1st Embodiment which showed 3rd Embodiment. It is sectional drawing of the tilt adjustment mechanism of 3rd Embodiment.

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a schematic side view of the lens barrel 1 of the present embodiment, showing a wide (wide angle) state.
The lens barrel 1 of the present embodiment is an interchangeable lens barrel 1 that can be attached to and detached from a camera body 2 indicated by a dotted line in FIG. However, the present invention is not limited to this, and a lens barrel integrated with the camera body may be used.

The lens barrel 1 includes a first lens group L1, a second lens group L2, a third lens group L3, and a fourth lens group L4.
The lens barrel 1 includes a lens side mount portion 11, a rear fixed cylinder (fixed cylinder) 27, an intermediate fixed cylinder 26, a front fixed cylinder 24, a first cam cylinder 22, a second cam cylinder 23 (second cylinder), The first lens moving cylinder 59, the first lens frame 51, the second lens frame 52, the third lens frame (lens frame) 53, the fourth lens frame 54, the focus ring 12, the zoom operation ring 20, and the zoom interlocking key 21 are provided. .
However, the configuration of the lens barrel 1 is not limited to this, and the number of fixed barrels, cam barrels, lens frames, and the arrangement described below may be different from the present embodiment.

  The lens side mount portion 11 is a bayonet lens side mount portion that can be attached to and detached from a lens side mount portion (not shown) of the camera body 2. However, the attachment / detachment structure of the lens barrel 1 and the camera body 2 is not limited to the bayonet lens side mount.

The rear fixed cylinder 27 is fixed to the lens side mount portion 11, the middle fixed cylinder 26 is fixed to the rear fixed cylinder 27, and the front fixed cylinder 24 is fixed to the middle fixed cylinder 26.
The first cam cylinder 22 is rotatably disposed on the inner diameter side of the front fixed cylinder 24.
The second cam cylinder 23 is rotatably disposed on the outer diameter side of the rear fixed cylinder 27.

The first lens moving cylinder 59 is disposed on the outer diameter side of the front end of the front fixed cylinder 24 so as to be movable in the direction of the optical axis OA.
The first lens frame 51 is held at the tip of the first lens moving cylinder 59.
The second lens frame 52 is disposed on the inner diameter side of the first cam cylinder 22 so as to be movable in the direction of the optical axis OA.
The third lens frame 53 is disposed on the inner diameter side of the rear fixed cylinder 27 and is driven by the rotation of the second cam cylinder 23.
The fourth lens frame 54 is disposed on the inner diameter side of the rear fixed cylinder 27 so as to be movable in the direction of the optical axis OA.

  The focus ring 12 is rotatably attached to the outer diameter side of the front fixed cylinder 24, and is connected to the second lens frame 52 by a connection key (not shown) so that the rotation operation is transmitted. When the focus ring 12 is rotated, the first cam cylinder 22 is rotated. A focusing operation is performed by this rotation.

The zoom operation ring 20 is disposed on the outer diameter side of the second cam cylinder 23.
The zoom interlocking key 21 is attached to the zoom operation ring 20 and engages the first cam cylinder 22 and the second cam cylinder 23.

  When the zoom operation ring 20 is rotated, the second cam cylinder 23 is rotated via the zoom interlocking key 21, and the first cam cylinder 22 is rotated accordingly. By this rotation, the first lens moving cylinder 59, the first lens frame 51, the second lens frame 52, the third lens frame 53, and the fourth lens frame 54 move straight in the direction of the optical axis OA, and a zooming operation is performed.

The third lens group L3 includes a blur correction device 200 that drives the blur correction lens group L31 in a plane orthogonal to the optical axis OA to reduce image blur caused by camera shake vibration.
FIG. 2 is an enlarged view of a portion A in FIG. 1 and shows a portion of the shake correction device 200 of the lens barrel 1. FIG. 3 is a perspective view of the periphery of the coil 204 of the shake correction apparatus 200 as viewed from the subject side.

As shown in FIG. 2, the shake correction apparatus 200 includes a shake correction lens group L31, a shake correction lens frame 201 that holds the shake correction lens group L31, a base unit 202, and a VCM 210 (voice coil motor).
The VCM 210 includes a magnet 203, a coil 204, and a yoke 205.
The coil 204 is attached to the blur correction lens frame 201. The coil 204 is disposed between the magnets 203. By controlling the current flowing through the coil 204, the coil 204 and the blur correction lens frame 201 move in a plane perpendicular to the optical axis OA.

  An FPC 220 for connection with a control unit (not shown) is soldered to the coil 204 of the VCM 210 in order to control the movement of the blur correction lens frame 201.

In the present embodiment, as shown in FIG. 3, the FPC 220 includes a first portion 220 a attached along the outer diameter of the standing wall 201 a that is horizontal in the optical axis OA direction of the shake correction lens frame 201, and the first portion. A bifurcated portion 220b that is divided into two forks from the end of 220a.
Each end of the bifurcated portion 220b is fixed at two spaced locations on the side surface of the coil 204. A slack is provided between the portion of the bifurcated portion 220b fixed to the coil 204 and the first portion 220a attached to the periphery of the blur correction lens frame 201.

Due to this slackness, even when the position where the FPC 220 is attached to the shake correction lens frame 201 is deviated from the design position, the amount of deviation is absorbed. For this reason, the possibility that the FPC 220 protrudes from the top surface of the coil 204 is reduced.
The standing wall 201a is located at a predetermined distance from the magnet 203. Further, the movable range mechanical end surface of the blur correction lens frame 201 is formed on the inner diameter side of the standing wall 201a.

(First comparative form)
Next, a first comparative example with respect to the FPC arrangement of the above embodiment will be described. FIG. 4 is a perspective view of the periphery of the coil 204 ′ viewed from the subject side in the first comparative embodiment.
In the first comparative embodiment, the FPC 220 ′ is soldered to the side surface of the coil 204 ′, bent at approximately 90 °, and extends in parallel with the top surface of the coil 204 ′.

In the configuration of the first comparative embodiment, if a deviation occurs from the design value between the bent position of the FPC 220 ′ and the position where the FPC 220 ′ is attached to the shake correction lens frame 201 ′, the FPC 220 ′ It may protrude from the top.
And if FPC220 'protrudes from the top | upper surface of coil 204', FPC220 'may interfere with magnet 203'.
Therefore, in the configuration of the first comparative embodiment, it is necessary to strictly manage the bending position and the attaching position of the FPC 220 ′, and high work accuracy is required. Further, since it is necessary to bend the FPC 220 ′ in the vicinity of the coil 204, the coil 204 ′ may be damaged.

Further, the FPC 220 ′ extending from the coil 204 ′ is attached to a surface parallel to the top surface of the coil 204 ′ in the shake correction lens frame 201.
For this reason, a space for attaching the FPC 220 ′ in the radial direction of the blur correction lens frame 201 ′ is required, and the blur correction lens frame 201 ′ becomes larger in the radial direction.
As a countermeasure, it is conceivable to bend the FPC 220 ′ in the direction of the optical axis OA. However, when the number of bent portions increases, workability deteriorates, and the FPC 220 ′ may further protrude from the top surface of the coil 204 ′, and the center end mechanical end of the vibration reduction lens group L31 (contact with the base part) Surface) may be covered with FPC 220 ′, which is not preferable in terms of mechanical accuracy.

However, according to the present embodiment, the FPC 220 is slackened in the vicinity of the side surface of the coil 204. Therefore, the slack in the FPC 220 is absorbed by this slack.
Therefore, complicated work management is not required in the assembly work of the FPC 220 and the VCM 220 to the third lens frame 53.
Further, unlike the comparative embodiment, a space for affixing the FPC 220 in the radial direction of the shake correction lens frame 201 is not required, and thus the third lens frame 53 can be reduced in size.

FIG. 5 is an exploded perspective view of the third lens frame 53, the rear fixed cylinder 27, and the second cam cylinder 23. FIG. 6 is an enlarged view of a portion B in FIG.
As shown in FIG. 5, a cam groove 23 a is provided on the inner periphery of the second cam cylinder 23. A rectilinear groove 27 a is provided on the subject side of the rear fixed cylinder 27.
In the present embodiment, a tilt adjustment mechanism 100 that adjusts the tilt of the third lens unit L3 with respect to the optical axis OA is provided.

7 is a perspective view of a portion of the tilt adjustment mechanism 100, FIG. 7A is an exploded view, and FIG. 7B is an assembly view.
The tilt adjustment mechanism 100 includes a recess 57 formed in the third lens frame 53, and a rectilinear portion 30 and a cam portion 40 that are attached to the outer peripheral side of the third lens frame 53. The tilt adjustment mechanism 100 is preferably provided at two of the three positions arranged at approximately 120 ° intervals on the outer periphery of the third lens frame 53, for example.

The third lens frame 53 holds the third lens group L3.
The third lens group L3 is moved in the optical axis OA direction by the movement of the third lens frame 53 in the optical axis OA direction, and the third lens group L3 is adjusted by adjusting the inclination of the third lens frame 53 with respect to the optical axis OA. It is adjusted in the tilt direction.

A first screw hole 55 provided on the mount side and a second screw hole 56 provided on the subject side are formed on the outer periphery of the third lens frame 53 along a straight line extending in the direction of the optical axis OA. .
The first screw hole 55 is provided at the bottom of a recess 57 provided on the outer periphery of the third lens frame 53.
The concave portion 57 has a two-stage shape, and has a shape in which an elongated concave portion 57a that is long in the circumferential direction of the third lens frame 5 is provided inside the elliptical concave portion 57b.
Moreover, the elliptical recessed part 57b is connected with the extended recessed part 57c extended on the both sides of the optical axis OA direction.

The rectilinear portion 30 is disposed on the outer peripheral side of the portion where the first screw hole 55 and the second screw hole 56 of the third lens frame 53 are provided. The rectilinear portion 30 moves linearly along the rectilinear groove 27a of the rear fixed cylinder 27. FIG. 8 is a perspective view of the rectilinear portion 30, FIG. 8 (a) is a view seen from the outer diameter side, and FIG. These are views seen from the inner diameter side.

The rectilinear portion 30 is formed with a first through hole 31 provided on the mount side and a second through hole 32 provided on the subject side along a straight line extending in the direction of the optical axis OA.
The second through hole 32 is a long hole that is long in the direction of the optical axis OA. The first through hole 31 is a circular hole and is larger than the second through hole 32.

The outside of the portion of the rectilinear portion 30 where the first through hole 31 is provided projects along the circumference of the first through hole 31 to form a circumferential protrusion 31a.
The side surface of the circumferential protrusion 31a is in contact with the inner peripheral surface of the rectilinear groove 27a of the rear fixed cylinder 27 and moves along the inner peripheral surface.
At this time, since the side surface of the circumferential protrusion 31a protrudes and is a curved surface, it is in line contact with the inner peripheral surface of the rectilinear groove 27a, which is a plane, instead of surface contact. For this reason, for example, even if the longitudinal direction of the rectilinear portion 30 is slightly inclined with respect to the longitudinal direction (optical axis OA direction) of the rectilinear groove 27a, line contact is maintained, and the rectilinear portion 30 moves along the rectilinear groove 27a. can do.

As shown in FIG. 8B, protrusions 33 are provided on the subject side and the mount side in the optical axis OA direction of the portion where the first through hole 31 is provided on the inner diameter side of the rectilinear portion 30, respectively. .
The protrusion 33 is inserted into an extending recess 57c provided in the recess 57 of the third lens frame 53 shown in FIG. 7A, and is movable in the optical axis OA direction along the extending recess 57c.
Thereby, the relative movement between the rectilinear portion 30 and the third lens frame 53 is restricted in the direction of the optical axis OA.

A cam portion 40 that moves along the cam groove 23 a of the second cam cylinder 23 is attached to the outer peripheral side of the third lens frame 53.
The cam portion 40 is inserted into the first through hole 31 of the rectilinear portion 30 and the concave portion 57 of the third lens frame 53.
9A and 9B are diagrams showing the cam portion 40. FIG. 9A is a plan view of the cam portion 40 viewed from the inner diameter side, and FIG. 9B is a perspective view of the cam portion 40 viewed from the inner diameter side.
The cam portion 40 has a shape in which a cylindrical eccentric portion 41, a fitting portion 42 with a rectilinear portion, and a cam groove engaging portion 43 are connected. The outer diameter increases in the order of the eccentric portion 41, the fitting portion 42, and the cam groove engaging portion 43.

  The eccentric part 41 is eccentric with respect to the cam groove engaging part 43 and the fitting part 42. As shown in FIG. 6, the outer diameter of the eccentric portion 41 is substantially the same as the short diameter (width in the optical axis OA direction) of the elongated hole-like recess 57 a of the third lens frame 53. When the eccentric portion 41 is inserted into the long hole-shaped concave portion 57 a, the outer peripheral surface of the eccentric portion 41 contacts the inner peripheral surface of the long hole-shaped concave portion 57 a of the third lens frame 53.

  The fitting portion 42 has substantially the same diameter as the first through hole 31 of the rectilinear portion 30, and when the fitting portion 42 is inserted into the first through hole 31, the outer peripheral surface of the fitting portion 42 is the first through hole 31. It touches the inner peripheral surface of.

  On the inner diameter side of the cam groove engaging portion 43, a rotary tool groove 45 is provided. The cam groove engaging portion 43 is inserted into the cam groove 23 a of the second cam cylinder 23.

As shown in FIG. 7, the cam portion 40 is inserted into the first through hole 31 of the rectilinear portion 30. The first screw 65 is inserted from the cam groove engaging portion 43 side of the cam portion 40 and screwed into the first screw hole 55 of the third lens frame 53.
Further, the second screw 66 passes through the second through hole 32 of the rectilinear portion 30 and is screwed into the second screw hole 56 of the third lens frame 53.

As described above, when the second cam cylinder 23 rotates, the cam groove engaging part 43 of the cam part 40 is engaged with the cam groove 23a of the second cam cylinder 23, so that driving force is transmitted to the cam part 40. The
On the other hand, the fitting portion 42 of the cam portion 40 is fitted into the first through hole 31 of the rectilinear portion 30, and the circumferential protrusion 31 a of the rectilinear portion 30 engages with the rectilinear groove 27 a of the rear fixed cylinder 27. Therefore, the cam part 40 moves along the optical axis OA direction.
Since the cam portion 40 is fixed to the third lens frame 53 via the first screw 65 and the second screw hole 56, the third lens frame 53 is also driven linearly in the direction of the optical axis OA.

Next, the tilt adjustment of the third lens unit L3 by the tilt adjustment mechanism 100 of this embodiment will be described.
FIGS. 10A to 10B are diagrams corresponding to FIG. 6 and illustrating the tilt adjustment of the third lens unit L3 by the tilt adjustment mechanism 100. FIG.
11A to 11B are views of the cam portion 40 as viewed from above, and correspond to FIGS. 10A to 10B.

  As shown in FIGS. 10A and 11A, when the tilt adjustment is performed, the first screw 65 and the second screw 66 are first loosened from the state shown in FIG. Then, the tip of the rotary tool is inserted into the rotary tool groove 45 of the cam portion 40 to rotate the cam portion 40 in the direction of the arrow in FIG.

Then, as shown in FIGS. 10B and 11B, the cam groove engaging portion 43 and the fitting portion 42 rotate coaxially. However, the eccentric portion 41 is eccentric with respect to the cam groove engaging portion 43 and the fitting portion 42. Therefore, the position of the eccentric part 41 with respect to the cam groove engaging part 43 and the fitting part 42 is moved by the rotation of the cam part 40.
Here, the outer peripheral surface 41 a of the eccentric portion 41 is in contact with the inner peripheral surface of the elongated hole-shaped concave portion 57 a of the third lens frame 53.
Therefore, the inner peripheral surface of the elongated hole-like concave portion 57 a of the third lens frame 53 is pressed by the outer peripheral surface 41 a of the eccentric portion 41. As a result, the third lens frame 53 moves in the direction of the arrow shown in FIG.

  At this time, the moving direction of the eccentric part 41 has not only the optical axis OA direction component but also a circumferential direction component. However, as shown in FIG. 7A, the eccentric portion 41 is engaged with the elongated hole-shaped concave portion 57 a of the third lens frame 53. For this reason, the eccentric part 41 can move in the circumferential direction (longitudinal direction) along the elongated hole-shaped recess 57a, and the moving component in the circumferential direction is absorbed.

  FIG. 10B shows a case where, for example, the cam portion 40 is rotated by 45 ° from the state shown in FIG. The third lens frame 53 has moved a distance a1 in the direction of the optical axis OA from the state of FIG.

FIGS. 10C and 11C are views showing a state where the cam portion 40 is further rotated by 45 ° from the states of FIGS. 10B and 11B.
That is, FIG.10 (c) is the figure which showed the state which rotated the cam part 40 90 degrees from the state of Fig.10 (a).
When the outer peripheral surface 41a of the eccentric portion 41 presses the inner side surface 15b of the elongated hole-like recess 57a of the third lens frame 53, the third lens frame 53 is moved from the state of FIG. Has moved. That is, the third lens frame 53 has moved a1 + a2 in the direction of the optical axis OA from the state of FIG.

As described above, by adjusting the rotation amount of the cam portion 40, the amount of movement of the third lens frame 53 in the direction of the optical axis OA can be adjusted, and the tilt adjustment of the third lens frame 53 can be performed.
Then, the tilt adjustment is completed by tightening the first screw 65 and the second screw 66.

  The preferred embodiments of the present invention have been described above, but comparative embodiments will be described in order to facilitate understanding of the effects of the present embodiments.

(Second comparative form)
FIG. 12 is a diagram for explaining a second comparative example with respect to the tilt adjustment mechanism 100 of the present embodiment. FIG. 12A is a view showing the entire cam portion 40 ′ engaged with the cam groove 23a ′, and FIGS. 12B and 12C are partially enlarged views thereof.
In the second comparative embodiment, the cam portion 40 ′ has a cam groove engaging portion 40c ′ that engages with the cam groove 23a ′ and a fitting portion 40b ′ that engages with the rectilinear groove 27a ′. The groove engaging portion 40c ′ and the fitting portion 40b ′ are eccentric.

In the second comparative embodiment, the tilt adjustment is performed by rotating the cam groove engaging portion 40c ′ and moving the fitting portion 40b ′ eccentrically.
For example, the cam portion 40 ′ is rotated at the position P shown in FIG. 12A, and the fitting portion 40b ′ of the cam portion 40 ′ is at the position indicated by the solid line in FIG. Suppose that the position of the dotted line.
Then, in order to engage the cam groove engaging portion 40c ′ with the cam groove 23a ′, the third lens frame 53 ′ is inclined. The amount of tilt (tilt amount) of the third lens frame 53 ′ at that time is the amount indicated by p in the diagram on the right side of FIG. 12B (p / radius when represented by angle θ).

When the cam portion 40 moves to the position Q shown in FIG. 12A while maintaining the relationship between the fitting portion 40b ′ and the cam groove engaging portion 40c ′, as shown in FIG. The tilt amount (tilt amount) of the third lens frame 53 ′ at this time is q.
That is, the inclination amount of the third lens frame 53 ′ is p at the position P, but is q at the position Q. Therefore, the tilt attitude changes by the difference between p and q.

This is because the relative relationship between the coaxial shift direction and the direction of the curved groove (lead angle) is related to the tilt posture. In particular, the curved groove design in which the direction of the lead angle is reversed (with an inflection point) In the case of (design), the change in tilt posture becomes significant.
In other words, the adjusted tilt posture cannot be maintained unless the entire cam groove (that is, Wide to Tele) is designed to have the same lead angle.

In contrast, in the present embodiment, the cam portion 40 includes a cam groove engaging portion 40c, a fitting portion 40b, and an eccentric portion 40a. The cam portion 40 is rotated during tilt adjustment.
Here, the rectilinear portion 30 in which the positional relationship between the cam groove engaging portion 40c and the fitting portion 40b is maintained, and the third lens frame 53 are in a relationship in which only movement in the optical axis OA direction is allowed.
Further, the circumferential movement of the eccentric part 40a of the cam part 40 with respect to the optical axis OA can be absorbed by the change of the position of the third lens frame 53 in the elongated hole-like concave part 57a.

That is, the amount of movement of the eccentric portion 40a according to the present embodiment from the position before adjustment to the position after adjustment is divided into movement in two directions, that is, a circumferential direction component and an optical axis direction component.
Then, the relative positional relationship in the optical axis OA direction between the rectilinear portion 30 (cam groove engaging portion 43) and the third lens frame 53 changes depending on the optical axis direction component, and thereby the tilt adjustment of the third lens frame 53 is performed. Is called.
On the other hand, the circumferential movement component is absorbed when the position of the third lens frame 53 in the elongated hole-shaped recess 57a changes.
Therefore, when the tilt adjustment is performed, the positional relationship between the rectilinear portion 30 (cam groove engaging portion 43) and the third lens frame 53 changes only in the direction of the optical axis OA, and the positional relationship in the circumferential direction does not change. Therefore, the third lens frame 53 tilt amount does not change depending on the lead angle of the cam groove 23a.

As described above, the lens barrel 1 of the present embodiment has the rear fixed cylinder 27 provided with the rectilinear groove 27a having a constant inclination angle around the optical axis OA, and the cam groove 23a where the inclination angle around the optical axis OA changes, A second cam cylinder 23 that is rotatable relative to the rear fixed cylinder 27 about the optical axis OA; a third lens frame 53 that is disposed inside the rear fixed cylinder 27 and the second cam cylinder 23 and holds a lens; A rectilinear portion 30 that is mounted so that the relative position with respect to the third lens frame 53 is adjustable in the direction in which the rectilinear groove 27a is formed, and moves along with the third lens frame 53 by moving along the rectilinear groove 27a, and a cam A cam portion 40 having a cam groove engaging portion 40 c that engages with the groove 23 a and having a fixed position relative to the rectilinear portion 30 and moving together with the third lens frame 53.
Accordingly, the tilt adjustment amount does not change even if the cam portion 40 moves along the cam groove 23a regardless of the lead angle of the cam groove 23a.

Further, the rectilinear portion 30 and the cam portion 40 are separate bodies.
For this reason, the cam portion can be rotationally adjusted while moving the rectilinear portion 30 relative to the third lens frame 53 in the direction in which the rectilinear groove 27a is formed.

The rectilinear portion 30 has a curved surface, and the curved surface moves along the rectilinear groove 27a.
Thus, since the rectilinear portion 30 has a curved surface, it does not come into surface contact with the inner peripheral surface of the rectilinear groove 27a. For this reason, for example, even if the longitudinal direction of the rectilinear portion 30 is slightly inclined with respect to the longitudinal direction of the rectilinear groove 27a (optical axis OA direction), the rectilinear portion 30 can move along the rectilinear groove 27a.

An elongated hole-shaped recess 57a is formed on the outer peripheral surface of the third lens frame 53. The longitudinal direction of the elongated hole-shaped recess 57a is orthogonal to the inclination angle of the rectilinear groove 27a, and the cam groove engaging portion 40c has a first axis. The cam portion 40 has an eccentric portion 41 having a second axis that is eccentric with respect to the first axis as a central axis, and the eccentric portion 41 is a first recess 57. It is rotatably arranged inside.
Thus, since the eccentric part 41 of the cam part 40 is arrange | positioned at the elliptical long hole-shaped recessed part 57a, when the eccentric part 41 is eccentric, the movement to the circumferential direction of the eccentric part 41 is carried out. Is possible.

The cam portion 40 is held on the third lens frame 53 by the first screw 65, and the first screw 65 and the cam portion 40 are relatively movable in the direction of the optical axis OA, and the rectilinear portion 30 relative to the third lens frame 53. There is a gap larger than the amount of movement.
Thereby, when the third lens frame 53 moves relative to the rectilinear portion 30, the first screw 65 can move together with the third lens frame 53.

(Second Embodiment)
FIG. 13 is a diagram corresponding to FIG. 7 of the first embodiment showing the second embodiment. FIG. 14 is a cross-sectional view of the tilt adjustment mechanism 100 of the second embodiment.
The second embodiment is different from the first embodiment in that the cam portion 40 does not have an eccentric portion, and the second screw 66 is not directly inserted through the rectilinear portion 30 but is inserted through the holder portion 35. It is a point.

The holder part 35 has a large diameter part 35c, a medium diameter part 35b, and a small diameter eccentric part 35a.
The small diameter eccentric portion 35a is eccentric with respect to the large diameter portion 35c and the medium diameter portion 35b. The holder portion 35 has a rotary tool groove 39.
The concave portion 57 of the third lens frame 53 is a one-step concave portion, and the elliptical concave portion is connected to an extended concave portion 57c extending on both sides in the optical axis OA direction.

Here, the tilt adjustment of the third lens unit L3 will be described.
When the tilt adjustment is performed, the first screw 65 and the second screw 66 are first loosened as in the first embodiment.
When the tip of the rotary tool for adjustment is inserted into the rotary tool groove 36 and the rotary tool is rotated, the rotary tool groove 36, that is, the holder portion 35 is rotated.
Then, the large diameter part 35c and the medium diameter part 35b rotate coaxially.
On the other hand, the eccentric part 35a is eccentric with respect to the large diameter part 35c and the medium diameter part 35b. Therefore, when the holder part 35 rotates, the position of the eccentric part 35a with respect to the large diameter part 35c and the medium diameter part 35b varies.
The outer periphery 35d of the eccentric part 35a is in contact with the inner periphery of the elongated hole-shaped recess 53a of the third lens frame 53. Since the positions of the eccentric part 35a with respect to the large diameter part 35c and the medium diameter part 35b change, the inner peripheral surface of the elongated hole-like concave part 53a of the third lens frame 53 is pushed when the position of the eccentric part 35a changes. Thereby, the 3rd lens frame 53 moves to the optical axis OA direction similarly to 1st Embodiment. In this way, tilt adjustment is performed by appropriately rotating the holder portion 35.

As described above, according to this embodiment, the same effects as those of the first embodiment can be obtained.
Further, in the second embodiment, since the eccentric portion 40a is not provided, the length of the cam portion 40 can be shortened because the eccentric portion 40a is not provided, so that the first screw 65 and the third lens frame 53 can be reduced. The length of the screwing can be increased, and the strength of the cam portion 40 is increased.
A holder portion 35 is attached to the outer periphery of the second screw 66. The holder portion 35 is not a portion that slides in the cam groove 23a like the cam portion 40. Therefore, it can manufacture with the material which adheres easily to an adhesive agent.
Then, by fixing the head portion of the second screw 66 and the holder portion 35 with an adhesive, the second screw 66 can be fixed so as not to loosen.

(Third embodiment)
FIG. 15 is a diagram corresponding to FIG. 7 of the first embodiment showing the third embodiment.
FIG. 16 is a cross-sectional view of the tilt adjustment mechanism.
The third embodiment is different from the first embodiment in that there is no eccentric portion in the cam portion 40, and the concave portion 57 of the third lens frame 53 is an elliptical step extending to both sides in the direction of the optical axis OA. This is a point connected to the recessed portion 57c.
Further, a tilt adjustment protrusion 37 is provided on the mount side of the extending recess 57 c of the third lens frame 53.
The tilt adjustment protrusion 37 is provided with a long hole 37a.

Here, the tilt adjustment of the third lens unit L3 will be described.
When the tilt adjustment is performed, the first screw 65 and the second screw 66 are first loosened as in the first embodiment.
And the eccentric tool 38 of the shape provided with the main-body part 38a and the eccentric part 38b eccentric | decentered with respect to the main-body part 38a as shown in FIG. 16 is inserted in the long hole 37a from the radial direction outer side.
When the eccentric tool 38 is rotated around the axis of the main body 38a in this state, the eccentric portion 38b is eccentrically rotated.
Then, the position of the long hole 37a in the optical axis OA direction moves. Thereby, the 3rd lens frame 53 can be moved to the optical axis OA direction similarly to 1st Embodiment. In this way, tilt adjustment is performed by appropriately rotating the eccentric tool 38.

As described above, according to this embodiment, the same effects as those of the first embodiment can be obtained.
Further, in the third embodiment, the length of the cam portion 40 can be shortened because the eccentric portion 40a is not provided, so that the first screw 65 and the third lens frame 53 can be reduced. The length of the screwing can be increased, and the strength of the cam portion 40 is increased.
Further, the third embodiment does not require the holder portion 35 as compared with the second embodiment.
Therefore, the structure of the tilt adjustment mechanism 100 is facilitated, the manufacturing cost is reduced, and the size can be reduced.

  As mentioned above, although embodiment of this invention was described, this invention is not limited to described embodiment, Arbitrary combinations may be sufficient and various deformation | transformation and a change are possible, Arbitrary combinations may be sufficient, Detailed description is omitted. Further, the present invention is not limited to the embodiment described above.

  L3: third lens group, L31: blur correction lens group, L4: fourth lens group, 1: lens barrel, 11: lens side mount, 15b: inner surface, 23: second cam cylinder, 23a: cam groove 27: rear fixed cylinder, 27a: rectilinear groove, 30: rectilinear section, 31: first through hole, 31a: circumferential projection, 32: second through hole, 33: projection, 35: holder section, 35a: Small diameter eccentric part, 35b: medium diameter part, 35c: large diameter part, 35d: outer periphery, 36: groove for rotating tool, 37: protrusion for tilt adjustment, 37a: long hole, 38: eccentric tool, 39: rotation Tool groove, 40: cam part, 40a: eccentric part, 40b: fitting part, 40c: cam groove engaging part, 41: eccentric part, 41a: outer peripheral surface, 42: fitting part, 43: cam groove Engaging portion, 45: groove for rotating tool, 51: first lens frame, 52: second lens frame, 53: third lens frame, 53 : Slotted recess, 54: fourth lens frame, 55: first screw hole, 56: second screw hole, 57: recess, 57a: slotted recess, 57b: elliptical recess, 57c: extended recess, 59: first lens moving cylinder, 65: first screw, 66: second screw, 100: tilt adjustment mechanism

Claims (8)

A first tube having a straight groove having a constant inclination angle around the optical axis;
A second cylinder having a cam groove with an inclination angle around the optical axis, the second cylinder being rotatable relative to the first cylinder about the optical axis;
A lens frame disposed inside the first cylinder and the second cylinder and holding a lens;
A rectilinear portion that is attached so that its relative position to the lens frame can be adjusted in the direction in which the rectilinear groove is formed, and moves along with the lens frame by moving along the rectilinear groove;
A cam portion that has a cam groove engaging portion that engages with the cam groove, and that moves with the lens frame with a fixed position relative to the rectilinear portion;
A lens barrel comprising: The lens barrel according to claim 1,
The rectilinear portion and the cam portion are separate bodies;
A lens barrel characterized by The lens barrel according to claim 1 or 2,
The rectilinear portion has a curved surface, and the curved surface moves along the rectilinear groove;
A lens barrel characterized by The lens barrel according to any one of claims 1 to 3,
An elliptical first recess is formed on the outer peripheral surface of the lens frame,
The longitudinal direction of the first recess is orthogonal to the inclination angle of the rectilinear groove,
The cam groove engaging portion has a cylindrical shape having a first axis as a central axis,
The cam portion has an eccentric portion having a second axis that is eccentric with respect to the first axis as a central axis,
The eccentric part is rotatably arranged inside the first recess;
A lens barrel characterized by The lens barrel according to any one of claims 1 to 3,
An elliptical second recess is formed on the outer peripheral surface of the lens frame,
The longitudinal direction of the second recess includes an eccentric pin that is perpendicular to the inclination angle of the rectilinear groove and is attached to the lens frame through the rectilinear portion.
The eccentric pin is
A first portion having an outer periphery held by the rectilinear portion; a second portion having a fourth axis eccentric to the third axis of the first portion; and a second portion disposed inside the second recess. And
Being held rotatably about the third axis with respect to the lens frame;
A lens barrel characterized by The lens barrel according to any one of claims 1 to 3,
A third recess is provided in a portion of the outer peripheral surface of the lens frame where the rectilinear portion is not disposed;
The third recess can be operated from the outer peripheral side in a state where the cam portion, the first tube, and the second tube) are disposed.
A lens barrel characterized by The lens barrel according to any one of claims 1 to 5,
The cam portion is held on the lens frame by a screw member,
The screw member and the cam portion are relatively movable in the optical axis direction, and have a gap greater than or equal to the amount of movement of the rectilinear portion relative to the lens frame;
A lens barrel characterized by   An optical apparatus comprising the lens barrel according to any one of claims 1 to 7.

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