JP2003207709A - Lens barrel - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent an unintentional zooming caused by a zooming barrel rotation by the gravity of a lens group in upward and downward photographing and also to reduce the operating physical force of an operation member by making the amount of force of a load member smaller in photographing in a nearly horizontal direction. <P>SOLUTION: A ring-shaped leaf spring 22 possessing a corrugated surface is disposed so as to be held between a load adjusting ring 21 screwed to a fixed barrel and movable in an optical axis direction by being rotated around an optical axis and the rear end part of the zooming barrel 11 in a lens barrel. The ring-shaped leaf spring 22 is deformed by rotating the load adjusting ring 21 around the optical axis, and the amount of force in the optical axis direction acting on the zooming barrel 11 is changed so that the amount of load force necessitated so as to rotate and operate the zooming barrel 11 is made adjustable. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a lens barrel in which the amount of rotational force of an operating member can be changed.

[0002]

2. Description of the Related Art When a lens barrel is installed in an upward direction or a downward direction at the time of shooting, the zoom barrel rotates due to the weight of the lens group even though no intentional actuation force is applied to the zoom barrel. There may be a problem that the composition is changed due to zooming. Hereinafter, this phenomenon will be referred to as a self-weight malfunction.

Particularly in the case of a zoom lens having a high zoom ratio, the amount of movement of the lens unit from the wide end to the tele end is large, and therefore the cam groove of the cam barrel also has a large inclination. Due to its own weight, the rotational force acting on the zoom cylinder becomes large, and the malfunction due to its own weight is likely to occur remarkably.

In order to solve such a problem, a friction member such as felt is incorporated between the zoom barrel and the fixed lens barrel to apply a large friction load to the zoom barrel to prevent malfunction due to its own weight.

[0005]

However, in the above-mentioned configuration, even when there is no risk of malfunction due to its own weight, for example, even when photographing in a posture close to horizontal, the amount of rotational force of the zoom operation cylinder remains large. It had to be done, which was uncomfortable for the user.

[0006]

In order to solve the above problems, in the invention according to claim 1, the lens barrel of the photographing optical system is arranged coaxially with the optical axis of the photographing optical system, and
In a lens barrel having an operation member that changes the optical characteristics of the photographing optical system by rotating around the optical axis, a load member that applies a load to the operation member and the load that acts on the load member. And a load adjusting means for changing.

Further, in the invention according to claim 2, the invention according to claim 1
In the lens barrel according to claim 1, the load adjusting means is an annular member that is arranged coaxially with the optical axis with respect to the lens barrel, and the load member is rotated by rotating the annular member around the optical axis. It was configured to adjust the ability.

Further, in the invention according to claim 3, the invention according to claim 1
Alternatively, in the lens barrel according to Item 2, the lens barrel has a fixed barrel, and the load member is configured to be prevented from rotating around the optical axis by engaging with the fixed barrel. . Further, in the invention according to claim 4, in the lens barrel according to any one of claims 1 to 3, a rotational force blocking member engaged with the fixed barrel so as to prevent rotation around the optical axis. Is arranged between the operating member and the load adjusting means to prevent the rotational force of the operating member from being transmitted to the friction load adjusting ring.

[0009]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 1 is a sectional view of the entire lens barrel which is an embodiment according to the present invention. FIG. 2 is a partially enlarged view according to the first embodiment of the present invention, and FIG. 3 is a partially enlarged view according to the second embodiment of the present invention. First, the entire lens barrel will be described with reference to FIG.

Six lens groups L1 to L6 are arranged in the lens barrel. At the time of focusing, the lens unit L1 moves in the optical axis direction to adjust the focus. At the time of zooming, the lens units L1 and L3 to L6 move in the optical axis direction to perform zooming. The fixed barrel 1 of the lens barrel is the inner fixed barrel 1
a, an outer fixed barrel 1b, and a mount portion 1c for mounting on the camera body. The inner fixed barrel 1a is provided with straight grooves 1e for holding the lens unit L3 and guiding the movement of the L3 holding barrel 9 which moves in the optical axis direction, at three locations at equal intervals in the circumferential direction. .

Further, a cam groove 1f for guiding the movement of the L6 holding barrel 13 that holds the lens unit L6 and moves in the optical axis direction, and an L5 holding barrel that holds the lens unit L5 and moves in the optical axis direction. 1g straight groove for guiding the movement of 14
Are provided at three locations at equal intervals in the circumferential direction. Further, the fixed lens group L is provided on the inner circumference of the inner fixed barrel 1a.
2, L4 is fixed.

On the outer periphery of the front end of the inner fixed barrel 1a of the fixed barrel 1, an L1 holding barrel 7 for holding the lens group L1 is provided.
It is fitted so as to be movable in the optical axis direction and non-rotatable. A straight groove is provided on the inner circumference of the L1 holding cylinder 7 for moving the L1 holding cylinder 7 straight.

A straight advance key 8 is provided on the outer periphery of the front end of the inner fixed barrel 1a of the fixed barrel 1. Straight key 8
Engages with the straight-moving groove of the L1 holding cylinder 7 to move the L1 holding cylinder 7 straight. (Only the straight movement of the L1 holding barrel 7 is permitted.) Further, the L3 holding barrel 9 holding the lens group L3 is provided on the inner circumference of the inner fixed barrel 1a on the front inner circumference of the inner fixed barrel 1a of the fixed barrel 1.
The straight groove 1e is fitted into the fixed barrel 1 so as to be movable in the optical axis direction and non-rotatable.

Further, an L6 holding cylinder 13 for holding the lens group L6 is provided on the inner periphery of the rear part of the inner fixed cylinder 1a of the fixed cylinder 1.
However, the cam groove 1f of the inner fixed barrel 1a is fitted to the fixed barrel 1 so as to move in the optical axis direction while rotating. A cam groove 13c for moving the lens unit L5 is provided on the front side of the L6 holding cylinder 13.

On the inner circumference of the L6 holding barrel 13, an L5 holding barrel 14 holding the lens group L5 is attached to the fixed barrel 1 by the straight groove 1g of the inner fixed barrel 1a and the cam groove 13c of the L6 holding barrel 13. On the other hand, it is arranged so that it cannot rotate but moves only in the optical axis direction. By the way, the inner fixed cylinder 1 of the fixed cylinder 1
A cam barrel 5 is rotatably held on the outer peripheral portion of a.
A circumferential groove 5 a for holding the cam barrel 5 with respect to the fixed barrel 1 is provided on the inner peripheral surface of the cam barrel 5. Further, a pin 1d for defining the position of the cam barrel 5 with respect to the fixed barrel 1 in the optical axis direction is planted on the outer periphery of the inner fixed barrel 1a of the fixed barrel 1 so as to slide on the circumferential groove 5a of the cam barrel 5. Touching.

The cam barrel 5 has an L1 sliding barrel cam groove 5b for moving the lens unit L1 during zooming.
L3 sliding cylinder cam groove 5 for moving the lens unit L3
c and the L6 sliding cylinder straight-moving groove 5e for moving the lens unit L6 are provided.

On the outer periphery of the rear end of the cam barrel 5, a relay barrel 6 for converting the rotation of the cam barrel 5 into the movement of the lens unit L1 in the optical axis direction is rotated relative to the cam barrel 5. And is held so as to move in the optical axis direction. The relay cylinder 6 and the L1 holding cylinder 7 fitted to the outer periphery of the front end portion of the inner fixed cylinder 1a are
The inner fixed barrel 1 is operated by the action of a straight guide guide (not shown).
The movement of the relay cylinder 6 with respect to a is possible only in the optical axis direction, and the rotation direction is blocked.

On the other hand, a distance tube 2 for focus adjustment is rotatably held at the tip of the outer fixed tube 1b. Distance tube 2
A rectilinear groove 2b is provided on the inner circumference of the parallel to the optical axis.
On the outer periphery of the rear end portion of the L1 holding cylinder 7, the lead cylinder 1 for moving the L1 holding cylinder 7 in the optical axis direction by the rotation of the distance cylinder 2.
0 is rotatably fitted. The lead cylinder 10 includes a lead groove 10 a that engages with the L1 holding cylinder 7, and a relay cylinder 6.
A circumferential groove 10b that engages with is provided.

Further, a focus interlocking pin 10c is planted on the outer peripheral surface of the lead tube 10. The focus interlocking pin 10 c is in sliding contact with the straight groove 2 b of the distance cylinder 2 and transmits the rotation of the distance cylinder 2 to the lead cylinder 10. On the outer peripheral surface of the outer fixed barrel 1b of the fixed barrel 1, a zoom barrel 11 for zooming operation is fitted so as not to move in the optical axis direction and to be rotatable.

A load adjusting ring 21 is screwed onto the outer periphery of the outer fixed cylinder 1b. On the outer peripheral portion of the L1 holding cylinder 7, follower pins 7a are planted in three locations at equal intervals in the circumferential direction. The follower pin 7a is in sliding contact with the lead groove 10a and converts the rotation of the lead tube 10 into the straight movement of the L1 holding tube 7.

Focus adjustment is performed by rotating the distance cylinder 2. At this time, the lead cylinder 10 rotates due to the sliding contact between the rectilinear groove 2b and the interlocking pin 10c, the sliding contact between the lead groove 10a and the follower pin 7a, and the rectilinear key 8 and the L1 holding cylinder 7.
The L1 holding cylinder 7 moves straight in the optical axis direction by fitting with the straight groove.

By the way, the interlocking lever 12 is provided on the inner periphery of the rear portion of the zoom cylinder 11 provided on the outer peripheral portion of the outer peripheral fixed barrel 1b.
Is installed. This interlocking lever 12 is a fixed cylinder 1.
Through the groove of the outer fixed barrel 1b, engages with the groove of the engagement member 5d fixed to the rear end of the cam barrel 5, and transmits the rotation of the zoom barrel 11 to the cam barrel 5.

A cam follower 9a is provided on the outer circumference of the L3 holding cylinder 9 fitted to the inner circumference of the front portion of the inner fixed cylinder 1a.
Three trees are planted at equal intervals in the circumferential direction. The cam follower 9a penetrates the straight groove 1e provided in the inner fixed barrel 1a of the fixed barrel 1 and comes into sliding contact with the cam groove 5c of the cam barrel 5, so that when the cam barrel 5 rotates, the L3 holding barrel 9a. Go straight in the direction of the optical axis.

On the other hand, a cam follower 6a is planted on the inner peripheral surface of the relay cylinder 6 held on the outer periphery of the rear end of the cam cylinder 5. The cam follower 6a is brought into sliding contact with the cam groove 5b of the cam barrel 5 and converts the rotation of the cam barrel 5 into the straight advance of the relay barrel 6. Further, a pin 6b is planted on the outer circumference of the front end portion of the relay cylinder 6. The pin 6b is in sliding contact with the circumferential groove 10b of the lead tube 10 and connects the lead tube 10 to the relay tube 6 so as to be immovable and rotatable in the optical axis direction.

L6 holding cylinder 1 fitted to the inner periphery of the rear portion of 1a
A pin 13 a is planted on the outer circumference of the pin 3. Pin 13
“A” is in sliding contact with the cam groove 1f of the inner fixed barrel 1a of the fixed barrel 1. Further, a key 13b is attached to the upper part of the pin 13a. The key 13b is fitted in the straight groove 5e of the cam barrel 5, and transmits the rotation of the cam barrel 5 to the L6 holding barrel 13.

L provided on the inner circumference of the L6 holding cylinder 13
5 Pins 14a are planted on the outer circumference of the holding cylinder 14. The pin 14a is slidably in contact with the cam groove 1g of the inner fixed cylinder 1a of the fixed cylinder 1 and the cam groove 13c of the L6 holding cylinder 13,
While rotating the 5 holding cylinder 14 in the same rotation as the L6 holding cylinder 13,
Move relative to the optical axis.

For zooming, when the zoom cylinder 11 is rotated, the cam cylinder 5 is rotated via the interlocking lever 12,
The relay cylinder 6 and the lead cylinder 1 follow the cam locus of the cam groove 5b.
0 together with the L1 holding cylinder 7 in the optical axis direction and the cam groove 5
According to the cam locus of c, the L3 holding cylinder 9 is moved in the optical axis direction, and further, the straight groove 5e and the key 13b, the cam groove 1f and the pin 13 are provided.
This is performed by moving the L6 holding cylinder and the L5 holding cylinder in the optical axis direction through the sliding contact between the a, the cam groove 1g and the pin 14a.

Next, the first embodiment of the present invention will be described in detail with reference to FIG. An annular leaf spring 22 having a wavy surface is arranged between the load adjusting ring 21 and the rear end of the zoom cylinder 11 so as to be sandwiched. As the load adjusting ring 21 moves in the optical axis direction by the rotation, the amount of deformation of the annular leaf spring 22 in the optical axis direction changes.

The annular leaf spring 22 has at least one projecting portion 22a in the inner diameter direction and is slidable in the optical axis direction by engaging with the rectilinear groove 1h provided in the outer fixed barrel 1b. Yes, it is installed so that it cannot rotate in the direction of rotation. When taking an image with the lens barrel facing up or down, rotating the load adjusting ring 21 clockwise to move the load adjusting ring 21 forward (to the left in the figure) causes the light from the annular leaf spring 22 to move. Since the amount of deformation in the axial direction increases and the amount of force in the optical axis direction that acts on the zoom barrel 11 increases, the load on the operation of the zoom barrel 11 increases, and as a result, malfunction of the zoom barrel 11 due to its own weight can be prevented. become.

On the other hand, when photographing in a posture close to horizontal,
Rotate the load adjusting ring 21 counterclockwise to rotate the load adjusting ring 21.
Is retracted (moved to the right in the figure), the annular leaf spring 22
The amount of deformation in the direction of the optical axis is reduced, and the amount of force acting on the zoom tube 11 in the optical axis direction is reduced. Therefore, the load on the operation of the zoom tube 11 is reduced and the operation of the zoom tube 11 is facilitated. Further, since the annular leaf spring 22 is engaged with the outer fixed barrel 1b, it is prevented from rotating around the optical axis, and when the zoom barrel 11 is rotated, the load adjusting ring 21 unintentionally rotates together. There is also no problem that the set rotational force amount of the zoom cylinder 11 changes.

Next, a second embodiment of the present invention will be described with reference to FIG. A rotational force blocking ring 23 and an annular leaf spring 24 are arranged so as to be sandwiched between the rear end portion of the zoom cylinder 11 and the load adjusting ring 21. The load adjusting ring 21 is screwed onto the outer periphery of the outer fixed cylinder 1b and moves in the optical axis direction by rotation, so that the deformation amount of the annular leaf spring 24 in the optical axis direction changes.

The rotational force blocking ring 23 has at least one projecting portion 23a in the inner diameter direction, and the outer fixed cylinder 1
It is slidable in the optical axis direction and non-rotatable in the rotation direction by engaging with the straight groove 1h provided in b. When shooting with the lens barrel facing upward or downward, rotating the load adjusting ring 21 clockwise to move the load adjusting ring 21 forward (to the left in the figure) causes the light from the annular leaf spring 24 to move. The amount of axial deformation increases,
Since the amount of force acting on the zoom barrel 11 in the optical axis direction increases, the load on the operation of the zoom barrel 11 increases, and as a result, the malfunction of the zoom barrel 11 due to its own weight can be prevented.

On the other hand, when shooting in a posture close to horizontal,
When the load adjusting ring 21 is rotated counterclockwise and the load adjusting ring 21 is retracted (moved to the right in the drawing), the deformation amount of the annular leaf spring 24 in the optical axis direction decreases, and the zoom cylinder 11
Since the amount of force acting on the optical axis in the optical axis direction decreases, the frictional load also decreases, and the operation of the zoom cylinder 11 becomes easy. Further, since the rotational force blocking ring 23 is engaged with the outer fixed barrel 1b, rotation about the optical axis is blocked, and the zoom barrel 11 is prevented.
There is no inconvenience that the load adjusting ring 21 unintentionally rotates with the rotation of the zoom lens, and the set rotational force amount of the zoom cylinder 11 changes.

[0034]

As described above, according to the lens barrel of the present invention, the load adjusting means capable of adjusting the amount of force of the load member for applying a load to the operating member is provided. It is possible to prevent the malfunction due to its own weight by increasing, and when shooting in a nearly horizontal direction, the operating force of the operating member can be reduced by reducing the force of the load member.

Further, by disposing a load member which is prevented from rotating around the optical axis by engaging with the fixed barrel or a rotational force blocking member which is engaged so as to prevent rotation around the optical axis, an operation is performed. Since the rotational force of the member is configured not to be transmitted to the friction load adjusting ring, it is possible to solve the problem that the friction adjusting ring unintentionally rotates during shooting and the set operation force amount changes.

[Brief description of drawings]

FIG. 1 is a sectional view of a lens barrel according to an embodiment of the present invention.

FIG. 2 is a partially enlarged view of the lens barrel according to the first embodiment of the present invention.

FIG. 3 is a partial enlarged view of a lens barrel according to a second embodiment of the present invention.

[Explanation of symbols]

1 ... Fixed tube 2 ... Distance tube 5 ... Cam tube 11 ... Zoom tube 21 ... Load adjustment ring 22, 24 ... Annular leaf spring 23 ... Rotational force blocking ring

Claims (4)

[Claims] 1. An operation for changing an optical characteristic of the photographing optical system by being arranged coaxially with an optical axis of the photographing optical system with respect to a lens barrel of the photographing optical system and rotating around the optical axis. A lens barrel having a member, comprising: a load member that applies a load to the operation member; and a load adjusting unit that acts on the load member to change the load. 2. The load adjusting means is an annular member arranged coaxially with the optical axis with respect to the lens barrel,
The lens barrel according to claim 1, wherein the amount of force of the load member is adjusted by rotating the annular member around the optical axis. 3. The lens barrel has a fixed barrel, and the load member is prevented from rotating around the optical axis by engaging with the fixed barrel.
Alternatively, the lens barrel described in 2. 4. A rotation force blocking member, which is engaged with the fixed barrel so as to prevent rotation around the optical axis, is arranged between the operating member and the load adjusting means to rotate the operating member. The lens barrel according to claim 1, wherein transmission of force to the friction load adjusting ring is blocked.