JPH08136788A - Zoom lens barrel - Google Patents

Abstract

PURPOSE: To increase the zoom quantity without making a zoom lens barrel larger in size. CONSTITUTION: A spiral cam groove for a cam barrel 55 is formed around an optical axis on a fixed barrel 50 and a spiral cam groove for a first lens group 13 is formed around the optical axis on a first lens group frame 10. A spiral groove for a third lens group 63 is formed around the optical axis on a cam barrel 60. Then, a third lens group frame 30 and an ornamental barrel 70 are coupled by a rotation regulation member 6. When a zoom operation ring 80 is rotated, the cam barrel 60 is moved in an optical axis direction while it is rotated around the optical axis. In accordance with it, the respective frames 10 and 30 and the barrel 70 are moved in the optical axis direction. The movement of the respective frames 10 and 30 is the movement obtained by adding the movement of the cam barrel 60 in the optical axis direction to the movement caused by the rotation of the cam barrel 60. Then, a gap between a focus operation ring 90 formed because of the movement of the rotation of the frame 10 is blocked by the barrel 70 moved in accordance with the movement of the frame 10.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a zoom lens barrel for moving a lens in its optical axis direction.

[0002]

2. Description of the Related Art As a conventional zoom lens barrel, for example, a lens barrel for holding a lens and a cam barrel rotatable around an optical axis of the lens and having a spiral cam groove formed around the optical axis. And a zoom pin that is fixed to the lens frame and fits into the cam groove of the cam barrel, and a zoom operation ring that rotates the cam barrel. In this zoom lens barrel, the cam barrel is rotated around the optical axis by rotating the zoom operation ring, and the cam pin is moved in the direction parallel to the optical axis by the rotation of the cam groove accompanying the rotation of the cam barrel. hand,
The lens frame and the lens are moved in the optical axis direction.

That is, the movement amount of the lens frame and the lens in the optical axis direction in the prior art is limited to the range of the length of the spiral cam groove formed in the cam barrel in the direction parallel to the optical axis. There is.

[0004]

The zoom lens barrel is
In recent years, while the displacement amount of the focal length, that is, the zoom amount is large, the compact size is also required. By the way, in order to increase the zoom amount, the length of the cam groove in the direction parallel to the optical axis must be increased to increase the amount of movement of the lens. Therefore, contrary to the demand for compactness, the length of the cam barrel in the optical axis direction inevitably becomes long. That is, in the related art, there is a problem in that the size cannot be reduced when the zoom amount is increased.

The present invention was made by paying attention to such conventional problems, and even if the zoom amount is increased,
An object is to provide a zoom lens barrel that does not increase in size.

[0006]

A zoom lens barrel for achieving the above object holds a first lens group of a plurality of lens groups, which is disposed farthest from a camera body, on an inner peripheral side. , A part of the outermost circumference of the lens barrel (hereinafter, referred to as the outermost circumference of the lens frame) is formed, and a spiral first lens group cam groove is formed around the optical axis,
A first lens group frame having a cylindrical first lens group frame which is formed with a straight-moving groove for the first lens group extending in a direction parallel to the optical axis and is movable in the optical axis direction, and the first lens among the plurality of lens groups. A cylindrical X-th lens group frame that holds the X-th lens group disposed closer to the camera body than the lens group on the inner peripheral side and is movable in the optical axis direction, and the first lens group frame is the optical axis. The camera body, which has an outer frame outer peripheral portion that is adjacent to the lens frame outermost peripheral portion and forms a part of the outermost periphery of the lens barrel when it is located at the position closest to the camera main body in the direction movement. On the other hand, a cylindrical outer frame which is immovable in the optical axis direction and a spiral cam groove for the X-th lens group are formed around the optical axis, and the optical frame is rotatable about the optical axis and movable along the optical axis. A cylindrical movement assistance tube and a spiral movement assistance tube cam groove are formed around the optical axis. And a cylindrical fixed tube in which a straight-moving groove for the X-th lens group extending in a direction parallel to is formed, and the first lens group frame is located at a position closest to the camera body due to movement in the optical axis direction. While overlapping, the outer frame overlaps with the outer frame in the optical axis direction, and closes a gap generated between the outermost peripheral portion of the lens frame and the outer peripheral portion of the outer frame by the movement of the first lens group frame in the optical axis direction. A makeup tube, and a first lens group cam pin having one end fixed to the movement assistance tube and the other end inserted into the first lens group cam groove of the first lens group frame, A cam pin for a movement assisting cylinder, one end of which is fixed to the movement assisting cylinder and the other end of which is inserted into the cam groove for the movement assisting cylinder of the fixed cylinder, and one end of which is the X-th lens. The X-th lens group is fixed to a group frame, and the other end is the movement assistance tube. A cam pin for the X-th lens group inserted in the cam groove and the rectilinear groove of the X-lens group of the fixed barrel, and a straight lens for the first lens group of the first lens group frame that cannot rotate about the optical axis. A lens frame rotation restricting member inserted into the groove, and a cosmetic tube connecting member having one end fixed to the X lens group frame and the other end fixed to the cosmetic tube. It is characterized by that.

Here, one end of the lens frame rotation restricting member is fixed to the X-th lens group frame, and a part thereof is inserted into the first lens group rectilinear groove of the first lens group frame. Preferably. Further, the lens frame rotation restricting member and the decorative barrel connecting member are the same member, one end of which is fixed to the X-th group lens frame, and the other end of which is fixed to the decorative barrel. It is preferable that a part thereof is inserted into the first lens group straight-moving groove of the first lens group frame.

In the above, the outer frame may be a part of the fixed barrel, a zoom operation ring for rotating the movement assist barrel, or a focus for performing a focusing operation. It may be an operation ring. That is, the outer frame is an outer frame outer periphery that is adjacent to the outermost peripheral portion of the lens frame and forms a part of the outermost periphery of the lens barrel when the first lens group frame is located closest to the camera body. If it has a portion and is immovable in the optical axis direction with respect to the camera body (however, it may be rotatable about the optical axis).
Any one may be used.

[0009]

When the rotational force about the optical axis or the moving force in the optical axis direction is applied to the movement assistance barrel, the rotational force about the optical axis or the optical axis direction is applied to the cam pin for the movement assistance barrel fixed to the movement assistance barrel. The movement power of is added. Since this cam pin is inserted into the cam groove for the cam barrel that is spiral around the optical axis, when a rotational force around the optical axis or a moving force in the optical axis is applied to the cam pin, the cam pin and the fixed movement of the cam pin are moved. The support tube moves in the optical axis direction while rotating around the optical axis. When the movement assisting cylinder rotates and the cam pin for the first lens group fixed to the movement assisting cylinder rotates, the first lens group in which a spiral cam groove for the first lens group is formed around the optical axis. Although the frame tries to move in the optical axis direction while rotating around the optical axis, the frame moves only in the optical axis direction because rotation around the optical axis is restricted by the rotation restricting member. Further, when the movement assisting cylinder rotates and the X-lens group cam groove formed in the movement assisting cylinder rotates, the X-lens group cam pin inserted therein rotates about the optical axis. While attempting to move in the optical axis direction, the X-lens group rectilinear groove formed in the fixed cylinder restricts rotation around the optical axis, and therefore moves only in the optical axis direction. Therefore, when the movement support cylinder rotates,
The X-th lens group frame to which the cam pin for the X-th lens group is fixed moves in the optical axis direction.

By the way, since the movement support barrel also moves in the optical axis direction as described above, the movement distance of each lens group frame is equal to the movement distance by the rotation of the movement support barrel in the optical axis direction of the movement support barrel. It will be the sum of the distance moved to. For this reason,
Each lens group frame can secure a movement amount equal to or more than the length of the cam groove in the direction parallel to the optical axis. That is, the lens frame can secure a movement amount equal to or longer than the length in the direction parallel to the optical axis of the movement assistance tube. Therefore, the zoom amount can be increased without increasing the length of the lens barrel in the optical axis direction.

In the above, the movement of each lens group frame has been described on the premise that the rotational force or the moving force is applied to the movement assisting cylinder, but the force for moving the first lens group frame in the optical axis direction is described. Even when added, in the configuration of the present invention, although the force is applied in the opposite manner to the above, the lens group frames, the cam pins, the movement assisting cylinder, and the like operate in exactly the same manner. Therefore, in the zoom lens barrel of the present invention, each lens group frame is moved even if a rotational force or a moving force is applied to the movement assisting barrel or a moving force in the optical axis direction is applied to the first lens group frame. Can be made.

Further, as in the present invention, since the movement amount of each lens group frame is large, the first lens group frame holding the first lens group arranged at the farthest position from the camera body is the most camera body. Moved far away (maximum telephoto state)
At, if you try not to create a gap with the outer frame,
It is necessary to lengthen the outer frame or the first lens group frame in the optical axis direction. However, this would increase the size of the lens barrel. Therefore, in the present invention, a makeup tube is interposed between the first lens group frame and the outer frame, and the makeup tube is moved along with the movement of the first lens group frame, thereby It closes the gap with the outer frame. More specifically, with the first lens group frame moved closest to the camera body (maximum wide-angle state), the outermost peripheral portion of the lens frame of the first lens group frame and the outer peripheral portion of the outer frame are adjacent to each other. When matching, the makeup tube is arranged so as to overlap the outer frame in the optical axis direction, and this makeup tube is connected to the X-th lens group frame by the makeup tube connecting member, and along with the movement of the first lens group frame. The makeup tube is configured to move in the optical axis direction together with the X-th lens group frame.

[0013]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A zoom lens barrel according to the present invention will be described below with reference to the drawings. The zoom lens barrel of this embodiment has a plurality of lens groups built therein and is attached to the camera body. In the following, for convenience of description, the camera body side is the rear side and the subject side is the front side.

In this embodiment, as the lens group, as shown in FIG. 1, the first lens group L1, the second lens group L2, the third lens group L3, and the fourth lens group L4 are arranged in order from the front side.
There is. As shown in FIG. 1, the zoom lens barrel of the present embodiment includes a first lens group frame 10 that holds the first lens group L1.
And a second lens group frame 20 that holds the second lens group L2
And a third lens group frame (Xth lens group) that holds the third lens group L3.
(Lens group frame) 30, a fourth lens group frame 40 that holds the fourth lens group L4, and a camera body (not shown).
Fixed cylinder 50 fixed to the plurality of cam grooves 62, 63,
A cam barrel (movement support barrel) 60 in which 64 is formed, a zoom operating ring 80 for zooming operation, a focus operating ring 90 for focusing operation, a first lens group frame 10 and a focus operating ring 90. Cosmetic tube 70 for closing the gap between the two, and the diaphragm operation ring 1 for performing the diaphragm operation.
00 and a diaphragm mechanism 105 that adjusts the amount of light guided to the camera body in association with the rotation of the diaphragm operation ring 100.

The fixed barrel 50 includes a mount portion 51 attached to the camera body, an inner tubular portion 52 extending forward from the mount portion 51 and having a cylindrical shape about the optical axis C, and similarly forward from the mount portion 51. An intermediate tubular portion 53 that extends and is cylindrical about the optical axis C, and an outer tubular portion 57 that extends forward from the mount portion 51 and is cylindrical about the optical axis C.
And have. In the outer cylinder portion 57 of the fixed cylinder 50,
A zoom operation ring insertion hole 58 penetrating from the inner peripheral side to the outer peripheral side and extending in the direction around the optical axis is formed. Further, in the intermediate cylinder portion 53 of the fixed cylinder 50, a spiral cam groove 55 for the cam cylinder is formed around the optical axis so as to penetrate from the inner peripheral side to the outer peripheral side. Further, on the inner peripheral side of the intermediate cylindrical portion 53, a third lens group rectilinear groove 54 extending in a direction parallel to the optical axis C is formed.

The cam barrel 60 is an intermediate barrel portion 53 of the fixed barrel 50.
A cam groove forming cylinder portion 61 formed in a cylindrical shape along the inner peripheral surface of the intermediate cylinder portion 53, and an outer cylindrical portion 65 formed in a cylindrical shape from the front end of the intermediate cylinder portion 53 of the fixed cylinder 50 to the outer peripheral side thereof. have. In the cam groove forming cylinder portion 61 of the cam cylinder 60,
A spiral second lens group cam groove 62 and a third lens group cam groove 63 are formed around the optical axis so as to penetrate from the inner peripheral side to the outer peripheral side. Further, the cam groove forming cylinder portion 6
1, a spiral cam groove 64 for the fourth lens group is also formed around the optical axis so as to have a bottom on its inner circumference. The fourth lens group frame 40 holds the fourth lens group L4 and has a cylindrical lens frame portion 41 formed along the inner peripheral surface of the inner tubular portion 52 of the fixed barrel 50, and the lens frame portion 41. And a cylindrical portion 42 that is formed in a cylindrical shape so as to extend forward from and extend along the inner peripheral surface of the cam groove forming cylindrical portion 61 of the cam cylinder 60.

The third lens group frame 30 includes a third lens group L3.
Is formed in a cylindrical shape so as to extend along the inner peripheral surface of the cylindrical portion 42 of the fourth lens group frame 40 on the outer peripheral side thereof. And a tubular portion 33 that is open. The second lens group frame 20 includes a lens frame portion 21 that holds the second lens group L2.
And the cam pin fixing portion 2 extending along the inner peripheral surface of the cylindrical portion 33 of the third lens group frame 30 and extending rearward from the lens frame portion 21.
And 2.

The first lens group frame 10 includes a first lens group L1.
And a cylindrical inner cylindrical portion 1 extending rearward from the lens frame 11 and having an optical axis C as a center.
2 also extends rearward from the lens frame 11 and has an optical axis C
It has a cylindrical outer cylindrical portion 15 centered on. The inner tubular portion 12 and the outer tubular portion 15 of the first lens group frame 10 are
It is located between the outer tubular portion 57 and the intermediate tubular portion 53 of the fixed barrel 50. The inner cylindrical portion 12 of the first lens group frame 10 is formed with a spiral cam groove 13 for the first lens group around the optical axis and penetrating from the inner peripheral side to the outer peripheral side thereof. A first lens group rectilinear groove 14 is formed which penetrates outward and extends in a direction parallel to the optical axis C.

The zoom operation ring 80 extends along the outer peripheral surface of the outer cylinder portion 57 of the fixed cylinder 50 and the operation ring portion 81 formed in a cylindrical shape along with the outer peripheral surface of the intermediate cylinder portion 53 of the fixed cylinder 50. The inner cylinder portion 82 formed in a cylindrical shape and the fixed cylinder 5
It has a connecting portion 84 that connects the operating ring portion 81 and the inner tubular portion 82 through the zero zoom operating ring insertion hole 58. On the inner peripheral surface of the inner cylinder portion 82, a cam cylinder straight-moving groove 83 extending in a direction parallel to the optical axis C is formed. The focus operation ring 90 is substantially the same as the outer diameter of the outer tubular portion 57 of the fixed barrel 50 and is located in front of the outer tubular portion 57.
And a straight groove forming portion 92 formed along the outer periphery of the intermediate cylinder portion 53 of the fixed cylinder 50, and a connecting portion 95 connecting the operation ring portion 91 and the straight groove forming portion 92. The rectilinear groove forming portion 92 is provided with a second lens group rectilinear groove 93 extending in a direction parallel to the optical axis C, and internal teeth 94 formed around the optical axis. Although not shown, the internal teeth 94 mesh with a gear driven by a focusing motor provided in the camera body. Cosmetic case 70
Has an outer peripheral surface of the operation ring portion 91 of the focus operation ring 90.
Of the first lens group frame 10 and a shield cylinder portion 71 that is in contact with the inner peripheral surface of the first lens group frame 10 and has an inner peripheral surface that contacts the outer peripheral surface of the outer cylinder portion 15 of the first lens group frame 10. Outer tube part 1
5 and the inner tubular portion 12 and a connecting tubular portion 72 formed so as to be located between the inner tubular portion 12 and the inner tubular portion 12.

The cam barrel cam pin 5 is fixed to the cam groove forming barrel portion 61 of the cam barrel 60 so as to project in a direction away from the optical axis C. The cam barrel cam pin 5 includes the cam barrel cam groove 55 of the intermediate barrel portion 53 of the fixed barrel 50 positioned on the outer peripheral side of the cam groove forming barrel portion 61, and the zoom positioned further on the outer peripheral side thereof. Inner tube portion 82 of operation ring 80
It is inserted in the straight groove 83 for the cam cylinder. Therefore, when the photographer rotates the zoom operation ring 80, the cam barrel cam pin 5 is rotated around the optical axis along the cam barrel cam groove 55 formed in the fixed barrel 50, and the cam barrel cam pin 5 becomes the optical axis C. Move in parallel direction. As a result, the cam barrel 60 to which the cam barrel cam pin 5 is fixed also moves in the optical axis direction while rotating around the optical axis.

A cam pin 3 for the third lens group is fixed to the cylindrical portion 33 of the third lens group frame 30 so as to project in a direction away from the optical axis C. Cam pin 3 for the third lens group
Is in the third lens group cam groove 63 of the cam barrel 60 located on the outer peripheral side of the tubular portion 33, and in the third lens group rectilinear groove 54 of the fixed barrel 50 located further on the outer peripheral side. Has been inserted. Therefore, when the cam barrel 60 rotates and the third lens group cam groove 63 formed in the cam barrel 60 rotates, the third lens group cam pin 3 moves around the optical axis along the cam groove 63. It tries to move in a direction parallel to the optical axis C while rotating. However, since the cam pin 3 for the third lens group is also inserted in the rectilinear groove 54 extending in the direction parallel to the optical axis C, the rotation around the optical axis is restricted by the rectilinear groove 54, and the optical axis C Move only in the direction parallel to. As a result, the third lens group frame 30 to which the third lens group cam pin 3 is fixed moves in the optical axis direction without rotating around the optical axis. The cam groove forming cylinder 61 of the cam cylinder 60 is provided between the intermediate cylinder 53 of the fixed cylinder 50 and the cylinder 33 of the third lens group frame 30, which are connected to each other by the third lens group cam pin 3. Besides, the cylindrical portion 4 of the fourth lens group frame 40
Since the second lens group 2 is located, the third lens group cam pin 3 does not move with the movement of the fourth lens group frame 40. A long cam pin escape hole 44 is formed in the direction parallel to the optical axis C and through which the lens group cam pin 3 penetrates.

A cam pin portion 4 for the fourth lens group is formed on the outer peripheral side of the cylindrical portion 42 of the fourth lens group frame 40 so as to project in a direction away from the optical axis C. The fourth lens group cam pin portion 4 is inserted into the fourth lens group cam groove 64 of the cam barrel 60 located on the outer peripheral side of the tubular portion 42.
Therefore, when the cam barrel 60 rotates and the fourth lens group cam groove 64 formed in the cam barrel 60 rotates, the fourth lens group cam pin portion 4 rotates around the optical axis along the cam groove 64. It tries to move in a direction parallel to the optical axis C while rotating in the direction of. Therefore, the fourth lens group frame 40 on which the fourth lens group cam pin portion 4 is formed also tries to move in the optical axis direction while rotating around the optical axis. However, the fourth lens group frame 4
0 indicates that the third lens group cam pin 3 that moves only in the direction parallel to the optical axis C is inserted into the cam pin escape hole 44 extending in the direction parallel to the optical axis C, Can not rotate to. Therefore, the fourth lens group frame 40
Also moves in the optical axis direction without rotating around the optical axis.

The cam pin 1 for the first lens group is fixed to the outer tubular portion 65 of the cam barrel 60. The first lens group cam pin 1 is inserted into the first lens group cam groove 13 of the inner cylindrical portion 12 of the first lens group frame 10 located outside the outer cylindrical portion 65. A rotation restricting member 6 is fixed to the front end of the cylindrical portion 33 of the third lens group frame 30 that does not rotate around the optical axis. The rotation restricting member 6 is inserted into the first lens group rectilinear groove 14 of the inner cylindrical portion 12 of the first lens group frame 10, and its tip end is fixed to the connecting cylindrical portion 72 of the decorative cylinder 70. Therefore, when the cam barrel 60 rotates and the first lens group cam pin 1 fixed to the cam barrel 60 rotates, the first lens group frame 10 rotates in the optical axis direction while rotating around the optical axis. Although it tries to move, the rotation around the optical axis is restricted by the rotation restricting member 6, so that it moves only in the optical axis direction. Further, since the makeup cylinder 70 is connected to the third lens group frame 30 that moves only in the optical axis direction by the rotation restricting member 6, the third lens group frame 30 moves in the optical axis direction. It moves in the optical axis direction integrally with the lens group frame 30.

The cam pin fixing portion 22 of the second lens group frame 20
The cam pin 2 for the second lens group is fixed to the. The cam pin 2 is formed in the cam groove 6 of the cam barrel 60 for the second lens group.
2 and the rectilinear groove 93 for the second lens group of the focus operation ring 90
And has been inserted into. Therefore, when the cam barrel 60 rotates and the second lens group cam groove 62 formed in the cam barrel 60 rotates, the second lens group cam pin 2 rotates around the optical axis. However, the second lens group rectilinear groove 93 restricts the movement in the direction parallel to the optical axis C, but moves only in the direction parallel to the optical axis C. As a result, the second lens group frame 20 to which the second lens group cam pin 2 is fixed is
When the cam barrel 60 rotates, it moves in the optical axis direction without rotating around the optical axis. The focus operation ring 90
Is a rotation of the cam barrel 60, it is necessary to restrict the second lens group cam pin 2 from rotating about the optical axis. Therefore, the second lens group cam pin 2 tries to rotate about the optical axis. In order to prevent the focus operation ring 90 from rotating, a constant frictional force acts on the fixed barrel 50. The second lens group frame 20 also moves in the optical axis direction by the rotation of the focus operation ring 90. That is, when the focus operation ring 90 is rotated by the photographer or the focusing motor, a rotational force is applied to the second lens group cam pin 2 from the second lens group rectilinear groove 93 of the focus operation ring 90. Since the second lens group cam pin 2 is also inserted in the second lens group cam groove 62 of the cam barrel 60, when a rotational force is applied, the second lens group cam pin 2 rotates about the optical axis along the cam groove 62. While moving, it moves in a direction parallel to the optical axis C. As a result, when the focus operation ring 90 rotates, the second lens group frame 20 to which the second lens group cam pin 2 is fixed moves in the optical axis direction while rotating around the optical axis. The cam groove of the cam barrel 60 is provided between the cam pin fixing portion 22 of the second lens group frame 20 and the rectilinear groove forming portion 92 of the focus operation ring 90, which are connected to each other by the second lens group cam pin 2. In addition to the forming cylinder 61, the cylinder 33 of the third lens group frame 30, the cylinder 42 of the fourth lens group frame 40, and the intermediate cylinder 53 of the fixed cylinder 50 are arranged. For this reason, the third lens group frame 30, the fourth lens group frame 40, and the fixed barrel 50 are rotated with respect to the rotation of the second lens group cam pin 2 about the optical axis and the movement in the direction parallel to the optical axis C. In order not to be affected, the second lens group cam pin 2 is avoided in the tubular portion 33 of the third lens group frame 30, the tubular portion 42 of the fourth lens group frame 40, and the intermediate tubular portion 53 of the fixed barrel 50, respectively. Cam pin escape notches 34, 43, 56 are formed. The cam grooves 13, 6 are provided on the outer periphery of each cam pin 1, 2 ,.
A cylindrical collar is provided in order to improve slidability between the two.

The configuration and the local operation of the zoom lens barrel of this embodiment have been described above, but the overall operation of the zoom lens barrel of this embodiment will be described below. When it is desired to set the photographing magnification to a specific magnification, the zoom operation ring 80 is rotated around the optical axis. When the zoom operation ring 80 rotates, as described above, a rotational force is applied from the operation ring 80 to the cam barrel cam pin 5, and the cam barrel cam pin 5 moves along the cam barrel cam groove 55 of the fixed barrel 50. While rotating around the optical axis, it moves in a direction parallel to the optical axis C. Therefore, the cam barrel 60 to which the cam barrel cam pin 5 is fixed also moves in the optical axis direction while rotating around the optical axis.

Here, the maximum moving distance of the cam barrel 60 in the optical axis direction, that is, as shown in FIG. 3, the cam barrel cam groove 5 is formed.
Let L be the length of 5 in the direction parallel to the optical axis. Further, as shown in the figure, the length of the first lens group cam groove 13, the length of the second lens group cam groove, and the length of the third lens group cam groove 63 in the direction parallel to the optical axis C. Length, cam groove 64 for the fourth lens group
The lengths of these are l ₁ , l ₂ + B, l ₃ , and l ₄ , respectively. , L ₂ is a length required for rotation of the zoom operation ring 80, and B is rotation of the focus operation ring 90 (however,
This is the length required for rotation when focusing on the wide angle side).

When the cam barrel 60 rotates, as described above, the first lens group frame 10 moves in the optical axis direction by the rotation of the first lens group cam pin 1, and the second lens group frame 20 moves to the second lens group frame 20. The third lens group frame 30 moves in the optical axis direction by the rotation of the cam groove 62 for use, the third lens group frame 30 moves in the optical axis direction by the rotation of the cam groove 63 for the third lens group, and the fourth lens group frame 40 makes the fourth lens group frame 40. The cam groove 64 for rotation is moved to move in the optical axis direction. At this time, each lens group frame 1 by rotation of the cam barrel 60
The maximum movement distance of 0, 20, 30, 40 in the optical axis direction is equal to the lengths l ₁ , l ₂ , l ₃ , l ₄ of the cam grooves 13, 62, 63, 64 in the direction parallel to the optical axis. . However, with respect to the second lens group frame 20, to be precise, the second lens group cam groove 62
Of the length (l ₂ + B) in the direction parallel to the optical axis C of, the maximum movement distance is l ₂ required for the zoom operation.

By the way, the cam barrel 60 is a zoom operation ring 80.
Is also moved in the optical axis direction by rotating the zoom operation ring 80, the moving distance of each lens group frame 10, 20, 30, 40 by the rotation of the zoom operation ring 80 is added to the moving distance of the cam barrel 60 in the optical axis direction. That is, the maximum movement distance of each lens group frame 10, 20, 30, 40 due to the rotation of the zoom operation ring 80 is equal to the maximum movement distance due to the rotation of the cam barrel 60, as shown in FIG.
The maximum movement distance L of the cam barrel 60 in the optical axis direction is added. Therefore, the maximum moving distance of the first lens group frame 10 is (L + l ₁ ), the maximum moving distance of the second lens group frame 20 is (L−1 ₂ ), and the maximum moving distance of the third lens group frame 30 (L
+ L ₃ ) is the maximum moving distance (L + l ₄ ) of the fourth lens group frame
Becomes Note that in FIG. 2, the upper half of the center line (= optical axis C) shows the lens barrel at maximum telephoto, and the lower half shows the lens barrel at maximum wide angle. Further, in FIG.
Is also drawn on the upper half side of the center line, but this is drawn for convenience in order to facilitate understanding of the position and connection relationship between the rotation restricting member 6 and the decorative case 70 at maximum telephoto. .

As described above, in this embodiment, each lens group frame 10, 20, 30, 40 is moved not only by the rotation of the cam barrel 60 around the optical axis but also by the movement of the cam barrel 60 in the optical axis direction. Therefore, the amount of movement of each cam groove 13, 62, 63, 64 in a direction parallel to the optical axis C or more can be secured. That is, each lens group frame 10, 20, 30, 4
With 0, it is possible to secure a movement amount equal to or greater than the length of the cam barrel 60 in the direction parallel to the optical axis C. Therefore, the zoom amount can be increased without increasing the length of the lens barrel in the direction parallel to the optical axis C. In the present embodiment, the two-step moving method by the combination of the movement of the cam barrel 60 around the optical axis and the movement of the cam barrel 60 in the optical axis direction is as follows.
Although it is adopted for all the lens groups, it is most effective to adopt it for the first lens group L1 having the largest maximum movement amount in the optical axis direction among the lens groups. You can

In the relative relationship between the cam pin and the cam groove,
When the cam groove rotates around the optical axis, it is necessary to regulate the cam pin so that the cam pin does not rotate in the optical axis direction but moves in the direction parallel to the optical axis C. In this example,
For the second lens group L2, the third lens group L3, and the fourth lens group L4, which have relatively short maximum movement distances, the fixed barrel 5
A straight groove 54 for the third lens group is formed at 0, and this straight groove 5
By inserting the third lens group cam pin 3 in 4, the straightness of the cam pin 3 with respect to the rotation of the cam groove 63 is secured. However, even for the first lens unit L1 having the largest maximum movement amount in the optical axis direction among the lens units, the fixed barrel 50
If the straight-moving groove formed in the above is used, the length of the fixed barrel 50 in the optical axis direction becomes long. Therefore, the first lens unit L1
With regard to the present embodiment, although there is a difference in the moving distance in the optical axis direction, the rectilinear groove 1 is formed in the first lens group frame 10 and the third lens group frame 30 which both move in the optical axis direction and in the same direction.
4 and 6 to be fitted in the straight-moving groove are respectively provided, and the absolute required lengths of the straight-moving groove are substantially offset by the movement of both 10, 30 in order to reduce the size of the lens barrel. Specifically, a first lens group rectilinear groove 14 is formed in the first lens group frame 10, and the first lens group frame 10 also moves in the optical axis direction with the movement of the first lens group frame 10 and does not rotate around the optical axis. The three-lens group frame 30 is provided with the rotation restricting member 6 that fits in the rectilinear groove 14, and the relative straightness of the cam pin 1 with respect to the cam groove 13,
Here, the straightness of the cam groove 13 with respect to the rotation of the cam pin 1 is secured.

Further, in this embodiment, as described above, since the first lens group frame 10 has a large movement amount, in the state in which the first lens group frame 10 has moved to the frontmost position (maximum telephoto state), The first lens group frame 10 among the parts forming the cylinder
Focus operation ring 9 that is adjacent to and does not move in the optical axis direction
If no gap is created between the focus operation ring 90 and the fixed barrel 50, it is necessary to lengthen the focus operation ring 90 or the fixed barrel 50 in the optical axis direction. However, this would increase the size of the lens barrel. Therefore, in the present embodiment, the decorative barrel 70 is interposed between the first lens group frame 10 and the focus operation ring 90, and the third lens group frame 30 that moves with the movement of the first lens group frame 10 is used. By moving the makeup cylinder 70, the first lens group frame 1
The gap between 0 and the focus operation ring 90 is closed.
More specifically, as shown in FIG. 2, the first lens group frame 1
When 0 is moved to the rearmost (maximum wide-angle state) and the first lens group frame 10 and the focus operation ring 90 overlap, the cosmetic tube 70 overlaps the focus operation ring 90. And the decorative barrel 70 is connected to the third lens group frame 30 by the rotation restricting member 6, and the decorative barrel 70 is moved together with the third lens group frame 30 along the optical axis as the first lens group frame 10 moves. It is configured to move in the direction. In this embodiment, the makeup barrel 70 and the third lens group frame 30 are connected, but any structure may be used as long as the makeup barrel 70 can be moved along with the movement of the first lens group frame 10. For example, the makeup cylinder 70 and the fourth lens group frame 40 may be connected by a pin or the like, and the makeup cylinder 70 may be moved together with the fourth lens group frame 40. However, in the case of the present embodiment, the second lens group frame 20 moves independently in the focusing operation unlike the other lens group frames. Therefore, the second lens group frame 20 and the makeup cylinder 70 should be connected. Is not preferable.

As shown in FIG. 2, it is assumed that the rear end 15a of the outer cylindrical portion 15 of the first lens group frame 10 is assumed to be at maximum telephoto.
Let ld be the length in the optical axis direction of the makeup cylinder 70 required to close the gap between the front end 91a of the operation ring portion 91 of the focus operation ring 90. 1st lens group frame 1 in the maximum wide-angle state
When 0 and the focus operating ring 90 overlap, as described above, the makeup cylinder 70 completely overlaps the focus operating ring 90. When the zoom operation ring 80 is rotated to move the first lens group frame 10 forward, and a gap is generated between the rear end 15a of the first lens group frame 10 and the front end 91a of the focus operation ring 90,
Along with the movement of the first lens group frame 10, the makeup cylinder 70 also moves. This is because the third lens group frame 30 that moves with the movement of the first lens group frame 10 and the makeup cylinder 70 are connected by the rotation restricting member 6. By the movement of the decorative case 70, the gap between the rear end 15a of the first lens group frame 10 and the front end 91a of the focus operation ring 90 is closed.
By the way, when the makeup cylinder 70 is not provided, as described above, it is necessary to lengthen the focus operation ring 90 or the fixed cylinder 50 by ld in the optical axis direction. However, in the present embodiment, the makeup cylinder 70 that completely overlaps the focus operation ring 90 at the maximum wide angle is the first lens group frame 1
If a gap is created between the rear end 15a of the first lens group frame 10 and the front end 91a of the focus operation ring 90 due to the movement of 0, the focus movement ring is moved accordingly and the gap is closed. It is not necessary to lengthen 90 or the fixed barrel 50 in the direction of the optical axis by ld, and the lens barrel does not become large.

When the zoom operation ring 80 is rotated to obtain the desired photographing magnification, the focus operation ring 90 is rotated to perform the focusing operation. The focus operation ring 90 can be rotated manually,
It is also possible to drive a focusing motor provided in the camera body. When the focus operation ring 90 rotates, as described above, the second lens group cam pin 2
Is a rectilinear groove 93 for the second lens group of the focus operation ring 90.
Receives rotational force from. Since the cam pin 2 is inserted into the second lens group cam groove 62 of the cam barrel 60, when it receives a rotational force from the focus operating ring 90, it rotates about the optical axis and moves in a direction parallel to the optical axis C. Moving. Therefore, the second lens group frame 20 to which the cam pin 2 is fixed also moves in the optical axis direction while rotating around the optical axis.

The second lens group cam pin 2 and the second lens group cam groove 62 operate not only during zooming but also during focusing. Therefore, the mutual relationship between the second lens group cam pin 2 and the second lens group cam groove 62 during zooming and focusing will be briefly described with reference to FIG. When the rotation angle of the zoom operation ring 80 is θz, the relative rotation angle of the second lens group cam pin 2 with respect to the second lens group cam groove 62 is also θz. At this time, the moving amount of the second lens group cam pin 2 in the direction parallel to the optical axis C is l ₂ . In addition, the second lens unit L2 necessary for focusing at the time of telephoto
The amount of movement in the direction of the optical axis is A (<l ₂ ) from the telephoto end T to the wide-angle end W. Further, the amount of movement of the second lens unit L2 in the optical axis direction required for focusing at wide angle is
It is B in the direction away from the wide-angle end W to the telephoto end T. Therefore, the range of movement of the cam pin 2 during focusing at the time of telephoto is the cam pin 2 due to the rotation of the zoom operation ring 80.
However, the range of movement of the cam pin 2 due to focusing at the time of wide angle is outside the range of movement of the cam pin 2 due to rotation of the zoom operation ring 80. Therefore, the length of the second lens group cam groove 62 in the direction parallel to the optical axis C is
The length l ₂ required for the rotation of the zoom operation ring 80 is added to the length B required for the rotation of the focus operation ring 90 at the wide angle. In the present embodiment, the amount of movement B of the second lens unit L2 in the optical axis direction required for focusing at the wide angle and the amount of movement A thereof at the telephoto are different, but the operation feeling of the focus operation ring 90 is improved. In order to achieve this, the second lens group cam groove 62 is formed such that the relative rotation angle θw of the cam pin 2 required for focusing at the wide angle and the relative rotation angle θt thereof at the telephoto position are the same.

[0035]

According to the present invention, the cam barrel moves in the optical axis direction while rotating around the optical axis, and each lens group frame moves not only by the rotation of the cam barrel but also the optical axis of the cam barrel. Since the movement accompanying the movement in the direction is also added, the movement amount of the lens, that is, the zoom amount can be increased without increasing the size of the lens barrel itself.

Furthermore, even if the movement of the first lens group frame causes a gap between the outermost peripheral portion of the first lens group frame and the outer peripheral portion of the outer frame, the first lens group frame or the outer frame is not removed. This gap can be closed by the movement of the makeup cylinder accompanying the movement of the first lens group frame without making the gap in the optical axis direction.

[Brief description of drawings]

FIG. 1 is a cross-sectional view (maximum wide-angle state) of a zoom lens barrel according to an embodiment of the present invention.

FIG. 2 is a sectional view of a zoom lens barrel according to an embodiment of the present invention (the upper half is in a maximum telephoto state, and the lower half is in a maximum wide-angle state).
Is.

FIG. 3 is an explanatory diagram showing a relationship between a cam pin and a cam groove according to an embodiment of the present invention.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... 1st lens group cam pin, 2 ... 2nd lens group cam pin, 3 ... 3rd lens group cam pin (X lens group cam pin), 4 ... 4th lens group cam pin part, 5 ... cam barrel Cam pins (movement support cylinder cam pins), 6 ... rotation restriction member (decorative cylinder connecting member), 10 ... first lens group frame, 13 ...
First lens group cam groove, 14 ... First lens group straight-moving groove,
20 ... Second lens group frame, 30 ... Third lens group frame (Xth lens group frame), 40 ... Fourth lens group frame, 50 ... Fixed barrel, 5
DESCRIPTION OF SYMBOLS 1 ... Mounting part, 54 ... Straight groove for 3rd lens group (straight groove for Xth lens group), 55 ... Cam groove for cam cylinder (cam groove for movement assistance cylinder), 60 ... Cam cylinder (movement assistance cylinder), 62 ... second lens group cam groove, 63 ... third lens group cam groove (Xth lens group)
Cam groove for lens group), 64 ... Cam groove for fourth lens group, 7
0 ... Makeup barrel, 80 ... Zoom operation ring, 90 ... Focus operation ring.

Claims (3)

[Claims] 1. A zoom lens barrel attached to a camera body for moving a plurality of lens groups in an optical axis direction, wherein a first lens of the plurality of lens groups is arranged at a position farthest from the camera body. The first lens group cam that holds the lens group on the inner circumference side and forms a part of the outermost circumference of the lens barrel (hereinafter referred to as the outermost circumference of the lens frame) and has a spiral shape around the optical axis. The first lens group rectilinear groove extending in the direction parallel to the optical axis is formed along with the groove, and the cylindrical first lens group frame is movable in the optical axis direction, and the plurality of lenses. Of the group, a cylindrical X-th lens group frame that holds the X-th lens group disposed closer to the camera body than the first lens group on the inner peripheral side and is movable in the optical axis direction, The first lens group frame is located at the position closest to the camera body due to movement in the optical axis direction. The outer peripheral portion of the outer frame is adjacent to the outermost peripheral portion of the lens frame and forms part of the outermost periphery of the lens barrel, and has a cylindrical outer shape that cannot move in the optical axis direction with respect to the camera body. A frame, a spiral cam groove for the X-th lens group is formed around the optical axis, a cylindrical movement assistance tube that is rotatable about the optical axis and movable in the optical axis direction, and a spiral shape around the optical axis. And a cylindrical fixed barrel in which a cam groove for the movement assisting cylinder is formed, and a straight-moving groove for the Xth lens group extending in a direction parallel to the optical axis is formed, and the first lens group frame. When it is located at the position closest to the camera body in the movement along the optical axis, it overlaps with the outer frame in the direction along the optical axis. A decorative tube that closes a gap formed between the outer peripheral portion and the outer peripheral portion of the outer frame; A first lens group cam pin having a portion fixed to the movement assisting cylinder and the other end portion inserted into the first lens group cam groove of the first lens group frame; A cam pin for the moving assistance cylinder fixed to the assistance barrel and the other end of which is inserted into the cam groove for the movement assistance barrel of the fixed barrel, and one end of which is fixed to the X-th lens group frame and the other end An end portion of the X-lens group cam pin inserted in the X-lens group cam groove of the movement assisting cylinder and the X-lens group straight-moving groove of the fixed barrel, and is not rotatable about the optical axis. A lens frame rotation restricting member inserted in the first lens group straight-moving groove of the first lens group frame, one end of which is fixed to the X lens group frame, and the other end of which is the decorative tube And a decorative tube connecting member fixed to the zoom. Lens barrel. 2. The lens frame rotation restricting member has one end fixed to the Xth lens group frame, and a part of which is inserted into the first lens group rectilinear groove of the first lens group frame. The zoom lens barrel according to claim 1, wherein: 3. The lens frame rotation restricting member and the decorative barrel connecting member are the same member, one end of which is fixed to the Xth group lens frame, and the other end is the decorative barrel. 3. The zoom lens barrel according to claim 1, wherein the zoom lens barrel is fixed to the first lens group frame, and a part thereof is inserted into the first lens group straight-moving groove of the first lens group frame.