JP7099477B2 - Lens barrel and camera - Google Patents

Description

The present invention relates to a lens barrel and a camera.

Conventionally, a part of the lens group of the lens barrel has a lens barrel that can be inserted and removed with respect to the optical axis as a movable part (see, for example, Patent Document 1).
The present invention provides a lens barrel and a camera having a movable portion that can be inserted and removed from a predetermined position, and the operability of the movable portion is further improved.

Japanese Unexamined Patent Publication No. 2014-98812

The lens barrel of the first aspect is a lens barrel that can be mounted on the camera body, and has a photographing optical system arranged along the optical axis, a mounting position on the optical axis, and retracted from the optical axis. A movable portion that can be moved between the retracted positions, an operation unit that is arranged at least a part outside the lens barrel to operate the movement of the movable portion, and a driving force from the operation unit to the movable portion. The transmission unit includes a first gear that serves as a rotation axis of the movable portion, a second gear that serves as a rotation axis of the operation unit, and the first gear and the second gear. An intermediate gear that transmits a driving force between the two gears is provided, and the intermediate gear center portion that is the center of the rotation shaft of the intermediate gear is the first gear center portion that is the center of the rotation shaft of the first gear. The configuration is different from that of the center of the second gear, which is the center of the rotation axis of the second gear .

Further, the camera of the third aspect is configured to include the lens barrel.

FIG. 3 is a perspective view of a camera 1 including a lens barrel 2 of an embodiment and a camera body 3 to which the lens barrel 2 is mounted. In the figure explaining the internal structure of the lens barrel 2, (a) shows a state in which a movable part 300 is in a mounting position, and (b) shows a state in which a movable part 300 is in a retracting position. It is a view seen from a different angle from FIG. 2, (a) shows a state where a movable part 300 is in a mounting position, and (b) shows a state where a movable part 300 is in a retracted position. 4 (a), 4 (b), and 4 (c) are diagrams illustrating a moving state between the mounted position and the retracted position of the movable portion 300. It is a figure which shows the gear part 50. It is a figure explaining the encoder which detects the mounting state of the movable part 300. The direction of gravity applied to the movable portion 300 when the camera 1 is in the vertical position is shown. It is a figure which shows the operation state of a camera 1.

Hereinafter, embodiments of the present invention will be described with reference to the drawings and the like. FIG. 1 is a perspective view of a camera 1 including a lens barrel 2 of an embodiment and a camera body 3 to which the lens barrel 2 is mounted. In the present embodiment, the lens barrel 2 is removable from the camera body 3, but the camera 1 may have the lens barrel 2 and the camera body 3 integrated.

In the following description, the up-down, left-right, and front-back directions when the camera 1 is viewed from the photographer side in the horizontal position are referred to as up-down, left-right, and front-back directions in the specification. The front-back direction coincides with the optical axis OA direction.
Here, the horizontal position is
When the long side of the rectangular image sensor 4 (indicated by the dotted line in the figure) included in the camera body 3 extends in the horizontal direction.
When the handle portion 5 (horizontal position handle portion 5a) included in the camera body 3 is in the right lateral direction of the image sensor 4 when viewed from the photographer.
When the release button 7a on which the photographer who operates the camera body 3 operates the shooting operation is in the upper right direction of the image sensor 4 when viewed from the photographer.
When the finder 6 and the flash light emitting unit 8 included in the camera body 3 are in the upward direction of the image sensor 4.
When the tripod hole (not shown) provided in the camera body 3 is in the downward direction of the image sensor 4.
When at least one of is satisfied.
The vertical position is a state in which the camera 1 is rotated 90 degrees counterclockwise when viewed from the photographer side around the optical axis OA from the horizontal position, and the horizontal position handle portion 5a is on the upper side. It is in.

(Camera body 3)
The camera body 3 is a so-called digital single-lens reflex camera that processes subject light incident on the image sensor 4 and records it in a recording unit (not shown). However, the camera body is not limited to the digital single-lens reflex camera. It may be a mirrorless camera or a compact digital camera. It may also be a binocular camera. It may be a camera built into a smartphone or tablet. Further, the camera is not limited to a digital camera, and may be a film camera.

The camera body 3 is provided with a lateral position handle portion 5a projecting to the front on the right side of the camera body 3 so that the user can stably grip the camera 1 in the lateral position. Further, on the lower side of the camera body 3, a vertical position handle portion 5b is provided so as to project forward so that the user can stably grip the camera 1 during vertical position shooting. The vertical handle portion 5b may be detachable from the camera body 3.

Release buttons 7a and 7b are provided on the upper side and the lower side of the lateral position handle portion 5, respectively. When the release buttons 7a and 7b are pressed halfway, the autofocus function is activated, and when the release buttons 7a and 7b are fully pressed, the subject image is imaged at a preset shutter speed.
The release button 7a provided on the upper side is a horizontal position release button 7a used when the camera body 3 is in the horizontal position. The release button 7b provided on the lower side is a vertical release button 7b used when the camera body 3 is in the vertical position.

A finder 6 is provided on the rear surface of the camera body 3 above the image sensor 4. The finder 6 is not limited to the optical finder method, but may be an electronic viewfinder method, and can confirm the subject and composition, confirm the focus position, confirm various settings, and the like.
A tripod hole (not shown) is provided on the lower surface of the camera body 3. A body mount BM is provided in the center of the front side of the camera body 3.

(Lens barrel 2)
The lens barrel 2 is provided with a lens mount LM on the rear side, and is detachably attached to the camera body 3 by engaging with the body mount BM of the camera body 3.

The lens barrel 2 has a photographing optical system composed of a plurality of lens groups arranged inside. In FIG. 1, only the front row lens L is shown.
On the outside of the lens barrel 2, an operation unit 21, an accommodating unit 22, and a strap mounting unit 23 are provided from the rear end toward the front side along the optical axis OA. A focus ring 24 and a zoom ring 25 are arranged further in front of the strap mounting portion 23.

The strap mounting portion 23 is attached to the left and right sides of the outer cylinder 26b of the lens barrel 2, and the lens strap 27 can be mounted on the left and right strap mounting portions 23.

(Accommodation unit 22)
The accommodating portion 22 is a portion that protrudes convexly from the outer cylinder 26a that covers the movable portion 300 including the teleconverter lens 30 described later when the housing portion 22 is in the retracted position.

FIG. 2 is a rear perspective view of the lens barrel 2 and is a diagram illustrating the internal structure of the lens barrel 2 from the state of FIG. 1 with the outer barrels 26a and 26b covering the outer periphery of the lens barrel 2 removed. FIG. 3 is a view seen from a different angle from FIG. 2 and 3, (a) shows a state in which the movable portion 300 (teleconverter lens 30) is in the mounting position, and (b) shows a state in which the movable portion 300 (teleconverter lens 30) is in the retracted position. 4 (a), 4 (b), and 4 (c) are diagrams illustrating a moving state between the mounted position and the retracted position of the movable portion 300 (teleconverter lens 30). An inner cylinder 29 that movably supports the movable portion 300 is arranged on the inner diameter side of the outer cylinder 26a.

(Movable part 300)
The movable portion 300 includes a teleconverter lens 30 and a frame 31 that covers the outer periphery of the teleconverter lens 30.

(Teleconverter lens 30)
The teleconverter lens 30 is a lens group that extends the focal length. The mounting position is the position of the teleconverter lens 30 when the center (optical axis) of the teleconverter lens 30 is placed on the optical axis OA of another photographing optical system. It will be possible to take even larger photographs. The retracted position is the position of the teleconverter lens 30 that is out of the optical path of the photographing optical system so as not to obstruct the optical path of the other photographing optical system.

(Frame 31)
The frame 31 includes an annular frame 32 that surrounds the outer periphery of the teleconverter lens 30, an arm portion 33 that protrudes outward from the annular frame 32, and a roller holding portion 34 that also protrudes outward from the annular frame 32. And have.

(Arm portion 33)
The arm portion 33 has a first portion 33a extending radially outward from the annulus frame 32, and a second portion 33b extending radially outward from the first portion 33a. The shape and arrangement of the first portion 33a and the second portion 33b in the arm portion 33 can be appropriately changed. In the present embodiment, the first portion 33a and the second portion 33b are arranged along the outer peripheral surface of the lens barrel 2 when the movable portion 300 is in the retracted position, so that the diameter of the lens barrel 2 is increased. It is preferable because it prevents it.
The tip of the second portion 33b is attached to the rotation shaft A4 of the teleconverter rotation gear 54 of the gear portion 50 described later. When the second portion 33b and the first portion 33a rotate (swing) with the rotation of the teleconverter rotation gear 54, the movable portion 300 rotates (swings) about the rotation shaft A4.
In the embodiment, since the weight of the frame 31 is lighter than the weight of the teleconverter lens 30, the center of gravity of the movable portion 300 is shown in FIG. 4 so as to substantially coincide with the center of the teleconverter lens 30. Further, since the teleconverter lens 30 and the annular frame 32 are cylindrical members whose axis is the optical axis of the teleconverter lens 30, the center of gravity of the movable portion 300 in the plane orthogonal to the optical axis direction is that of the teleconverter lens 30. Approximately coincides with the center.

(Spring member 36)
The first mounting portion 33c is provided at a position close to the annular frame 32 in the first portion 33a of the arm portion 33. Further, a second mounting portion 33d is provided on the fixing portion 29a fixed to the inner cylinder 29. A spring member 36 is attached between the first attachment portion 33c and the second attachment portion 33d.
In this embodiment, the spring member 36 is attached, but the present invention is not limited to this, and if the first attachment portion 33c and the second attachment portion 33d are urged and deformable so as to attract each other, rubber or the like is used. It may be another elastic member.
Then, when the arm portion 33 rotates about the rotation shaft A4 of the teleconverter rotation gear 54 as described above, the spring member 36 is fixed to the first mounting portion 33c centering on one end attached to the second mounting portion 33d. The other end is rotated. The spring member 36 may have at least one of one end and the other end rotatable so that the arm portion 33 can rotate.

(Roller holding portion 34)
The roller holding portion 34 projects outward from a position different from that of the arm portion 33 in the annular frame 32 of the frame body 31. A cylindrical portion 35 made of an elastic member is rotatably attached to the tip of the roller holding portion 34 with respect to an axis extending in the optical axis OA direction. The cylindrical portion 35 is not limited to the elastic member, but may be another flexible member. Further, the cylindrical portion 35 is not an elastic member, and the contact wall portion 40 side described below may be an elastic member or a flexible member.

(Abutment wall portion 40 (first limiting portion))
When the movable portion 300 (teleconverter lens 30) is in the mounting position, the movable portion 300 (teleconverter lens 30) is counterclockwise due to the spring force of the spring member 36 described above and the gravity applied to the movable portion 300 described later. (Movement in the direction opposite to the direction toward the retracted position, movement to the left side of the arrow R in the figure) A force in the direction is applied.
Therefore, in order to limit the counterclockwise movement beyond the mounting position of the movable portion 300 (teleconverter lens 30), the contact wall portion 40 (first limiting portion) fixed to the inner cylinder 29 is provided. Has been done. When the movable portion 300 (teleconverter lens 30) reaches the mounting position, the contact wall portion 40 comes into contact with the cylindrical portion 35, and the movable portion 300 (teleconverter lens 30) rotates counterclockwise above the mounting position. To prevent.

(Abutment member 41 (second limiting part))
When the movable portion 300 (teleconverter lens 30) is in the retracted position, the movable portion 300 (teleconverter lens 30) is rotated clockwise due to the spring force of the spring member 36 described above and the gravity applied to the movable portion 300 described later. A force is applied in the direction (movement in the direction opposite to the direction toward the mounting position, movement to the right side of the arrow R in the figure).
Therefore, in order to limit the clockwise movement beyond the retracted position of the movable portion 300 (teleconverter lens 30), a contact member 41 (second limiting portion) fixed to the inner cylinder 29 is provided. There is. The contact member 41 is an L-shaped metal fitting, and when the movable portion 300 (teleconverter lens 30) reaches the retracted position, it contacts the cylindrical portion 35, and the clock is equal to or higher than the retracted position of the movable portion 300 (teleconverter lens 30). Prevent rotation around.

The first limiting portion is a contact wall portion 40 fixed to the inner cylinder 29, and the second limiting portion is a contact member 41 which is an L-shaped metal fitting. However, the material and shape of the limiting portion are this. Not as long. Further, the first limiting portion and the second limiting portion may be used in combination with another member. Further, in the present embodiment, the contact member 41 is in contact with the first limiting portion and the second limiting portion, but two contact members are provided to contact the first limiting portion and the second limiting portion, respectively. You may let it.

It is preferable that the location where the roller holding portion 34 is provided has a large distance from the rotating shaft A4 so that the force with which the cylindrical portion 35 is pressed against the abutting wall portion 40 and the abutting member 41 by the spring member 36 can be reduced.

With the movable portion 300 (teleconverter lens 30) in FIG. 4A in the mounted position, the center of the movable portion 300 is located on the optical axis OA of the lens barrel 2. Here, the center of the movable portion 300 in the present embodiment substantially coincides with the central axis of the annular frame 32 and the optical axis of the teleconverter lens 30, but this is not the case depending on the members included in the movable portion 300. Since the teleconverter lens 30 of the movable portion 300 is included in the present embodiment, it is preferable in terms of optical performance that the center of the movable portion 300 substantially coincides with the optical axis OA of another lens included in the lens barrel 2 at the mounting position. .. Depending on the member included in the movable portion 300, the center of the movable portion 300 may not be located on the optical axis OA at the mounting position.
Further, the center of gravity of the movable portion 300 in the present embodiment substantially coincides with the center of gravity of the teleconverter lens 30, and also substantially coincides with the center of gravity of the member in which the annulus frame 32 and the teleconverter lens 30 are combined, but this is not limited to this. ..

Further, it is sufficient that the movable portion 300 (teleconverter lens 30) in FIG. 4C is in the retracted position so as not to block the light rays in the lens barrel 2, and the accommodating portion 22 does not need to be enlarged. Is preferable. That is, the position accuracy when the movable portion 300 (teleconverter lens 30) is in the retracted position may be lower than the position accuracy when the movable portion 300 (teleconverter lens 30) is in the mounted position. Further, when the teleconverter lens 30 is in the retracted position, it is preferably on the semicircular side on the optical axis OA side on the outer circumference of the frame body 31.

The cylindrical portion 35 is rotatable with respect to the roller holding portion 34. Therefore, when the cylindrical portion 35 comes into contact with the contact wall portion 40 or the contact member 41, the same portion does not always abut, and the contact portion moves due to the rotation of the cylindrical portion 35. Therefore, the wear is not concentrated on a part of the cylinder portion 35, and the durability of the cylindrical portion 35 is good.
Further, since the cylindrical portion 35 is an elastic member, no collision noise is generated at the time of contact with the contact wall portion 40 or the contact member 41, and the noise reduction is excellent. In the present embodiment, the cylindrical portion 35 is an elastic member, but it can be appropriately changed as long as the collision noise can be reduced. The elastic member may be any of a flexible member, a shock absorbing member, and a sound absorbing member. Further, the elastic member is provided on at least one of the contact wall portion 40 (first limiting portion), the contact member 41 (second limiting portion), and the member that abuts on the limiting portion (cylindrical portion 35 in this embodiment). Just do it.

(Gear part 50)
FIG. 5 is a diagram showing the gear portion 50, and is a state in which the gear portion cover 56 shown in FIGS. 2 and 3 is removed. The gear unit 50 transmits a driving force to the movable unit 300 when the operation unit 21 is operated, and includes an operation unit connecting gear 51, an intermediate gear 52, a brush rotation gear 53, and a teleconverter rotation gear 54. , With a damper gear 55.
These gears are arranged in a row along the circumferential direction centered on the optical axis OA, but are not limited to this, and if the driving force can be transmitted, they are arranged in a row along the circumferential direction centered on the optical axis OA. It does not have to be.

One end of the rotating portion 21a of the operating portion 21, which will be described later, is attached to the rotating shaft A1 of the operating portion connecting gear 51. A brush portion 61, which will be described later, is attached to the rotation shaft A3 of the brush rotation gear 53. As described above, the tip end portion of the second portion 33b of the arm portion 33 is attached to the rotation shaft A4 of the teleconverter rotation gear 54. The damper gear 55 is a gear whose rotation speed is limited by, for example, viscous oil, and reduces the rotation speed of the teleconverter rotation gear 54.

(Operation unit 21)
Returning to FIGS. 1, 2 and 3, the operation unit 21 is attached to the rear side of the accommodating unit 22. The operation unit 21 is L-shaped and includes a rotating portion 21a extending in a direction orthogonal to the optical axis OA and an extending portion 21b extending in the optical axis OA direction.
One end of the rotating portion 21a is attached to the rotating shaft A1 of the operation portion connecting gear 51 of the above-mentioned gear portion 50, and can rotate (swing) about the rotating shaft A1.
The extending portion 21b extends from the other end side of the rotating portion 21a to the outside of the outer cylinder 26a toward the front side in the optical axis OA direction. The outer cylinder 26a is provided with a slit opened in a predetermined range in the circumferential direction, and the extending portion 21b extends to the outside of the outer cylinder 26a through the slit.

When the photographer moves the extending portion 21b of the operating portion 21 from the outside of the outer cylinder 26a in the circumferential direction of the outer cylinder 26a along the slit, the rotating portion 21a rotates about the rotation axis A1.
Then, the operation unit connecting gear 51 rotates, and the rotation rotates the teleconverter rotation gear 54 having a large number of teeth via the intermediate gear 52 and the brush rotation gear 53. When the teleconverter rotation gear 54 rotates, the arm portion 33 also rotates. The rotation of the arm portion 33 causes the movable portion 300 (teleconverter lens 30) to move between the mounting position and the retracted position. At this time, the center of the movable portion 300 rotates in the direction of the arrow R in FIG.

In this way, the operation unit 21 is connected to the teleconverter rotation gear 54 having a large number of teeth via the operation unit connection gear 51, the intermediate gear 52, and the brush rotation gear 53. Therefore, even if the force for driving the operation unit 21 is small, the movable unit 300 (teleconverter lens 30) that requires a large force for driving can be rotated through these gear units.

A stopper 28 is provided between the extending portion 21b at the mounting position and the extending portion 21b at the retracting position. The stopper 28 is slidable with respect to the outer cylinder 26a, and when it slides forward in the optical axis OA direction, the extending portion 21b becomes movable between the mounting position and the retracted position, and when it slides backward in the optical axis OA direction. , The movement of the extending portion 21b between the mounting position and the retracting position is prevented.

(Encoder)
FIG. 6 is a diagram illustrating an encoder (signal generation unit) that detects a mounted state of the movable unit 300 (teleconverter lens 30). The encoder includes an FPC (flexible printed circuit board) 60 and a brush portion 61.
The FPC 60 is attached to the outer surface of the gear portion cover 56 that houses the gear portion 50. The brush portion 61 is attached to the rotation shaft A3 of the brush rotation gear 53 and rotates together with the rotation shaft A3.

When the movable portion 300 (teleconverter lens 30) shown in FIG. 6 (c) is in the retracted position, the brush portion 61 is not in contact with the wiring for the movable portion attachment / detachment signal of the FPC 60.
When the movable portion 300 (teleconverter lens 30) shown in FIG. 6A is in the mounting position, the brush portion 61 is in contact with the wiring for the movable portion attachment / detachment signal of the FPC 60.

The contact state of the brush portion 61 with the wiring for the movable portion attachment / detachment signal of the FPC 60 is switched at the position shown in FIG. 6 (b).
That is, before the movable portion 300 (teleconverter lens 30) reaches the mounting position or the retracting position while moving between the mounting position and the retracting position, the moving direction of the center of the movable portion 300 is from the upper side to the lower side. When switching to, the contact state between the wiring for the movable portion attachment / detachment signal of the FPC 60 and the brush portion 61 is switched. Then, a signal indicating a change in the mounting state is sent via the FPC 60 to a control unit (not shown) provided in the lens barrel 2 and the camera body 3.

The control unit provided in at least one of the lens barrel 2 and the camera body 3 performs processing for calculating the lens position, shutter speed, aperture, and exposure at the time of autofocus. At the time of these calculations, the presence or absence of the teleconverter function differs depending on whether the movable portion 300 (teleconverter lens 30) is in the mounting position or the retracted position, so that different calculations are performed.

On the other hand, for example, if the structure is such that when the movable portion 300 (teleconverter lens 30) reaches the mounting position or the retracted position, the mounting signal is sent to the control unit, it takes time to calculate for shooting and tele. There will be a time lag between switching the presence / absence of the converter function and enabling shooting.
However, according to the present embodiment, the movable portion 300 (teleconverter lens 30) starts moving from the retracted position and reaches the mounting position, or the movable portion 300 (teleconverter lens 30) moves from the mounting position. A signal indicating a change in the mounting state is sent to the control unit via the FPC 60 before the engine reaches the retracted position. Therefore, the calculation process can be started at the timing before the position switching of the movable portion 300 (teleconverter lens 30) is completed, and the calculation is performed when the movable portion 300 (teleconverter lens 30) reaches the mounting position or the retracted position. The process is complete and you can start shooting immediately.
In the present embodiment, the timing at which the contact state is switched is when the moving direction of the center of the movable portion 300 is switched from the upper side to the lower side, but this is not the case. The timing at which the contact state is switched may be before the movable portion 300 (teleconverter lens 30) reaches the mounting position or the retracted position, and is appropriately changed depending on the time required for transmission to the control unit and the arithmetic processing in the control unit. It is possible.

(In the case of horizontal position)
Returning to FIG. 4, the arrow G in the figure indicates the direction of gravity applied to the center of the movable portion 300 when the camera 1 is in the horizontal position.
The arrow R is a movement locus of the center of the movable portion 300. When the movable portion 300 (teleconverter lens 30) moves between the mounting position and the retracted position, the vertical position (vertical direction) of the center of the movable portion 300 temporarily moves upward as shown by the arrow R. Then, after exceeding the highest point shown in FIG. 4 (b), it moves downward. The arrow R extends along the circumferential direction about the rotation axis A4.
That is, the movement locus of the center of the movable portion 300 has a U-turn shape in the vertical direction. Therefore, when the camera 1 is in the horizontal position, the movable portion 300 (teleconverter lens 30) is prevented from stopping in the middle of switching, and the movable portion 300 (teleconverter lens 30) is placed in either the mounting position or the retracting position. Moving.

In the state shown in FIG. 4B, the position in the vertical direction of the center of the movable portion 300 is the highest position. In this state, the first mounting portion 33c and the rotating shaft A4 of the spring member 36 and the second mounting portion 33d are aligned in a straight line, and the spring member 36 is in the state of being most extended from the retracted position to the mounting position.

When the teleconverter lens 30 moves from this state to the mounting position side of (a), the spring member 36 becomes the inner diameter side of the rotation shaft A4. Then, since the urging force is applied to the spring member 36 in the contracting direction, the spring member 36 urges the movable portion 300 (teleconverter lens 30) toward the mounting position.
That is, in addition to the above-mentioned gravity, the spring force of the spring member 36 also urges the movable portion 300 (teleconverter lens 30) toward the mounting position.

Further, when the movable portion 300 (teleconverter lens 30) moves from the retracted position side of (b) to (c), the spring member 36 becomes the outer diameter side of the rotating shaft A4. Then, since the urging force is applied to the spring member 36 in the contracting direction, the spring member 36 urges the movable portion 300 (teleconverter lens 30) toward the retracted position.
That is, in addition to the above-mentioned gravity, the spring force of the spring member 36 also urges the movable portion 300 (teleconverter lens 30) toward the retracted position.

As described above, in the horizontal position, the movable portion 300 (teleconverter lens 30) is placed in the movable portion 300 (teleconverter lens 30) from the highest position regardless of whether the movable portion 300 (teleconverter lens 30) is in the mounting position or the retracted position. According to gravity, a force is applied in the direction of falling downward, and a tensile force is also applied in the same direction by the spring force. Therefore, the force for the photographer to move the operation unit 21 is almost unnecessary in the latter half of the movement, so that the operation is easy. In particular, operability is improved when the movable portion 300 (teleconverter lens 30) is heavy.

Further, at the mounting position shown in FIG. 4A and the retracting position shown in FIG. 4C, the spring force and gravity are applied to the movable portion 300 (teleconverter lens 30) in substantially the same direction. Therefore, the movable portion 300 (teleconverter lens 30) is difficult to move from the mounting position or the retracted position, and is held more stably.

(In the case of vertical position)
FIG. 7 shows the direction of gravity applied to the movable portion 300 when the camera 1 is in the vertical position tilted 90 degrees from the horizontal position shown in FIG.
Even in the case of the vertical position, when the movable portion 300 (teleconverter lens 30) moves from (b) to the mounting position side of (a), the movable portion 300 (teleconverter lens 30) is caused by the spring force of the spring member 36. Is urged to move to the mounting position.
Then, even due to gravity, a force is applied to the center of the movable portion 300 so as to move toward the mounting position side.
Therefore, even when the camera 1 is in the vertical position, the movable portion 300 (teleconverter lens 30) moves to the mounting position side after the maximum value of the spring force is exceeded.
Then, at the mounting position, the spring force and gravity are applied to the movable portion 300 in substantially the same direction. Therefore, the movable portion 300 (teleconverter lens 30) is less likely to move from the mounting position and is more stably held in the mounting position.

Even in the vertical position, when the movable portion 300 (teleconverter lens 30) moves from (b) to the retracted position side of (c), the movable portion 300 (teleconverter lens 30) retracts due to the spring force of the spring member 36. You are urged to move to a position.
At this time, the spring force of the spring member 36 is in a direction opposite to gravity, but the teleconverter lens 30 is moved to the retracted position by selecting so that the spring force is stronger than gravity.
Therefore, even when the camera 1 is in the vertical position, after the maximum value of the spring force is exceeded, the camera 1 moves to the movable portion 300 (teleconverter lens 30) and the retracted position side.
Then, at the retracted position, the spring force applied to the movable portion 300 (teleconverter lens 30) and gravity are on the opposite side, so that the stability is lower than that of the mounting position, but the movable portion 300 (teleconverter lens 30) is located. In the case of the retracted position, there is little adverse effect because it does not affect the shooting.

Further, according to the embodiment, at least a part of the operation unit 21, at least a part of the gear unit 50, and at least a part of the teleconverter lens 30 in the retracted state are arranged on the same straight line along the optical axis OA. ing.
An extending portion 21b of the operating portion 21 extending outside the outer cylinder 26a is arranged on the rear side of the accommodating portion 22 for accommodating the movable portion 300 (teleconverter lens 30) in the retracted state. That is, the accommodating unit 22 is arranged closer to the subject than the operating unit 21.
The extending portion 21b is located radially inside the optical axis OA with respect to the accommodating portion 22. Therefore, even if something comes into contact with the lens barrel 2 from the outside, the accommodating portion 22 comes into contact with the extending portion 21b before the extending portion 21b, so that there is little possibility that the operating portion 21 will malfunction.

As described above, the lens strap 27 is attached to the strap mounting portion 23 on the front side of the accommodating portion 22, but since the accommodating portion 22 is provided, the lens strap 27 is mistakenly caught on the extending portion 21b. Therefore, the operation unit 21 does not malfunction.

According to the present embodiment, the operation unit 21 and the accommodating unit 22 are provided on the right side of the lens barrel 2. That is, the operation unit 21 is arranged at a position closer to the lateral position handle portion 5a than the optical axis OA.
FIG. 8 is a diagram showing an operating state of the camera 1. When the photographer holds the camera 1 in the lateral position, the photographer generally grips the lateral handle portion 5a with the right hand RH. Then, the tip of the index finger is placed on the horizontal release button 7a. At this time, the focus ring 24 and the zoom ring 25 are operated while supporting the tip portion of the lens barrel 2 with the left hand LH.
According to the embodiment, the operation unit 21 is arranged on the right hand RH side holding the lateral position handle unit 5a.
Further, the operation unit 21 is closer to the horizontal position handle portion 5a for the photographer to hold during the horizontal position shooting than the optical axis OA when the lens barrel 2 is attached to the camera body 3. Placed in position. That is, the handle portion 5a for the lateral position is gripped by the right hand RH and is arranged within the reach of the middle finger and the ring finger.
Therefore, the photographer can switch whether or not the teleconverter lens 30 has a function at the time of shooting while looking into the finder 6 and pressing the release button 7a. That is, the presence or absence of the function of the teleconverter lens 30 can be switched without changing the posture from the normal shooting state, so that the operability is good.

In particular, when the lens barrel 2 is heavy, the left-hand LH often operates the focus ring 24 and the zoom ring 25 while supporting the tip of the lens barrel 2. Assuming that the operation unit 21 is arranged on the left hand LH side, it is necessary to operate the operation unit 21 by separating the left hand LH from the lens barrel 2 or shifting the support position to the operation unit 21 position. .. Then, the lens barrel 2 cannot be held by the left hand LH or is not stable, so that the operability is poor.

(Deformed form)
Although the preferred embodiment has been described above, the present invention is not limited to the above embodiment. For example, the following modifications are possible.
(1) In the present embodiment, the teleconverter lens 30 is attached / detached by the L-shaped lever-shaped operation unit 21, but it may be, for example, a push button.
(2) Further, in the embodiment, the gear unit 50 is used for power transmission between the operation unit 21 and the movable unit 300 (teleconverter lens 30), but the gear unit 50 is not limited to the gear unit 50 and is in the middle of the transmission of switching. Motors may be placed.
(3) In the embodiment, the member including the teleconverter lens 30 as the movable portion has been described, but the movable portion is not limited to this, and the movable portion is, for example, a photographing optical system that moves when the lens barrel length of the lens barrel is reduced. It may be a member including a part of the lens, a member including a lens used for switching the focal distance in the bifocal lens, and further, the movable portion may not include the lens.
(4) In the embodiment, the switching detection is performed by the FPC 60 as an encoder and the brush unit 61, but the switching is not limited to this. Other structures such as may be used. Further, in the embodiment, the brush is at the base of the operation unit 21, and the encoder is at the side surface of the gear unit, but this is not the case.
(5) In the embodiment, the operation unit 21 has a structure of being manually driven, but is not limited to this, and may have a structure of electrically moving when the switch is turned on.

A1: Rotation axis, A3: Rotation axis, A4: Rotation axis, BM: Body mount, L: Lens, LM: Lens mount, OA: Optical axis, 1: Camera, 2: Lens barrel, 3: Camera body, 4 : Image pickup element, 5a: Horizontal handle, 5b: Vertical handle, 6: Finder, 7: Release button, 7a: Horizontal release button, 7b: Vertical release button, 21: Operation unit, 21a: Rotating part, 21b: Extended part, 22: Accommodating part, 23: Strap mounting part, 24: Focus ring, 25: Zoom ring, 26a, 26b: Exterior cylinder, 27: Strap, 28: Stopper, 29: Inside Cylinder, 29a: Fixed part, 30: Teleconverter lens, 31: Frame body, 32: Ring frame, 33: Arm part, 33a: First part, 33b: Second part, 33c: First mounting part, 33d: 2nd mounting part, 34: roller holding part, 35: cylindrical part, 36: spring member, 40: contact wall part, 41: contact member, 50: gear part, 51: operation part connecting gear, 52: second Gear, 53: 3rd gear, 54: Telecon rotary gear, 55: Damper gear, 56: Gear part cover, 61: Brush part, 300: Moving part

Claims (14)

It is a lens barrel that can be attached to the camera body.
The shooting optical system arranged along the optical axis and
A movable part that can move between the mounting position on the optical axis and the retracted position retracted from the optical axis.
An operation unit that is arranged at least a part on the outside of the lens barrel to operate the movement of the movable portion, and an operation unit.
A transmission unit that transmits a driving force from the operation unit to the movable unit is provided.
The transmission unit
The first gear, which is the axis of rotation of the movable part,
The second gear, which is the axis of rotation of the operation unit,
An intermediate gear that transmits a driving force between the first gear and the second gear is provided.
The intermediate gear center portion, which is the center of the rotation shaft of the intermediate gear, is the first gear center portion, which is the center of the rotation shaft of the first gear, and the second gear center portion, which is the center of the rotation shaft of the second gear. A different lens barrel. The intermediate gear is composed of a plurality of gears.
Arranged along the circumferential direction around the optical axis,
The lens barrel according to claim 1. When the lens barrel is attached to the camera body, the operation unit is arranged at a position closer to the handle portion for the photographer to hold during lateral position shooting than the optical axis.
The lens barrel according to claim 1 or 2. A housing unit for accommodating the movable portion in the retracted position is provided.
At least a part of the operation part, at least a part of the transmission part, and at least a part of the accommodation part are arranged along the optical axis.
The lens barrel according to any one of claims 1 to 3. The accommodating portion is arranged closer to the subject than the operation unit.
The lens barrel according to claim 4. The lens barrel has a handle portion for the photographer to hold during horizontal position shooting.
The movable portion includes a lens that can be moved between a mounting position on the optical axis and a retracted position retracted from the optical axis.
When the lens barrel is attached to the camera body, the operation unit is arranged at a position closer to the handle portion than the optical axis.
The operation unit includes a rotating portion extending in a direction intersecting the optical axis and an extending portion extending in the optical axis direction.
The lens barrel according to any one of claims 1 to 5 , wherein the rotating portion is arranged on the image side from at least a part of the movable portion. The lens barrel according to claim 6, wherein the position where the extending portion is in contact with the rotating portion is on the image side of at least a part of the movable portion. The horizontal position is
When the long side of the rectangular image sensor included in the camera body extends in the horizontal direction
When the handle portion of the camera body is in the right lateral direction of the image sensor,
When the finder included in the camera body is in the upward direction of the image sensor, or
When the tripod hole provided in the camera body is in the downward direction of the image sensor
When at least one of
The lens barrel according to claim 6 or 7. An elastic member for urging the movable part is provided.
The elastic member is
When the movable portion moves between the mounting position and the retracting position,
When the movable portion is closer to the mounting position than a predetermined position between the mounting position and the retracting position, the movable portion is urged toward the mounting position.
When the movable portion is closer to the retracted position than the predetermined position, the movable portion is urged toward the retracted position.
The lens barrel according to any one of claims 1 to 8. A first limiting portion that restricts the movement of the movable portion to the side opposite to the retracted position beyond the mounting position,
The movable portion includes at least one of a second limiting portion that restricts the movement of the movable portion to the side opposite to the mounting position beyond the retracted position.
The lens barrel according to any one of claims 1 to 9. The movable portion is provided with an elastic cylindrical portion that abuts at least one of the first limiting portion or the second limiting portion when the movable portion is located at the mounting position or the retracting position.
The cylindrical portion is rotatably fixed to the movable portion, and the outer peripheral surface abuts on the first limiting portion or the second limiting portion.
The lens barrel according to claim 10. A signal generating unit that generates a signal when the moving direction of the movable unit is switched from the upper side to the lower side is provided.
The lens barrel according to any one of claims 1 to 10. The movable part is a teleconverter lens.
The lens barrel according to any one of claims 1 to 12. A camera provided with a lens barrel according to any one of claims 1 to 13.

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