JP2007199293A - Lens unit, interchangeable lens and camera system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a lens unit wherein a movable lens part can be fixed, to provide an interchangeable lens and a camera system. <P>SOLUTION: A projecting flange part 31a is provided on a locking pin 31, and a locking pin rubber 41, formed of rubber, is fixedly stuck to the flange part 31a. An engagement groove 31b is provided in the locking pin 31; then a shake correction operation switch 18 is engaged with the engagement groove 31b through an interlocking member. The locking pin 31 is energized, by a locking pin energizing spring 32 in the locking direction. In the locking state, the locking pin rubber 41 is energized by the locking pin-energizing spring 32, toward the direction of an engagement hole 174 so as to come into contact with a movable lens frame 17. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a lens unit, an interchangeable lens, and a camera system that can limit the movement of a movable lens that moves during a blur correction operation.

A lens that corrects image blur by moving this blur correction lens in a direction along a plane substantially perpendicular to the optical axis of the shooting optical system as a movable lens unit that can move the blur correction lens that is a part of the shooting optical system. An interchangeable lens having a unit and a camera system are known.
In such a lens unit or the like, when the blur correction operation is not performed, the blur correction lens is used to prevent the blur correction lens from being damaged and to prevent deterioration of the optical performance due to the movement of the blur correction lens during shooting. Is fixed (locked) near the optical axis.
Patent Document 1 discloses a lock mechanism that uses a latch solenoid, and the movement of the blur correction lens is restricted by engaging a lock pin of the lock member with an engagement hole provided in the holding member. .

However, in the lock mechanism as in Patent Document 1, it is necessary to allow a dimensional tolerance for the lock pin and the engagement hole, and there is a gap due to this dimensional tolerance even in the locked state. Could move. Therefore, slight mechanical vibration of the photographing device (for example, shock due to a mirror and shutter in a single-lens reflex camera) is transmitted, and even in the locked state, the blur correction lens moves within the lock range, and the optical performance. There was a problem of deterioration.
JP 2004-205606 A

  The subject of this invention is providing the lens unit which can fix a movable lens part, an interchangeable lens, and a camera system.

The present invention solves the above problems by the following means. In addition, in order to make an understanding easy, although the code | symbol corresponding to the Example of this invention is attached | subjected and demonstrated, it is not limited to this.
According to the first aspect of the present invention, the movable lens unit can be moved between a movable movable lens unit (2, 17), a contact position that contacts the movable lens unit, and a retracted position that does not contact the movable lens unit. A member (31), and a biasing member (32) for biasing the moving member against the movable lens portion at the contact position, and one of the portions where the moving member and the movable lens portion are in contact with each other Is provided with a recess (174), and the other is provided with an elastic member (41) having a contact surface facing the recess, and the elastic member is deformed by the urging force of the urging member. By doing so, a part of the lens unit enters the recess rather than the contact surface.
According to a second aspect of the present invention, in the lens unit according to the first aspect, the moving member is inserted into the concave portion (174) to restrict the movement of the movable lens portion from the lock position and the lock position. The lens unit is a lock member (31) that moves between the retracted non-lock position and the elastic member (41) is attached to the lock member.
According to a third aspect of the present invention, there is provided a movable lens part (2, 17) having a concave part (174), a lock position for restricting movement of the movable lens part by being inserted into the concave part, and the lock. A locking member (31) that moves between a non-locking position retracted from a position, and a contact position that is attached to the locking member and contacts the movable lens unit when the locking member is in the locking position; An elastic member (41) that is movable between a retracted position that does not contact the movable lens portion when the locking member is in the unlocked position, and the elastic member is moved relative to the movable lens portion at the contact position. And a biasing member (32) that biases the lens unit.
According to a fourth aspect of the present invention, in the lens unit according to the third aspect, the elastic member (41) is deformed by the urging force of the urging member (32), whereby the concave portion (174) and the locking member ( 31) is a lens unit characterized in that the lens unit enters a gap formed between the lens unit 31).
According to a fifth aspect of the present invention, in the lens unit according to any one of the first to fourth aspects, the elastic member (41) is made of rubber. is there.
The invention of claim 6 is the lens unit according to any one of claims 2 to 5, wherein the movable lens portion (2, 17) is movable in a direction perpendicular to the optical axis, When the lock member (31) is in the locked position, the lock member engages with the recess (174) in a direction perpendicular to the optical axis, and the elastic member is in a direction along the optical axis. The lens unit is urged by the urging member (32) to come into contact with the movable lens portion.
According to a seventh aspect of the present invention, in the lens unit according to any one of the first to sixth aspects, the movable lens portion (2, 17) corrects a blur of an image by moving. It is a lens unit characterized by including a lens (2).
The invention of claim 8 is an interchangeable lens comprising the lens unit according to any one of claims 1 to 7 and a mount portion (19) for attaching the lens unit to a camera (200). (100).
A ninth aspect of the invention is a camera system including the lens unit according to any one of the first to seventh aspects.
Note that the configuration described with reference numerals may be modified as appropriate, and at least a part of the configuration may be replaced with another component.

  According to the present invention, since the concave portion and the elastic member are provided, the movable lens portion can be reliably fixed.

  The purpose of fixing the movable lens portion is realized by providing a concave portion and an elastic member.

FIG. 1 is a diagram illustrating an overview of a camera system according to an embodiment.
The camera system of the embodiment includes an interchangeable lens 100 and a camera body 200 to which the interchangeable lens 100 can be attached and detached.
The interchangeable lens 100 includes shake detection sensors 11 and 12, a shake correction lens 2, shake correction actuators 13 and 14, lens position detection sensors 15 and 16, a movable lens frame 17, a shake correction operation switch 18, a mount unit 19, and the like. Have. The blur correction lens 2, the blur correction actuators 13 and 14, the lens position detection sensors 15 and 16, and the movable lens frame 17 constitute a blur correction lens unit. The interchangeable lens 100 is detachably attached to the camera body 200 by the mount unit 19.
The camera body 200 has an imaging unit (not shown) in addition to the release switch 201.

  The shake detection sensors 11 and 12 are shake detection units formed by an angular velocity sensor such as a gyro sensor. The shake detection sensors 11 and 12 detect angular velocities around two detection axes (X axis and Y axis) perpendicular to each other in a plane substantially perpendicular to the optical axis Z of the shake correction lens 2. When the switch 200 is operated, the acceleration components in each of these two directions are output. The shake around the Y axis is called yawing, the shake around the X axis is called pitching, and the blur correction operation normally corrects the image blur caused by the shake in these two directions. Is done.

The blur correction lens 2 forms a part of the photographing optical system, and is attached to a photographing unit (an image pickup device or a film) (not shown) disposed on the focal plane of the photographing optical system within a plane substantially orthogonal to the optical axis Z. On the other hand, it is a blur correction lens that corrects image blur in the photographing unit by moving in a direction to cancel image blur of the subject image caused by camera shake or the like of the photographer.
The movable lens frame 17 is a member that holds the shake correction lens 2 in a movable state. The blur correction lens 2 is assembled to the movable lens frame 17 to form a movable lens unit that can move in a plane substantially perpendicular to the optical axis. The movable lens frame 17 is provided with engagement holes 173 and 174 (see FIG. 2) which are concave portions used by a lock mechanism described later. Note that the movable lens frame 17 is actually provided with a central portion to which the vibration reduction lens 2 is directly attached, and the central portion is screwed, and coils 131 and 141 (see FIG. 2) described later are provided. However, for the sake of simplicity, in the description of the present embodiment, these are collectively described as the movable lens frame 17.
The shake correction actuators 13 and 14 are drive units that generate a drive force for moving the shake correction lens 2 and the movable lens frame 17, and are arranged separately for driving in the X-axis direction and driving in the Y-axis direction. In this embodiment, voice coil motors are used for the blur correction actuators 13 and 14.

The lens position detection sensors 15 and 16 are position sensors that detect the positions of the shake correction lens 2 and the movable lens frame 17, and are arranged separately for position detection in the X-axis direction and position detection in the Y-axis direction. .
The shake correction operation switch 18 is an operation member that is manually operated by the photographer when selecting whether or not to perform the shake correction operation. Specifically, an ON position for performing the shake correction operation and an OFF position for not performing the shake correction operation are provided, and the lock pin 31 (to be described later) is moved and the shake correction operation is turned on / off electrically. Tell the control unit (not shown).
In the shake correction operation, the drive direction and drive amount of the shake correction lens 2 are calculated by a calculation unit (not shown) based on the detection results of shake by the shake detection sensors 11 and 12, and the shake correction actuators 13 and 14 are calculated according to the calculation results. The image blur correction lens 2 is driven and controlled using the lens position detection sensors 15 and 16 to correct the image blur.

FIG. 2 is a view of the blur correction lens 2 and the movable lens frame 17 as viewed from the subject side.
FIG. 3 is a cross-sectional view of the blur correction lens unit cut along the AA cross section shown in FIG.
FIG. 4 is a cross-sectional view of the vibration reduction lens unit cut along the BB cross section shown in FIG. FIG. 4A shows the unlocked state of the manual lock mechanism, and FIG. 4B shows the locked state of the manual lock mechanism.
The movable lens frame 17 is driven in the X direction and the Y direction by the blur correction actuators 13 and 14. Two coils 131 and 141 are fixed to the movable lens frame 17.

The blur correction actuator 13 is a voice coil motor including a front yoke 135, a front magnet 134, a coil 131, a rear magnet 132, and a rear yoke 133.
The front yoke 135 is fixed to a base member (not shown), and the front magnet 134 is fixed on the front yoke 135 by its own magnetic force.
The rear yoke 133 is fixed to a base member (not shown), and the rear magnet 132 is fixed on the rear yoke 133 by its own magnetic force.
The coil 131 is disposed between the front magnet 134 and the rear magnet 132.
The shake correction actuator 13 having these configurations can drive the shake correction lens 2 and the movable lens frame 17 by applying a current in the Y direction to the coil 131 by passing a current through the coil 131.
The shake correction actuator 14 has the same configuration as the shake correction actuator 13 except that the drive direction is the X direction.

A lens position detection sensor 15 for detecting the positions of the blur correction lens 2 and the movable lens frame 17 includes a slit 171 formed in the movable lens frame 17, an LED (Light Emitting Diode) 151, and a PSD (Position Sensitive Detector). 152.
The LED 151 is fixed to the movable lens frame 17.
The PSD 152 is fixed to an electric board (not shown).
Light emitted from the LED 151 passes through the slit 171 and reaches the PSD 152.
Accordingly, the movement of the blur correction lens 2 and the movable lens frame 17 moves the position of the light reaching the PSD 152, and the output signal of the PSD 152 changes. With this signal, the position of the blur correction lens 2 and the movable lens frame 17 in the Y direction in FIG. 2 can be detected.
Further, the lens position detection sensor 16 can detect the positions of the blur correction lens 2 and the movable lens frame 17 in the X direction in FIG. 2 with the same configuration as the lens position detection sensor 15 described above.

The movable lens frame 17 is engaged with the guide shaft 3 by hook portions 17 a and 17 b, and the movable lens frame 17 is movable in the longitudinal direction of the guide shaft 3 with respect to the guide shaft 3. The guide shaft 3 is rotatably supported by a guide arm (not shown). The guide arm is fixed to a base shaft of a base member (not shown) so as to be rotatable around the shaft, thereby constituting a link mechanism.
Therefore, although the movable lens frame 17 is restricted from rotating around the optical axis by the guide shaft 3, it can move in the longitudinal direction of the guide shaft 3 and the guide shaft 3 is substantially perpendicular to the longitudinal direction. Therefore, it can move in both the X direction and the Y direction.
The blur correction lens 2 and the movable lens frame 17 are applied to a sliding portion (not shown) by a spring (not shown), and the position in the optical axis direction is regulated.
Accordingly, the blur correction lens 2 and the movable lens frame 17 are held without being floated in the optical axis direction in a state where they can move smoothly with a low load.

The shake correction lens unit of this embodiment includes two types of lock mechanisms, namely, an electric lock mechanism 20 and a manual lock mechanism 30 as lock mechanisms for locking the shake correction lens 2 and the movable lens frame 17.
The electric lock mechanism 20 includes a lock pin 27, a lock pin urging spring 26, a lock lever 25, and a latch solenoid 24.
The lock pin 27 is fitted to the lock pin holding frame 51 and is movable in a direction substantially parallel to the optical axis. The lock pin 27 has a lock pin collar portion 27a, and is urged in the unlocking direction by a lock pin urging spring 26 provided between the lock pin holding frame 51 and the lock pin collar portion 27a. Yes.

The latch solenoid 24 is a lock actuator having a bistable state, and if it is energized only at the moment of operation, the latch solenoid 24 holds either the unlocked state or the locked state even if the energization is stopped thereafter. The plunger 24a is movable between these two states by passing an electric current. The latch solenoid 24 is fixed to the lock pin holding frame 51.
The lock lever 25 is a transmission member that is attached to the lock pin holding frame 51 so as to be rotatable about the rotation center 51g. The protrusion 25b is engaged with the lock pin collar portion 27a, and the other protrusion 25a. Is engaged with the plunger 24a. The lock lever 25 changes the drive direction and drive position of the latch solenoid 24 and transmits it to the lock pin 27.

When the electric lock mechanism 20 is locked, the latch solenoid 24 is energized, whereby the plunger 24 a is pulled toward the latch solenoid 24, and the lock pin 27 is inserted into the engagement hole 173 via the lock lever 25.
During the unlocking operation, the latch solenoid 24 is energized in reverse to the locking operation, so that the force with which the plunger 24a is pulled toward the latch solenoid 24 is weakened, and the lock pin biasing spring 26 engages the lock pin 27. It is moved in the direction to retract from the inside of the joint hole 173.

The manual lock mechanism 30 includes a lock pin 31, a lock pin rubber 41, and a lock pin biasing spring 32.
The lock pin 31 is an axial lock member (moving member) whose tip is formed in a conical shape, and is supported by the lock pin holding frame 51 so as to be movable in the optical axis direction. The lock pin 31 is movable between a lock position that restricts movement of the blur correction lens 2 and the movable lens frame 17 and an unlocked position that is retracted from the lock position.
Further, the lock pin 31 has a protruding flange portion 31a, and a rubber lock pin rubber 41 is bonded and fixed to the flange portion 31a. The lock pin rubber 41 moves together with the lock pin 31 so that a contact position where the lock pin rubber 41 is in contact with the movable lens frame 17 and a retreat position where the lock pin rubber 41 is not in contact with the movable lens frame 17 when the lock pin 31 is in the unlocked position. It is possible to move between.

Further, the lock pin 31 is provided with an engagement groove 31b, and the shake correction operation switch 18 is engaged with the engagement groove 31b via an interlocking member (not shown). , Not shown).
The lock pin biasing spring 32 is provided between the lock pin holding frame 51 and the flange 31a, and biases the lock pin 31 in the direction of the engagement hole 174 (lock position direction) of the movable lens frame 17. Yes.
In the manual lock mechanism 30, when the camera shake correction operation switch 18 is operated by the photographer, the lock pin 31 moves in conjunction with this, and the lock position and the unlock position are switched. That is, the lock is released when the shake correction operation switch 18 is in the position where the shake correction operation is ON, and the lock state is set when the shake correction operation switch 18 is in the position where the shake correction operation is OFF.

Here, the reason for providing two types of lock mechanisms, that is, the electric lock mechanism 20 and the manual lock mechanism 30, will be described.
There are many interchangeable lenses having a shake correction mechanism that have only one lock mechanism. The electric lock mechanism 20 has the same function as that used in the lock mechanism of an interchangeable lens having only one lock mechanism. First, the operation of the electric lock mechanism 20 will be described.

Even when the power of the camera system is turned on, the electric lock mechanism 20 is in a locked state when the release switch 201 is not half-pressed. When the release switch 201 is pressed halfway, the camera system starts a shooting preparation operation. At this time, if the shake correction operation switch 18 is ON, the latch solenoid 24 is energized and locked. In the released state, the shake correction lens 2 is driven to perform the shake correction operation. Note that when the shake correction operation switch 18 is OFF, the shake correction operation is not performed, and thus the electric lock mechanism 20 maintains the locked state.
Thereafter, when the half-press of the release switch 201 is released, after the blur correction lens 2 and the movable lens frame 17 are driven to the lock position, the latch solenoid 24 is energized to enter the locked state. When the release switch 201 is fully pressed, a blur correction operation is performed after the centering operation, and shooting is performed.

Thus, even with only the electric lock mechanism 20, it is possible to limit the movable range of the shake correction lens 2 and the movable lens frame 17 to a specific range. However, it is necessary to allow a dimensional tolerance between the outer diameter of the lock pin 27 and the inner diameter of the engagement hole 173, and a gap due to this dimensional tolerance always occurs even in the locked state.
Further, the electric lock mechanism 20 inserts the lock pin 27 into the engagement hole 173 by the driving force of the latch solenoid 24, but this driving force cannot generate a very large force in order to reduce the size of the latch solenoid 24. In addition, when the shake correction lens 2 and the movable lens frame 17 are driven and controlled in a plane orthogonal to the optical axis, there is a possibility that their stop positions vary depending on the control accuracy. Therefore, the inner diameter of the engagement hole 173 has a margin with respect to the outer diameter of the lock pin 27 so that the lock pin 27 can be surely inserted into the engagement hole 173 even if the driving force of the latch solenoid 24 is small. Need to be larger.

  Thus, the inner diameter of the engagement hole 173 is larger than the outer diameter of the lock pin 27 for reasons of dimensional tolerance and accuracy of the stop position. Therefore, even when the electric lock mechanism 20 is in the locked state, a gap is generated between the lock pin 27 and the engagement hole 173, and the blur correction lens 2 and the movable lens frame 17 are equivalent to this gap. , Movable (undefined position).

  An interchangeable lens having only an electric lock mechanism includes a photographic optical system in which the movable amount of the blur correction lens in the locked state by the electric lock mechanism does not adversely affect the photographic image. Specifically, even if the blur correction lens moves during the shooting by the gap in the locked state by the electric lock mechanism, the movement (blur) of the subject image on the imaging surface is sufficiently small, and the obtained captured image The photographic optical system has no effect.

  However, depending on the lens configuration of the photographing optical system, if the blur correction lens is moved by an amount that the blur correction lens can be moved in the locked state by the electric lock mechanism, an adverse effect may be caused on the obtained captured image. . In such a photographing optical system, even if the camera is locked by an electric lock mechanism when the shake correction operation is not performed, mechanical vibrations are transmitted to the shake correction lens by an impact caused by a mirror and a shutter in a single-lens reflex camera. Due to this vibration, the blur correction lens moves during shooting and image blurring occurs in the shot image.

  Therefore, in this embodiment, a manual lock mechanism 30 is added in addition to the electric lock mechanism 20. As described above, in the manual lock mechanism 30, the lock pin 31 is mechanically engaged with the shake correction operation switch 18 via the interlocking member (not shown). Therefore, the lock pin 31 is driven by an operation force for the photographer to operate the shake correction operation switch 18. The manual driving force by the photographer is much larger than the driving force by the latch solenoid 24. Therefore, even if the center positions of the lock pin 31 and the engagement hole 174 are slightly deviated, the tip of the lock pin 31 is formed in a conical shape, so that it can be easily switched to the locked state. That is, when the lock pin 31 is driven in the lock direction, the inner periphery of the engagement hole 174 contacts the conical surface at the tip of the lock pin 31, and the positions of the shake correction lens 2 and the movable lens frame 17 are forced. After the correction, the lock by the manual lock mechanism 30 is performed.

For this reason, in setting the clearance between the lock pin 31 and the engagement hole 174 in the manual lock mechanism 30, it is necessary to consider the variation in the stop position of the shake correction lens 2 and the movable lens frame 17. Absent. Therefore, in the manual lock mechanism 30, the movable range of the shake correction lens 2 and the movable lens frame 17 in the locked state can be limited to a narrower range than the electric lock mechanism 20.
Therefore, when the shake correction operation is not performed, the range in which the shake correction lens 2 and the movable lens frame 17 can be moved is set to a very narrow range (electric lock) by setting the shake correction operation switch 18 to the position of the shake correction operation OFF. The range is narrower than the range limited by the mechanism 20), and quality degradation of the captured image when the shake correction operation is not performed is prevented.

  However, even when the manual lock mechanism 30 is in the locked state, a gap on the dimensional tolerance exists between the lock pin 31 and the engagement hole 174. The gap on the dimensional tolerance is very small, and in many photographic optical systems, a large image blur occurs in the captured image even if the blur correction lens and the movable lens frame are moved by this gap during shooting. Absent. However, depending on the lens configuration of the photographing optical system, the movement of the blur correction lens 2 and the movable lens frame 17 due to a slight gap due to the dimensional tolerance may appear as image blur on the photographed image. In addition, when obtaining the quality of a captured image at a higher level, it is desirable to limit the movement of the blur correction lens 2 and the movable lens frame 17 by a slight gap due to this dimensional tolerance.

Therefore, in the manual lock mechanism 30 of the present embodiment, the lock pin rubber 41 is provided on the flange portion 31 a of the lock pin 31.
FIG. 5 is an enlarged view of the vicinity of the engagement hole 174 in the locked state of the manual lock mechanism 30 of the present embodiment.
FIG. 6 is a diagram schematically showing the range C shown in FIG. 5 further enlarged.
In the locked state of the manual lock mechanism 30, the lock pin rubber 41 is urged toward the engagement hole 174 (lock position direction) via the lock pin 31 by the lock pin urging spring 32 and comes into contact with the movable lens frame 17. ing. At this time, in the lock pin rubber 41, a deformed portion 41 a that protrudes and deforms from the contact surface with the movable lens frame 17 enters a gap between the lock pin 31 and the engagement hole 174. Therefore, in the locked state of the manual lock mechanism 30, the gap between the lock pin 31 and the engagement hole 174 is filled with the lock pin rubber 41, and the positions of the blur correction lens 2 and the movable lens frame 17 become indefinite. It is fixed securely without any play.

As described above, in this embodiment, when the blur correction operation is not performed, the blur correction lens 2 and the movable lens frame 17 are securely fixed, so that the blur correction lens 2 and the movable lens frame 17 move during shooting. It is possible to prevent image blurring.
Further, the manual lock mechanism 30 of this embodiment mechanically locks the movable lens frame 17 by engaging the lock pin 31 with the engagement hole 174 provided in the movable lens frame 17 that holds the shake correction lens 2. Therefore, the number of parts can be reduced without increasing the size of the lens unit.

(Modification)
The present invention is not limited to the embodiments described above, and various modifications and changes are possible, and these are also within the equivalent scope of the present invention.
(1) In the present embodiment, an example in which the lock mechanism is provided at two places has been described.

(2) In this embodiment, an example in which the lock pin rubber 41 that is an elastic member moves is shown. However, the present invention is not limited to this, and for example, a member having a recess such as an engagement hole moves with respect to the elastic member. It may be a configuration.

(3) In the present embodiment, an example in which the lock pin rubber 41 is provided so as to move integrally with the lock pin 31 is shown. However, the present invention is not limited to this. You may make it operate | move independently of another locking mechanism.

(4) In this embodiment, the lens interchangeable camera system including the interchangeable lens 100 and the camera body 200 has been described as an example. However, the present invention is not limited to this, and for example, even a camera system in which lenses cannot be interchanged. Good.

It is a figure explaining the outline | summary of the camera system of a present Example. It is the figure which looked at the blurring correction lens 2 and the movable lens frame 17 from the subject side. It is sectional drawing which cut | disconnected the blurring correction lens unit in the AA cross section shown in FIG. It is sectional drawing which cut | disconnected the blurring correction lens unit in the BB cross section shown in FIG. It is the figure which expanded the engagement hole 174 vicinity in the locked state of the manual locking mechanism 30 of a present Example. It is the figure which expanded the range C shown in FIG. 5 further, and was shown typically.

Explanation of symbols

30: Manual lock mechanism, 31: Lock pin, 32: Lock pin biasing spring, 41: Lock pin rubber, 100: Interchangeable lens, 200: Camera body

Claims (9)

A movable movable lens unit;
A movable member that is movable between a contact position that contacts the movable lens unit and a retracted position that does not contact the movable lens unit;
An urging member for urging the moving member with respect to the movable lens portion at the contact position;
With
One of the portions where the moving member and the movable lens portion come into contact is provided with a recess, and the other is provided with an elastic member having a contact surface facing the recess,
A part of the elastic member enters the recess rather than the contact surface by being deformed by the urging force of the urging member;
Lens unit characterized by The lens unit according to claim 1,
The moving member is a lock member that moves between a lock position that restricts movement of the movable lens unit by being inserted into the recess and an unlocked position that is retracted from the lock position,
The elastic member is attached to the locking member;
Lens unit characterized by A movable lens part having a recess and movable;
A lock member that moves between a lock position that restricts movement of the movable lens portion by being inserted into the recess and an unlocked position that is retracted from the lock position;
A contact position that is attached to the lock member and contacts the movable lens unit when the lock member is in the locked position, and does not contact the movable lens unit when the lock member is in the unlocked position. An elastic member movable between the retracted position;
A biasing member that biases the elastic member against the movable lens portion at the contact position;
A lens unit comprising: The lens unit according to claim 3,
The elastic member enters a gap generated between the recess and the lock member by being deformed by an urging force of the urging member;
Lens unit characterized by In the lens unit according to any one of claims 1 to 4,
The elastic member is made of rubber;
Lens unit characterized by In the lens unit according to any one of claims 2 to 5,
The movable lens unit is movable in a direction perpendicular to the optical axis;
When the lock member is in the lock position, the lock member engages with the recess in a direction perpendicular to the optical axis, and the elastic member is applied by the biasing member in a direction along the optical axis. Being urged to contact the movable lens unit;
Lens unit characterized by In the lens unit according to any one of claims 1 to 6,
The movable lens unit includes a blur correction lens that corrects blur of an image by moving;
Lens unit characterized by The lens unit according to any one of claims 1 to 7,
A mount for attaching the lens unit to the camera;
Interchangeable lens with A camera system including the lens unit according to any one of claims 1 to 7.

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