JP5758167B2 - Optical element position control device - Google Patents

Description

  The present invention relates to an optical element position control apparatus capable of moving for image blur correction and inserting / removing on / from the optical axis.

  In an optical device such as a camera, when camera shake is detected, a specific optical element such as a lens or an image sensor is driven in a plane perpendicular to the optical axis of the optical system, and an image on the imaging surface is displayed. Many are equipped with an image stabilization mechanism (image shake correction mechanism) that suppresses the shake. Patent Document 1 proposes a technique for moving the optical element for image stabilization out of the range for image stabilization movement (outside the optical axis) in the housed state in which shooting is not performed for the purpose of downsizing the lens barrel. Yes.

JP 2007-163961 A

  In the lens barrel of Patent Document 1, a fixed frame is provided in a lens group cylinder movable in the optical axis direction, and a vibration frame is orthogonal to the optical axis with a steel ball (rolling element) sandwiched between the fixed frame. It is supported so as to be movable in the plane. On the vibration frame, a shake correction lens group chamber holding a shake correction lens group is pivotally supported so as to be rotatable about a rotation axis whose axis is parallel to the optical axis. At the time of shake correction, the vibration frame is smoothly moved by the actuator with respect to the fixed frame via the support portion of the steel ball. When the lens barrel is housed, the lens group tube is moved to the image plane side (backward in the optical axis direction) and approaches the CCD table. Then, the contact portion of the shake correction lens group chamber comes into contact with the cam surface portion of the drive unit provided on the CCD base, and the shake correction lens group chamber is rotated by rotating the contact portion with respect to the cam surface portion. Rotate around. This rotation retracts the blur correction lens group from the optical axis. With such a configuration, a load in the optical axis direction is applied to the vibration reduction lens group chamber in a state where the cam surface portion and the contact portion are in contact with each other during the storing operation of the lens barrel, and this load is also transmitted to the vibration frame. As described above, a steel ball is sandwiched between the vibration frame and the fixed frame, and when a load in the optical axis direction is applied, there is a risk that a dent of the steel ball is formed on the clamping surface of the vibration frame or the fixed frame. is there. Such dents adversely affect the operation accuracy of the vibration frame. In Patent Document 1, as a countermeasure, a vibration frame is arranged on the object side (front side in the optical axis direction) of the fixed frame, and the vibration frame is attached to the steel ball in the direction in which the steel ball is pressurized (the approaching direction to the fixed frame). It is fast. When a load in the optical axis direction is applied to the vibration reduction lens chamber by the cam surface portion, the vibration frame moves to the object side against the biasing force of the biasing spring, preventing an excessive load from being applied to the steel ball. .

  In the configuration of Patent Document 1, if the degree of freedom of movement of the vibrating frame to the object side with respect to the fixed frame is too high, the steel ball may fall off without maintaining the clamping state. An urging force exceeding a predetermined value is required. On the other hand, if the urging force by the urging spring is too strong, the moving load of the vibration frame with respect to the fixed frame becomes excessive. For this reason, even if the pressing force by the cam surface portion is transmitted and the vibration frame is about to be separated from the fixed frame, the steel ball is surely held and the movement resistance to the vibration frame during image blur correction is suppressed. Adjustment of the force of the biasing spring is very difficult to meet the general requirements.

  Further, in the configuration of Patent Document 1, since the shake correction lens group chamber is pressed by the cam surface portion, it is inevitable that a load in the optical axis direction is applied to the shake correction lens group chamber. The shake correction lens group chamber is a lens group holding member, and its positional accuracy directly affects the optical performance. Therefore, it is desirable that a load is not applied as much as possible from the viewpoint of management of the positional accuracy. In addition, since the vibration reduction lens group chamber is held on the vibration frame, the relative position of the contact portion on the vibration correction lens group chamber side and the cam surface portion on the CCD base side is shifted depending on the moving position of the vibration frame. It is difficult to determine the contact points with each other with high accuracy. For this reason, the retraction operation of the blur correction lens group chamber may not be performed smoothly.

  The present invention has been made in view of the above problems, and in a position control device for an optical element capable of movement for image blur correction and insertion / removal on the optical axis, the load can be reduced with a simple configuration. The purpose is to realize low-precision driving.

An optical element position control device according to the present invention is movable in the optical axis direction of a photographic optical system, and is moved to a different position in the optical axis direction in an imaging state and a storage state in which imaging is not performed. An anti-vibration moving member that is supported so as to be movable along a plane orthogonal to the optical axis, and an optical element that holds the optical element and is rotatable about a rotation axis that is parallel to the optical axis. An insertion / removal member that is pivotally supported by the actuator is provided. On the anti-vibration moving member, the insertion / removal movement member rotates to the insertion position for positioning the optical element on the optical axis of the photographing optical system and the separation position for removing the optical element from the optical axis, and is inserted in the photographing state. It is held at the insertion position by the holding means. Furthermore, the anti-vibration movement is supported with respect to the advancing / retreating member so as to be rotatable about a rotation axis parallel to the rotation axis of the insertion / removal member and without contacting the insertion / removal member at the insertion position. An insertion allowance position that does not restrict movement of the insertion / removal movement member within the movable range of the member, and a separation drive member that rotates to a separation forcing position that contacts the insertion / removal movement member and presses and rotates from the insertion position to the separation position. The detachment drive member is held in the insertion allowable position by the insertion / removal control means by the insertion / removal control means, and when the advancing / retreating member moves in the optical axis direction from the shooting state position to the storage state position, the separation drive member is forcibly removed from the insertion allowable position. Rotate to position . In accordance with the shake applied to the photographic optical system, the image blur correction is performed by driving the vibration-proof moving member to an arbitrary position along the plane orthogonal to the optical axis. The insertion / removal control means is spaced apart from the separation drive member in the optical axis direction in the photographing state, and when the advancing / retreating member moves in the optical axis direction from the photographing state position to the storage state position, And a component force applying member that abuts against the detachment driving member and applies a component force to rotate the detachment driving member from the insertion allowable position to the detachment forcing position.

The present invention is suitable when the advance / retreat member is an annular member surrounding the optical axis of the photographing optical system.

As a component of the insertion / removal control means, in addition to the component force applying member, an urging member that moves and urges the detachment drive member in the direction of the insertion allowable position , and the detachment drive member abuts by the urging force of the urging member. It is preferable to provide a stopper on the advance / retreat member that determines the insertion allowable position. The component applying member pushes the detachment drive member to the detachment forced position against the urging means when the advance / retreat member moves in the optical axis direction from the photographing position to the retracted position.

  It is practical that the advancing / retreating member moves from the object side to the image plane side when changing from the photographing state to the retracted state. In this case, as a structure for supporting the anti-vibration moving member with respect to the advancing / retreating member, a first plane facing the image plane and orthogonal to the optical axis is formed on the advancing / retreating member, and a second plane facing the object side and orthogonal to the optical axis is formed. An anti-vibration guide member that allows the anti-vibration movement member to move in the plane perpendicular to the optical axis relative to the advancing / retreating member between the first plane and the second plane that are opposed to each other after being formed on the anti-vibration movement member. The anti-vibration moving member may be moved and urged in a direction in which the first flat surface and the second flat surface are brought close to each other. Then, the separation drive member is positioned on the image plane side with respect to the vibration proof moving member and supported by the advance / retreat member. In addition, it is preferable to provide a projecting portion toward the object side on a fixed member positioned on the image plane side with respect to the advancing / retreating member in the photographing state, and to configure a component applying member for pressing the detachment driving member.

  The present invention is particularly effective in a configuration in which the vibration-proof guide member sandwiched between the advance / retreat member and the vibration-proof moving member is a spherical rolling element.

The interpolation de moving member comprises a pressed portion consisting of the outer circumferential surface of the cylindrical projection of the optical axis parallel to the axis, the disengagement driving member includes a detachment pressing portion comprising a plane facing the rotation radial direction, When the insertion / removal movement member is in the insertion position and the separation drive member is in the insertion permission position, the pressed portion and the separation pressing portion are spaced apart from each other, and the separation drive member rotates from the insertion permission position toward the separation forcing position. It is good to comprise so that a detachment press part may contact | abut a to-be-pressed part when it moves.

  The insertion holding means is provided in the biasing member for moving and biasing the insertion / removal movement member to the insertion position and the anti-vibration movement member, and the insertion / removal movement member abuts on the insertion position by the biasing force of the biasing member. It is good to have a configuration provided with a stopper to be determined.

According to the present invention, the movement and the position controller of the optical elements can be inserted and removed moved onto the optical axis, inserting and removing movable member respectively is rotatably supported against the advancing and retracting member for image blur correction And a separation drive member, and a structure in which the insertion / removal movement member is pressed and moved to the separation position via a separation drive member that receives a pressing force in the optical axis direction by the component applying member according to the movement of the advance / retreat member in the optical axis direction For this reason, the insertion / removal member that holds the optical element and the vibration-proof movement member that supports the insertion / removal member can be operated from the shooting state to the storage state without applying a load in the optical axis direction. Can do. Moreover, the removal operation of the insertion / removal movement member can be performed without being influenced by the position of the vibration-proof movement member. Therefore, the vibration-proofing operation and the insertion / removal operation of the optical element can be performed with a simple configuration with low load and high accuracy.

It is the disassembled perspective view which looked at the anti-vibration lens block to which this invention was applied from back. It is the perspective view which looked at the anti-vibration lens block of the state which removed the sensor holder and the rectilinear moving ring from back. It is the perspective view which looked at the anti-vibration lens block and the separation | desorption press protrusion in the middle of the accommodation operation | movement of a lens-barrel from the back. It is a perspective view which shows the relationship between the insertion / removal frame in the imaging | photography state, and the separation drive lever. It is the perspective view which showed the insertion / removal frame in the imaging | photography state, and the separation drive lever from another angle. It is the figure which looked at the principal part of the vibration-proof lens block in a photographing state from the image plane side. It is the figure which extracted and showed the part and coil which are driven at the time of shake correction from FIG. It is the figure which highlighted and showed the component of the vibration proof drive actuator from FIG. It is the figure which looked at the principal part of the anti-vibration lens block in the accommodation state from the image plane side. Detachment pressing protrusion FIG. 10 is a diagram showing an excerpt of a portion and a coil that are driven at the time of shake correction. It is the figure which emphasized and showed the component of the vibration proof drive actuator from FIG. It is the figure which looked at the anti-vibration lens block in the imaging | photography state from the image surface side except the rectilinear advance / retraction ring and the sensor holder. It is sectional drawing which follows the AA line of FIG. It is sectional drawing which follows the BB line of FIG.

  The anti-vibration lens block 10 shown in FIGS. 1 to 3 supports an anti-vibration insertion / removal lens (optical element) 12 that constitutes a part of the photographing optical system of the lens barrel. As shown in FIG. The shutter unit (advance / retreat member) 16, the anti-vibration frame (anti-vibration movement member) 18, the insertion / removal frame (insertion / removal member) 20, the sensor holder 22, the release drive lever (detachment) The structure is provided with a drive member 24, an anti-vibration drive actuator (anti-vibration drive means) 26, and the like.

  Although the entire structure of the lens barrel provided with the anti-vibration lens block 10 is not shown, the rectilinear moving ring 14 can move linearly in the lens barrel in the direction along the photographic optical axis O of the photographic optical system. The lens barrel is moved from the object (subject) side toward the image plane side when the lens barrel is changed from the photographing state to the retracted state. In the following description, in the direction along the photographing optical axis O, the object side is referred to as the front, and the image plane side is referred to as the rear. A known cam mechanism or the like can be applied as a mechanism for moving the rectilinear moving ring 14 in the optical axis direction.

  The rectilinear moving ring 14 has a cylindrical portion 14a surrounding the photographing optical axis O, and a shutter unit 16 is fixed inside thereof. The shutter unit 16 has a photographing opening 16b (FIG. 1) penetrating in the optical axis direction at the center of a shutter housing 16a containing a shutter (not shown), and opens and closes the photographing opening 16b by driving the shutter with a built-in shutter actuator. Let The outer peripheral portion of the shutter housing 16a is provided with three spring hooking projections 16c (only one is shown in FIGS. 1 and 2) at different positions in the circumferential direction, and on the rear surface of the shutter housing 16a, Two movement restriction protrusions (movement restriction means) 16d and three ball support holes 16e are formed. The ball support hole 16e is a bottomed concave portion opened rearward (see FIG. 13).

  A vibration isolating frame 18 is supported at the rear part of the shutter unit 16. As shown in FIG. 13, a ball contact surface (second plane) 18a is formed on the vibration isolating frame 18 on the front side facing the shutter unit 16, and the ball support hole 16e is formed on the ball contact surface 18a. The ball contact surface (first flat surface) 16f that is the bottom surface of each of the two surfaces faces each other. A guide ball (anti-vibration guide member) 28, which is a spherical rolling element, is sandwiched between the ball contact surface 16f and the ball contact surface 18a. As described above, the ball support hole 16e (ball contact surface 16f) is formed in three locations in the shutter unit 16, and the ball contact surface 18a and the guide ball 28 are also provided correspondingly (three locations). It has been. Both the ball contact surface 16f and the ball contact surface 18a are smooth flat surfaces that are substantially orthogonal to the photographing optical axis O. The guide ball 28 is loosely fitted in the ball support hole 16e in the direction orthogonal to the optical axis, and the guide ball 28 does not contact the inner wall of the ball support hole 16e when positioned near the center of the ball support hole 16e. .

  Three spring hooking protrusions 18b are provided on the outer peripheral portion of the vibration isolating frame 18 at different positions in the circumferential direction, and a tension spring is provided between each spring hooking protrusion 18b and three spring hooking protrusions 16c provided on the shutter unit 16. A (proximity urging member) 30 is stretched. The anti-vibration frame 18 is urged in the direction (front) approaching the shutter unit 16 by the urging force of the three tension springs 30, and the ball contact surface 18 a is brought into contact with the guide ball 28, thereby Forward movement is restricted. In this state, the three ball contact surfaces 18a are in point contact with the three guide balls 28, respectively, and by sliding the point contact portions (or the guide balls 28 inside the ball support holes 16e). The anti-vibration frame 18 can freely move in a direction perpendicular to the photographing optical axis O while the guide ball 28 rolls when not in contact with the wall.

  The anti-vibration frame 18 is also formed with two movement restriction holes 18c into which two movement restriction projections 16d provided on the shutter unit 16 are inserted. As shown in FIGS. 6 to 12, each movement limiting hole 18 c has a rectangular inner surface shape that is substantially square in a plane orthogonal to the photographing optical axis O. Hereinafter, one diagonal direction of the inner wall of each movement limiting hole 18c in the optical axis orthogonal plane is referred to as an X axis, and the other diagonal direction is referred to as a Y axis. The anti-vibration frame 18 is freely movable with respect to the shutter unit 16 (straight forward moving ring 14) in a plane perpendicular to the photographing optical axis O until the movement restriction projection 16d comes into contact with the inner surface of the movement restriction hole 18c. Can move.

  The anti-vibration frame 18 is driven by an anti-vibration drive actuator 26. The anti-vibration drive actuator 26 includes two coils 31 and 32 supported on the shutter unit 16 side and two permanent magnets 34 and 36 supported on the anti-vibration frame 18 side. The permanent magnets 34 and 36 are fixed to magnet holding portions 18d and 18e provided on the vibration isolation frame 18, respectively. The shapes and sizes of the permanent magnets 34 and 36 are substantially the same, are each formed into an elongated rectangular thin plate shape, pass through the photographing optical axis O, and are symmetrical with respect to a virtual plane P (FIGS. 6 to 12) along the Y axis. Arranged in relationship. More specifically, each of the permanent magnets 34 and 36 has an N-pole, one of the halved regions divided by the magnetic pole boundary lines M1 and M2 (FIGS. 8 and 11) passing through the approximate center in the short direction and facing the longitudinal direction. The other is the S pole, and the magnetic pole boundary line M1 of the permanent magnet 34 and the magnetic pole boundary line M2 of the permanent magnet 36 are above (described later) from below in the Y-axis direction (insertion side of the insertion / removal frame 20 described later). As it moves toward the separation position side of the insertion / removal frame 20, it is inclined so as to be separated from each other. The inclination angle of the magnetic pole boundary line M1 of the permanent magnet 34 and the magnetic pole boundary line M2 of the permanent magnet 36 with respect to the virtual plane P is set to about 45 degrees in the forward and reverse directions. That is, the permanent magnet 34 and the permanent magnet 36 have a relationship in which their longitudinal directions (magnetic pole boundary lines M1, M2) are substantially orthogonal.

  As shown in FIGS. 1, 8 and 11, the coils 31 and 32 are air-core coils having a pair of substantially parallel long side portions and a pair of curved portions connecting the long side portions. The size is substantially the same. A pair of positioning protrusions 16g and 16h are provided on the rear surface of the shutter housing 16a (FIG. 1), and the coil 31 is supported by the shutter unit 16 in such a manner that the pair of positioning protrusions 16g are engaged with the air core portion. The coil 32 is supported by the shutter unit 16 in such a manner that the pair of positioning protrusions 16h are engaged with the air core portion. In this supported state, the major axis direction of the coil 31 is substantially parallel to the magnetic pole boundary line M1 of the permanent magnet 34, and the major axis direction of the coil 32 is substantially parallel to the magnetic pole boundary line M2 of the permanent magnet 36. The coil 31 and the coil 32 are connected to a flexible substrate (not shown) extending from the shutter unit 16, and further connected to a camera control substrate via another flexible substrate in the lens barrel. The energization control of the coil 31 and the coil 32 is performed by the control circuit.

  In the anti-vibration drive actuator 26 having the above configuration, the coil 31 and the permanent magnet 34 face each other in the optical axis direction, and when the coil 31 is energized, the magnetic pole boundary line of the permanent magnet 34 in a plane orthogonal to the imaging optical axis O. A driving force in a direction substantially orthogonal to M1 (long axis direction line of the coil 31) acts. The acting direction of this driving force is F1 (FIGS. 8, 11 and 12). Further, as shown in FIG. 14, the coil 32 and the permanent magnet 36 are opposed to each other in the optical axis direction. When the coil 32 is energized, the magnetic pole boundary M2 (coil) of the permanent magnet 36 in a plane orthogonal to the photographing optical axis O is obtained. A driving force in a direction substantially orthogonal to (32 major axis direction lines) acts. The direction of action of this driving force is F2 (FIGS. 8, 11, and 12). The directions F1 and F2 of the driving force intersect with each other at an angle of about 45 degrees with respect to both the X axis and the Y axis. By controlling the energization of the coils 31 and 32, the imaging optical axis O and The anti-vibration frame 18 can be moved to an arbitrary position within an orthogonal plane. As described above, the movement range is restricted by the movement restriction hole 18c coming into contact with the inner surface of the movement restriction protrusion 16d.

  A sensor holder 22 is fixed to the rear portion of the vibration isolation frame 18. The sensor holder 22 has a shape that covers the rear portions of the magnet holding portions 18 d and 18 e, and holds a position detection sensor 38 that is located behind the permanent magnet 34 and a position detection sensor 40 that is located behind the permanent magnet 36. The position detection sensor 38 and the position detection sensor 40 are connected to a flexible substrate (not shown) extending from the shutter unit 16, and further connected to the camera control substrate via another flexible substrate in the lens barrel. The position detection sensor 38 and the position detection sensor 40 can detect the drive position of the vibration isolation frame 18 by the vibration isolation drive actuator 26.

  An insertion / removal frame 20 is supported on the vibration isolation frame 18 so as to be rotatable (swingable) about a rotation axis 42 parallel to the photographing optical axis O. Both ends of the rotation shaft 42 are fixed to a shaft support hole 18 f provided in the vibration isolation frame 18 and a retaining member 44 fixed to the vibration isolation frame 18. The insertion / removal frame 20 includes a lens holding cylinder portion 20a for holding the vibration-proof insertion / removal lens 12, a shaft hole portion 20b having a shaft hole through which the rotation shaft 42 is inserted, a lens holding cylinder portion 20a, and a shaft hole portion 20b. The arm part 20c to connect is provided. The insertion / removal frame 20 can swing between the insertion position shown in FIGS. 2 to 8 and 12 and the separation position shown in FIGS. 9 to 11, and a stopper (insertion holding) provided on the vibration isolation frame 18. Means) The insertion position is determined by bringing the stopper contact portion 20d provided on the lens holding cylinder portion 20a into contact with 18g. An insertion / removal frame biasing spring (insertion holding means, biasing member) 46 comprising a torsion coil spring having one end and the other end locked to the vibration isolation frame 18 and the insertion / removal frame 20 is inserted into the insertion / removal frame 20. Energizing in the direction. Further, the insertion / removal frame 20 is biased forward by an optical axis direction biasing spring 48 formed of a compression spring inserted between the shaft hole portion 20b and the retaining member 44, and the position in the optical axis direction is stabilized.

  When the insertion / removal frame 20 is in the insertion position, the vibration-proof insertion / removal lens 12 is positioned on the photographing optical axis O. A movement restricting position in the Y-axis direction (hereinafter, referred to as “vibration restricting frame 18”) where the movement restricting protrusion 16 d is brought into contact with the end portion on the insertion position side (the lower end portion in FIGS. 6 to 12) of the inner surface of the movement restricting hole 18 c. When the insertion / removal frame 20 is rotated to the separation position in a state of being referred to as a separation assistance position, the center of the vibration-proof insertion / removal lens 12 is displaced in the Y-axis direction with respect to the photographing optical axis O. An escape hole 18h having a shape corresponding to the movement locus of the lens holding cylinder portion 20a at this time (an arcuate locus centering on the rotation shaft 42) is formed in the vibration isolation frame 18 so as to penetrate in the optical axis direction. The front end portion of the lens holding cylinder portion 20a enters the escape hole 18h. The escape hole 18h penetrates (opens) the outer peripheral portion of the vibration isolation frame 18, and a bridge portion 18i that reinforces the opening portion of the escape hole 18h is provided. The bridging portion 18i is formed so as to be offset rearward so that it does not interfere with the lens holding cylinder portion 20a when the insertion / removal frame 20 is rotated to the removal position.

  The rectilinear moving ring 14 is detachable so as to be rotatable (swingable) between an insertion allowable position shown in FIG. 6 and a detachment forcing position shown in FIG. 9 around a rotation axis 50 parallel to the photographing optical axis O. A drive lever 24 is supported. The rotation shaft 50 is formed in the vicinity of the rotation shaft 42 and formed integrally with the rectilinear movement ring 14, and is inserted into a shaft hole formed in the shaft hole portion 24 a of the detachment drive lever 24. A retaining plate 52 is fixed to the rear portion of the rectilinear moving ring 14 to restrict the rearward movement of the separation drive lever 24. The detachment drive lever 24 has a detachment pressing portion 24c near the tip of an arm 24b extending in the outer diameter direction from the shaft hole portion 24a. The detachment pressing portion 24c is provided on the arm portion 20c of the insertion / removal frame 20. It is possible to contact the pressed part 20e. As shown in FIGS. 4 and 5, the detachment pressing portion 24 c is a plane that faces the rotational radius direction of the detachment drive lever 24. The pressed portion 20e is formed as an outer peripheral surface of a cylindrical projection whose axis is parallel to the photographic optical axis O, and is opposed to a plane that forms the separation pressing portion 24c. For this reason, the detachment pressing portion 24c and the pressed portion 20e transmit a rotational force from the detachment drive lever 24 to the insertion / removal frame 20, but do not transmit a force in a direction parallel to the photographing optical axis O. . The aforementioned urging force of the insertion / removal frame urging spring 46 urges the insertion / removal frame 20 from the disengagement position to the insertion position direction (counterclockwise in FIGS. 6 to 12). It is urged to rotate by a detachment drive lever urging spring (insertion / removal control means, urging member) 54 toward an insertion allowable position in the same direction (counterclockwise in FIGS. 6 to 12). In the rectilinear movement ring 14, a stopper (insertion / removal control means) 14b for determining a rotation end of the separation drive lever 24 in the urging direction by the detachment drive lever urging spring 54, that is, an allowable insertion position of the detachment drive lever 24 is provided. 1 to 3) are provided. The stopper 14b is formed as a groove formed on the inner peripheral surface of the rectilinear moving ring 14, and when the insertion allowable position of the separation drive lever 24 is determined, a part of the pressed portion 24d abuts on the inner surface of the groove. On the other hand, the rotation of the insertion / removal frame 20 in the urging direction by the insertion / removal frame urging spring 46 is regulated by the contact between the stopper contact portion 20d and the stopper 18g. FIG. 6 shows a state where the insertion / removal frame 20 and the separation drive lever 24 are in contact with the respective stoppers. At this time, the pressed portion 20e and the separation pressing portion 24c are separated from each other (see FIGS. 4 and 5). . The clearance between the pressed portion 20e and the separation pressing portion 24c is within the movable range of the vibration isolation frame 18 relative to the shutter unit 16 (the range until the movement restricting projection 16d contacts the inner surface of the movement restricting hole 18c). The size is set such that the pressing portion 20e is not brought into contact with the separation pressing portion 24c. In other words, the detachment drive lever 24 does not restrict the anti-vibration driving of the anti-vibration frame 18 and the insertion / removal frame 20 by the anti-vibration drive actuator 26 when in the insertion allowable position. If no external force is applied to the insertion / removal frame 20 and the separation drive lever 24, the insertion / removal frame 20 is maintained at the insertion position by the biasing force of the insertion / removal frame biasing spring 46 as shown in FIGS. .

  The separation drive lever 24 includes a pressed portion 24d in the vicinity of the shaft hole portion 24a. In the lens barrel, a detachment pressing protrusion (insertion / removal control means, component force applying member) 58 is fixed at the rear of the detachment drive lever 24, and is located behind the rectilinear moving ring 14 when in the retracted state. In accordance with the movement, the separation pressing protrusion 58 contacts the pressed portion 24d, and the separation driving lever 24 is rotated from the insertion allowable position to the separation forcing position. More specifically, an end face cam 58a is formed at the tip of the separation pressing protrusion 58, and when the linear movement ring 14 moves backward and approaches the separation pressing protrusion 58, the pressed part 24d comes into contact with the end cam 58a. By this contact, the detachment drive lever 24 is rotated in the direction against the urging force of the detachment drive lever urging spring 54 (the direction of the detachment position of the insertion / removal frame 20) from the moving force of the rectilinear movement ring 14 rearward in the optical axis direction. A component force to be moved is generated, and after the separation driving lever 24 is rotated by the amount of the clearance described above, the separation pressing portion 24 c comes into contact with the pressed portion 20 e of the insertion / removal frame 20. Then, the pressing force in the direction of the detachment position is transmitted to the insertion / removal frame 20 via the detachment pressing portion 24c and the pressed portion 20e, and resists the urging forces of both the insertion urging spring 46 and the detachment drive lever urging spring 54. Then, the detachment drive lever 24 presses and rotates the insertion / removal frame 20 in the detachment direction. After the insertion / removal frame 20 reaches the disengagement position, the disengagement holding surface 58b substantially parallel to the photographing optical axis O provided on the side surface of the disengagement pressing projection 58 engages the side surface of the pressed portion 24d, and the disengagement drive lever 24 is moved. As a result, the insertion / removal frame 20 is held at the separation position (FIG. 9). The separation pressing projection 58 can be provided on an arbitrary fixing member constituting the lens barrel. For example, in the case of a digital camera integrated with a lens barrel, the separation pressing protrusion 58 is a fixing member positioned on the image plane side with respect to the rectilinear moving ring 14. An image sensor holder for supporting the image sensor at the imaging position of the photographing optical system may be provided, and a release pressing projection 58 may be provided on the image sensor holder.

  The operation of the anti-vibration lens block 10 having the above structure will be described. 6 to 8, the insertion / removal frame 20 is held at the insertion position by the urging force of the insertion / removal frame urging spring 46, and the center of the anti-vibration insertion / removal lens 12 is aligned with the photographic optical axis O. I'm doing it. Further, the detachment drive lever 24 is held at the insertion allowable position by the urging force of the detachment drive lever urging spring 54. In the photographing state, the vibration-proof insertion / removal lens 12 is moved to the photographing optical axis by driving the vibration-proof frame 18 in the plane orthogonal to the optical axis by the vibration-proof drive actuator 26 according to the direction and magnitude of the vibration applied to the lens barrel. It is possible to suppress the shift (image blurring) of the subject image on the imaging plane by shifting with respect to O. More specifically, the moving angular velocity of the lens barrel is detected by a gyro sensor built in the lens barrel, and the moving angle is obtained by integrating the angular velocity of the shake over time, and the image is moved on the imaging surface from the moving angle. In addition to calculating the amount, the driving amount and the driving direction of the anti-vibration insertion / removal lens 12 (anti-vibration frame 18) for canceling the image blur are calculated. Then, energization control of the coil 31 and the coil 32 is performed based on the calculated value. Then, the anti-vibration frame 18 is moved while the three ball contact surfaces 18a receive the support guidance with respect to the three guide balls 28. When the anti-vibration frame 18 is subjected to anti-vibration driving, the insertion / removal frame 20 is held at an insertion position where the stopper contact portion 20d is brought into contact with the stopper 18g, and the anti-vibration frame 18 and the insertion / removal frame 20 (anti-vibration) The insertion / removal lens 12) is moved together. As described above, since the clearance is provided between the pressed portion 20e and the detachment pressing portion 24c, the detachment drive lever 24 is used for vibration isolation between the vibration isolation frame 18 and the insertion / removal frame 20 by the vibration isolation drive actuator 26. Does not regulate driving.

  In the photographing state, the position detection sensors 38 and 40 can be calibrated using the moving end position of the vibration isolating frame 18 by the contact between the movement restricting projection 16d and the inner surface of the movement restricting hole 18c. The direction of action F1 and F2 of the driving force of each pair of the coils 31 and 32 and the permanent magnets 34 and 36 constituting the anti-vibration driving actuator 26 intersect with the X axis and the Y axis at a relationship of about 45 degrees, and movement limitation The moving end where the X-axis direction both ends of the movement restricting hole 18c abut against the protrusion 16d is set as the X-axis drive reference position of the anti-vibration drive actuator 26, and the Y of the movement restricting hole 18c with respect to the movement restricting protrusion 16d A moving end where both end portions in the axial direction come into contact with each other can be set as a drive reference position for the Y axis. The practical vibration-proof drive range of the vibration-proof frame 18 in the photographing state is set in a range in which the movement restriction protrusion 16d does not contact the inner surface of the movement restriction hole 18c.

  When changing from the photographing state to the retracted state, the anti-vibration lens block 10 (the rectilinear moving ring 14) is moved rearward in the optical axis direction by a motor that drives the entire lens barrel to move forward and backward, and eventually retracts along with the rectilinear moving ring 14 The pressed portion 24 d of the drive lever 24 contacts the end face cam 58 a of the detachment pressing protrusion 58. Then, the pressed portion 24d is pressed by the end face cam 58a, and a component force is generated from the backward movement force of the rectilinear moving ring 14, and the detachment drive lever 24 is allowed to be inserted against the urging force of the detachment drive lever urging spring 54. It is rotated from the position toward the forcible separation position, and the separation pressing portion 24c comes into contact with the pressed portion 20e. As described above, an urging force toward the insertion position is applied to the insertion / removal frame 20 by the insertion / removal frame urging spring 46, and the detachment drive lever 24 with which the detachment pressing portion 24c abuts the pressed portion 20e is provided. Then, the insertion / removal frame urging spring 46 is pressed against the urging force of the insertion / removal frame urging spring 46 from the insertion position toward the separation position. In addition, an urging force in a direction of pressing the ball contact surface 18 a against the guide ball 28 by the three tension springs 30 acts on the vibration isolation frame 18 that supports the insertion / removal frame 20. That is, movement resistance due to the urging force of the insertion / removal frame urging spring 46 and the tension spring 30 acts on the insertion / removal frame 20 and the vibration isolation frame 18, respectively. Here, the rotational resistance of the insertion / removal frame 20 provided by the insertion / removal frame biasing spring 46 is set larger than the movement resistance of the vibration isolation frame 18 provided by the tension spring 30. Therefore, the pressing force acting on the insertion / removal frame 20 is transmitted to the vibration isolation frame 18, and the vibration isolation frame 18 together with the insertion / removal frame 20 before the rotation of the insertion / removal frame 20 in the direction of the separation position is started. It is moved toward the separation position. Then, the anti-vibration frame 18 is moved to the separation assist position (FIGS. 9 to 11) where the Y-axis direction end portion (end portion on the insertion position side) of the movement restriction hole 18c contacts the movement restriction protrusion 16d. . As described above, the practical anti-vibration driving range of the anti-vibration frame 18 in the shooting state does not include a place where the inner surface of the movement restriction hole 18c contacts the movement restriction protrusion 16d. It is located outside the vibration drive range. When the vibration isolating frame 18 reaches the separation assist position and further movement is restricted, the insertion / removal frame 20 is independently rotated from the insertion position to the separation position. In other words, the separation movement of the vibration-proof insertion / removal lens 12 is a combined movement of the movement of the vibration-proof frame 18 to the separation assist position in the Y-axis direction and the rotation of the vibration-proof frame 18 to the separation position of the insertion / removal frame 20. Done.

  By the movement of the anti-vibration frame 18 to the separation assisting position and the rotation of the insertion / removal frame 20 to the separation position, the anti-vibration insertion / removal lens 12 moves from the optical path (photographing optical axis O) as shown in FIGS. Will be withdrawn. When the rectilinear moving ring 14 continues to move backward, the separation holding surface 58b of the separation pressing protrusion 58 abuts against the pressed portion 24d, and the separation driving lever 24 is held at the separation forcing position (FIG. 9), and the insertion / removal frame 20 is held at the disengagement position by the disengagement pressing protrusion 58 together with the disengagement drive lever 24, and the rotation to the insertion position is restricted. Although not shown, when the lens barrel reaches the retracted state, a rear member (for example, in the shooting state, is prevented in the space in the straight moving ring 14 vacated by detachment of the vibration-proof insertion / removal lens 12 (lens holding cylinder portion 20a). Another optical element positioned behind the transfer / removal lens 12 enters. Thereby, the optical axis direction size at the time of accommodation can be made smaller than a lens barrel of a type in which a plurality of optical elements are accommodated in series on the optical axis.

  Conversely, when shifting from the stored state to the photographing state, the rectilinear moving ring 14 is moved forward to release the pressing of the detachment driving lever 24 by the detachment pressing protrusion 58 (holding at the detachment forced position), and the detachment driving lever 24 is moved. The urging force of the detachment drive lever urging spring 54 returns to the insertion allowable position shown in FIG. Then, the insertion / removal frame 20 is rotated from the removal position to the insertion position by the biasing force of the insertion / removal frame biasing spring 46. Along with this, the holding of the anti-vibration frame 18 at the separation assist position is also released, and the anti-vibration frame 18 can be driven by the anti-vibration drive actuator 26. Then, the above-described position detection sensors 38 and 40 are calibrated when the photographing state is entered.

  In the anti-vibration lens block 10 described above, the separation drive lever 24 is supported in the linear movement ring 14 separately from the insertion / removal frame 20 and the anti-vibration frame 18 for holding the anti-vibration insertion / removal lens 12, so At this time, the detachment drive lever 24 is pressed by the detachment pressing protrusion 58 to move to the detachment forced position, and the insertion / removal frame 20 is pressed and moved to the detachment position via the detachment drive lever 24. The detachment drive lever 24 is pivotally supported by a rotation shaft 50 parallel to the rotation shaft 42 of the insertion / removal frame 20 and is rotated along a plane orthogonal to the photographing optical axis O. The part where the load in the optical axis direction is transmitted under pressure is up to the separation drive lever 24, and the load in the optical axis direction does not act on the insertion / removal frame 20 and the vibration isolation frame 18. As described above, the detachment pressing portion 24c and the pressed portion 20e are formed as surfaces having a shape that does not transmit a force in a direction parallel to the photographing optical axis O. Even if the drive lever 24 moves a little in the direction along the axis of the rotation shaft 50, the insertion / removal frame 20 is not pressed in the direction along the axis of the rotation shaft 42. As a result, the load on the support mechanism for the insertion / removal frame 20 and the vibration isolation frame 18 is reduced, and high-accuracy driving of the vibration isolation insertion / removal lens 12 is ensured. In particular, when the release drive lever 24 is pressed by the release pressing protrusion 58, the light is applied to the guide ball 28 sandwiched between the ball contact surface 18a of the vibration isolating frame 18 and the ball contact surface 16f of the shutter unit 16. An excessive load is not applied in the axial direction, and there is no possibility that a dent by the guide ball 28 is formed on the ball contact surface 18a or the ball contact surface 16f.

  Further, since the detachment drive lever 24 is interposed, the pressing force in the optical axis direction by the detachment pressing protrusion 58 does not directly act on the insertion / removal frame 20 or the vibration isolation frame 18. The urging force of the tension spring 30 for sandwiching the guide ball 28 between the shutter unit 16 and the shutter unit 16 can be set without taking into account the load variation due to the pressing force from the detachment pressing protrusion 58. Specifically, if the biasing force of the tension spring 30 is too strong, the load on the vibration-proof drive actuator 26 that drives the vibration-proof frame 18 becomes large. If the biasing force of the tension spring 30 is too small, the guide ball 28 Since there is a possibility of falling off, the biasing force of the tension spring 30 may be set in consideration of the balance. Unlike the present embodiment, if the structure is such that the pressing force in the optical axis direction by the detachment pressing protrusion 58 acts on the vibration isolation frame 18, the balance of the urging force set by the tension spring 30 is lost. However, according to the configuration of the present embodiment, such a problem can be avoided.

  Further, unlike the insertion / removal frame 20 that changes the position of the rotation shaft 42 according to the movement of the vibration isolation frame 18, the separation drive lever 24 that is pressed by the separation pressing protrusion 58 rotates in the rectilinear movement ring 14. Since the position of the moving shaft 50 is not changed, the positional relationship with the separation pressing protrusion 58 can be kept constant without being affected by the moving position of the vibration isolation frame 18. Accordingly, the relative position of the pressed portion 24d of the separation drive lever 24 and the end face cam 58a of the separation pressing protrusion 58 is not displaced, and the separation drive lever 24 can be driven with high accuracy. The contact portion between the detachment drive lever 24 and the insertion / removal frame 20 is formed by a planar detachment pressing portion 24c that faces the turning radius direction of the detachment driving lever 24 and a pressed portion 20e that is a protruding portion of a cylindrical outer surface. Therefore, even if the position of the insertion / removal frame 20 changes due to the vibration-proof movement of the vibration isolation frame 18, the release pressing portion 24c is moved when the release drive lever 24 is rotated from the insertion allowable position to the release forcing position. The insertion / removal frame 20 can be rotated to the disengagement position by reliably abutting against the pressed portion 20e.

  As mentioned above, although demonstrated based on illustration embodiment, this invention is not limited to this. For example, in the illustrated embodiment, the anti-vibration frame 18 responsible for the image blur correction movement is supported by the guide ball 28 and can freely move along a plane orthogonal to the photographing optical axis O. Is a rotating member that is pivotally supported on the anti-vibration frame 18 via the rotating shaft 42, but includes a first stage that can move straight along the X-axis instead of the anti-vibration frame 18. It can also be set as the aspect provided with the 2nd stage which can move straight along the Y-axis instead of the unframe 20. In this aspect, the permanent magnets 34 and 36 of the image stabilization drive actuator 26 are supported on the second stage, and image blur correction may be performed by moving the first stage and the second stage in combination.

  In the illustrated embodiment, the shutter unit 16 supports the vibration isolation frame 18 with the guide ball 28 interposed therebetween, but the support member of the vibration isolation frame 18 may be other than the shutter unit. For example, a portion corresponding to the movement restricting projection 16d and the ball support hole 16e (ball contact surface 16f) is provided in the flange portion integrally formed in the linear movement ring 14, and the vibration isolating frame 18 is not interposed through the shutter unit 16. It may be supported movably.

10 Anti-Vibration Lens Block 12 Anti-Vibration Insertion / Removal Lens (Optical Element)
14 Straight moving ring (advancing / retracting member)
14b Stopper (insertion / removal control means)
16 Shutter unit (advance / retreat member)
16d Movement limiting projection 16e Ball support hole 16f Ball contact surface (first plane)
18 Anti-vibration frame (vibration-proof moving member)
18a Ball contact surface (second plane)
18c Movement limiting hole 18g Stopper (insertion holding means)
20 Insertion / removal frame (insertion / removal member)
20d Stopper contact portion 20e Pressed portion 22 Sensor holder 24 Detachment drive lever (detachment drive member)
24c Detachment pressing portion 24d Pressed portion 26 Anti-vibration driving actuator (anti-vibration driving means)
28 Guide ball (anti-vibration guide member, spherical rolling element)
30 Tension spring (approaching biasing member)
31 32 Coil 34 36 Permanent magnet 38 40 Position detection sensor 44 Stopping member 46 Insertion / removal frame biasing spring (insertion holding means, biasing member)
54 Release drive lever biasing spring (insertion / removal control means, biasing member)
58 Detachment pressing protrusion (insertion / removal control means, component force applying member)
58a End face cam 58b Detachment holding surface

Claims (8)

An advancing / retracting member that is movable in the optical axis direction of the imaging optical system and is moved to a different position in the optical axis direction in an imaging state and a storage state in which imaging is not performed;
An anti-vibration moving member supported so as to be movable along a plane perpendicular to the optical axis with respect to the advance / retreat member;
An insertion that holds an optical element and is pivotally supported about a rotation axis parallel to the optical axis with respect to the vibration-proof moving member, and the optical element is positioned on the optical axis of the photographing optical system An insertion / removal moving member that rotates to a position and a separation position for separating the optical element from the optical axis;
Insertion holding means for holding the insertion / removal moving member in the insertion position in the photographing state;
The advancing / retreating member is pivotally supported around a rotation axis parallel to the rotation axis of the insertion / removal member, and does not contact the insertion / removal member at the insertion position. An insertion permissible position that does not restrict movement of the insertion / removal movement member within the movable range of the vibration-proof movement member, and a forcible release position that contacts the insertion / removal movement member and presses and rotates from the insertion position to the separation position. A detachable drive member that rotates ;
When the detachable driving member is held in the insertion allowable position in the photographing state and the advance / retreat member moves in the optical axis direction from the photographing state position to the retracted position, the separation driving member is moved to the insertion allowable position. Insertion / removal control means for rotating from to the forcible separation position; and
Image stabilization drive means for performing image stabilization by driving the image stabilization moving member to an arbitrary position along a plane orthogonal to the optical axis in accordance with the motion applied to the photographing optical system;
Equipped with a,
The insertion / removal control means is separated from the separation drive member in the optical axis direction in the photographing state, and the separation drive is performed when the advance / retreat member moves in the optical axis direction from the position in the photographing state to the position in the storage state. A component applying member for reducing a distance between the member and the optical axis in contact with the detachment driving member and applying a component force for rotating the detachment driving member from the insertion allowable position to the detachment forcing position; position control device of the optical element, characterized in that there. The position control apparatus for an optical element according to claim 1, wherein the insertion / removal control means further includes the component force applying member.
A biasing member that moves and biases the separation driving member in the direction of the insertion allowable position; and a stopper that is provided in the advancement / retraction member and that determines the insertion allowable position by the contact of the separation driving member by the biasing force of the biasing member ;
An optical element position control device comprising: The position control device for an optical element according to claim 1 or 2, wherein the advance / retreat member moves from the object side to the image plane side when changing from the shooting state to the storage state,
A first plane formed on the advancing / retreating member and facing the image plane side and orthogonal to the optical axis;
A second plane formed on the anti-vibration moving member facing the object side and facing the first plane and orthogonal to the optical axis;
An anti-vibration guide member that is sandwiched between the first plane and the second plane and allows the anti-vibration moving member to move in the plane orthogonal to the optical axis with respect to the advance / retreat member; and the first plane; An approach urging member that urges the anti-vibration moving member with respect to the advance / retreat member in a direction in which the second plane approaches, and maintains the clamping state of the anti-vibration guide member;
Have
The position control device for an optical element, wherein the separation driving member is positioned on the image plane side with respect to the vibration-proof moving member and supported by the advance / retreat member. 4. The position control device for an optical element according to claim 3, wherein the anti-vibration guide member is a spherical rolling element. In the position control system of the optical element of claim 3 or 4 wherein said component force applying member is provided on the fixed member located on the image surface side than the reciprocating member in the photographing state, projecting on the object side from the stationary member Device for controlling the position of an optical element comprising a projected portion. 6. The position control apparatus for an optical element according to claim 1, wherein the insertion / removal member has a pressed portion including an outer peripheral surface of a cylindrical protrusion having an axis parallel to the optical axis, The detachment drive member has a detachment pressing portion composed of a plane facing the turning radius direction,
When the insertion / removal movement member is at the insertion position and the separation drive member is at the insertion permission position, the pressed portion and the separation pressing portion are spaced apart from each other, and the separation drive member is the insertion permission An optical element position control device in which the detachment pressing portion comes into contact with the pressed portion when it is rotated from a position toward the detachment forced position. The position control device for an optical element according to any one of claims 1 to 6 , wherein the insertion holding means includes:
An urging member for moving and urging the insertion / removal member to the insertion position; and an anti-vibration movement member, and the insertion / removal member abuts by the urging force of the urging member to determine the insertion position. Stopper;
An optical element position control device comprising: 8. The position control apparatus for an optical element according to claim 1, wherein the advance / retreat member is an annular member surrounding the optical axis.