JP2013213848A - Optical unit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an optical unit capable of achieving the stability of an assembled state while improving assembly properties.SOLUTION: A third lens frame unit 70 comprises: a third front-side lens frame 73 having a first reference surface 73b; a third rear-side lens frame 74 having second reference surfaces 74d and 174d which abut on the first reference surface 73b; a third front-side lens group G3A mounted on the third front-side lens frame 73; a third rear-side lens group G3B mounted on the third rear-side lens frame 74; and a flat spring 72 which is mounted on the third front-side lens frame 73 and which presses the third rear-side lens frame 74 such that the second reference surfaces 74d and 174d are pressed to the first reference surface 73b.

Description

  The technology disclosed herein relates to an optical unit.

  For example, a digital camera is known as an imaging device. The digital camera has a lens barrel and an image sensor. The image sensor is, for example, a CCD (Charge Coupled Device) image sensor or a CMOS (Complementary Metal Oxide Semiconductor) image sensor. The image sensor converts an optical image formed by the lens barrel into an image signal. Thus, the image data of the subject can be acquired.

JP 2005-62432 A

  The lens barrel has a plurality of frames that support the optical system. Each frame is usually integrally formed of resin or the like. When the frames are fixed, they are usually fixed with screws or an adhesive.

  However, if the screws are used, the frame body is distorted, and the optical performance of the lens barrel may be deteriorated.

  In addition, in the case of adhesive fixation, it becomes difficult to disassemble during maintenance, and in some cases, it is necessary to discard the parts.

  In view of this, a configuration has been proposed in which constituent members are bayonet-coupled (see, for example, Patent Document 1). Thereby, a some structural member can be assembled | attached easily.

  However, if the portion where the bayonet is connected expands due to a temperature change, rattling occurs between the constituent members, which is not preferable.

  The subject of the technique disclosed here is providing the optical unit which can implement | achieve stability of an assembly | attachment state, improving assembly property.

  The optical unit disclosed herein includes at least one of a first member having a first contact surface, a second member having a second contact surface that contacts the first contact surface, and the first or second member. And at least one optical element mounted on one side, and a pressing member that is mounted on the first member and presses the second member so that the second contact surface is pressed against the first contact surface.

  Here, for example, “the optical element is attached to the first member” includes the case where the optical element is a separate member from the first member, and further, the optical element is integrally formed with the first member. It is also included. In addition, “the optical element is attached to the second member” includes the case where the optical element is a separate member from the second member, and further, the optical element may be integrally formed with the second member. included.

  In this optical unit, since the second contact surface is pressed against the first contact surface by the pressing member, the second member can be positioned with respect to the first member. Furthermore, since the pressing member is a separate member from the first and second members, it is possible to suppress fluctuations in the pressing force due to temperature changes compared to the case where the pressing member is integrally formed with the first or second member, The mounting state of the first and second members is more stable.

  As described above, with this optical unit, the stability of the assembled state can be realized while improving the assemblability.

Perspective view of digital camera Perspective view of lens barrel Sectional view of lens barrel (stored) Cross section of lens barrel (intermediate position) Cross section of lens barrel (wide angle end) Cross section of lens barrel (telephoto end) Disassembled perspective view of lens barrel Exploded perspective view of third lens frame unit (A) Exploded perspective view of third lens frame unit, (B) Perspective view of third lens frame unit (A) Exploded perspective view of third lens frame unit, (B) Perspective view of third lens frame unit (A) Perspective view of cap, (B) Perspective view of cap Exploded perspective view of third lens frame unit Perspective view of the third lens frame unit Exploded perspective view of third front lens frame and leaf spring Perspective view of the third front lens frame and leaf spring (mounted state) (A) Plan view of third front lens frame and leaf spring (in the middle of mounting), (B) Plan view of third front lens frame and leaf spring (when mounting is completed) Enlarged view around the first and second positioning parts (when assembled) Enlarged view around the first and second positioning parts (when assembled) Enlarged view around the first and second positioning parts (in the middle of assembly) Enlarged view around the first and second positioning parts (in the middle of assembly) Perspective view of optical unit (second embodiment) Perspective view of optical unit (second embodiment) (A) Plan view of optical unit, (B) XXIIIB-XXIIIB sectional view of FIG. (A) XXIVA-XXIVA sectional view of FIG. 23 (A), XXIVB-XXIVB sectional view of FIG. 23 (A), (C) XXIVC-XXIVC sectional view of FIG. Enlarged view around the first and second positioning portions (another embodiment)

<First Embodiment>
[Overall configuration of digital camera]
As shown in FIG. 1, the digital camera 1 includes an exterior part 2 and a lens barrel 3. The lens barrel 3 is fixed to the exterior part 2.

  2 to 7, the lens barrel 3 includes an optical system V, a master flange 90, a fixed frame 10, a zoom motor 4, a rectilinear frame 20, a drive frame 30, an intermediate frame 40, a first lens frame 50, A second lens frame 60, a third lens frame unit 70, and a fourth lens frame 80 are provided.

  The optical system V includes a first lens group G1, a second lens group G2, a third lens group G3, a fourth lens group G4, an aperture unit GA, and a shutter unit GS. The optical axis A is defined by the first lens group G1, the second lens group G2, the third lens group G3, and the fourth lens group G4.

  As shown in FIG. 1, a three-dimensional orthogonal coordinate system is set for the digital camera 1. The Y axis is set parallel to the optical axis A of the optical system V. The Y axis is an example of the first direction.

  The first lens group G1 is fixed to the first lens frame 50. The second lens group G2 is fixed to the second lens frame 60. The third lens group G3 is supported by the third lens frame unit 70. The third lens group G3 includes a third front lens group G3A and a third rear lens group G3B. As will be described later, the third front lens group G3A is fixed to the third front lens frame 73, and the third rear lens group G3B is a shake correction lens group, and is fixed to the correction lens frame 77. The fourth lens group G4 is a lens group for focus adjustment, and is fixed to the fourth lens frame 80. The aperture unit GA and the shutter unit GS are built in the third rear lens frame 74. The aperture unit GA and the shutter unit GS are disposed between the third front lens group G3A and the third rear lens group G3B. The third front lens group G3A, the third rear lens group G3B, the aperture unit GA, and the shutter unit GS are supported by the third lens frame unit 70, and in the Y-axis direction with respect to the exterior portion 2 and the fixed frame 10. Move together.

  The master flange 90 is fixed to the fixed frame 10. The image sensor unit 110 is fixed to the master flange 90.

  The fixed frame 10 is fixed to the exterior part 2. The fixed frame 10 and the master flange 90 constitute a stationary member of the lens barrel 3. The zoom motor 4 is fixed to the fixed frame 10.

  The drive frame 30 is supported by the fixed frame 10 so as to be rotatable with respect to the fixed frame 10 and movable in the Y-axis direction. The drive frame 30 is rotationally driven by the zoom motor 4. When the drive frame 30 rotates with respect to the fixed frame 10, the drive frame 30 moves in the Y axis direction with respect to the fixed frame 10. The drive frame 30 drives the first lens frame 50, the second lens frame 60, and the third lens frame unit 70 in the Y-axis direction.

  The first lens frame 50 supports the first lens group G1, and is guided in the Y-axis direction by the cam groove of the drive frame 30. The rotation of the first lens frame 50 relative to the fixed frame 10 is restricted by the intermediate frame 40. When the drive frame 30 rotates with respect to the fixed frame 10, the first lens frame 50 moves in the Y axis direction without rotating with respect to the fixed frame 10.

  The intermediate frame 40 is supported by the fixed frame 10 so as to be movable in the Y-axis direction, and restricts the rotation of the first lens frame 50 with respect to the fixed frame 10.

  The rectilinear frame 20 is supported by the fixed frame 10 so as to be movable in the Y-axis direction with respect to the fixed frame 10. The rotation of the rectilinear frame 20 relative to the fixed frame 10 is regulated by the fixed frame 10. Further, the rectilinear frame 20 is supported by the drive frame 30 so as to be rotatable with respect to the drive frame 30 and movable integrally in the Y-axis direction. The rectilinear frame 20 restricts the rotation of the third lens frame unit 70 relative to the fixed frame 10.

  The second lens frame 60 supports the second lens group G2, and is guided in the Y-axis direction by the cam groove of the drive frame 30. The rotation of the second lens frame 60 relative to the fixed frame 10 is restricted by the rectilinear frame 20. When the drive frame 30 rotates with respect to the fixed frame 10, the second lens frame 60 moves in the Y-axis direction without rotating with respect to the fixed frame 10.

  The third lens frame unit 70 supports the third lens group G3 and is guided in the Y-axis direction by the cam groove of the drive frame 30. The rotation of the third lens frame unit 70 relative to the fixed frame 10 is restricted by the rectilinear frame 20. When the drive frame 30 rotates with respect to the fixed frame 10, the third lens frame unit 70 moves in the Y-axis direction without rotating with respect to the fixed frame 10.

  The fourth lens frame 80 supports the fourth lens group G4 and is supported by the master flange 90 so as to be movable in the Y-axis direction with respect to the master flange 90. The fourth lens frame 80 is driven in the Y-axis direction by a focus motor M3 fixed to the master flange 90.

[Configuration of third lens frame unit]
Here, the configuration of the third lens frame unit 70 will be described in detail.

  As shown in FIGS. 8 to 18, the third lens frame unit 70 (an example of an optical adjustment unit) includes a third front lens frame 73, a leaf spring 72 (see FIGS. 12 to 17), and a third rear lens frame. 74, a correction lens frame 77, and a cap 71.

(1) Third Front Lens Frame As shown in FIGS. 12 to 16B, the third front lens frame 73 (an example of the first or second member, an example of the first or second frame unit) is, for example, It is a single member made of resin and integrally formed. The third front lens frame 73 is an annular member having a first center line. The first center line substantially coincides with the optical axis A. A third front lens group G3A is mounted on the third front lens frame 73. A leaf spring 72 and a cap 71 are attached to the third front lens frame 73.

  The third front lens frame 73 includes a front frame body 73k (an example of a first or second frame body), three first positioning portions 73a (an example of a first or second contact portion), three restricting portions 73c, Two first openings 73m (an example of an opening) and a second opening 73n (an example of an opening) are provided. The front frame main body 73k has a first cylindrical portion 73p and a first disc portion 73s.

  The first cylindrical portion 73p is a cylindrical portion. The first disc portion 73s is disposed on the inner peripheral side of the first cylindrical portion 73p. The third front lens group G3A is fixed to the first disc portion 73s.

  The first positioning portion 73a is disposed on the inner peripheral side of the first cylindrical portion 73p and protrudes radially inward from the first cylindrical portion 73p. In the present embodiment, the three first positioning portions 73a are arranged at equal intervals in the circumferential direction. The first positioning portion 73a is in contact with a second positioning portion 74b (described later) of the third rear lens frame 74 in the Y-axis direction, and has a first reference surface 73b. The first reference surface 73b is a plane perpendicular to the Y-axis direction. The first reference surface 73b is in contact with a second reference surface 74d (described later) of the third rear lens frame 74 in the Y-axis direction.

  The restricting portion 73c is disposed so as to be in contact with the second positioning portion 74b. The restricting portion 73c is disposed to face the tip of the second positioning portion 74b in the Y-axis direction. The restricting portion 73c is disposed on the Y axis direction negative side of the second positioning portion 74b. A gap C is formed between the restricting portion 73c and the second positioning portion 74b. More specifically, the restricting portion 73c has a restricting surface 73d that is inclined with respect to the Y-axis direction. The restricting surface 73d is disposed to face an inclined guide surface 74c (described later) of the second positioning portion 74b. A gap C is secured between the regulation surface 73d and the inclined guide surface 74c.

  When the third front lens frame 73 and the third rear lens frame 74 are separated in the Y-axis direction in a state where the third rear lens frame 74 is mounted on the third front lens frame 73, the second positioning is performed on the restriction portion 73c. The part 74b comes into contact, and the restriction part 73c restricts the movement of the third rear lens frame 74 in the Y-axis direction with respect to the third front lens frame 73. Therefore, it is possible to prevent the pressing portion 72b of the leaf spring 72 from being plastically deformed.

  The first opening 73m is formed by a first disc portion 73s and a first cylindrical portion 73p. A pressing portion 72b (described later) of the leaf spring 72, a second positioning portion 74b (described later) of the third rear lens frame 74, and a stopper projection 71b (described later) of the cap 71 are inserted into the first opening 73m.

  The second opening 73n is formed by the first disc portion 73s and the first cylindrical portion 73p. The circumferential dimension of the second opening 73n is larger than the circumferential dimension of the first opening 73m. A pressing portion 72b (described later) of the leaf spring 72, a second positioning portion 174b (described later) of the third rear lens frame 74, and a shutter motor M1 (described later) are inserted into the second opening 73n.

(2) Third Rear Lens Frame As shown in FIG. 8, the third rear lens frame 74 (an example of the first or second member, an example of the first or second frame unit) is a third front lens frame. 73 is arranged side by side in the Y-axis direction, and is arranged on the Y-axis direction negative side of the third front lens frame 73. The third rear lens frame 74 is an annular member having a second center line. This second center line substantially coincides with the optical axis A.

  The third rear lens frame 74 includes a diaphragm unit GA and a shutter unit GS. As shown in FIGS. 10A and 10B, the aperture unit GA has an aperture drive motor M2. The aperture drive motor M2 projects rearward (Y-axis direction negative side) from the third rear lens frame 74. As shown in FIG. 8, the shutter unit GS has a shutter motor M1. The shutter motor M1 protrudes forward (Y-axis direction positive side, third front lens frame 73 side) from the third rear lens frame 74. The shutter motor M1 is inserted into the second opening 73n of the third front lens frame 73. The third rear lens frame 74 has a rear frame main body 74a (an example of the first or second frame main body), two second positioning portions 74b, and a second positioning portion 174b.

  The second positioning portion 74b protrudes from the second frame body in the Y-axis direction and is inserted into the first opening 73m. The second positioning portion 174b protrudes from the second frame body in the Y-axis direction and is inserted into the second opening 73n.

  As shown in FIGS. 17 and 18, the second positioning portions 74 b and 147 b (an example of the first or second contact portion) are in contact with the first positioning portion 73 a in the Y-axis direction, and the leaf spring 72 It is pressed by the first positioning part 73a. The second positioning portions 74b and 174b are sandwiched between the pressing portion 72b of the leaf spring 72 and the first positioning portion 73a. Positioning of the third front lens frame 73 and the third rear lens frame 74 in the Y-axis direction is performed by the first positioning portion 73a and the second positioning portions 74b and 174b. The second positioning portion 74b has a second reference surface 74d, a third reference surface 74e, and an inclined guide surface 74c. The second positioning portion 174b has a second reference surface 174d, a third reference surface 174e, and an inclined guide surface 174c.

  The second reference surfaces 74d and 174d are flat surfaces perpendicular to the Y-axis direction and are in contact with the first reference surface 73b. The third reference surface 74e is disposed on the opposite side to the second reference surface 74d in the Y-axis direction, and is substantially parallel to the second reference surface 74d. The third reference surface 174e is disposed on the opposite side of the second reference surface 174d in the Y-axis direction, and is substantially parallel to the second reference surface 174d. The leaf spring 72 presses the third reference surfaces 74e and 174e. The inclined guide surfaces 74c and 174c are inclined with respect to the Y-axis direction, and are disposed to face the restricting surface 73d of the restricting portion 73c. When the third rear lens frame 74 is assembled to the third front lens frame 73, the pressing portion 72b is guided to the third reference surfaces 74e and 174e by the inclined guide surfaces 74c and 174c.

  Further, the second positioning portion 174 b restricts the rotation of the third rear lens frame 74 with respect to the third front lens frame 73. Specifically, the second positioning portion 174b has a rotation restricting surface 174f that faces the circumferential direction. The rotation restricting surface 174f is disposed so as to be able to contact the rotation restricting portion 73r in the circumferential direction. When the third rear lens frame 74 rotates with respect to the third front lens frame 73, the rotation restricting surface 174f contacts the rotation restricting portion 73r.

  As shown in FIG. 18, the second positioning portion 174b has a protrusion 174g. The protrusion 174g protrudes from the third reference surface 174e to the Y axis direction negative side, and forms a part of the inclined guide surface 174c. The protrusion 174g can prevent the pressing portion 72b from dropping from the second positioning portion 174b.

(3) Leaf Spring The leaf spring 72 (an example of the first pressing portion) is a member for mounting the third rear lens frame 74 to the third front lens frame 73, and includes the second positioning portions 74b and 174b. The first positioning portion 73a is pressed. The leaf spring 72 sandwiches the front frame body 73k and the second positioning portion 74b in the Y-axis direction.

  The leaf spring 72 is made of a metal plate and is attached to the third front lens frame 73. The plate spring 72 is an elastic member, and the rigidity of the plate spring 72 is lower than the rigidity of the third front lens frame 73 and the third rear lens frame 74. As a material of the leaf spring 72, for example, phosphor bronze can be considered. Since phosphor bronze is a non-magnetic material, it does not affect the magnet of the shake correction device. The material of the leaf spring 72 may be another material as long as it can generate an elastic force.

  The leaf spring 72 has a main body 72a, a rotation stop hook 72g, and three pressing portions 72b. The main body 72 a is a substantially annular portion and is attached to the third front lens frame 73. The main body 72a is disposed on the Y axis direction positive side of the front frame main body 73k (the Y axis direction positive side of the first disc part 73s). The main body 72a is pressed against the first disk portion 73s by a rotation stop hook 72g.

  The anti-rotation hook 72g is disposed on the outer periphery of the main body 72a and protrudes from the main body 72a to the Y axis direction positive side. The third front lens frame 73 has a rotation stop protrusion 73g. The anti-rotation hook 72g is disposed in an elastically deformed state between the anti-rotation protrusion 73g and the first disc portion 73s.

  The pressing part 72b is a part protruding from the main body part 72a to the Y axis direction negative side, and presses the second positioning part 74b against the first positioning part 73a. The pressing portion 72b has an elastic support portion 72c, an inclined portion 72d, and a curved portion 72e. The elastic support portion 72c extends from the outer peripheral portion of the main body portion 72a to the Y axis direction negative side (the third rear lens frame 74 side). The inclined portion 72d extends in the circumferential direction from the end of the elastic support portion 72c, and is inclined with respect to the Y-axis direction. More specifically, the inclined portion 72d is disposed so as to gradually approach the third reference surfaces 74e and 147e from the end portion of the elastic support portion 72c. The curved portion 72e is disposed at the end of the inclined portion 72d and is in contact with the third reference surfaces 74e and 174e. The curved portion 72e is curved in a semicircular shape. The pressing portion 72b is bent while being in contact with the third reference surfaces 74e and 174e.

(4) Correction Lens Frame The third rear lens group G3B is attached to the correction lens frame 77. The correction lens frame 77 is supported by the third rear lens frame 74 so as to be movable in the X-axis direction and the Z-axis direction. A first magnet 77 a and a second magnet 77 b are fixed to the correction lens frame 77. A first coil 79 a and a second coil 79 b are attached to the third rear lens frame 74. The first magnet 77a is disposed close to the first coil 79a. The second magnet 77b is disposed close to the second coil 79b. The first magnet 77a and the first coil 79a constitute a first drive actuator that drives the correction lens frame 77 in the X-axis direction. The second magnet 77b and the second coil 79b constitute a second drive actuator that drives the correction lens frame 77 in the Z-axis direction.

(5) Cap The cap 71 is provided so that the third rear lens frame 74 is detached from the third front lens frame 73, and is attached to the third front lens frame 73. The cap 71 has a cap body 71a, two stopper protrusions 71b, two fixing protrusions 71c, and two pole portions 71d. In the present embodiment, the cap 71 is made of, for example, a resin, and is composed of a single member that is integrally molded.

  The cap body 71a is a disk-shaped part. The cap main body 71 a covers the leaf spring 72 in a state where the cap 71 is attached to the third front lens frame 73. The stopper protrusion 71 b protrudes from the cap body 71 a in the Y-axis direction, and is inserted into the first opening 73 m in a state where the cap 71 is attached to the third front lens frame 73. Since the stopper protrusion 71b is inserted into the first opening 73m, the relative rotation of the third front lens frame 73 and the third rear lens frame 74 is restricted.

  Specifically, the state of the third front lens frame 73 and the third rear lens frame 74 in which the first reference surface 73b and the second reference surface 74d do not contact each other is in the first state (for example, the state shown in FIG. 19). When the state of the third front lens frame 73 and the third rear lens frame 74 in which the first reference surface 73b and the second reference surface 74d are in contact is set to the second state (for example, the state shown in FIG. 17), The stopper protrusion 71b prevents the third front lens frame 73 and the third rear lens frame 74 from rotating relative to each other from the second state to the first state. Therefore, it is possible to prevent the third rear lens frame 74 from dropping from the third front lens frame 73.

  The fixed protrusion 71 c protrudes from the cap body 71 a to the Y axis direction negative side, and is inserted into the fixed hole 73 e of the third front lens frame 73. The cap 71 is fixed to the third front lens frame 73 by the fixing protrusion 71c. The pole portion 71d is inserted into the auxiliary hole 73h.

[Assembly method of third lens frame unit]
Here, a method of assembling the third lens frame unit 70 will be described. A plate spring 72 is attached to the third front lens frame 73. Specifically, as shown in FIGS. 14 and 16A, the pressing portion 72b of the leaf spring 72 is inserted into the first opening 73m and the second opening 73n. At this time, the position of the leaf spring 72 with respect to the third front lens frame 73 is determined so that the anti-rotation hook 72g comes near the anti-rotation protrusion 73g.

  When the plate spring 72 is rotated in the R1 direction with respect to the third front lens frame 73 in a state where the main body portion 72a is in contact with the first disc portion 73s, the anti-rotation hook 72g and the anti-rotation protrusion 73g and the first circle are rotated. It enters between the plate portion 73s and gets over the return portion of the rotation stop projection 73g. In this state, the rotation stop hook 72g is compressed in the Y-axis direction between the rotation stop projection 73g and the first disc portion 73s. When the leaf spring 72 rotates in the R2 direction with respect to the third front lens frame 73, the rotation stop hook 72g is caught by the rotation stop protrusion 73g, and thus the leaf spring 72 is less likely to drop off from the third front lens frame 73.

  After the leaf spring 72 is attached, the third rear lens frame 74 is attached to the third front lens frame 73. Specifically, as shown in FIGS. 19 and 20, the second positioning portion 74b is inserted into the first opening 73m, and the second positioning portion 174b is inserted into the second opening 73n. At this time, the third front lens frame 73 and the third rear lens frame 74 are in the first state in which the first reference surface 73b is not in contact with the second reference surfaces 74d and 174d.

  Thereafter, when the third rear lens frame 74 is rotated in the R1 direction with respect to the third front lens frame 73, the curved portion 72e of the pressing portion 72b is made to be the third reference surface 74e by the inclined guide surface 74c of the second positioning portion 74b. The curved portion 72e of the pressing portion 72b is guided to the third reference surface 174e by the inclined guide surface 174c of the second positioning portion 174b. Since the second positioning portion 174b has the protrusion 174g, the curved portion 72e corresponding to the second positioning portion 174b gets over the protrusion 174g and reaches the third reference surface 174e. Thus, in the third front lens frame 73 and the third rear lens frame 74, the first reference surface 73b is the second reference from the first state where the first reference surface 73b is not in contact with the second reference surfaces 74d and 174d. The second state comes into contact with the surfaces 74d and 174d.

  As shown in FIG. 17, in a state where the pressing portion 72b is in contact with the third reference surface 74e, the second positioning portion 74b is pressed against the first positioning portion 73a. Further, as shown in FIG. 18, in a state where the pressing portion 72b is in contact with the third reference surface 174e, the second positioning portion 174b is pressed against the first positioning portion 73a. Accordingly, the Y-axis direction positioning of the third rear lens frame 74 with respect to the third front lens frame 73 is performed. Further, since the second positioning portions 74b and 174b are in contact with the inner peripheral surface of the first cylindrical portion 73p, the third rear lens frame 74 is positioned in the radial direction with respect to the third front lens frame 73.

  Eventually, the rotation restricting surface 174f of the second positioning portion 174b comes into contact with the rotation restricting portion 73r of the third rear lens frame 74, and the third front lens frame 73 and the third rear lens frame 74 are positioned in the rotational direction. Is called.

  Subsequently, the cap 71 is assembled to the third front lens frame 73. At this time, when the two pole portions 71d are inserted into the auxiliary hole 73h and the two fixing protrusions 71c are inserted into the fixing hole 73e, the two stopper protrusions 71b are inserted into the first opening 73m. When the fixing protrusion 71c is completely inserted into the fixing hole 73e, the barb of the fixing protrusion 71c is caught on the periphery of the fixing hole 73e, and the assembly of the cap 71 is completed (FIGS. 17 and 18). In this state, since the second positioning portions 74b and 174b interfere with the stopper projection 71b, even if a rotational force acts on the third front lens frame 73 and the third rear lens frame 74 due to an impact at the time of dropping or the like, It is possible to prevent the third rear lens frame 74 from falling off the third front lens frame 73.

  Note that after the third rear lens frame 74 is assembled to the third front lens frame 73, the correction lens frame 77 is assembled to the third rear lens frame 74.

Second Embodiment
In the first embodiment described above, the third front lens frame 73 and the third rear lens frame 74 are circular members, but the first and second members may be plate-shaped members. In addition, about the structure which has the function substantially the same as the structure of above-mentioned embodiment, the same code | symbol is attached | subjected and the detailed description is abbreviate | omitted.

  As shown in FIGS. 21 to 24C, the optical unit 300 includes a base plate 302, a plastic lens 301, and a leaf spring 303.

(1) Base plate The base plate 302 (an example of a first or second member, an example of a first or second frame unit) is composed of a plate body 302a (an example of a first or second contact portion), and a pair of restricting portions 302b. It has a pair of fixing portions 302c, a pair of stopper portions 302d, a central hole 302e, and a pair of openings 302s.

  The plate body 302a is larger than the plastic lens 301 and abuts the positioning plate 301a of the plastic lens 301 in the Y-axis direction. The first reference surface 302m (an example of the first or second contact surface) of the plate body 302a is in contact with the second reference surface 301m (an example of the first or second contact portion) of the plastic lens 301. That is, the plate body 302a positions the plastic lens 301 in the Y-axis direction.

  A groove 302h is formed in the plate body 302a. The groove 302h is disposed approximately at the center in the X-axis direction of the plate body 302a. A lens portion 301b is disposed in the groove 302h. Positioning of the plastic lens 301 with respect to the base plate 302 in the X-axis direction is performed by the groove 302h.

  Further, a positioning portion 302k is formed on the plate body 302a. The positioning of the plastic lens 301 in the Z-axis direction is performed by the positioning unit 302k.

  The restricting portion 302b restricts the movement of the plastic lens 301 in the Y-axis direction with respect to the base plate 302 within a predetermined range. Specifically, the restricting portion 302b is an L-shaped portion that protrudes from the plate body 302a in the Y-axis direction. The restricting portion 302b has a root portion 302f and a protruding portion 302g. The base portion 302f protrudes from the plate body 302a in the Y-axis direction. The protruding portion 302g protrudes in the Z-axis direction from the end portion of the root portion 302f. A gap C1 is secured between the protrusion 302g and the positioning plate 301a of the plastic lens 301.

  The fixing portion 302c supports a connecting portion 303g (described later) of the leaf spring 303. The fixed portion 302c protrudes from the plate body 302a to the Y axis direction negative side. A connecting portion 303g is sandwiched between the fixing portion 302c and the plate body 302a.

  The stopper portion 302d (an example of a stopper member) prevents the plastic lens 301 from falling off. The stopper portion 302d is disposed at a position corresponding to a pressing portion 303b (described later) of the leaf spring 303 in the X-axis direction. The stopper portion 302d is disposed at a position in contact with the positioning plate 301a in the Z-axis direction.

  The state of the base plate 302 and the plastic lens 301 where the first reference surface 302m and the second reference surface 301m do not contact each other is defined as the first state, and the base plate 302 and the plastic lens where the first reference surface 302m and the second reference surface 301m contact each other. When the state of 301 is set to the second state, the stopper portion 302d prevents the base plate 302 and the plastic lens 301 from moving relative to each other in the Z-axis direction to change from the second state to the first state.

  The center of the central hole 302e substantially coincides with the optical axis A of the plastic lens 301. Light transmitted through the plastic lens 301 passes through the central hole 302e. A pressing portion 303b of a leaf spring 303 is inserted into the opening 302s.

(2) Plastic Lens A plastic lens 301 (an example of a first or second member, an example of a first or second frame unit) includes a lens portion 301b (an example of an optical element) and a pair of positioning plates 301a (a first positioning plate). Or an example of a second member). The positioning plate 301 a extends in the X-axis direction from the lens portion 301 b and is pressed against the base plate 302 by a leaf spring 303. The positioning plate 301a has a second reference surface 301m and a third reference surface 301n. The second reference surface 301m is in contact with the first reference surface 302m of the base plate 302. The third reference surface 301n is in contact with a curved portion 303e (described later) of the pressing portion 303b.

  The positioning plate 301a is inserted into the protruding portion 302g so that the positioning plate 301a contacts the restricting portion 302b even if the plastic lens 301 moves in the Y-axis direction with respect to the base plate 302. Therefore, the movement range of the plastic lens 301 in the Y-axis direction is restricted to a predetermined range by the restriction portion 302b, and the pressing portion 303b can be prevented from being damaged due to excessive deformation.

  In addition, although the lens part 301b and the positioning plate 301a are integrally molded, these parts may be separate members. For example, the same effect can be obtained even when the lens is fixed to the lens frame.

(3) Plate Spring The plate spring 303 (an example of a pressing member) presses the plastic lens 301 against the base plate 302 and is attached to the base plate 302. The leaf spring 303 is an elastic member, and is formed of a metal plate, like the leaf spring 72. The rigidity of the leaf spring 303 is lower than the rigidity of the base plate 302. The leaf spring 303 has a connecting portion 303g (an example of a main body portion) and a pair of pressing portions 303b (an example of a pressing portion).

  The coupling portion 303g is disposed behind the base plate 302 (Y-axis direction negative side), and is inserted between the fixing portion 302c and the plate body 302a. The connecting portion 303g is a plate-like portion that is elongated in the X-axis direction.

  The pressing portion 303b is a portion protruding in the Y-axis direction from the connecting portion 303g, and presses the plastic lens 301 against the base plate 302. Specifically, the pressing part 303b has an elastic support part 303c, an inclined part 303d, and a bending part 303e. The elastic support portion 303c, the inclined portion 303d, and the bending portion 303e correspond to the elastic support portion 72c, the inclined portion 72d, and the bending portion 72e of the first embodiment.

  The elastic support portion 303c extends from the coupling portion 303g to the Y axis direction positive side and is inserted into the opening 302s. The inclined portion 303d extends from the end of the elastic support portion 303c to the positive side in the Z-axis direction and is inclined with respect to the Y-axis direction. More specifically, the inclined portion 303d is disposed so as to gradually approach the third reference plane 301n from the end portion of the elastic support portion 303c. The curved portion 303e is disposed at the end of the inclined portion 303d and is in contact with the third reference surface 301n. The curved portion 303e is curved in a semicircular shape. The pressing portion 303b bends while being in contact with the third reference surface 301n.

  In the optical unit 300, the positioning plate 301 a is pressed against the plate body 302 a by the plate spring 303, so that the plastic lens 301 can be positioned with respect to the base plate 302. Further, since the leaf spring 303 is a separate member from the base plate 302 and the plastic lens 301, the pressing force accompanying the temperature change and dimensional error is larger than when the leaf spring 303 is integrally formed with the base plate 302 or the plastic lens 301. The fluctuation can be suppressed, and the mounting state of the base plate 302 and the plastic lens 301 becomes more stable.

  As described above, with this optical unit 300, the positioning and mounting state of the base plate 302 and the plastic lens 301 can be further stabilized.

<Other embodiments>
The present invention is not limited to the above-described embodiments, and various changes and modifications can be made without departing from the scope of the present invention.

  In addition, about the structure which has the function substantially the same as the structure of above-mentioned embodiment, the same code | symbol is attached | subjected and the detailed description is abbreviate | omitted.

  (A) The configuration of the optical unit is not limited to the lens barrel 3 described above.

  (B) The configuration of the first and second frame units is not limited to the third lens frame unit 70 described above. For example, the third lens frame unit 70 includes a third front lens group G3A, a third rear lens group G3B, an aperture unit GA, a shutter unit GS, and a shake correction unit GB. In addition, these optical elements and the optical adjustment unit may not be mounted on the third rear lens frame 74. Here, examples of the optical element include a lens, a prism, and a filter, and examples of the optical adjustment unit include an aperture unit, a shutter unit, and a shake correction unit.

  In the above-described embodiment, the leaf spring 72 is attached to the third front lens frame 73, but the leaf spring 72 may be attached to the third rear lens frame 74. That is, the third front lens frame 73 may be an example of a first frame unit or an example of a second frame unit, and the third rear lens frame 74 may be an example of a first frame unit or an example of a second frame unit. It may be.

  Further, although the cap 71 is attached to the third front lens frame 73, the cap 71 may not be attached to the third front lens frame 73. Further, the cap 71 may be integrally formed with the third front lens frame 73.

  (C) The configuration of the pressing member is not limited to the plate springs 72 and 303 described above. For example, the main body portion of the pressing member may not be an annular portion. Moreover, the structure of a press part is not limited to the above-mentioned press part 72b, 302b.

  (D) The configuration of the stopper member is not limited to the cap 71 described above. For example, the stopper member may be integrally formed with the first or second member like the stopper portion 302d of the base plate 302. Further, the stopper portion 302d of the base plate 302 may be a separate body from the plate main body 302a.

  (E) The third lens group G3 and the third front lens frame 73 may be integrally molded. That is, “the optical element is attached to the first frame unit” includes a case where the optical element is a separate member from the first frame unit, and further, the optical element is integrally formed with the first frame unit. It is also included. In addition, “the optical element is attached to the second frame unit” includes a case where the optical element is a separate member from the second frame unit, and further, the optical element is integrally formed with the second frame unit. It is also included.

  (F) In the above-described embodiment, the main body portion 72a is mounted on the front frame main body 73k, the pressing portion 72b is replaced with the second positioning portions 74b and 174b (second abutting portion) and the first positioning portion 73a (first abutting portion). ). However, the pressing member may sandwich the first contact portion and the second contact portion.

  For example, as shown in FIG. 25, the pressing member 272 includes a second pressing portion 279 in addition to the main body portion 72a and the pressing portion 72b. The second pressing part 279 is disposed on the side opposite to the pressing part 72b from the main body part 72a. The first positioning portion 73a and the second positioning portion 74b are sandwiched between the pressing portion 72b and the second pressing portion 279 in the Y-axis direction.

  The second pressing portion 279 presses the first positioning portion 73a against the second positioning portions 74b and 174b. The second pressing portion 279 has a second elastic support portion 279c, a second inclined portion 279d, and a second bending portion 279e.

  The second elastic support portion 279c extends from the outer peripheral portion of the main body portion 72a to the Y axis direction positive side (the third front lens frame 73 side). The second inclined portion 279d extends in the circumferential direction from the end of the second elastic support portion 279c, and is inclined with respect to the Y-axis direction. More specifically, the second inclined portion 279d is disposed so as to gradually approach the third reference surfaces 74e and 147e from the end of the second elastic support portion 279c. The second curved portion 279e is disposed at the end of the second inclined portion 279d and is in contact with the third reference surfaces 274e and 147e. The second bending portion 279e is bent in a semicircular shape.

  By providing the second pressing portion 279, the third rear lens frame 74 can be more firmly connected to the third front lens frame 73.

<Features of the embodiment>
The features of the embodiment are listed below. The invention included in the embodiment is not limited to the following features. The information described in parentheses after each component is a specific example described to assist understanding of the features, and each component is not limited to these specific examples.

(1)
The optical unit (70, 300) according to the first feature is:
A first frame unit (73, 302) having a first contact portion (73a, 302a);
A second contact portion (a second contact portion) that is arranged in a first direction with the first frame unit (73, 302) and contacts the first contact portion (73a, 302a) in the first direction. A second frame unit (74, 301) having 74b, 174b, 301a);
The first and second frame units (73, 74, 302, 301) are separate members, and the second contact portions (74b, 174b, 301a) are replaced with the first contact portions (73a, 302a). Pressing members (72, 272, 303) that press the

  In this optical unit (70, 300), the second contact portions (74b, 174b, 301a) are pressed against the first contact portions (73a, 302a) by the pressing members (72, 272, 303). The second frame unit (74, 301) can be positioned with respect to the first frame unit (73, 302). Furthermore, since the pressing members (72, 272, 303) are separate members from the first frame and the second frame unit (74, 301), the pressing members (72, 272, 303) are replaced with the first or second frame. Compared with the case of integral molding with the units (73, 74, 302, 301), fluctuations in the pressing force due to temperature changes and dimensional errors can be suppressed, and the first and second frame units (73, 74, 302, 301). The wearing state of is more stable.

  As described above, with this optical unit (70, 300), the positioning and mounting state of the first frame unit (73, 302) and the second frame unit (74, 301) can be further stabilized.

(2)
The optical unit (70, 300) according to the second feature is the optical unit (70, 300) according to the first feature.
The first frame unit (73, 302) has the first and second frame units (73, 74, 302, 301) such that the first and second contact portions (74b, 174b, 301a) are separated from each other. There is a restricting portion (73c, 302b) for restricting the relative movement of the first and second frame units (73, 74, 302, 301) to a predetermined range when they are relatively moved.

  In this optical unit (70, 300), since the first frame unit (73, 302) has the restricting portion (73c, 302b), the pressing member (72, 272, 303) is damaged due to excessive deformation. Can be prevented.

(3)
The optical unit (70, 300) according to the third feature is the optical unit (70, 300) according to the second feature.
The restriction portion (73c, 302b) is disposed adjacent to the second contact portion (74b, 174b, 301a),
Gaps (C, C1) are formed between the restricting portions (73c, 302b) and the second contact portions (74b, 174b, 301a).

(4)
The optical unit (70, 300) according to the fourth feature is the optical unit (70, 300) according to any one of the first to third features.
The first contact portion (73a, 302a) has a first support surface (73b, 302m) that contacts the second contact portion (74b, 174b, 301a),
The second contact portions (74b, 174b, 301a) have second support surfaces (74d, 174d, 301m) that contact the first support surfaces (73b, 302m).

  In this optical unit (70, 300), the first support surface (73b, 302m) and the second support surface (74d, 174d, 301m) are the first and second frame units (73, 74, 302, 301). Positioning in one direction is easy.

(5)
The optical unit (70, 300) according to the fifth feature is the optical unit (70, 300) according to the fourth feature.
The first support surface (73b, 302m) is substantially perpendicular to the first direction;
The second support surfaces (74d, 174d, 301m) are substantially perpendicular to the first direction.

  In the optical unit (70, 300), since the first and second support surfaces (74d, 174d, 301m) are substantially perpendicular to the first direction, the pressing member (72, 272, 303) is the second contact portion. Even if (74b, 174b, 301a) is pressed against the first abutment portion (73a, 302a), the positions of the first and second frame units (73, 74, 302, 301) remain the pressing members (72, 272, 303) can be prevented from being displaced by the pressing force.

(6)
The optical unit (70, 300) according to the sixth feature is the optical unit (70, 300) according to the fourth or fifth feature.
The second contact portion (74b, 174b, 301a) is disposed on the opposite side of the second support surface (74d, 174d, 301m) in the first direction, and the second support surface (74d, 174d, 301m). And a third support surface (74e, 174e, 301n) generally parallel to
The pressing member (72, 272, 303) presses the third support surface (74e, 174e, 301n).

  In this optical unit (70, 300), even if the pressing member (72, 272, 303) presses the second contact portion (74b, 174b, 301a) against the first contact portion (73a, 302a), It is possible to more reliably prevent the positions of the first and second frame units (73, 74, 302, 301) from shifting due to the pressing force of the pressing members (72, 272, 303).

(7)
The optical unit (70, 300) according to the seventh feature is the optical unit (70, 300) according to the sixth feature.
The second contact portion (74b, 174b, 301a) has an inclined guide surface that is disposed adjacent to the third support surface (74e, 174e, 301n) and is inclined with respect to the first direction. .

(8)
The optical unit (70, 300) according to the eighth feature is the optical unit (70, 300) according to any one of the first to seventh features.
A first optical element (G3A) mounted on the first frame unit (73, 302);
A second optical element (G3B) mounted on the second frame unit (74, 301);
Optical adjustment disposed between the first optical element (G3A) and the second optical element (G3B) and supported by at least one of the first and second frame units (73, 74, 302, 301). A unit (GA, GS, GB),
The optical adjustment unit (GA, GS, GB) includes at least one of a diaphragm unit (GA), a shutter unit (GS), and a shake correction unit (GB).

(9)
The optical unit (70, 300) according to the ninth feature is the optical unit (70, 300) according to any one of the first to eighth features.
The pressing member (72, 272, 303) includes a main body portion attached to the first frame unit (73, 302), and the second abutting portion (74b, 174b) extending from the main body portion in the first direction. , 301a) and first pressing portions (72b, 303b) for pressing the first contact portions (73a, 302a).

  In this optical unit (70, 300), since the pressing members (72, 272, 303) have the main body portion and the first pressing portion (72b, 303b), they are attached to the first frame unit (73, 302). And the portion that presses the second contact portion (74b, 174b, 301a) are separate portions, and the pressing member (72, 272, 303) is assembled to the first frame unit (73, 302). It becomes easy.

(10)
The optical unit (70, 300) according to the tenth feature is the optical unit (70, 300) according to the ninth feature.
The first pressing portions (72b, 303b) are bent while being in contact with the second contact portions (74b, 174b, 301a).

(11)
The optical unit (70, 300) according to the eleventh feature is the optical unit (70, 300) according to the ninth or tenth feature.
The first frame unit (73, 302) further includes a first frame main body (73k, 302a) to which the main body portion is mounted.
The first frame body (73k, 302a) has openings (73m, 73n, 302f) into which the first pressing portions (72b, 303b) are inserted.

(12)
The optical unit (70, 300) according to the twelfth feature is the optical unit (70, 300) according to the eleventh feature.
The second frame unit (74, 301) has a second frame body (74a) arranged side by side with the first frame unit (73) in the first direction,
The second contact portions (74b, 174b) protrude from the second frame body (74a) in the first direction and are inserted into the openings (73m, 73n).

(13)
The optical unit (70) according to the thirteenth feature is the optical unit (70) according to the eleventh or twelfth feature.
A stopper member (71) attached to the first frame unit (73);
The stopper member (71) has a stopper portion (71b) inserted into the opening.

(14)
The optical unit (70) according to the fourteenth feature is the optical unit (70) according to the thirteenth feature.
The stopper part (71b) is arranged side by side with the second contact part (74b, 174b) in the opening.

(15)
The optical unit (70) according to the fifteenth feature is the optical unit (70) according to any of the ninth to fourteenth features,
The pressing member (72, 272) has a second pressing portion (279) that presses the first contact portion (73a) against the second contact portion (74b, 174b).

(16)
The optical unit (70) according to the sixteenth feature is the optical unit (70) according to the fifteenth feature.
The second pressing part (279) is bent in contact with the first contact part (73a), and the first pressing part (72b) is in contact with the first contact part (73a). Located on the opposite side.

(17)
The optical unit (70, 300) according to the fifteenth feature is the optical unit (70, 300) according to any one of the first to sixteenth features,
The pressing members (72, 272, 303) are elastic members,
The rigidity of the pressing member (72, 272, 303) is lower than the rigidity of the first frame unit (73, 302).

  The present invention is useful in the field of optical units used in lens barrels.

DESCRIPTION OF SYMBOLS 1 Digital camera 2 Exterior part 3 Lens barrel 4 Zoom motor 10 Fixed frame 20 Straight advance frame 30 Drive frame 40 Intermediate frame 50 First lens frame 60 Second lens frame 70 Third lens frame unit (an example of an optical unit)
71 Cap (Example of stopper member)
71b Stopper protrusion (example of stopper)
72 Leaf spring (an example of a pressing member)
72a body part (example of body part)
72b pressing part (an example of a first pressing part, an example of an elastic pressing part)
72c Elastic support portion 72d Inclined portion 72e Curved portion 73 Third front lens frame (an example of the first or second member, an example of the first or second frame unit)
73a 1st positioning part (an example of the 1st or 2nd contact part)
73b 1st reference surface (an example of the 1st or 2nd contact surface, an example of the 1st or 2nd support surface)
73c restriction part (an example of the first or second restriction part)
73d Restricting surface 73e Fixing hole 73g Anti-rotation protrusion 73k Front side frame main body (an example of the first or second frame main body)
73m 1st opening (an example of opening)
73n 2nd opening (an example of opening)
73p First cylindrical portion 73r Rotation restricting portion 73s First disc portion 74 Third rear lens frame (an example of the first or second member, an example of the first or second frame unit)
74a Rear frame body (an example of a first or second frame body)
74b 2nd positioning part (an example of the 1st or 2nd contact part)
74c Inclined guide surface (an example of an inclined guide surface)
74d Second reference surface (an example of a first or second contact surface, an example of a first or second support surface)
74e Third reference surface (an example of a third support surface)
174b 2nd positioning part (an example of the 1st or 2nd contact part)
174c Inclined guide surface (an example of an inclined guide surface)
174d Second reference surface (an example of the first or second contact surface, an example of the first or second support surface)
174e Third reference surface (an example of a third support surface)
80 Fourth lens frame 90 Master flange G1 First lens group G2 Second lens group G3 Third lens group G3A Third front lens group (an example of an optical element, an example of a first or second optical element)
G3B third rear lens group (an example of an optical element, an example of a first or second optical element)
G4 Fourth lens group GA Aperture unit (an example of an optical adjustment unit)
GS shutter unit (an example of an optical adjustment unit)
GB shake correction unit (an example of an optical adjustment unit)

Claims (5)

A first member having a first contact surface;
A second member having a second contact surface that contacts the first contact surface;
At least one optical element mounted on at least one of the first and second members;
A pressing member that is mounted on the first member and presses the second member so that the second contact surface is pressed against the first contact surface;
Optical unit equipped with. The first member has a first restricting portion,
The second member has a second restricting portion,
The first restricting portion contacts the second restricting portion when the first and second members move relative to each other so that the first and second contact surfaces are separated from each other.
The optical unit according to claim 1. The pressing member has at least one elastic pressing portion that presses the second member such that the second contact surface is pressed against the first contact surface.
The optical unit according to claim 1 or 2. A stopper member mounted on at least one of the first and second members;
The state of the first and second members where the first contact surface and the second contact surface do not contact each other is defined as a first state, and the first contact surface and the second contact surface contact each other. When the state of the first and second members is the second state, the stopper member prevents the first and second members from rotating relative to each other to change from the second state to the first state.
The optical unit according to claim 1. A stopper member mounted on at least one of the first and second members;
The state of the first and second members where the first contact surface and the second contact surface do not contact each other is defined as a first state, and the first contact surface and the second contact surface contact each other. When the state of the first and second members is the second state, the stopper member moves from the second state when the first and second members move relative to each other in a direction parallel to the first contact surface. Deter the first state;
The optical unit according to claim 1.

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