JP4130963B2 - Shading structure of a retractable lens barrel - Google Patents

Description

  The present invention relates to a light shielding structure for a retractable lens barrel.

  As a light shielding structure for a retractable lens barrel, a structure in which a light shielding member for preventing entry of harmful light is supported on a lens frame that supports a lens group is known.

  However, in the case of the retractable lens barrel, the change in the distance between the lens groups is large, and accordingly, the light shielding member needs to be arranged at a position relatively away from the lens frame. In particular, in the case of a lens barrel that employs a high-magnification zoom lens as an optical system, the tendency becomes stronger, and an adjustment mechanism for the lens group is required, so that it is more difficult to reduce the thickness and size of the lens barrel.

  It is an object of the present invention to provide a light shielding structure for a retractable lens barrel that can be reduced in size and thickness.

The collapsible lens barrel of the present invention is a collapsible lens barrel having a lens system whose position changes between the photographing position and the storage position, and a lens to which a lens group that adjusts the position in the optical axis direction during assembly is fixed. Fixed frame; a moving cylinder member that is screwed with this lens fixing frame and is moved along a predetermined locus; this moving cylinder member is configured to prevent the entry of harmful light that is supported so as to be movable in the front-rear direction by regulating the backward end. A light- shielding member having a light-shielding portion to be located behind the lens fixing frame ; a first spring which is contracted between the light-shielding member and the lens fixing frame and moves and urges the light-shielding member to the rearward projecting end A member; and when positioned at the storage position, the first spring member is compressed by contact with the light shielding member biased rearward by the first spring member, and positioned behind the light shielding member. to have; housing upon contact member It is characterized.

  The movable cylinder member is configured to screw a movable cylinder that is advanced and retracted in the optical axis direction by a cam mechanism in accordance with a zooming operation, and a lens fixing frame that is supported by the movable cylinder so as to be movable in the optical axis direction by restricting the forward end. It is practical to include a second spring member which is composed of a combined intermediate cylinder member and which constantly biases the intermediate cylinder member forward.

  Furthermore, at least the lens group fixed to the lens fixing frame can be a variable power lens group.

  According to the present invention, in the retractable lens barrel, not only the degree of freedom of installing the light shielding member in the photographing state is improved, but also the size and thickness can be reduced.

  First, a zoom lens optical system according to an embodiment in which the present invention is applied to a zoom lens barrel will be described with reference to FIG. The zoom lens system includes, in order from the object side, a first lens unit L1 having a positive power, a second lens unit L2 having a negative power, a third lens unit L3 having a positive power, and a fourth lens unit having a positive power. This is a varifocal lens system consisting of L4. The zooming is performed by the first to third lens units L1 to L3, and the focal point movement accompanying the zooming is corrected by the fourth lens unit L4. At the time of zooming, the first lens unit L1 and the third lens unit L3 move together at a constant interval. The fourth lens group L4 is a focus group at the same time. FIG. 1 depicts both a zooming trajectory and a trajectory during storage. Strictly speaking, the varifocus lens system is defined as a lens system in which focal movement is caused by zooming, and the zoom lens system is defined as a lens system in which focal movement does not occur. The system is treated as a kind of zoom lens system, and in the following description, the varifocal lens system is referred to as a zoom lens system.

  The overall structure of the zoom lens barrel of the present embodiment will be described with reference to FIGS. For example, as shown in FIG. 8, the fixed cylinder 11 fixed to the camera body is formed with a female helicoid 11a and a rectilinear guide groove 11b in a direction parallel to the optical axis. A male helicoid 12a formed at the rear end of the cam helicoid ring 12 is screwed into the female helicoid 11a of the fixed cylinder 11 as shown in FIG. A spur gear 12b is formed at the peak of the male helicoid 12a, and the spur gear 12b is positioned in the inner surface recess 11c (FIG. 3) of the fixed cylinder 11 and is rotatably supported (FIG. 15). Always see). Accordingly, when the cam helicoid ring 12 is rotated via the drive pinion 13 and the spur gear 12b, the cam helicoid ring 12 moves in the optical axis direction according to the male helicoid 12a and the female helicoid 11a. In the zoom lens barrel of this embodiment, the cam helicoid ring 12 is the only rotating member centered on the optical axis.

  A rectilinear guide ring 14 is fitted on the outer periphery of the cam helicoid ring 12. The rectilinear guide ring 14 has a radial rectilinear guide projection 14a on the outer surface of the rear end portion, and a bayonet projection 14b (FIG. 4) on the inner surface of the rear end portion. The rectilinear guide protrusion 14a is fitted in the rectilinear guide groove 11b of the fixed cylinder 11 so as to be relatively movable, and the bayonet protrusion 14b is a circumferential groove formed immediately before the male helicoid 12a (spur gear 12b) of the cam helicoid ring 12. It fits in 12c so as to be relatively rotatable. Therefore, the linear guide ring 14 moves together with the cam helicoid ring 12 in the optical axis direction without rotating.

  On the outer peripheral surface of the cam helicoid ring 12, as shown in FIGS. 4, 9, and 16, a cam groove C15 for the first group moving cylinder 15 that supports the first lens group L1 and a cam groove for the decorative cylinder 16 are provided. C16 is formed, and a cam groove C17 (see FIG. 19) for the second group moving cylinder 17 supporting the second lens group L2 is formed on the inner peripheral surface. The first group cam groove C15 and the decorative cylinder cam groove C16 are slightly different in shape and are formed in three circumferentially spaced apart, and the second group cam groove C17 has the same basic locus in the circumferential direction and the optical axis. Six are formed apart from each other in the direction. The first group moving cylinder 15, the decorative cylinder 16, and the second group moving cylinder 17 are each guided in a straight line in the optical axis direction, and follow the first group cam groove C15, the decorative cylinder cam groove C16, and the second group cam groove C17. As the cam helicoid ring 12 rotates, it advances and retreats in the optical axis direction.

  These straight-ahead guidance relationships will be described. As shown in FIGS. 4 and 5, the first group moving cylinder 15 has an outer cylinder 15X, an inner cylinder 15Y, and a flange wall 15Z connecting the outer cylinder 15X and the tip of the inner cylinder 15Y. The cam helicoid ring 12 is located between the outer cylinder 15X and the inner cylinder 15Y. A cam follower 15a that fits in the first group cam groove C15 of the cam helicoid ring 12 is fixed to the rear end portion of the outer cylinder 15X. As shown in FIGS. 8 and 9, a first group frame 24 to which the first lens group L1 is fixed is screwed and fixed to the distal end portion of the inner cylinder 15Y. The first group frame 24 can be used when zooming adjustment is performed by adjusting the position of the first lens group L1 in the optical axis direction.

  On the inner peripheral surface of the rectilinear guide ring 14 guided linearly by the fixed cylinder 11, rectilinear guide grooves 14c (FIG. 9) parallel to the optical axis are formed at intervals of approximately 120 °. A rectilinear guide protrusion 15b protruding in the radial direction from the rear end portion of the outer cylinder 15X is fitted. The outer cylinder 15X of the first group moving cylinder 15 is formed with a narrow rectilinear guide groove 15d (FIG. 16) at the rear end of the assembly groove 15c. The rectilinear guide groove 15d is linearly moved with the outer cylinder 15X. A rectilinear guide key 16a fixed to the decorative cylinder 16 located between the guide rings 14 is located. The relative movement distance of the first group moving cylinder 15 and the decorative cylinder 16 in the optical axis direction (the difference in shape between the first group cam groove C15 and the decorative cylinder cam groove C16) is slight, and the optical axis direction of the rectilinear guide groove 15d is small. The length of is correspondingly short. The linear guide key 16a is integrally provided with a cam follower 16b that fits into the decorative cylinder cam groove C16.

  A compression coil spring 19 (see FIGS. 3 to 5) is inserted between the first group moving cylinder 15 and the decorative cylinder 16. The compression coil spring 19 moves and energizes the first group moving cylinder 15 backward and the decorative cylinder 16 forward, and between the first group cam groove C15 and the cam follower 15a and between the decorative cylinder cam groove C16 and the cam follower 16b. It works to take backlash between.

  Further, as shown in FIG. 16, the first group cam groove C15 and the decorative cylinder cam groove C16 extend the decorative cylinder 16 forward relative to the first group movable cylinder 15 in the storage position compared to the photographing position. The shape is set to be slightly different so as to prevent interference between the barrier of the barrier block 30 (FIG. 8) and the first lens unit L1. More specifically, as shown in FIG. 16, the optical axis direction distance Q between the first group cam groove C15 and the decorative tube cam groove C16 is greater in the preparation section (section from the storage position until the barrier is fully opened). The shapes of the first group cam groove C15 and the decorative tube cam groove C16 are set to be larger than the zoom section (section from the wide end position to the tele end position). That is, in the preparatory section, Q = Q1 in all sections, but the distance Q gradually decreases from the position OP2 (that is, from the position where the lens L1 and the barrier do not interfere) after passing through the barrier fully open position OP1 by a predetermined amount. In the wide end position, Q = Q2 (<Q1). In the zoom section, Q = Q2 in all the sections. In the storage position shown in FIG. 3, the clearance c1 between the flange wall 15Z at the front end of the first group moving cylinder 15 and the flange wall of the decorative cylinder 16 positioned in front of the flange wall 15Z is the shooting state shown in FIG. It can be seen that the clearance is larger than the clearance between both flange walls. In other words, vignetting by the barrier block 30 is prevented by bringing the barrier block 30 closer to the first lens unit L1 at the photographing position. The barrier block 30 is supported by the front end of the decorative cylinder 16, and the barrier opening / closing ring 31 (FIG. 9) positioned immediately behind the barrier block 30 is rotated by the cam helicoid ring 12 in the vicinity of the storage position. Open and close the barrier. A barrier mechanism that opens and closes the barrier block 30 by the rotational movement of the barrier opening and closing ring 31 is well known. In the present embodiment, the shapes of the first group cam groove C15 and the decorative cylinder cam groove C16 are set so that the distance Q becomes a constant value (= Q2) in the zoom section, but depending on the focal length. The distance Q may be changed, and the distance Q in the zoom section may be larger than the distance Q in the preparation section.

  The front end of the decorative cylinder cam groove C16 is opened, and the cam follower 16b of the decorative cylinder 16 is inserted into the cam groove C16 from the open end C16a (FIG. 16) at a specific assembly position. The Similarly, for the first group cam groove C15, the cam follower 15a of the first group moving cylinder 15 is inserted from the front end open end C15a.

  The inner cylinder 15Y of the first group moving cylinder 15 is formed with a rectilinear guide protrusion 15f (FIGS. 6 and 7) in a direction parallel to the optical axis on the inner peripheral surface. A rectilinear guide groove 17a is formed in a direction parallel to the optical axis into which the rectilinear guide protrusion 15f is slidably fitted. A suspension groove 15e is formed at the center of the straight guide protrusion 15f in a direction parallel to the optical axis, and the rear end of the suspension groove 15e is closed (see FIGS. 17 and 18). The second group moving cylinder 17 is formed with a cam follower 17c that fits into the second group cam groove C17 of the cam helicoid ring 12.

  On the inner periphery of the second group moving cylinder 17, the third group moving cylinder 18 supporting the third lens group L3 is located. The third group moving cylinder 18 is formed with a rectilinear guide protrusion 18a that is parallel to the optical axis and is fitted in the rectilinear guide groove 17a of the second group moving cylinder 17 so as to be relatively slidable from the inside. A rectilinear key 18b (FIGS. 11, 17, and 18) that fits in the hanging groove 15e is formed at the center of the rectilinear guide protrusion 18a. As shown in FIG. 11, a shutter block 20 is inserted into the third group moving cylinder 18 in front of the third lens group L3, and is fixed by a holding ring 20a. A compression coil spring 21 is inserted between the third group moving cylinder 18 (restraining ring 20 a) and the second group moving cylinder 17, and the third group moving cylinder 18 is always in relation to the second group moving cylinder 17. Is urged to move backward. The rearward movement end of the third group moving cylinder 18 is restricted at a position where the linear key 18b contacts the rear end of the suspension groove 15e of the first group moving cylinder 15. In other words, in the shooting state, the state where the straight key 18b is in contact with the rear end portion of the suspension groove 15e of the first group moving cylinder 15 is maintained, and the relative distance between the first lens group L1 and the third lens group L3 is constant. It becomes. When the zoom lens barrel changes from the photographing state to the retracted state, after the third lens unit L3 (third group moving barrel 18) reaches the mechanical retracted end, the first lens unit L1 moves to the first group cam. When further retracting according to the groove C15, the compression coil spring 21 is bent and the first lens unit L1 approaches the third lens unit L3 (see FIG. 1). The straight key 18b has a swelled head and is prevented from falling off the hanging groove 15e.

  The compression coil spring 21 may be directly applied to the second group moving cylinder 17 (the second lens group L2 may be fixed to the second group moving cylinder 17), but in the illustrated embodiment, the storage length is further reduced. Therefore, the second lens unit L2 can be retracted with respect to the second group moving cylinder 17. FIG. 12 and FIG. 13 show the configuration. The second group moving cylinder 17 is formed with a cylindrical portion 17e having an inward flange 17d at the tip, and this cylindrical portion 17e has an optical axis and Three rectilinear guide grooves 17f that are parallel and open at the rear end and the front end are formed at equiangular intervals in the circumferential direction. The cylindrical portion 17e is fitted with a flange portion 25a formed on the intermediate cylindrical member 25, and three radially outward guide projections 25d are provided on the outer peripheral surface of the flange portion 25a so as to protrude at equal angular intervals in the circumferential direction. Are fitted into the corresponding straight guide grooves 17f from the rear. For this reason, the intermediate cylinder member 25 is restricted in relative rotation around the optical axis with respect to the second group moving cylinder 17, and can be relatively moved only in the optical axis direction. It can move forward until it comes into contact. The second lens group L2 is fixed to the second group frame 26, and the male screw 26b of the second group frame 26 is screwed into a female screw 25e formed on the inner periphery of the intermediate cylinder member 25. Therefore, by rotating the second group frame 26 relative to the intermediate cylinder member 25 whose rotation about the optical axis is restricted, the position of the second lens group L2 in the optical axis direction can be adjusted (zooming adjustment). After the adjustment, the second group frame 26 can be fixed to the intermediate cylinder member 25 by dropping the adhesive from the adhesive hole 25b. Between the front end face of the inner flange 17d of the second group moving cylinder 17 and the outer flange 26a of the second group frame 26, there is a gap c2 (FIG. 13) including the adjustment allowance. The compression coil spring 21 acts on the intermediate cylinder member 25, and normally, the intermediate cylinder member 25 is held at a position where the flange portion 25a abuts against the inner flange 17d. That is, the position of the second lens group L2 is controlled by the second group cam groove C17 in the shooting state, while the second group frame 26 is mechanically pushed backward by the rear end of the first group frame 24 during storage. The outer flange 26a can be retracted to a position where it abuts against the inner flange 17d, and the storage length can be shortened by the gap c2.

  A light shielding frame 27 is supported on the intermediate cylinder member 25. The light-shielding frame 27 includes an annular light-shielding portion 27a, a holding leg 27b extending forward from the annular light-shielding portion 27a at an interval of approximately 120 °, and a retaining hook portion 27c that is bent outward at the tip end portion of the holding leg 27b. The intermediate cylinder member 25 is formed with a light shielding member holding hole 25c into which the retaining hook portion 27c is fitted (FIG. 12). A conical coil spring 28 is inserted between the light shielding frame 27 and the second group frame 26, and always urges the light shielding frame 27 to move backward. When the light shielding frame 27 reaches the mechanical retracted end when the lens barrel is housed, the light shielding frame 27 bends the conical coil spring 28 and approaches the second group frame 26. The length of the light shielding member holding hole 25c in the optical axis direction is set so that the annular light shielding portion 27a can come into contact with the second lens unit L2.

  The conical coil spring 28 further functions to remove backlash during zooming adjustment performed by rotating the second group frame 26. The zooming adjustment is an adjustment performed by adjusting the position of the second lens unit L2 in the optical axis direction while observing the image position, and backlash with respect to the intermediate cylinder member 25 (second group moving cylinder 17) of the second group frame 26 is performed. By removing, accurate adjustment can be made.

  The fourth lens group L4 is fixed to the fourth group frame 22. As described above, the fourth lens group L4 has a role of correcting the focal movement of the varifocal lens system and a role of the focus lens group, and is advanced and retracted by the pulse motor 23. That is, the drive shaft of the pulse motor 23 is a screw shaft 23a, and a nut member 23b whose rotation is restricted is screwed onto the screw shaft 23a. The nut member 23b is constantly urged to move in a direction in which the nut member 23b comes into contact with the foot portion 22a of the fourth group frame 22 by the spring means S, and the rotation of the fourth group frame 22 is restricted by the guide bar 22b. Therefore, when the pulse motor 23 is driven, the fourth group frame 22 (fourth lens group L4) moves forward and backward in the optical axis direction. The pulse motor 23 is controlled according to focal length information and subject distance information.

  Therefore, in the zoom lens barrel having the above-described configuration, when the cam helicoid ring 12 is rotated via the drive pinion 13, the first group moving cylinder 15, the decorative cylinder 16, and the second group moving cylinder 17 which are guided in a straight line are cam grooves. It moves in the optical axis direction according to C15, C16, C17. The third group moving cylinder 18 moves together with the first group moving frame 15 when the first group moving cylinder 15 moves forward from the storage position and the rectilinear key 18b contacts the rear end of the suspension groove 15e. The position of the fourth lens unit L4 is controlled by a pulse motor 23 that is controlled according to the focal length information, and the focal movement of the varifocal lens system is corrected. As a result, a zooming locus as shown in FIG. 1 is obtained. The pulse motor 23 is also controlled by subject distance information, and a focusing operation is executed.

  Thus, in the present embodiment, the second group moving cylinder (moving cylinder member) (moving cylinder member) (moving cylinder member) positioned inside the helicoid ring 12 in the cam groove C17 formed on the inner peripheral surface of the cam helicoid ring 12 that is rotationally driven. ) 17 cam followers 17c are fitted, and the second group moving cylinder 17 is guided straight by the first group moving cylinder 15. Inside the second group moving cylinder 17, there is an intermediate cylinder member (moving cylinder member) 25 whose forward end with respect to the second group moving cylinder 17 is regulated by the flange portion 25a coming into contact with the inner flange 17d in the optical axis direction. The male screw 26b of the second group frame (lens fixing frame) 26 fixed to the second lens group L2 is engaged with the female screw 25e of the intermediate cylinder member 25. The cam groove C17 of the cam helicoid ring 12 and the cam follower 17c of the second group moving cylinder 17 are components of a cam mechanism for moving the second group moving cylinder 17 forward and backward in the optical axis direction.

A third group moving cylinder 18 that supports the third lens unit L3 is located behind the second group moving cylinder 17, and the third group moving cylinder 18 includes an inner cylinder 15Y of the first group moving cylinder 15 and a second group moving cylinder 17. It is guided straight by. Further, between the intermediate cylinder member 25 and the third group moving cylinder 18, the intermediate cylinder member 25 is always moved to the forward end with respect to the second group moving cylinder 17, and the second group moving cylinder 17 and the third group moving cylinder 18 are moved. A compression coil spring (second spring member) 21 that is urged to move in a direction to be separated from each other is contracted.
When the cam helicoid ring 12 is rotated around the optical axis, the second group moving cylinder 17 and the third group moving cylinder 18 move in the front-rear direction, and the second lens group L2 and the third lens group L3 operate as a variable power lens. To do.

Behind the intermediate cylinder member 25 is disposed a light shielding frame (light shielding member) 27 including an annular light shielding portion (light shielding portion) 27a and holding legs 27b extending forward from the annular light shielding portion 27a at approximately 120 ° intervals. The hook portions 27c of the holding legs 27b are supported by the light shielding member holding holes 25c of the intermediate cylinder member 25. Further, a conical coil spring (first spring member) 28 is contracted between the second group frame 26 and the annular light shielding portion 27a, and always urges the light shielding frame 27 to move backward.

When the zoom lens barrel is in the photographing state, as shown in FIG. 13, the annular light shielding part 27a is moved rearward relative to the second group moving cylinder 17 by the conical coil spring 28, and the annular light shielding part. The entrance of harmful light is prevented by 27a. The position of the annular light-shielding portion 27a can be arbitrarily set by changing the length of each holding leg 27b in accordance with the characteristics of the zoom optical system and the like, so that the position of the intermediate cylindrical member 25 that supports the light-shielding frame 27 is set. The light shielding frame 27 can be installed without being restricted, and the degree of freedom in design is improved.
On the other hand, when the zoom lens barrel is moved to the accommodated state, as shown in FIG. 3, the annular light-shielding portion 27a is in contact with the third lens group moving cylinder (housing upon contact member) 18, against the biasing force of the conical coil spring 28 Thus, the annular light shielding portion 27 a moves in the opposite direction to the intermediate cylinder member 25 and approaches the second group moving cylinder 17. At this time, the hook portion 27c of each holding leg 27b advances to the inner flange 17d side through the inside of the cylindrical portion 17e of the second group moving cylinder 17, and the length dimension of each holding leg 27b in the optical axis direction is It is absorbed by the dimension of the cylindrical portion 17e in the optical axis direction.
Since the gap between the second group frame 26 and the annular light-shielding portion 27a that existed in the shooting state disappears during storage, the zoom lens barrel can be thinned during storage.

  Further, as described above, the light shielding frame 27 is linked with the conical coil spring 28, and the male screw 26b of the second group frame 26 and the female screw 25e of the intermediate cylinder member 25 during zooming adjustment performed by rotating the second group frame 26. It acts as a backlash remover. Zooming adjustment adjusts the position of the second lens unit L2 in the optical axis direction while observing the image position. Therefore, when such backlash removal is performed, accurate zooming adjustment can be performed. That is, the light blocking structure of the lens barrel can be used for backlash removal of a lens group that adjusts the position in the optical axis direction during assembly.

The zoom lens barrel described with reference to FIGS. 1 to 19 is an example to which the light blocking structure of the present invention is applied, and a zoom having a cam ring and a lens support cylinder regardless of whether the cam ring is a helicoid cam ring or not. Obviously, it is applicable to lens barrels in general.
Of course, the present invention can be applied to a retractable lens barrel that does not have a zoom function.

It is a figure which shows the zooming basic locus | trajectory of the zoom lens system to which the zoom lens barrel by this invention is applied. FIG. 2 is a half-cut perspective view showing a lens group and its lens frame of the zoom lens system. It is an upper half sectional view in the storage state of the zoom lens barrel according to an embodiment of the present invention. It is an upper half sectional view in the wide end infinity photographing state of the zoom lens barrel. It is a lower half sectional view in the tele end infinity photographing state of the zoom lens barrel. It is sectional drawing which follows the VI-VI line of FIG. It is sectional drawing which follows the VII-VII line of FIG. It is a disassembled perspective view of a part of the zoom lens barrel. It is a disassembled perspective view of the another part. It is a disassembled perspective view around the first group moving cylinder. It is a disassembled perspective view around the third group moving cylinder. It is a disassembled perspective view around the second group moving cylinder. It is an upper half sectional view around the second group moving cylinder. It is the disassembled perspective view seen from the back surface around the pulse motor supported by a fixed cylinder. FIG. 6 is an exploded perspective view around the fixed cylinder and a fourth lens group. It is an expanded view of the cam groove for 1 group of a cam helicoid cylinder, and the cam groove for a decoration cylinder. It is an expanded view which shows the rectilinear guide relationship of the 1st group moving cylinder, 2nd group moving cylinder, and 3rd group moving cylinder. FIG. It is an expanded view which shows the shape of the cam groove for 2 groups of a cam helicoid ring.

Explanation of symbols

C15 Cam groove for first group C16 Cam groove for decorative cylinder C17 Cam groove for second group (cam mechanism)
L1 1st lens group L2 2nd lens group L3 3rd lens group L4 4th lens group S Spring means 11 Fixed cylinder 11a Female helicoid 11b Straight guide groove 11c Inner surface recessed part 12 Cam helicoid ring 12a Male helicoid 12b Spur gear 12c Circumferential groove 12d rectilinear guide groove 13 drive pinion 14 rectilinear guide ring 14a rectilinear guide protrusion 14b bayonet protrusion 14c rectilinear guide groove 15 first group moving cylinder 15a cam follower 15b rectilinear guide protrusion 15c assembling groove 15d rectilinear guide groove 15e suspension groove 15f rectilinear guide protrusion 15X outside Cylinder 15Y Inner cylinder 15Z Flange wall 16 Decoration cylinder 16a Linear guide key 16b Cam follower 17 Second group moving cylinder (moving cylinder member) (moving cylinder)
17a Linear guide groove 17c Cam follower (cam mechanism)
17d Inner flange 17e Cylindrical portion 17f Straight guide groove 18 Third group moving barrel 18a Straight guide protrusion 18b Straight key 19 Compression coil spring 20 Shutter block 20a Retaining ring 21 Compression coil spring (second spring member)
22 4th group frame 22a Foot part 22b Guide bar 23 Pulse motor 23a Screw shaft 23b Nut member 24 1st group frame 25 Intermediate cylinder member 25a Flange part 25b Adhesive hole 25c Shading member holding hole 25d Guide projection 25e Female thread 26 Second group frame (lens Fixed frame)
26a Outer flange 26b Male screw 27 Shading frame (shading member)
27a Annular light shielding part 27b Holding leg 27c Retaining hook part 28 Conical coil spring (first spring member)
30 Barrier block 31 Barrier ring

Claims (3)

A retractable lens barrel having a lens system whose position changes between a shooting position and a storage position,
A lens fixing frame that fixes a lens group that adjusts the position in the optical axis direction during assembly;
A moving cylinder member that is screwed with the lens fixing frame and is moved along a predetermined locus;
A light shielding member that is supported by the movable cylinder member so as to be movable in the front-rear direction by restricting the retracted end and located behind the lens fixing frame ;
A first spring member which is contracted between the light shielding member and the lens fixing frame and which urges the light shielding member to move toward the rearward projecting end; and
When positioned at the storage position, the first spring member is compressed by contact with the light-shielding member biased rearward by the first spring member. Contact member;
A light shielding structure for a collapsible lens barrel, characterized by comprising: 2. The retractable lens barrel light-shielding structure according to claim 1, wherein the movable cylinder member includes a movable cylinder that is advanced and retracted in a direction of an optical axis by a cam mechanism in accordance with a zooming operation, and a forward end that is regulated by the movable cylinder. A retractable lens mirror comprising an intermediate cylinder member screwed to the lens fixing frame supported so as to be movable in the axial direction, and further comprising a second spring member that constantly biases the intermediate cylinder member forward. Light shielding structure of the tube. 3. A light shielding structure for a collapsible lens barrel according to claim 1 or 2, wherein at least the lens group fixed to the lens fixing frame is a variable power lens group.

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