This application claims priority to Japanese Patent Application No. 2019-035198 filed on Feb. 28, 2019. The entire disclosure of Japanese Patent Application No. 2019-035198 is hereby incorporated herein by reference.
The present disclosure relates to a light shielding unit and to a lens barrel comprising the same.
An imaging device such as a camera is provided with a plurality of lens groups, an aperture for adjusting the surface area of an opening through which light passes, a shutter unit, and so forth.
For example, Patent Literature 1 discloses a blade drive device comprising a plurality of blades disposed in a ring around a light passage path, and a drive ring for rotating these blades, in order to reduce upward warpage of the blade group. Each of the blades has an engaging portion that engages with a cam groove provided to the drive ring, and at least part of the cam groove is provided so as to be inclined outward in the radial direction of the drive ring.
Patent Literature 1: JP-A 2016-102830
Patent Literature 2: Japanese Patent No. 6,068,903
It is an object of the present disclosure to provide a light shielding unit capable of suppressing the warping of movable blades while affording smooth operation of the movable blades, as well as a lens barrel comprising this light shielding unit.
The light shielding unit according to the present disclosure comprises a first frame, a second frame, a plurality of movable blades, a drive ring, and a support. The first frame has a first frame having a first opening through which light passes. The second frame has a second opening through which light passes. The movable blades are disposed between the first frame and the second frame, a third opening through which the light that has passed through the first opening passes is formed in the movable blades, and these movable blades adjust the amount of light passing through by varying the size of the third opening. The drive ring is disposed between the first frame and the second frame and is rotatably driven when the movable blades are opened and closed. The support is provided to the first frame and/or the second frame and supports the movable blades in the direction of suppressing upward warpage of the movable blades in a state in which the movable blades have moved in the direction of reducing the size of the third opening.
The light shielding unit according to the present disclosure allows upward warpage of the movable blades to be suppressed, while affording smooth operation of the movable blades.
Knowledge on which this Disclosure is Based, etc.
The above-mentioned conventional blade drive device has the following problems.
With the device disclosed in the above-mentioned publication, part of the cam groove is inclined outward in the radial direction of the drive ring. Therefore, when the blades are driven, the bosses that move through the cam grooves are more likely to snag, which may cause the blades to malfunction.
Embodiments will now be described in detail with reference to the drawings as needed. However, some unnecessarily detailed description may be omitted. For example, detailed description of already known facts or redundant description of components that are substantially the same may be omitted. This is to avoid unnecessary repetition in the following description, and facilitate an understanding on the part of a person skilled in the art.
The applicant has provided the appended drawings and the following description so that a person skilled in the art might fully understand this disclosure, but does not intend for these to limit what is discussed in the patent claims.
The “subject side,” “image plane side,” and “light incident direction” referred to herein are shown in
A lens barrel 10 including an aperture unit (light shielding unit) 20 according to an embodiment of the present disclosure will now be described with reference to
Here, the lens barrel 10 in this embodiment a configuration for suppressing the upward warpage of aperture blades 23 that occurs in a state in which the aperture blades (movable blades) 23 constituting the aperture unit (light shielding unit) 20 are constricted (a state in which the opening diameter is reduced). Specific configurations of these will be described below.
The “direction of the upward warpage of the aperture blades 23” is the direction in which the distal ends of the aperture blades 23 overlap with each other (are woven together) and expand when the aperture blades 23 are rotated in the direction of constricting the opening diameter, and in this embodiment, it means the direction on the image plane side, as shown in
The lens barrel 10 according to this embodiment is an interchangeable lens barrel mounted on a camera body (not shown), and as shown in
The outer frame 11 is a substantially cylindrical member, constitutes the outer contour of the lens barrel 10, and encompasses various components such as the first lens L1 to the fifth lens L5.
The inner frame 12 is disposed on the inner peripheral surface side of the outer frame 11, and holds the first lens L1 on the furthest upstream side in the light incident direction, the second lens L2 downstream of that, and the third lens L3 downstream of that. The inner frame 12 also holds the actuator 13 and the guide pole 14 substantially to the side of the third lens L3; the fourth lens frame 15 downstream from the third lens L3, holding it so that it can move on the guide pole 14 in the optical axis X direction; the aperture unit 20 downstream of that; and the fifth lens L5 downstream of that.
The actuator 13 is a focus motor that is driven for focusing, and is held by the inner frame 12. When power is supplied from an electric circuit (not shown), the actuator 13 moves the fourth lens frame 15, which holds the fourth lens (focus lens) L4, back and forth along the guide pole 14 in the optical axis X direction.
The guide pole 14 is a rod-shaped member that guides the fourth lens frame 15, which is driven by the actuator 13, back and forth in the optical axis X direction. The guide pole 14 is held by the inner frame 12 and is disposed parallel to the optical axis X direction.
The fourth lens frame 15 is included in the lens group constituting the optical system of the lens barrel 10, holds the fourth lens L4, which moves in the optical axis X direction to adjust the focus of a light beam incident on the lens, that is, for focusing, and is driven by the actuator 13.
Alternatively, the fourth lens frame 15 holds the fourth lens L4, which moves in the optical axis X direction to adjust the focal length of the light beam incident on the lens, that is, for zooming, and is driven in conjunction with the zoom operation. That is, the fourth lens frame 15 is movable in the optical axis direction for focusing and zooming.
The mount 16 is the portion that is mounted on the camera body (not shown), is held by the outer frame 11, and is disposed the furthest downstream in the light incident direction inside the lens barrel 10.
As shown in
Of all the lens groups included in the lens barrel 10, the first lens L1 is disposed closest to the subject.
The second lens L2 is disposed at a position close to the image plane side (opposite side from the subject side) of the first lens L1 inside the inner frame 12.
The third lens L3 is disposed inside the inner frame 12 at a position that is a specific distance away from the second lens L2 to the image plane side.
The fourth lens L4 is a focus lens provided inside the inner frame 12, can be moved back and forth in the optical axis X direction by the actuator 13, and is held by the fourth lens frame 15.
The fifth lens L5 is disposed downstream from the aperture unit 20 in the optical axis X direction, and is the closest to the image plane of all the lens groups included in the lens barrel 10.
The aperture unit 20 is disposed between the fourth lens L4 and the fifth lens L5 inside the inner frame 12, and adjusts the amount of light incident on an imaging element provided on the camera body side by adjusting the surface area or the opening diameter through which light transmitted from the first lens L1 through the fourth lens L4 passes. The configuration of the aperture unit 20 will be described in detail below.
With the lens barrel 10 in this embodiment, as shown in
As shown in
As shown in
At this point, as shown in
When the aperture blades 23 are rotated from the state shown in
When the aperture blades 23 are further rotated from the state shown in
In the state shown in
As described above, the aperture unit 20 in this embodiment can adjust the amount of light passing through the open portion by rotating the aperture blades 23 between the closed state shown in
As shown in
As shown in
As shown in
More precisely, as shown in
Consequently, the drive ring 22 is sandwiched between the two optical axis direction restrictors 21e and 21f of the base plate 21, and therefore rotates around the optical axis X while its position in the optical axis direction is restricted. As a result, the drive ring 22 rotates the aperture blades 23 and adjusts the amount of light passing through the opening between the constricted and open states of the aperture blades 23, that is, between the minimum diameter and the maximum diameter.
As shown in
The opening 22b is an opening through which the light of the aperture unit 20 passes, and has a diameter or surface area substantially equal to or slightly larger than that of the opening 23e formed when the aperture blades 23 are fully opened. The opening 22b has a diameter or surface area substantially equal to or larger than the opening 27b in the fixed opening sheet 27 (discussed below).
As shown in
The protrusions 22c (first supports) have a convex shape protruding from the surface of the drive ring 22 in the direction of the upward warpage of the aperture blades 23, and support the vicinity of the bosses 23b (first main shafts) of the aperture blades 23.
The protrusions 22c preferably have a substantially arced shape, a substantially elliptical shape, a substantially parabolic shape, a substantially multidimensional curve shape, or a gentle curved shape in a cross section that includes the center axis of the through holes or the bosses 23c (first main shafts).
With these configurations, the aperture blades 23 can be smoothly moved without an increase in the drive load due to abrasion or catching, and at the same time, upward warpage due to the weaving together of the aperture blades can be efficiently suppressed.
The gear 22d is formed on part of the outer peripheral surface of the main body 22a so as to mesh with the gear 28a (see
The light blocker 22e is formed so as to protrude outward in the radial direction from a part of the outer peripheral surface of the main body 22a. When the drive ring 22 is rotationally driven to a certain position during the opening or closing of the aperture blades 23 (discussed below), the light blocker 22e is inserted between the light emitter and the light receiver of the photo interrupter 29a, and blocks the light emitted from the light emitter toward the light receiver (see
The aperture blades (movable blades) 23 are disposed downstream of the drive ring 22 in the light incident direction, as shown in
More precisely, as shown in
As shown in
Because the aperture blades 23 are thus molded using a material having relatively high rigidity, the amount of upward warpage (discussed below) can be suppressed.
The bosses 23b (first main shafts) are provided so as to protrude from the upper surfaces (the surfaces facing the drive ring 22) at one end (the first end) of each main body 23a, and serve as rotation shafts when the aperture blades 23 rotate. The bosses 23b (first main shafts) are inserted into through-holes formed in the center of the protrusions 22c of the drive ring 22, as described above. Accordingly, the bosses 23b (first main shafts) move in the circumferential direction when the drive ring 22 is rotationally driven in the opening or closing of the aperture blades 23 (discussed below).
The bosses 23c (first auxiliary shafts) are provided so as to protrude from the surfaces of the main body 23a on the opposite side from the bosses 23b (first main shafts) (the surfaces facing the cover 25). The bosses 23c (first auxiliary shafts) are inserted into cam grooves 25c (see
The distal ends 23d are free ends provided on the other end (second end) side of the main body 23a, and when the aperture blades 23 rotate around the bosses 23b (first main shafts), these distal ends 23d either move out into the opening so as to cover the opening, or retract from the opening.
The configuration of the aperture blades 23 and the opening/closing mechanism for rotating these blades will be described in detail below. In this embodiment, eleven aperture blades 23 are provided, for example.
As shown in
As shown in
As shown in
The opening 25b is an opening through which the light of the aperture unit 20 passes, and has a surface area equal to or slightly larger than that of the opening 23e formed when the aperture blades 23 are fully opened.
The cam grooves 25c are guide grooves formed in the main body 25a, and the above-mentioned bosses 23c (first auxiliary shafts) of the aperture blade 23 are inserted therein. Therefore, the cam grooves 25c are formed in the same number as the aperture blades 23 (eleven in this embodiment). When the drive ring 22 is rotationally driven and the aperture blades 23 move in the circumferential direction, the bosses 23c (first auxiliary shafts) move along the cam grooves 25c, whereby each of the plurality of aperture blades 23 is rotated.
In this state, the boss 23c (first auxiliary shaft) is inserted into the cam groove 25c as shown in
The wall 25d is a wall-shaped member disposed so as to cover a part of the outer peripheral portion of the main body 25a, and constitutes an oil intrusion prevention structure (discussed below) (see
The protrusion 25e is an annular portion disposed on the inner peripheral side of the upper surface of the main body 25a (the surface facing the aperture blades 23 and the sheet member 24), and is formed to protrude from the upper surface of the main body 25a. The protrusion 25e formed in an annular shape is disposed substantially concentrically with the opening 25b. The protrusion 25e comes into contact with a part of the aperture blades 23, and supports the aperture blades 23 from the opposite side from the subject side.
More specifically, as shown in
In an open state in which the aperture blades 23 are accommodated in the gap between the base plate 21 and the cover 25, the protrusion 25e is disposed at a position where three aperture blades 23 overlap.
On the other hand, since the protrusions 22c on the drive ring 22 side are provided near the rotation shafts (the bosses 23b (first main shafts)) of the aperture blades 23, they are disposed at a position overlapping one aperture blade 23 regardless of the rotation position of the aperture blades 23.
Accordingly, the protrusion 25e is formed to have a lower protruding height than the protrusions 22c so that the three aperture blades 23 can move easily.
The protrusion 25e (second support) is formed on the cover (second frame) 25, and is located near the opening of the aperture unit 20 or the opening 25b (second opening) of the cover (second frame) 25. Furthermore, the protrusion 25e (second support) is located outside the opening 27b of the fixed opening sheet 27 that determines the opening diameter or opening surface area of the aperture unit 20 when the aperture blades 23 are fully open, that is, on the side away from the center of the opening.
Furthermore, the protrusion 25e (the second support) is provided so as to be located more to the center axis side of the opening of the aperture unit 20 or the opening 25b (the second opening) of the cover (second frame) 25, than the protrusions 22c (first supports) of the drive ring 22, and to be in contact with the surface on the same side as the direction of upward warpage of the aperture blades 23.
Furthermore, the protrusion 25e (second support) is provided in an annular shape with respect to the center axis of the opening of the aperture unit 20 or the opening 25b (second opening) of the cover (second frame) 25.
Furthermore, the protrusion 25e (second support) preferably has a substantially arced shape, a substantially elliptical shape, a substantially parabolic shape, a substantially multidimensional curve shape, or a gentle curved shape in a cross section that includes the center axis of the opening of the aperture unit 20 or the opening 25b (second opening) of the cover (second frame) 25.
With these configurations, the aperture blades 23 can be smoothly moved without an increase in the drive load due to abrasion or catching, and at the same time, upward warpage due to the weaving together of the aperture blades can be efficiently suppressed.
As shown in
As shown in
The drive motor 28 is fixed to the base plate 21 by an attachment screw 28b (see
More specifically, the drive motor 28 rotates the gear 28a press-fitted to the rotation shaft, and thereby rotates the drive ring 22 around the optical axis X via the gear 22d disposed so as to mesh with the gear 28a.
The photo interrupter 29a has a light emitter and a light receiver, and is provided in order to sense the rotational position of the drive ring 22. The photo interrupter 29a is attached to the upper surface of the cover 25 (the surface on the subject side) as shown in
The FPC 29b is a flexible printed circuit board, and as shown in
The mechanism for opening and closing the eleven aperture blades 23 in the aperture unit 20 of this embodiment will now be described.
As described above, the aperture unit 20 in this embodiment rotates the eleven aperture blades 23 around their respective bosses 23b (first main shafts), thereby changing the surface area of the opening 23e formed in the center portion of the eleven aperture blades 23.
More specifically, the bosses 23b (first main shafts) of the eleven aperture blades 23 are inserted into the through-holes in the centers of the protrusions 22c formed on the drive ring 22. Meanwhile, the bosses 23c (first auxiliary shafts) of the aperture blades 23 are inserted into the cam grooves 25c formed in the cover 25, as shown in
Here, when the bosses 23c (first auxiliary shafts) are in the position shown in
The drive ring 22 is rotated around the optical axis X when the rotational drive force of the drive motor 28 is transmitted to the gear portion 22d via the gear 28a. Rotational position information about the drive ring 22 is sensed when the light blocker 22e provided integrally to the outer peripheral portion of the drive ring 22 passes through the photo interrupter 29a. This allows for adjustment of the opening diameter or opening surface area of the opening 23e of the aperture blades 23.
As shown in
This allows the surface area or the diameter of the opening 23e formed by the aperture blades 23 to be adjusted smaller or larger.
The aperture unit 20 in this embodiment comprises an upward warpage suppression structure in order to suppress upward warpage to the side on which the distal ends 23d of the aperture blades 23 are woven together when the aperture blades 23 are closing, as shown in
As shown in
At this point, if the aperture blades 23 are in such a warped state, there is the risk, for example, that they may come into contact with the lens L5 or the like disposed opposite from them, and that this will leave a contact mark on the lens L5 or the like. Furthermore, there is the risk that this upward warpage will cause the center position of the opening 23e formed by the aperture blades 23 to shift, and that the position on the optical axis X will be shifted, the result being that the designed optical performance cannot be exhibited.
In view of this, the aperture unit 20 in this embodiment comprises a structure for suppressing the upward warpage of the aperture blades 23 with a simple configuration, without increasing the number of parts.
More specifically, as shown in
The protrusions 22c and 25e are disposed on the drive ring 22 and the cover 25, respectively, so as to hit part of the aperture blades 23. The protrusions 22c and 25e respectively support the aperture blades 23 in the direction of suppressing upward warpage when the aperture blades 23 are woven together.
As mentioned above, eleven protrusions 22c, the same number as that of the aperture blades 23, are provided on the surface of the drive ring 22 facing the aperture blades 23. The protrusions 22c are disposed around all the holes into which the bosses 23b (first main shafts) of the eleven aperture blades 23 are inserted. As shown in
As described above, the protrusion 25e is provided in an annular shape on the surface of the cover 25 facing the aperture blades 23. As shown in
Consequently, in a state in which the aperture blades 23 have constricted (a state in which the opening diameter is reduced), the aperture blades 23 can hit the protrusions 22c and 25e to restrict deformation of the aperture blades 23.
Thus, with the configuration of the aperture unit 20 (solid line) in this embodiment, the amount of upward warpage of the aperture blades 23 toward the downstream side can be suppressed more effectively as compared to the aperture blade position in a configuration in which the protrusions 22c and 25e are not provided, as shown by the broken line in
As a result, it is possible to prevent problems attributable to the fact that the distal ends 23d of the aperture blades 23 hit the lens L5 or the like disposed downstream of the aperture unit 20 in the light incident direction.
Furthermore, with the aperture unit 20 in this embodiment, as shown in
Here, as shown in
Thus, as the warped portions of the aperture blades 23 are rotated from the substantially open state shown in
As described above, with the aperture unit 20 in this embodiment, when the aperture blades 23 are in a substantially open state as shown in
Consequently, from the state in which the opening 23e formed by the aperture blades 23 is at its largest to the state in which the opening 23e is at its smallest (
When the aperture blades 23 move in the direction of reducing the size of the opening 23e (third opening), the aperture blades 23 are moved in the same direction as the upward warpage so as to go beyond the imaginary plane constituting the opening 27b formed by the movable opening sheet 27 (fixed opening member) as the amount of upward warpage increases.
When the aperture blades 23 are in the fully opened state of the opening 23e (third opening), the fixed opening sheet 27 and the aperture blades 23 are in a state in which gaps are provided between them and they are not in contact with each other, and when the aperture blades 23 move in the direction of reducing the size of the third opening 23e, the aperture blades 23 approach the fixed opening sheet 27 as the amount of upward warpage increases.
When the aperture blades 23 move such that the size of the opening 23e (third opening) goes from its largest to its smallest, that is, from fully open to tightly constricted, the distal ends 23d of the aperture blades 23 pass through three regions as the amount of upward warpage increases in the optical axis X direction.
The first region is a region on the opposite side from the direction of upward warpage from the extension line Y2, the second region is a region between the extension line Y2 and the extension line Y1, and the third region is a region on the upward warpage direction side of the extension line Y1. The spacer 25f of the cover 25 is configured between the extension line Y2 and the extension line Y1, and forms the second region.
By providing the second region, even if the amount of upward warpage of the aperture blades 23 is large, some of the upward warpage to the inside of the aperture unit 20 in the optical axis X direction, that is, to the inside of the fixed opening sheet 27 in the optical axis X direction, can be absorbed and accommodated, so the aperture blades 23 are less likely to protrude outside of the aperture unit 20 in the optical axis X direction.
The second region is preferably thick in the optical axis X direction in order to minimize the amount of upward warpage, but if the second region is too thick, the aperture unit 20 ends up being too large. Therefore, the second region is preferably approximately equal to the size in the optical axis X direction of the blade chamber in which the aperture blades 23 are accommodated, or between approximately equal and approximately twice the size, or between approximately equal and approximately three times the size. Furthermore, when the aperture unit size is prioritized, the second region may be approximately half of the size in the optical axis X direction of the blade chamber in which the aperture blades 23 are accommodated, or between approximately half and approximately the same size, or between approximately half and approximately twice the size.
Thus, it is possible to prevent the position of the fixed opening diameter and the position of the aperture opening of the aperture blades 23 from being disposed at positions that are apart in the light incident direction.
The aperture unit 20 of this embodiment comprises a foreign matter intrusion prevention structure for preventing grease, foreign matter, and the like from entering the gap between the base plate 21 and the cover 25. This foreign matter intrusion prevention structure will be described below with reference to
The foreign matter intrusion prevention structure is constituted by a wall (second wall) 25d disposed on the outer peripheral side of the cover 25 shown in
As shown in
As shown in
With the aperture unit 20 in this embodiment, the foreign matter intrusion prevention structure is disposed on the outer peripheral side where grease infiltration is a concern, in order to prevent grease, foreign matter, or the like from coming into contact with the aperture blades 23 that move in the gap between the base plate 21 and the cover 25.
Here, the aperture unit 20 has a configuration in which the aperture blades 23 are sandwiched between the cover 25 and the base plate 21 in order to accommodate the aperture blades 23 and hold them in the optical axis X direction.
With this configuration, since a gap is formed between the base plate 21 and the cover 25, when a part to which grease or a foreign substance has adhered is disposed near the aperture unit 20, there is the risk that this grease or the like will stick to the aperture unit 20 and find its way into the interior of the aperture unit 20 through the gap. For instance, if grease that has come in through the gap sticks to the aperture blades 23, the drive load of the aperture blades 23 may increase so much that the blades will not rotate smoothly.
With the aperture unit 20 in this embodiment, the wall 21c and the wall 25d are provided to the portions where grease or the like is likely to adhere. More specifically, the wall 25d is provided to the cover 25, and the wall 21c is provided to the base plate 21.
The wall 21c and the wall 25d have a staggered overlapping structure in which they are provided on the upstream side and the downstream side in the light incident direction, respectively. This eliminates a gap that can be seen from the outer peripheral side of the aperture unit 20, and has the walls 21c and 25d disposed in a staggered layout, so it effectively prevents foreign substances such as grease from sticking to the aperture blades 23.
Also, the effect of preventing foreign matter such as grease from entering can be further improved by applying an oil-repellent component such as an oil barrier to a portion of the staggered structure constituted by the wall 25d and the wall 21c.
The aperture unit (light shielding unit) 120 according to Embodiment 2 of the present disclosure will now be described with reference to
The aperture unit 120 in this embodiment differs from the configuration of Embodiment 1 above in that it comprises aperture blades (movable blades, second blades) 123 having a different shape in addition to the aperture blades 23 described in Embodiment 1 above.
Components having the same functions and shapes as those Embodiment 1 above will be numbered the same and will not be described again.
That is, with the aperture unit 120 in this embodiment, the six aperture blades (movable blades, first blades) 23 shown in
As shown in
As shown in
As shown in
Since the aperture blades 123 are thus formed using a material having relatively high rigidity, the amount of upward warpage of the alternately disposed aperture blades 23 can be suppressed.
The boss 123b (second main shaft) is provided protruding from the upper surface (the surface facing the drive ring 22) at one end (first end) of the main body 123a, serving as the rotation shaft when the aperture blade 123 rotates. The boss 123b (second main shaft) is inserted into a through-hole formed at the center portion of the protrusion 22c on the drive ring 22 described above. Accordingly, the bosses 123b (second main shafts) move in the circumferential direction along with the rotational drive of the drive ring 22 during the opening or closing of the aperture blades 123 (discussed below).
The bosses 123c (second auxiliary shafts) are provided so as to protrude from the surface (the surface facing the cover 25) of the main body 123a on the opposite side form the bosses 123b (second main shafts). The bosses 123c (second auxiliary shafts) are inserted into the cam grooves 25c (see
The rotating portion 123d is provided on the other end (second end) side of the main body 123a, and when the aperture blade 123 rotates around the boss 123b (second main shaft), the rotating portion 123d moves in the gap between the base plate 21 and the cover 25.
With the aperture unit 120 in this embodiment, the aperture blades 23 and 123 having different shapes are alternately disposed in the circumferential direction.
Here, when the aperture blades 23 rotate to a state in which the opening diameter of the opening 123e is at its smallest (closed state), the distal ends 23d move from between the base plate 21 and the cover 25 to near the optical axis X, as shown in
At this point, as shown in
Meanwhile, when the aperture blades 123 rotate to a state in which the opening diameter of the opening 123e is at its smallest (closed state), the rotating portions 123d rotate within the gap between the base plate 21 and the cover 25, without coming out from the gap between the base plate 21 and the cover 25, as shown in
Therefore, unlike the aperture blades 23, even in a state in which the aperture blades 123 have constricted to reduce the opening diameter of the opening 123e, there is no upward warpage to the downstream side in the light incident direction in the aperture blades 123 by themselves.
At this point, just as with the aperture blades 23, the aperture blades 123 are driven open and closed when the bosses 123c (second auxiliary shafts) move along the cam grooves 25c provided to the cover 25, with the bosses 123b (second main shafts) inserted into the through-holes formed in the center of the protrusions 22c provided to the drive ring 22 serving as rotation shafts.
As described above, the aperture unit 120 in this embodiment is configured such that the aperture blades 23 shown in
Consequently, as shown in
Furthermore, using a combination of the aperture blades 23 and the aperture blades 123 as in this embodiment allows the drives load exerted on the drive motor 28, which is necessary for moving the rotating portion 123d in the gap between the base plate 21 and the cover 25, can be reduced as compared to a configuration in which the opening 123e is formed using just the aperture blades 123, for example.
With the configuration of the aperture unit 120 in this embodiment, as described above, the aperture blades 23 and the aperture blades 123 are used in combination, so that the amount of upward warpage of the aperture blades 23 to the downstream side in the light incident direction can be suppressed, and the load on the drive motor 28 can be reduced.
With the aperture unit 120 in this embodiment, as in Embodiment 1 above, the two protrusions 22c and 25e provided to the base plate 21 and the cover 25, respectively, hit a part of the aperture blades 23 and 123, allowing the amount of upward warpage of the aperture blades 23 and 123 to be suppressed.
However, as in this embodiment, when using a combination of the aperture blades 23 and 123 having different shapes, the aperture blades 123 have the function of suppressing the upward warpage of the aperture blades 23, and therefore the aperture unit 120 in this embodiment may have a configuration that does not include the two protrusions 22c and 25e described in Embodiment 1 above.
Embodiments of the present disclosure were described above, but the present disclosure is not limited to or by the above embodiments, and various modifications are possible without departing from the gist of the disclosure.
(A)
In Embodiments 1 and 2 above, an example was described in which a plurality of the flat aperture blades 23 and 123 were combined to adjust the surface area or the diameter of the openings 23e and 123e. However, the present disclosure is not limited to this.
For instance, as shown in
That is, with this configuration, as shown in
The direction in which the individual aperture blades are bent is not limited to the direction shown in
With the aperture unit 220 in this embodiment, just as in Embodiment 1 above, the two protrusions 22c (first support) and 25e (second support) provided to the base plate 21 and the cover 25, respectively, will hit a part of the aperture blades 223, thereby suppressing the amount of upward warpage of the aperture blades 223.
However, using the aperture blades 223 having a pre-bent shape as in this embodiment gives the aperture blades 223 themselves an upward warpage suppressing effect, so the aperture unit 220 in this embodiment may be configured not to include the two protrusions 22c and 25e described in Embodiment 1 above.
(B)
In Embodiments 1 and 2 above, an example of an aperture unit (light shielding unit) was described in which, in a state in which the aperture blades 23 and 123 are constricted (a state in which the opening diameter or the surface area is reduced), the aperture blades 23 and 123 warp upward toward the downstream side (image plane side) in the light incident direction. However, the present disclosure is not limited to this.
For instance, the aperture unit may be configured such that in their constricted state the aperture blades warp upward toward the upstream (subject side) in the light incident direction. The side where the distal ends of the aperture blades are woven together may be the subject side.
(C)
In Embodiments 1 and 2 above, an example was given of a configuration in which the protrusions 22c (first support) and 25e (second support) are provided to hit part of the aperture blades 23 and 123 and to suppress the upward warpage of the aperture blades 23 and 123 when the open portions of the aperture units 20 and 120 are closed. However, the present disclosure is not limited to this.
For instance, the support for suppressing the upward warpage of the aperture blades in the closed state of the open portions of the aperture units may be a flat member instead of a protruding shape. That is, the shape of the support does not need to be one that protrudes, and the support may be any member that supports the support in the direction of suppresses upward warpage.
(D)
In Embodiments 1 and 2 above, an example was given of a configuration in which the drive ring 22 and the cover 25 are respectively provided with the protrusions 22c (first support) and 25e (second support) as supports for suppressing upward warpage of the aperture blades 23 and 123 in the closed state of the opening portions of the aperture units 20 and 120. However, the present disclosure is not limited to this.
For instance, the configuration may be such that just one of the protrusions 22c (first support) and 25e (second support) is provided as a support for suppressing upward warpage of the aperture blades when the opening portion of the aperture units are closed.
(E)
In Embodiments 1 and 2 above, an example was given in which the plurality of annular protrusions 22c provided along the circumferential direction on the substantially annular drive ring 22 are used as supports (first supports). However, the present disclosure is not limited to this. For instance, the shape of the support (first support) is not limited to an annular protrusion, and may be some other shape such as a columnar shape or a polygonal shape.
(F)
In Embodiments 1 and 2 above, an example was given in which the plurality of annular protrusions 22c provided along the circumferential direction on the substantially annular drive ring 22 are used as supports (first supports). However, the present disclosure is not limited to this.
For instance, rather than going through, the holes in the drive ring 22 (drive ring) may have a bottom portion (first support) constituting the surface facing the aperture blades 23 side, that is, the surface that is across from the distal ends of the rotation shafts (first main shafts), and the bottom portion (first support) supports by hitting the distal ends of the rotation shafts (first main shafts).
In this case, the bottom (first support) is configured in a concave shape from the surface of the drive ring 22 (drive ring). The shape of the distal ends of the rotation shafts (first main shafts), or of the bottom portions (first supports), may be a flat shape, a spherical surface, a conical surface, some other rotationally symmetric surface, a polygonal pyramid shape, or the like.
(G)
In Embodiments 1 and 2 above, an example was given in which a single annular protrusion 25e provided on the inner diameter side of the substantially annular cover 25 is used as a support (second support). However, the present disclosure is not limited to this.
For instance, a plurality of arc-shaped or linear protrusions formed along the rotation path of the aperture blades may be used as the support (second support).
(H)
In Embodiments 1 and 2 above, as an example of a blade drive mechanism, an example was described in which the bosses 23b (first main shafts) and 123b (second main shafts) functioning as rotation shafts are provided on the aperture blades 23 and 123 side, and through-holes into which the bosses 23b (first main shafts) and 123b (second main shafts) are inserted are provided on the drive ring side. However, the present disclosure is not limited to this.
For instance, the configuration may be such that the rotation shafts are provided on the drive ring side, and holes 23 (first main holes) and holes 123 (second main holes) into which the rotary shafts are inserted are provided on the aperture blades 23 and 123 side.
In this case, protrusions (first supports) are disposed at substantially equal angular intervals in the circumferential direction so as to protrude in an annular shape from the surface of the main body that is in contact with the opposite surface from the direction of upward warpage of the aperture blades, the opposite side from the subject side (the cover 25 side), that is, from the surface on the image plane side. The protrusions hit a part of the aperture blades at the annular portion, and support the aperture blades from the subject side.
Also, rotation shafts are formed in the approximate center of the annularly protruding portions of the protrusions (first support), and are inserted into holes (first main holes) in the aperture blade. The protrusions (first support) are configured in a convex shape from the surface of the drive ring, and support the vicinity of the rotation shafts.
Therefore, the blade driving mechanism is not limited to the bosses 23b (first main shafts) and 123b (second main shafts) on the side of the aperture blades 23 and 123, and the through-holes into which the bosses 23b (first main shafts) and 123b (second main shafts) on the side of the drive ring 22 are inserted. Any drive mechanism may be used as long as the movable blades and the drive ring are engaged, and drive force is transmitted to the movable blades as the drive ring is rotationally driven.
(I)
In Embodiments 1 and 2 above, as an example of the cam mechanism, an example was described in which the bosses 23c (first auxiliary shafts) and 123c (second auxiliary shafts) that move along the cam grooves 25c are provided on the aperture blades 23 side, and the cam grooves 25c into which the bosses 23c (first auxiliary shafts) and 123c (second auxiliary shafts) are inserted are provided on the cover 25 side. However, the present disclosure is not limited to this.
For instance, the configuration may be such that cam grooves 23 (first auxiliary holes) and cam grooves 123 (second auxiliary holes) are provided on the aperture blades 23 and 123 side, and bosses that move along the cam grooves are provided on the cover side.
In the opening or closing operation of the aperture blades, when the drive ring is rotationally driven and the aperture blades move in the circumferential direction, this is accompanied by movement of the cam grooves (first auxiliary holes and second auxiliary holes) on the aperture blade side while being guided by the bosses on the cover side.
Consequently, the amount of light passing through the opening portion of the aperture unit 20 can be adjusted by varying the amount of rotation of the aperture blades according to the amount of rotation of the drive ring, and thereby varying the surface area or the diameter of the opening 23e formed by the aperture blades.
When the drive ring is rotationally driven, the relative positions of the bosses 23b (first main shafts) and 123b (second main shafts) and the cam grooves 23 (first auxiliary holes) and the cam grooves 123 (second auxiliary holes) with respect to the base plate 21 or the cover 25 are changed, the aperture blades rotate around the bosses 23b (first main shafts), and the size of the opening of the aperture unit 20 changes.
(J)
In Embodiments 1 and 2 above, as an example of the cam mechanism, an example was described in which through-holes into which the bosses 23b (first main shafts) and 123b (second main shafts) of the aperture blades 23 and 123 are inserted are provided on the drive ring 22 side, and the cam grooves 25c into which the bosses 23c (first auxiliary shafts) the bosses 123c (second auxiliary shafts) are inserted are provided on the cover 25 side. However, the present disclosure is not limited to this.
For instance, the configuration may be such that the cam grooves are provided on the drive ring side and the through-holes are provided on the cover side.
In the opening or closing operation of the aperture blades, when the drive ring is rotationally driven and the aperture blades move in the circumferential direction, the aperture blades rotate around the main bosses (first main shafts and second main shafts) inserted into the through-holes of the drive ring, and the auxiliary bosses (first auxiliary shafts and second auxiliary shafts) of the aperture blades move while being guided by the cam grooves on the drive ring side. Consequently, the amount of light passing through the opening portion of the aperture unit 20 can be adjusted by varying the amount of rotation of the aperture blades according to the amount of rotation of the drive ring, and thereby varying the surface area or the diameter of the opening 23e formed by the aperture blades.
When the drive ring is rotationally driven, the relative positions of the main bosses (first main shafts and second main shafts) and the auxiliary bosses (first auxiliary shafts and second auxiliary shafts) with respect to the base plate 21 or the cover 25 change, the aperture blades rotate around the main bosses 23b (first main shafts and second main shafts), and the size of the opening of the aperture unit 20 changes.
In this case, a plurality of protrusions, which are supports (first supports), are formed along the circumferential direction on the cover and protrude in an annular shape, and through-holes are disposed in the approximate centers of these annular protrusions. The protrusions, which are supports (first supports), protrude from the cover so as to be in contact with the surface on the opposite side from the direction of upward warpage of the aperture blades.
The protrusions, which are supports (second supports), are formed on the base plate (first frame) or the drive ring, and are located near the opening of the aperture unit, the opening of the base plate (first frame), or the opening of the drive ring. The protrusions, which are supports (second supports), are configured as parts disposed near the opening of the aperture unit. Furthermore, the supports (second supports) are located closer to the center axis side of the opening of the aperture unit than the supports (first supports), and are provided so as to be in contact with the surface on the same side as the direction of upward warpage of the aperture blades. Furthermore, the supports (second supports) are provided in an annular shape with respect to the center axis of the opening of the aperture unit. Furthermore, the supports (second supports) have a substantially arced shape, a substantially elliptical shape, a substantially parabolic shape, a substantially multidimensional curve shape, or a gentle curved shape in a cross sectional view that includes the center axis of the opening of the aperture unit.
(K)
The cam mechanism was described in Embodiments 1 and 2 and in (I) and (J) above. However, the cam mechanism is not limited to the above.
For instance, any cam mechanism may be used in which either a fixed frame (the base plate 21 or the cover 25) or a drive ring engages with the movable blades, and the movable blades move along with the rotation of the drive ring.
(L)
In Embodiment 1 above, an example was described in which the aperture unit 20 includes eleven movable aperture blades 23. However, the present disclosure is not limited to this.
For instance, the number of movable blades included in the aperture unit is not limited to eleven, and may instead be ten or fewer, or twelve or more.
(M)
In Embodiment 2 above, an example was described in which the aperture unit 120 includes six of the aperture blades 23 and five of the aperture blades 123. However, the present disclosure is not limited to this.
For instance, the aperture blades of different shapes included in the aperture unit are not limited to the above number, but may instead be a combination of five and six blades, or may be the same number of each, such as five and five, or six and six.
Also, the aperture blades of different shapes are not limited to two types, and may instead be made up of a combination of three or more types.
(N)
In the above embodiments, an example was described in which the content of the present disclosure is applied to the aperture unit 20 (light shielding unit) mounted on an interchangeable lens type of lens barrel 10. However, the present disclosure is not limited to this.
For instance, the light shielding unit is not limited to an interchangeable lens barrel, and can also be applied to a lens barrel that integrated with a camera body.
(O)
In the above embodiments, an example was described in which the content of the present disclosure is applied to the aperture unit (light shielding unit) 20 mounted on the lens barrel 10 disposed on the downstream side in the light incident direction of the fourth lens L4 functioning as a focus lens. However, the present disclosure is not limited to this.
The aperture unit 20 may be disposed on the upstream side in the light incident direction of the fourth lens L4 functioning as a focus lens.
In this case, the focus lens is disposed in the direction of the upward warpage of the aperture blades, and there is the risk of interference between the aperture blades and the focus lens during focusing, but if the content of the present disclosure is applied, the amount of upward warpage of the aperture blades is suppressed, so there is less risk of interference.
The light shielding unit disclosed herein has the effect of suppressing upward warpage of the movable blades while operating the movable blades smoothly, and can therefore be widely applied to a variety of devices such as optical devices.
Number | Date | Country | Kind |
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2019-035198 | Feb 2019 | JP | national |