JP2019053336A - Rotating member and holding member for light amount adjusting device, light amount adjusting device, and optical device - Google Patents

Abstract

A rotating member or the like for a light quantity adjusting device with improved sliding performance is provided. At least one rotating member (for example, drive ring 1) constituting a part of a light amount adjusting device that adjusts the amount of light in a light passage path is another built-in member in the light amount adjusting device. At least part of the surface side that comes into sliding contact with (for example, the holding member 2) is formed of the ceramic fiber reinforced layer 100. As shown in FIG. [Selection drawing] Fig. 1

Description

  The present invention relates to a built-in member incorporated as at least a part of a configuration of a light amount adjusting device mounted in an imaging device such as a camera, a light amount adjusting device provided with the built-in member, and an optical equipped with the light amount adjusting device. Relates to the device.

  2. Description of the Related Art Conventionally, for example, in a light amount adjusting device such as a diaphragm device, a configuration in which the shape of a diaphragm opening as a light passage opening is formed by a large number of diaphragm blades (light amount adjusting blades) is known (see Patent Document 1). Japanese Patent Application Laid-Open No. H10-260260 discloses a configuration in which a large number of diaphragm blades are rotated by a drive ring that is rotatable around a fixed opening formed in a pedestal.

Japanese Utility Model Publication No. 2-48928

  By the way, the drive ring incorporated in the light quantity adjusting device of the above-mentioned Patent Document 1 operates while contacting with other members when rotationally driven. As described above, since the component incorporated in the light amount adjusting device has the movable portion of the blade, sliding performance for smooth operation is required. Such a problem also occurs in a portion where friction occurs when moving even in a built-in member of the light amount adjusting device other than the drive ring.

  The present invention provides a rotating member and a holding member for a light amount adjusting device with improved sliding performance, a light amount adjusting device, and an optical device including the same.

  The rotating member for the light amount adjusting device according to the present invention rotates to rotate a plurality of blades for narrowing an opening through which the light passes by rotating around the optical axis in the light passage path of the light amount adjusting device. At least a part of the surface side that is in sliding contact with another built-in member in the light amount adjusting device is formed of a fiber-reinforced composite material, and the longitudinal direction of the reinforcing fiber is oriented in the surface direction of the rotating member It consists of a fiber reinforced layer having fiber orientation, the fiber orientation of the fiber reinforced layer circulates around the optical axis, and the core portion other than the fiber reinforced layer of the rotating member is the fiber reinforced composite material And the reinforcing fibers in which the fiber orientation of the reinforcing fiber is lower than the fiber orientation in the fiber reinforcing layer and the longitudinal direction faces the optical axis direction and the other reinforcing fibers. Complicated crossing The features. According to such an aspect of the present invention, a rotating member for a light amount adjusting device having high sliding performance can be realized.

  Moreover, in the said invention, the said rotation member is provided with several protrusion part along the rotation direction, and the said some protrusion part is a holding member which hold | maintains the said rotation member so that rotation is possible. The rotating member is rotatable with respect to the holding member in contact with an end face of the opening which is a part of the provided light passage path, and the fiber reinforced layer is at least the A surface of a plurality of protrusions is formed. According to such an aspect of the present invention, since the surface of the plurality of protrusions that become the sliding contact portion between the rotating member and the holding member is formed by the fiber reinforced layer, the sliding performance at the sliding contact portion is improves.

  Further, the holding member for the light amount adjusting device according to the present invention rotates around the optical axis in the light passage path of the light amount adjusting device, thereby rotating a plurality of blades for narrowing the aperture through which the light passes. A holding member for holding a moving member, wherein at least a part of the surface side in sliding contact with the rotating member is formed of a fiber reinforced composite material, and a fiber in which a longitudinal direction of the reinforcing fiber is oriented in a surface direction of the holding member It is composed of a fiber reinforced layer having orientation, and the fiber orientation of the fiber reinforced layer circulates around the optical axis, and the core portion other than the fiber reinforced layer of the holding member is integrated with the fiber reinforced composite material. And the reinforcing fiber having a lower fiber orientation than the fiber orientation in the fiber reinforced layer and having a longitudinal direction facing the optical axis direction and the other reinforcing fibers are complicated. Cross and before The holding member is provided with a plurality of protrusions along the rotating direction of the rotating member, and the rotating member is engaged with the rotating member while the plurality of protruding parts provided on the holding member are engaged with the rotating member. The moving member is rotatable with respect to the holding member, and the fiber reinforced layer forms surfaces of the plurality of protrusions. According to such an aspect of the present invention, a holding member for a light amount adjusting device having high sliding performance can be realized.

  In the present invention, the reinforcing fiber is preferably a ceramic fiber made of a titanium compound. According to such an aspect of the present invention, high sliding performance can be obtained using the fiber surface of titanium compound fibers such as potassium titanate.

  The present invention can be applied not only to the rotating member and the holding member for the light amount adjusting device described above, but also to the light amount adjusting device or an optical device provided with the light amount adjusting device, and should be widely applied. Is possible.

  For example, the light amount adjusting device of the present invention includes a plurality of blades for narrowing an opening through which light passes, a rotating member that rotates the plurality of blades, and a holding member that rotatably holds the rotating member. And at least a part of the surface side in sliding contact with the other of at least one of the rotating member and the holding member is formed of a fiber-reinforced composite material, and the longitudinal direction of the reinforcing fiber is the surface direction of the surface A core portion other than the fiber reinforced layer of the rotating member or the holding member provided with the fiber reinforced layer is formed integrally with the fiber reinforced composite material. In addition, the fiber orientation of the reinforcing fiber is lower than the fiber orientation in the fiber reinforced layer, and the reinforcing fiber whose longitudinal direction faces the optical axis direction and the other reinforcing fiber intersect in a complicated manner. And features. Thereby, sufficient sliding performance is obtained between the rotating member and the holding member, and stable light amount adjustment can be realized.

  ADVANTAGE OF THE INVENTION According to this invention, it becomes possible to provide the rotation member and holding member for light quantity adjustment apparatuses which improved sliding performance, the light quantity adjustment apparatus, and an optical apparatus provided with the same.

1 is an exploded perspective view showing an outline of a light amount adjustment device according to Embodiment 1. FIG. The front view which shows operation | movement of the light quantity adjustment apparatus which concerns on Embodiment 1 (blade fully open state). The front view which shows operation | movement of the light quantity adjustment apparatus which concerns on Embodiment 1 (blade fully closed state). 1 is a schematic cross-sectional view of a light amount adjustment device according to Embodiment 1. FIG. The figure which shows the surface fiber state in the rotation member of the light quantity adjustment apparatus which concerns on Embodiment 1. FIG. The figure which shows the cross-sectional fiber state in the rotating member of the light quantity adjustment apparatus which concerns on Embodiment 1. FIG. FIG. 5 is an exploded perspective view illustrating an outline of a light amount adjustment device according to a second embodiment. The front view which shows the outline of the light quantity adjustment apparatus which concerns on Embodiment 2 (blade fully open state). FIG. 6 is an exploded perspective view illustrating an outline of a light amount adjustment device according to a third embodiment. The front view which shows the outline of the light quantity adjustment apparatus which concerns on Embodiment 3 (blade fully open state).

  Hereinafter, the present invention will be described in detail based on embodiments.

(Embodiment 1)
FIG. 1 is an exploded perspective view of a light amount adjusting apparatus that is Embodiment 1 of the present invention. As shown in FIG. 1, the light amount adjustment device of the present embodiment is a device that is mounted on a photographing device that is an optical device such as a camera and adjusts the light amount at the time of photographing. In this embodiment, for example, the light amount adjusting device includes a drive ring 1 that is a rotating member, a holding member 2 that rotatably holds the drive ring, and a plurality of diaphragm blades 3 that are rotated by the drive ring 1. And a cam member 4 that rotatably holds a plurality of diaphragm blades 3 with the drive ring 1.

  That is, the light adjusting device of the present embodiment grips the plurality of diaphragm blades 3 between the drive ring 1 and the cam member 4, and further cams the drive ring 1 from the side opposite to the plurality of diaphragm blades 3. 4, the holding member 2 is joined. Accordingly, the drive ring 1 can be rotated between the holding member 2 and the cam member 4, and the plurality of aperture blades 3 are rotated by the rotation of the drive ring 1. Since the holding member 2 or the cam member 4 substantially covers the drive system composed of the drive ring 1 and the plurality of aperture blades 3 as described above, it has a role as a cover member.

  Hereinafter, each of the members (built-in members) constituting the light amount adjusting device will be described in detail.

  In FIG. 1, reference numeral 1 denotes a drive ring formed in a ring shape. An opening 1 a is formed at the center of the drive ring 1. The drive ring 1 includes shaft hole portions 1b to 1h formed at seven locations in the circumferential direction, protrusions 1i that are a plurality of projection portions divided into seven in the circumferential direction, and a portion in the circumferential direction. And formed gear portion 1j. A light shielding portion 1k is formed at one place in the circumferential direction of the drive ring 1.

  Reference numeral 2 denotes a holding member formed in a ring shape. In the center of the holding member 2, an opening 2 a communicating with the opening 1 a of the drive ring 1 is formed. Further, the inner peripheral surface 2b of the opening 2a is a surface with which the drive ring 1 is slidably contacted as described later.

  Reference numeral 3 denotes a diaphragm blade serving as a light amount adjusting blade. In the present embodiment, a case where seven diaphragm blades 3 are used will be described. However, the present invention can be applied to a diaphragm device using a plurality of three or more diaphragm blades 3.

  Further, the diaphragm blade 3 has a first shaft portion 3a serving as a rotation center axis and a second shaft portion 3b serving as a driven shaft to which a driving force for rotation is input on opposite surfaces. The blade portion 3c is formed in a tapered shape toward the tip. The blade portions 3c of the diaphragm blades 3 are portions that shield light by moving toward the light passage path.

  Reference numeral 4 denotes a cam member that is formed in a ring shape and guides the movement of each diaphragm blade 3, and also serves as a base member of the light amount adjusting device in the present embodiment. In the center of the cam member 4, an opening 4 a that communicates with the opening 1 a of the drive ring and the opening 2 a of the holding member 2 is formed. The cam member 4 is formed with cam groove portions 4b to 4h at seven places in the circumferential direction. Furthermore, a hole 4 i and a motor mounting portion 4 j are provided at one place in the circumferential direction of the cam member 4.

  Reference numeral 5 denotes a stepping motor for rotationally driving the drive ring 1. A pinion gear 6 is attached to the output shaft of the stepping motor 5 so as to rotate integrally with the output shaft. The stepping motor 5 is fixed to the motor mounting portion 4j of the cam member 4, and the pinion gear 6 passes through the hole portion 4i of the cam member 4 and meshes with the gear portion 1j of the drive ring 1. Note that the stepping motor 5 may be fixed to the holding member 2. The drive ring 1, the cam member 4, the stepping motor 5 and the pinion gear 6 constitute a drive mechanism of the light amount adjusting device of this embodiment.

  Reference numeral 7 denotes a position sensor, which is composed of, for example, a photo interrupter. When the light shielding portion 1k formed on the drive ring 1 enters between the light projecting portion and the light receiving portion of the position sensor 7, it can be detected that the drive ring 1 is in its initial position (predetermined position). The initial position here is a position where the diameter (size) of the aperture opening formed by the plurality of aperture blades 3 becomes a predetermined open aperture diameter. By counting the number of drive pulse signals given to the stepping motor 5 with the initial position detected by the position sensor 7 as a reference, the aperture diameter of the diaphragm can be controlled and the amount of light can be adjusted.

  The holding member 2 forms a space in which the diaphragm blade 3 and the drive ring 1 are arranged in this order between the holding member 2 and is fixed to the cam member 4 so that the rotating member 1 and the diaphragm blade with respect to the cam member 4 are fixed. 3 is prevented from falling off. The ridge 1i formed on the drive ring 1 is rotatably inserted into the opening 2a of the holding member 2. The drive ring 1 is rotatable in the circumferential direction (the direction around the optical axis) by sliding the outer peripheral surfaces of the plurality of protrusions 1 i with respect to the inner peripheral surface 2 b of the opening 2 a of the holding member 2. Supported. In addition, as a material which forms such a holding member 2, the polycarbonate composite material which added glass flakes to polycarbonate resin etc. are mentioned, for example.

  Further, the first shaft portions 3a of the diaphragm blades 3 are rotatably inserted into shaft hole portions 1b to 1h formed in the drive ring 1, respectively. On the other hand, the second shaft portion 3b is inserted into cam groove portions 4b to 4h formed in the cam member 4, respectively.

  When the stepping motor 5 fixed to the cam member 4 is driven and the pinion gear 6 rotates, the drive ring 1 in which the gear portion 1j is engaged with the pinion gear 6 also rotates. Thereby, the diaphragm blade 3 moves the second shaft portion 3b along the cam groove portions 4b to 4h of the cam member 4 (that is, the second shaft portion 3b receives a driving force from the cam groove portions 4b to 4h), It rotates around the first shaft portion 3a.

  The diaphragm blades 3 are arranged at equal intervals in the circumferential direction, that is, annularly arranged so as to surround the light passage path, and the respective blade portions 3c overlap with the blade portions of other diaphragm blades, A diaphragm aperture which is a light passage aperture is formed inside. Then, when the diaphragm blade 3 rotates, the overlapping amount of the blade portion 3c is changed, and the aperture diameter of the diaphragm is continuously changed, so that the amount of light passing therethrough can be adjusted.

  In FIG. 2, the figure from the holding member 2 side of the light quantity adjustment apparatus comprised as mentioned above is shown (blade fully open state). FIG. 3 shows a blade fully closed state of the light amount adjusting device in FIG. When the drive ring 1 in the present embodiment is rotated, the plurality of diaphragm blades 3 engaged with the drive ring 1 and the cam member 4 are in a fully opened state of the diaphragm blades 3 shown in FIG. 2 (a state where the light passage opening is opened). 3 to the fully closed state (state in which the light passage opening is closed) of the diaphragm blade 3 shown in FIG. Thus, when the drive ring 1 rotates, the several protrusion part 1i of the drive ring 1 slides with respect to the internal peripheral surface 2b of the opening part 2a of the holding member 2 (refer FIG. 4). Therefore, as the drive ring 1 rotates, friction is generated between the protrusion 1i and the inner peripheral surface 2b of the opening 2a.

  Here, in the present embodiment, the built-in member of the light amount adjusting device in which such friction occurs, for example, the drive ring 1 is entirely formed of a ceramic fiber reinforced composite material. Specifically, the drive ring 1 has a ceramic fiber reinforced layer 100 having a fiber orientation in which the longitudinal direction of the ceramic fibers contained in the ceramic fiber reinforced composite material is substantially oriented in the surface direction of the drive ring 1.

  This ceramic fiber reinforced layer 100 is mainly composed of a resin contained in a ceramic fiber reinforced composite material and dispersed fine ceramic fibers. In the ceramic fiber reinforced layer 100, the ceramic fibers are substantially oriented in the surface direction of the drive ring 1. For example, the ratio in which the longitudinal direction of the ceramic fibers is oriented in the surface direction of the drive ring 1 is greater. , Indicating that the ratio is relatively higher than the ratio of the thickness direction. Thus, when the ceramic fiber reinforced layer 100 has the above fiber orientation, high sliding performance between the drive ring 1 and another member (the holding member 2 in the present embodiment) can be obtained. Since the fiber orientation of the ceramic fiber reinforced layer 100 is substantially uniform in the plane direction, the resin portion supporting the ceramic fiber is scraped off from the sliding contact surface, and the outer peripheral surface (side surface) of the ceramic fiber is slid as it is. Even if it appears on the contact surface, since the outer peripheral surface of the ceramic fiber is in the surface direction of the sliding contact surface, each ceramic fiber can be effectively prevented from lowering the slidability. High slidability with this member can be sufficiently secured.

  For example, even if the resin portion of the ceramic fiber reinforced layer 100 is scraped on the surface side of the drive ring 1 due to friction generated between the drive ring 1 and the holding member 2 as the drive ring 1 is rotated, the remaining ceramic fibers are not Since it is oriented in the surface direction, the holding member 2 and the outer peripheral surface along the longitudinal direction of the ceramic fiber are substantially in sliding contact. That is, the outer peripheral surface of each ceramic fiber that appears on the surface of the ceramic fiber reinforced layer 100 becomes a sliding contact surface, and the high sliding performance of the drive ring 1 between the drive ring 1 and the holding member 2 is maintained over a long period of time. Can be maintained. Further, when a protective film is formed on the surface of the ceramic fiber reinforced layer 100 by painting, the surface of the protective film becomes a sliding contact surface at the beginning of use, and after the protective film is scraped, the surface of the ceramic fiber reinforced layer ( (Resin surface) becomes the sliding contact surface, and then the surface on which the outer peripheral surface of the ceramic fiber appears becomes the sliding contact surface after the resin surface is scraped. In addition, when not providing a protective film, the surface of the ceramic fiber reinforcement layer 100 turns into a slidable contact surface.

  The ceramic fiber reinforced layer 100 can be produced, for example, by molding a ceramic fiber reinforced composite material, and the dimensions (length, diameter, etc.) of the ceramic fiber, pressure and temperature during molding, etc. It is possible to form a desired fiber orientation by appropriately adjusting.

Here, the ceramic fiber reinforced composite material will be described. Examples of the ceramic fiber reinforced composite material include composite materials of ceramic fibers such as potassium titanate fibers and resin materials such as polycarbonate. The potassium titanate fiber is represented by the general formula K ₂ O · nTiO ₂ . In addition, when ceramic fibers are used, for example, an average fiber diameter of 0.3 to 0.6 μm and an average fiber length of 10 to 20 μm and extremely fine potassium titanate fibers (manufactured by Otsuka Chemical: 8 potassium titanate fibers) are used. It is effective in forming fiber orientation in the form. That is, in the present invention, if ceramic short fibers are used as the ceramic fibers, it is advantageous in forming the fiber orientation. That is, the ceramic fiber reinforced layer is preferably a ceramic short fiber reinforced layer in order to ensure high sliding performance. In particular, when ceramic short fibers are used, the fiber orientation is further improved and the surface roughness of the sliding contact surface can be kept small, so that high sliding performance can be obtained. Furthermore, the ceramic fiber preferably has, for example, high strength, high elasticity, and a high aspect ratio. This is because it exhibits excellent reinforcement performance. In addition, even if the ceramic fiber other than the potassium titanate fiber, other titanium compound fibers may be used as long as the fiber length is relatively short and the properties such as high strength and high elasticity are satisfied. Ceramic fiber may be used.

  In terms of Mohs hardness, which is an index of hardness, for example, 6 for carbon fiber and 7 for glass fiber, whereas potassium titanate fiber (manufactured by Otsuka Chemical: 8 potassium titanate fiber) is 4 and flexible. It is difficult to wear the sliding member. In the present embodiment, since the sliding performance of the drive ring 1 with respect to the holding member 2 is improved, it is possible to effectively prevent the holding member 2 from being scraped from the polycarbonate composite material by friction.

  In the present embodiment, as the ceramic fiber to be contained in the ceramic fiber reinforced layer 100, for example, the fiber surface is not subjected to a conductive treatment, and the fiber surface is formed by a ceramic material itself such as potassium titanate. By using the fiber surface as a sliding contact surface, high sliding performance can be obtained.

  Here, FIG. 5 shows a schematic surface state of a molded member using the above-described ceramic fiber reinforced composite material. As shown in FIG. 4, since the longitudinal direction of the ceramic fiber F that is relatively softer than the conventional carbon fiber or glass fiber is oriented on the surface, high sliding performance can be obtained, and the holding member 2 It is possible to effectively reduce wear due to wear.

  FIG. 6 shows a schematic cross-sectional view of a molded member using the above-described ceramic fiber reinforced composite material. As shown in FIG. 6, the surface portion is oriented in the surface direction, but the core portion other than the ceramic fiber reinforced layer 100 has a matrix structure M of ceramic fibers, so that the ceramic fibers are in the thickness direction. As a result, the rigidity of the entire drive ring 1 can be sufficiently ensured. Thereby, since the drive ring 1 can be shape | molded thinly, the weight reduction of the drive ring 1 and the performance of rotational drive can be improved.

  Hereinafter, the present invention will be described in detail while comparing Examples and Comparative Examples.

<Example 1>
The drive ring of Example 1 is driven using a ceramic fiber composite material (commercial grade: CT112N / manufactured by Otsuka Chemical) obtained by adding 5% by weight of ceramic fiber (potassium titanate fiber) to polycarbonate (PC) resin. A ring 1 (no coating) was prepared, and a material obtained by adding 20% by weight of glass flakes to polycarbonate resin was used for the holding member 2 and incorporated in the above light amount adjusting device, and a diaphragm operation durability test was performed. As a result, as shown in Table 1, the operation and drawing accuracy were good even after 1 million operations, and there was no noticeable wear on the external appearance of the drive ring 1 and the holding member 2. In addition, the drive ring 1 of Example 1 was able to achieve high durability exceeding 1 million operations even without painting.

<Example 2>
The drive ring of Example 2 is driven using a ceramic fiber composite material (commercial grade: CT132NC / manufactured by Otsuka Chemical) obtained by adding 15% by weight of ceramic fiber (potassium titanate fiber) to polycarbonate (PC) resin. A ring 1 (no coating) was prepared, and a material obtained by adding 20% by weight of glass flakes to polycarbonate resin was used for the holding member 2 and incorporated in the above light amount adjusting device, and a diaphragm operation durability test was performed. As a result, as shown in Table 1, the operation and drawing accuracy were good even after 1 million operations, and there was no noticeable wear on the external appearance of the drive ring 1 and the holding member 2. Moreover, in the drive ring 1 of this Example 3, even if there was no painting, the high durability exceeding 1 million times operation | movement was able to be implement | achieved.

<Comparative Example 1>
Subsequently, Comparative Example 1 will be described for reference. As a driving ring of Comparative Example 1, a driving ring (no coating) was prepared using a glass fiber composite material obtained by adding 20% by weight of glass fiber to polycarbonate resin, and 20% by weight of glass flake was added to polycarbonate resin. The material obtained in this manner was used for the holding member 2 and incorporated in the light amount adjusting device described above, and a diaphragm operation durability test was performed. As a result, as shown in Table 1, both the drive ring and the holding member were worn and the material was scraped after 150,000 operations.

<Comparative example 2>
As a driving ring of Comparative Example 2, a driving ring (without coating) was prepared using a material obtained by adding 15% by weight of carbon fiber to polycarbonate resin, and obtained by adding 20% by weight of glass flakes to polycarbonate resin. The obtained material was used for the holding member 2 and incorporated in the light amount adjusting device described above, and a diaphragm operation durability test was performed. As a result, as shown in Table 1, both the drive ring and the holding member were worn and the material was scraped after 150,000 operations.

<Comparative Example 3>
As a driving ring of Comparative Example 3, a driving ring (without coating) was prepared using a material obtained by adding 15% by weight of carbon fiber to polycarbonate resin, and 15% by weight of carbon fiber was added to polycarbonate resin. The obtained material was used as a holding member and incorporated in the light amount adjusting device described above, and a diaphragm operation durability test was performed. As a result, as shown in Table 1, both the drive ring and the holding member were worn out and the material was scraped by 50,000 operations.

<Comparative example 4>
As a driving ring of Comparative Example 4, a driving ring (without coating) was prepared using a material obtained by adding 15% by weight of carbon fiber to polycarbonate resin, and 20% by weight of glass fiber was added to polycarbonate resin. The obtained material was used as a holding member and incorporated in the light amount adjusting device described above, and a diaphragm operation durability test was performed. As a result, as shown in Table 1, both the drive ring and the holding member were worn out and the material was scraped by 50,000 operations.

<Comparative Example 5>
As a driving ring of Comparative Example 5, a driving ring (without coating) was prepared using a material obtained by adding 20% by weight of glass fiber to polycarbonate resin, and 20% by weight of glass fiber was added to polycarbonate resin. The obtained material was used as a holding member and incorporated in the light amount adjusting device described above, and a diaphragm operation durability test was performed. As a result, as shown in Table 1, both the drive ring and the holding member were worn out and the material was scraped by 50,000 operations.

  Each embodiment described above is only a representative example, and various modifications and changes can be made to each embodiment in carrying out the present invention.

(Embodiment 2)
FIG. 7 is an exploded perspective view showing an outline of the light amount adjusting apparatus according to the second embodiment. FIG. 8 shows a front view (blade fully open state) showing an outline of the light amount adjusting device of FIG. As shown in FIGS. 7 and 8, in the light amount adjustment device of the present embodiment, an annular protrusion 11 that is a cylindrical protrusion is provided at the periphery of the opening 10 a of the drive ring 10. Except for the sliding contact with the inner peripheral surface 20b (the convex portion 20c) that defines the opening 20a of the holding member 20, the second embodiment is the same as the first embodiment described above. 7 and 8, the same parts as those in the first embodiment are denoted by the same reference numerals, and redundant description is omitted.

  Specifically, in the present embodiment, the surface of the annular protrusion 11 of the drive ring 10 is constituted by the ceramic fiber reinforced layer 100. On the other hand, the holding member 20 is provided with seven convex portions 20c at substantially equal intervals on the inner peripheral surface 20b of the opening 20a. Each convex portion 20c is provided so as to protrude from the inner peripheral surface 20b of the opening 20a toward the light passing path side, and the surface thereof is an R surface. In the present embodiment, when the drive ring 10 is rotated, the annular protrusion 11 of the drive ring 10 comes into sliding contact with the convex portion 20 c of the holding member 20. At this time, in this embodiment, since the part which comprises the surface of the side which contacts the convex part 20c in this annular projection part is comprised by the ceramic fiber reinforcement layer 100, similarly to Embodiment 1 mentioned above, High sliding performance can be obtained.

(Embodiment 3)
FIG. 9 is an exploded perspective view showing an outline of the light amount adjusting apparatus according to the third embodiment. Further, FIG. 10 shows a front view (blade fully open state) showing an outline of the light amount adjusting device of FIG. As shown in FIGS. 9 and 10, in the light amount adjustment device of the present embodiment, an annular protrusion 11 that is a cylindrical protrusion is provided at the periphery of the opening 10 a of the drive ring 10. The second embodiment is the same as the second embodiment described above except that it comes into sliding contact with the inner peripheral surface 2b that defines the opening 2a of the holding member 2. 9 and 10, the same parts as those in the first or second embodiment are denoted by the same reference numerals, and redundant description is omitted.

  Specifically, in the present embodiment, the surface of the annular protrusion 11 of the drive ring 10 is constituted by the ceramic fiber reinforced layer 100. In this embodiment, the annular protrusion 11 of the drive ring 10 and the inner peripheral surface 2b of the holding member 2 are in sliding contact with each other. Even in this case, in the present embodiment, the portion constituting the surface of the annular projecting portion 11 that is in sliding contact with the inner peripheral surface 2b of the holding member 2 is configured by the ceramic fiber reinforced layer 100, and thus described above. As in the first or second embodiment, high sliding performance can be obtained.

(Other embodiments)
As mentioned above, although this invention was demonstrated in detail based on each Embodiment 1-3, this invention is not limited to each Embodiment 1-3 mentioned above. For example, in the first embodiment described above, the case where the ceramic fiber reinforced layer 100 is applied on the drive ring 1 side has been described. However, the present invention is of course not limited thereto, and for example, contacts the drive ring 1 of the holding member 2. At least the ceramic fiber reinforced layer 100 may be applied to the portion to be applied, and this may also be applied to the second and third embodiments.

  Moreover, in Embodiment 1 mentioned above, although the case where the ceramic fiber reinforcement layer 100 was applied with respect to one drive ring 1 among the drive ring 1 and the holding member 2, of course, this invention is not limited to this, For example, you may apply the ceramic fiber reinforcement layer 100 to each of the part which mutually contacts in both the drive ring 1 and the holding member 2. FIG.

  In addition, the ceramic fiber reinforced layer 100 described above may be provided as appropriate only in the portion in sliding contact between the built-in members of the light amount adjusting device, or the entire built-in member may be formed of a ceramic fiber reinforced composite material.

DESCRIPTION OF SYMBOLS 1 Drive ring 2 Holding member 3 Diaphragm blade 4 Cam member 5 Stepping motor

Claims (6)

A rotating member that rotates a plurality of blades for narrowing an opening through which light passes by rotating around the optical axis in the light passage path of the light amount adjusting device,
At least a portion of the surface side in sliding contact with the other built-in member in the light amount adjusting device is formed of a fiber reinforced composite material and has a fiber orientation in which the longitudinal direction of the reinforcing fiber is oriented in the surface direction of the rotating member. Consisting of a fiber reinforced layer,
The fiber orientation of the fiber reinforced layer circulates around the optical axis,
The core portion other than the fiber reinforced layer of the rotating member is integrally formed of the fiber reinforced composite material, and the fiber orientation of the reinforcing fiber is lower than the fiber orientation in the fiber reinforced layer. The rotating member for the light amount adjusting device, wherein the reinforcing fiber whose longitudinal direction is directed to the optical axis direction and the other reinforcing fiber intersect in a complicated manner. The rotating member is provided with a plurality of protrusions along the rotating direction,
The plurality of protrusions are in contact with an end surface of an opening that is a part of the light passage path provided on a holding member that rotatably holds the rotating member, and the rotating member is in contact with the end surface. , Is rotatable with respect to the holding member,
The rotating member for a light amount adjusting device according to claim 1, wherein the fiber reinforced layer forms at least surfaces of the plurality of protrusions. A holding member that holds a rotating member that rotates a plurality of blades for narrowing an opening through which light passes by rotating around the optical axis in the light passage path of the light amount adjusting device,
At least a portion of the surface side in sliding contact with the rotating member is formed of a fiber reinforced layer formed of a fiber reinforced composite material and having a fiber orientation in which the longitudinal direction of the reinforcing fiber is oriented in the surface direction of the holding member,
The fiber orientation of the fiber reinforced layer circulates around the optical axis,
The core portion other than the fiber reinforced layer of the holding member is integrally formed with the fiber reinforced composite material, and the fiber orientation of the reinforcing fibers is lower than the fiber orientation in the fiber reinforced layer, The reinforcing fiber whose longitudinal direction is directed to the optical axis direction and the other reinforcing fiber intersect in a complicated manner,
The holding member is provided with a plurality of protrusions along the rotation direction of the rotation member,
In a state where the plurality of protrusions provided on the holding member are engaged with the rotating member, the rotating member is rotatable with respect to the holding member,
The holding member for a light amount adjusting device, wherein the fiber reinforced layer forms surfaces of the plurality of protrusions.   The rotating member for a light amount adjusting device according to claim 1, wherein the reinforcing fiber is a ceramic fiber made of a titanium compound. A plurality of blades for narrowing the aperture through which the light passes;
A rotating member for rotating the plurality of blades;
A holding member that rotatably holds the rotating member;
A fiber in which at least a part of the surface side in sliding contact with the other of at least one of the rotating member and the holding member is formed of a fiber-reinforced composite material, and the longitudinal direction of the reinforcing fiber is oriented in the surface direction of the surface It consists of a fiber reinforced layer with orientation,
Of the rotating member or the holding member provided with the fiber reinforced layer, the core portion other than the fiber reinforced layer is integrally formed of the fiber reinforced composite material, and the fiber orientation in the fiber reinforced layer And the reinforcing fiber having a low fiber orientation of the reinforcing fiber and having a longitudinal direction facing the optical axis direction and the other reinforcing fiber intricately intersect with each other.   An optical device comprising the light amount adjusting device according to claim 5.

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