JP2019219494A - Light-amount adjusting apparatus and optical instrument - Google Patents

Abstract

To provide a light-amount adjusting apparatus and an optical instrument that has a light-amount adjusting blade having high sliding property without forming a linear contact part in a total region of the light-amount adjusting blade.SOLUTION: A light-amount adjusting apparatus 100, in which each of a plurality of light-amount adjusting blades 103 forms a light passage opening by overlapping with other light-amount adjusting blades 103, and size of the light passage opening is changed due to rotating of the plurality of light-amount adjusting blades, is provided. The plurality of light-amount adjusting blades 103 comprise: a blade part 203 that forms a marginal part of the light passage opening; and a partial contact part 205 that is formed at a region of a portion of the blade part 203 such that contact area contacted with the blade part 203 of the other light-amount adjusting blade is decreased, and the partial contact part 205 is provided in a region contacting with the other light-amount adjusting blade 103 when at least the light passage opening has a minimum diaphragm aperture.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a light amount adjusting device and an optical device for adjusting a light passing amount.

  An optical device such as a camera is provided with a plurality of aperture blades in order to adjust the amount of light that reaches the imaging surface. The plurality of aperture blades are configured to be rotatable, and by rotating the plurality of aperture blades, the size of the opening through which light passes changes. In a diaphragm device in which an aperture of an optical system is defined by a plurality of light-shielding wings overlapping each other, a technique has been proposed in which the light-shielding wings include a linear contact portion having a contact surface that comes into contact with an adjacent member adjacent thereto (Patent) Reference 1).

JP 2013-217984 A

  The light amount adjusting device has a plurality of light amount adjusting blades arranged in a ring shape, and the size of the opening changes by rotating each light amount adjusting blade. Here, when each light amount adjusting blade rotates, sliding friction occurs due to contact with other light amount adjusting blades. In the technique of Patent Document 2, in order to reduce sliding friction, a plurality of linear contact portions are formed in a direction intersecting each other over the entire surface of two overlapping light-shielding wings among the plurality of light-shielding wings. .

  However, if a linear contact portion is formed over the entire area of the light amount adjusting blade as in Patent Literature 1, the flowability of the resin decreases when integrally molded with a synthetic resin. Further, when the linear portion is formed separately, the processing area increases.

  The present invention provides a light amount adjusting device and an optical apparatus having a light amount adjusting blade having high slidability without forming a linear contact portion over the entire area of the light amount adjusting blade.

  In order to solve the above problem, the light amount adjusting device according to the present invention is configured such that each of the plurality of light amount adjusting blades overlaps with another light amount adjusting blade to form a light passage opening, and the plurality of light amount adjusting blades rotates. A light amount adjusting device in which the size of the light passage opening is changed by a plurality of light amount adjustment blades, wherein the plurality of light amount adjustment blades form an edge of the light passage opening, and a partial area of the blade portion A concave and convex portion formed so as to reduce the contact area with the blade portion of a plurality of other light amount adjusting blades, wherein the concave and convex portion is at least when the light passage opening has a minimum aperture diameter. It is characterized in that it is provided in a region in contact with another light quantity adjusting blade.

  According to the present invention, it is possible to realize a light amount adjusting device and an optical device having a light amount adjusting blade having high slidability without forming a linear contact portion over the entire area of the light amount adjusting blade.

FIG. 2 is an exploded perspective view of the light amount adjusting device according to the embodiment. FIG. 3 is a plan view of three types of light amount adjusting blades of a first pattern. 2A and 2B are a plan view and a cross-sectional view illustrating a state in which two light amount adjusting blades illustrated in FIG. FIG. 6 is a plan view of three types of light amount adjusting blades of a second pattern. 5A and 5B are a plan view and a cross-sectional view illustrating a state in which two light amount adjusting blades illustrated in FIG. 5A and 5B are a plan view and another cross-sectional view illustrating a state in which two light amount adjusting blades of FIG. FIG. 9 is a plan view of three types of light amount adjusting blades of a third pattern. 8A and 8B are a plan view and a cross-sectional view illustrating a state in which two light amount adjusting blades illustrated in FIG. FIGS. 4A and 4B are a perspective view and a plan view of a first pattern light amount adjusting blade provided with a spring hook portion. FIGS. The perspective view and top view of the light quantity adjustment blade of the 3rd pattern in which the spring hook part was provided. FIG. 4 is a perspective view of a back surface of the light amount adjusting device. The figure which expanded a part of FIG. FIG. 3 is a diagram illustrating a light amount adjustment device in a minimum aperture state. The figure which shows the state of each light quantity adjustment blade in an open state. FIG. 5 is a diagram illustrating a state of each light amount adjusting blade in a minimum aperture state. The top view and sectional drawing which show the state in which the two light-quantity adjustment blades in other examples have overlapped.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. However, the configurations described in the following embodiments are merely examples, and the scope of the present invention is not limited by the configurations described in the embodiments.

  FIG. 1 is an exploded perspective view of a light amount adjusting device 100 according to the present embodiment. The light amount adjusting device 100 is incorporated in an optical device such as a camera as a mechanism for adjusting the aperture of the optical device. By adjusting the size of the light passage opening by the light amount adjusting device 100, the light amount and the depth of field of the light taken into the imaging surface of the camera (optical device) are adjusted. As shown in FIG. 1, the light amount adjusting device 100 includes an actuator 101, a base member 102, a plurality of light amount adjusting blades 103, a drive ring 104, and a case member 105. The actuator 101 is a driving unit for rotating a plurality of light amount adjusting blades 103, and a pinion 111 is attached to a rotation shaft of the actuator 101. Further, the actuator 101 is fixed to the base member 102 by the fixing member 112.

  The base member 102 is a ring-shaped member, and has a shape whose center is open in a circular shape. The base member 102 has a plurality of bearings 121, a plurality of through grooves 122, and a pinion insertion hole 124. A rotation center pin 201 provided on the light amount adjusting blade 103 is rotatably inserted into each bearing 121. Further, a spring retaining portion described later provided on the light amount adjusting blade 103 is inserted into each through groove 122, and the spring retaining portion moves in a predetermined range while being guided by the through groove 122. The number of the bearings 121 and the through grooves 122 is the same as the number of the light amount adjusting blades 103. Each bearing 121 and each through groove 122 are provided at predetermined rotation angles around the opening area of the base member 102. If the light-amount adjusting blade 103 is not provided with the spring retaining portion, the through groove 122 is not formed in the base member 102. The pinion insertion hole 124 is a hole for inserting the pinion 111 attached to the rotation shaft of the actuator 101. FIG. 1 shows an example in which the rotation center pin 201 is provided on one light amount adjustment blade 103, but the rotation center pin 201 is provided on each of the light amount adjustment blades 103, as described later. Has been.

  Each light quantity adjusting blade 103 has a configuration arranged in a ring shape. An edge of the opening 300 is formed by the inside of each of the light amount adjusting blades 103 arranged in an annular shape. In the example of FIG. 1, nine light amount adjusting blades 103 are arranged in an annular shape, and each light amount adjusting blade 103 is configured to overlap with an adjacent light amount adjusting blade 103 (another light amount adjusting blade 103). Have been. Each light quantity adjusting blade 103 has a rotation center pin 201 described later on a surface facing the base member 102, and the rotation center pin 201 is rotatably inserted into the base member 102. The rotation center pin 201 corresponds to the rotation center. Each light amount adjusting blade 103 has a drive pin 202 on a surface facing the drive ring 104, and the drive pin 202 is inserted into a cam groove 131 of the drive ring 104. In each of the light amount adjusting blades 103, a portion including the rotation center pin 201 and the drive pin 202 forms a base (blade base), and a portion from the base to the tip forms a blade portion 203. Each light amount adjusting blade 103 of the present embodiment is an integrally molded product made of a synthetic resin. Each of the light amount adjusting blades 103 has the same shape, and is generated by integral molding by injection molding using the same mold. In the present embodiment, an example in which nine light amount adjusting blades 103 are used is shown, but the number of light amount adjusting blades 103 may be an arbitrary number.

  The drive ring 104 is a ring-shaped member whose center is open in a circular shape, and has a plurality of cam grooves 131 and a gear portion 132. The cam groove 131 is a groove for guiding the drive pin 202 of the light amount adjusting blade 103. The gear section 132 as a driven section is engaged with the pinion 111 attached to the actuator 101. When the driving force of the actuator 101 is transmitted from the pinion 111 to the gear portion 132, the driving ring 104 rotates.

  The case member 105 is a ring-shaped member whose center is open in a circular shape. For example, the base member 102 and the case member 105 are screwed with the light amount adjusting blades 103 and the drive ring 104 sandwiched therebetween. Thereby, the light amount adjusting device 100 is assembled.

  When the actuator 101 is driven in a state where the light amount adjusting device 100 is assembled, a driving force is transmitted to the pinion 111, and the driving ring 104 rotates. When the drive ring 104 rotates, the drive pins 202 of the light amount adjusting blades 103 move along the cam grooves 131, so that the light amount adjusting blades 103 rotate around the rotation center pins 201. Each light amount adjusting blade 103 rotates in conjunction with the rotation of the drive ring 104. When the light amount adjusting blades 103 rotate in conjunction with each other, the area of the circular opening 300 formed by each light amount adjusting blade 103 changes. When the driving force of the actuator 101 acts, each of the light amount adjusting blades 103 rotates from a position where the area of the opening 300 is widest to a position where the area is narrowest. When the area of the opening 300 is the largest, the aperture adjusted by the light amount adjusting device 100 is in the widest open state. When the area of the opening 300 is the smallest, the aperture adjusted by the light amount adjusting device 100 is the smallest minimum aperture. At the time of the minimum aperture, the opening 300 (light passage aperture) becomes the minimum aperture. The minimum aperture is also called a small aperture. When the aperture is in the open state, the amount of light taken into the imaging surface of the optical device is the largest, and the depth of field is the smallest. When the diaphragm is in the minimum diaphragm state, the amount of light taken into the imaging surface of the optical device becomes the smallest, and the depth of field becomes the deepest. The range of the aperture may be set arbitrarily, and the amount of rotation of each light amount adjusting blade 103 is determined according to the set range of the aperture.

  FIG. 2 is a plan view of three types of light amount adjusting blades 103 in the first pattern. The first pattern is a pattern in which a linear partial contact portion 205 that intersects at a predetermined angle or more with a direction toward the tip of the light amount adjusting blade 103 is formed on the light amount adjusting blade 103. The partial contact portion 205 corresponds to the uneven portion. FIG. 2A shows the light amount adjusting blade 103 when the partial contact portion 205 is the widest. The light amount adjusting blade 103 includes a base portion 204 including a rotation center pin 201 and a driving pin 202, and a blade portion 203 forming an edge of the opening 300. The base 204 is thick, and the blade 203 is thinner than the base 204 (the thickness of the blade 203 is smaller than the thickness of the base 204). For example, when the light amount adjusting blade 103 is integrally formed of a synthetic resin by using an injection molding apparatus in which a mold having an injection gate and an ejector pin are set, the injection gate and the ejector pin are arranged on the base 204 side. Thereby, the base 204 side can be made thick. On the other hand, the resin flows from the base 204 side where the injection gate and the ejector pin are arranged, so that the blade 203 can be made thinner than the base 204. As shown in FIG. 2A, the blade portion 203 includes a region where the partial contact portion 205 is formed and a region where the partial contact portion 205 is not formed. The region where the partial contact portion 205 is not formed (the region other than the region where the partial contact portion 205 is formed in the blade portion 203) has a planar shape, and the region becomes the planar portion 206. In the wing portion 203, the partial contact portion 205 is formed on the tip portion 207 side, and the flat portion 206 is formed on the base portion 204 side. In the blade portion 203, the edge of the opening 300 (light passage opening) forms a curved portion 210, and the curved portion 210 has a shape curved from the starting point 211 to the tip portion 207. As shown in FIGS. 2A to 2C, a boundary between the partial contact portion 205 and the plane portion 206 is a first boundary 212. Further, as shown in FIGS. 2B and 2C, the region from the partial contact portion 205 to the tip portion 207 is a flat portion, and the boundary between the flat portion and the partial contact portion 205 is the second portion. Is the boundary 213.

  FIG. 3A shows a plan view of a state in which two light amount adjusting blades 103 of FIG. 2A overlap each other, and FIG. 3B shows a cross-sectional view taken along the line AA of FIG. . As shown in FIG. 3 (B), the partial contact portion 205 is configured by arranging undulating portions 205 </ b> A having a mountain-shaped cross section in a direction intersecting at a predetermined angle or more with a direction toward the tip portion 207 of the blade portion 203. Formed in shape. The vertex of each undulation 205A extends linearly in a direction that intersects the direction toward the tip 207 of the blade 203. Therefore, a partial contact portion 205 having a plurality of linear line contact portions is formed by linearly extending the apex of each undulating portion 205A. Due to the plurality of linear contact portions, the partial contact portion 205 has a striped shape as a whole. In this case, the direction of the stripe pattern of the partial contact portion 205 is a direction that intersects with the direction toward the tip portion 207 of the blade portion 203. One surface of each light quantity adjusting blade 103 is a surface on which the partial contact portion 205 is formed, and the other surface is a planar shape on which the partial contact portion 205 is not formed. Each of the light amount adjusting blades 103 is combined so that the surface on which the partial contact portion 205 is formed overlaps the surface (plane) of the other light amount adjusting blade 103 on which the partial contact portion 205 is not formed. .

  With the above configuration, each light amount adjusting blade 103 makes line contact with another light amount adjusting blade 103 at the partial contact portion 205. As described above, the light amount adjusting blades 103 rotate in conjunction with each other by the driving force of the actuator 101. Each light amount adjusting blade 103 rotates while contacting the other light amount adjusting blades 103, so that sliding friction occurs. Therefore, by forming a partial contact portion 205 in a partial area of the blade portion 203 of each light amount adjusting blade 103, each light amount adjusting blade 103 rotates while performing line contact with another light amount adjusting blade 103. The sliding friction is reduced as compared with the case of rotating while making surface contact. Thereby, the slidability when each of the light amount adjusting blades 103 rotates is increased, and each of the light amount adjusting blades 103 rotates smoothly.

  Here, as shown in FIGS. 2A and 3A, the partial contact portion 205 is formed in a partial region of the blade portion 203 of the light amount adjusting blade 103. In the light amount adjusting blade 103 of the present embodiment, the partial contact portion 205 is not formed in a region that is not in contact with another adjacent light amount adjusting blade 103. That is, the plane portion 206 is formed on the blade portion 203 in addition to the partial contact portion 205. Even if the partial contact portion 205 is formed in a region (non-contact region) of the blade portion 203 of the light amount adjusting blade 103 which does not contact the adjacent other light amount adjusting blade 103, the slidability is not improved, and There is no need to form the partial contact portion 205 in the non-contact area. Therefore, in the light amount adjusting blade 103 of the present embodiment, the partial contact portion 205 is formed in a region of the blade portion 203 that comes into contact with the other light amount adjusting blade 103, and a region other than the region is a flat portion 206.

  As described above, the light amount adjusting blade 103 is an integrally molded product made of a synthetic resin. When the light amount adjusting blade 103 is integrally molded using an injection molding apparatus in which a mold having an injection gate and an ejector pin are set, the resin flows from the base 204 toward the tip 207. Here, the partial contact portion 205 formed on the light amount adjusting blade 103 has a striped pattern in which a plurality of undulating portions 205A extending linearly are arranged in parallel. When the injection molding is performed using the injection molding apparatus, the flow of the resin is deteriorated because the pattern is formed in the area of the partial contact portion 205. In particular, the striped pattern of the partial contact portion 205 in FIG. 2A is a pattern that is directed in a direction that intersects the direction that is directed to the tip portion 207 of the blade portion 203, and the direction of the pattern is the direction of the resin flow. It is the direction to resist. Therefore, in the region where the partial contact portion 205 is formed, the flow of the resin is deteriorated during the injection molding. As a result, the precision of molding in the region of the partial contact portion 205 is reduced. In the light amount adjusting blade 103 of the present embodiment, a partial contact portion 205 is formed in a partial region of the blade portion 203, and the other region (non-contact region) is a flat portion 206. In the area of the flat portion 206, the resin flows stably, so that even when the partial contact portion 205 is formed on a part of the blade portion 203, compared with the case where the partial contact portion 205 is formed on the entire surface of the blade portion 203. Thus, the accuracy of molding the light amount adjusting blade 103 is improved.

  Each of the light amount adjusting blades 103 contacts the other light amount adjusting blades 103 in the widest range when the aperture is in the open state. In the light amount adjusting blade 103 shown in FIG. 2A, when the diaphragm is in the open state, the partial contact portions 205 are formed in both rain areas that come into contact with the other light amount adjusting blades 103. On the other hand, the region of the partial contact portion 205 shown in FIGS. 2B and 2C is smaller than the region of the partial contact portion 205 shown in FIG. FIG. 2B shows a state where the light amount adjusting blade 103 is in contact with another light amount adjusting blade 103 when the diaphragm is in a state from the open state to the minimum diaphragm state (hereinafter, referred to as an intermediate diaphragm state). An example in which a contact portion 205 is formed is shown. FIG. 2C shows an example in which the light-amount adjusting blade 103 forms a partial contact portion 205 in a region where the light-amount adjusting blade 103 contacts another light-amount adjusting blade 103 in the minimum aperture state.

  As described above, when each light amount adjusting blade 103 is rotated, the aperture changes from the open state to the minimum aperture state. Here, since the aperture changes from the open state to the minimum aperture state, the sliding friction generated when each light amount adjusting blade 103 rotates may increase. In each of the light amount adjusting blades 103 of the present embodiment, a partial contact portion 205 is formed at least in a region where the light amount adjusting blade 103 overlaps the other light amount adjusting blades 103 when the aperture is in the minimum aperture state (when the light passage opening has the minimum aperture diameter). So that In the case of FIG. 2 (C), the region where the partial contact portion 205 is formed is the smallest in the blade portion 203, and the undulating portion 205A forming the partial contact portion 205 is formed intermittently. Therefore, in the case of FIG. 2C, the area of the flat portion 206 where the partial contact portion 205 is not formed is widened, so that the flow of the resin when the light amount adjusting blade 103 is integrally molded is stabilized. For this reason, the molding accuracy of the light amount adjusting blade 103 is improved. In the case of the light amount adjusting blade 103 of FIG. 2C, the partial contact portion 205 is formed in a region overlapping with the other light amount adjusting blades 103 in the minimum aperture state where the sliding friction is the largest. Accordingly, since the region of the light amount adjusting blade 103 where the sliding friction acts most has a partial line contact with the other light amount adjusting blades 103, the sliding friction can be reduced and the slidability is improved.

  The area of the partial contact portion 205 formed on the blade portion 203 of the light amount adjusting blade 103 in FIG. 2B is narrower than the light amount adjusting blade 103 in FIG. 2A, and is smaller than the light amount adjusting blade 103 in FIG. wide. In the blade portion 203 of the light amount adjusting blade 103 in FIG. 2B, a partial contact portion 205 is formed in a region that comes into contact with another light amount adjusting blade 103 in the intermediate aperture state. In some cases, the light amount adjusting blade 103 in the intermediate aperture state may have greater sliding friction due to contact with other light amount adjusting blades 103 than in the open state. For this reason, the sliding friction can be reduced by forming the partial contact portion 205 on the blade portion 203 of the light-amount adjusting blade 103 in a region in contact with another light-amount adjusting blade 103 in the intermediate aperture state. . Further, the partial contact portion 205 formed on the light amount adjusting blade 103 in FIG. 2B is narrower than the partial contact portion 205 formed on the light amount adjusting blade 103 in FIG. It is possible to suppress a reduction in the precision of molding the light amount adjusting blade 103 due to this.

  In the intermediate aperture state shown in FIG. 2B, no partial contact portion 205 is formed from the second boundary 213 to the distal end 207, and the area from the second boundary 213 to the distal end 207 is flat. Department. The area of the plane portion is an area that does not come into contact with the other light amount adjusting blades 103 in the intermediate stop state. As shown in FIG. 2B, by forming the partial contact portion 205 limited to the region from the first boundary 212 to the second boundary 213, the partial contact portion for reducing the sliding friction is formed. 205 can be a necessary minimum area. The same applies to the case of the minimum aperture state shown in FIG. 2C, and a region from the second boundary 213 to the tip 207 is a flat portion where the partial contact portion 205 is not formed. Therefore, by forming the partial contact portion 205 limited to the region from the first boundary 212 to the second boundary 213, the partial contact portion 205 for reducing the sliding friction is set to a minimum necessary region. be able to.

  As shown in FIG. 2B, an outer edge 221 is formed outside the curved portion 210 forming the edge of the opening 300, and a partial contact portion 205 is formed on the outer edge 221. It is not a flat part. The region of the outer edge portion 221 is a region that does not contact the other light amount adjusting blade 103 in the intermediate aperture state, and it is not necessary to form the partial contact portion 205 on the outer edge portion 221. Therefore, by making the region of the outer edge 221 not the partial contact portion 205, the partial contact portion 205 for reducing the sliding friction can be a minimum necessary region. Further, the outer edge portion 221 may be thicker than other regions of the blade portion 203. Since the region of the outer edge portion 221 of the blade portion 203 is thicker than other regions, there is an effect that the overall rigidity of the light amount adjusting blade 103 is improved. The same applies to the case of the minimum aperture state shown in FIG. 2C. An outer edge 222 is formed outside the curved portion 210 forming the edge of the opening 300, and the outer edge 222 has a partial contact portion. 205 is not formed and is a flat portion. Thereby, the partial contact portion 205 for reducing the sliding friction can be set to a necessary minimum area. Further, by making the outer edge portion 222 thicker than other regions of the blade portion 203, the overall rigidity of the light amount adjusting blade 103 is improved. Hereinafter, in the second pattern and the third pattern, the first boundary 212, the second boundary 213, the outer edges 221 and 222, etc. are not particularly illustrated, but the second pattern and the third pattern are also not illustrated. It is assumed that the pattern is the same as the pattern No. 1.

  FIG. 4 shows a plan view of the light amount adjusting blade 103 in the second pattern. The second pattern is a pattern in which a linear partial contact portion 205 is formed on the light amount adjusting blade 103 in a direction along the direction toward the tip of the light amount adjusting blade 103. Similar to the first pattern described above, the second pattern has a shape in which the undulations 205A having a mountain-like cross section are arranged in parallel, and the apex of each undulation 205A extends linearly. . Thus, a plurality of linear line contact portions are formed in the partial contact portion 205. The direction of each line contact part of the partial contact part 205 of the second pattern is different from that of the partial contact part 205 of the first pattern. FIG. 4A shows an example of the light amount adjusting blade 103 in which the above-mentioned partial contact portion 205 is formed in an area overlapping with another light amount adjusting blade 103 in the open state. FIG. 4B shows an example of the light amount adjusting blade 103 in which the partial contact portion 205 is formed in a region overlapping with the other light amount adjusting blades 103 in the intermediate stop state. FIG. 4C shows an example of the light amount adjusting blade 103 in which the above-mentioned partial contact portion 205 is formed in a region overlapping with another light amount adjusting blade 103 in the minimum aperture state. FIG. 5A is a plan view of a state in which two light amount adjusting blades 103 of FIG. 4A are overlapped, and FIG. 5B is a cross-sectional view taken along line BB of FIG. 5A. . FIG. 6A is a plan view of a state in which two light amount adjusting blades 103 of FIG. 4A overlap each other, and FIG. 6B is a cross-sectional view taken along line CC of FIG. 6A. .

  As shown in FIG. 4A, the direction in which each line contact portion of the partial contact portion 205 in the light amount adjusting blade 103 of the second pattern extends extends along the direction from the base 204 to the tip 207. Therefore, the direction of the stripe pattern of the partial contact portion 205 of the second pattern is different from the direction of the stripe pattern of the partial contact portion 205 of the first pattern. In the first pattern, the direction in which each line contact portion of the partial contact portion 205 of the light amount adjusting blade 103 in FIG. 2A extends extends in a direction intersecting with the direction toward the tip 207 of the blade portion 203. This is a factor that lowers the flow of resin during injection molding. On the other hand, since the direction in which each line contact portion of the partial contact portion 205 of the light amount adjusting blade 103 of the second pattern extends extends toward the tip 207 of the blade portion 203, the light amount adjustment of the first pattern is performed. The resin flows more stably during injection molding than the blade 103. Since the flow of the resin during the injection molding is stabilized, the accuracy in integrally molding the light amount adjusting blade 103 of the second pattern is improved. In the light amount adjusting blade 103 of the second pattern, a partial contact portion 205 corresponding to any of the open state, the intermediate aperture state, and the minimum aperture state is formed in a part of the blade section 203. Therefore, sliding friction can be reduced.

  FIG. 7 shows a plan view of the light amount adjusting blade 103 in the third pattern. The third pattern is a pattern in which a partial contact portion 205 having a plurality of protrusions 205B is formed on the light amount adjusting blade 103. FIG. 7A shows an example of the light-amount adjusting blade 103 in which the above-mentioned partial contact portion 205 is formed in a region overlapping with another light-amount adjusting blade 103 when the diaphragm is in an open state. FIG. 7B shows an example of the light-amount adjusting blade 103 in which the partial contact portion 205 is formed in a region overlapping with another light-amount adjusting blade 103 when the stop is in the intermediate stop state. FIG. 7C shows an example of the light amount adjusting blade 103 in which the above-mentioned partial contact portion 205 is formed in an area overlapping with another light amount adjusting blade 103 when the stop is in the minimum stop state. FIG. 8A is a plan view of a state in which two light amount adjusting blades 103 of FIG. 7A are overlapped, and FIG. 8B is a cross-sectional view taken along line DD of FIG. 8A. .

  As shown in the cross-sectional view of FIG. 8B, the tips of the projections 205B (the tips of the convex portions of the uneven portions) formed on the partial contact portions 205 of the light intensity adjusting blade 103 are respectively different from the other light intensity adjusting blades. A point contact is made with the blade 103. Therefore, the partial contact portion 205 of the third pattern is different from the first and second patterns in which the partial contact portion 205 of the light amount adjusting blade 103 makes line contact with the other light amount adjusting blades 103. The point contact with the light amount adjusting blade 103 can reduce the contact area. For this reason, the slidability when each light amount adjusting blade 103 rotates can be further improved. Further, as shown in FIGS. 7A to 7C, a partial contact portion 205 is formed in a part of the blade portion 203 of each light amount adjusting blade 103 in contact with another light amount adjusting blade 103. The region of the blade 203 where the partial contact portion 205 is not formed becomes the flat portion 206. Therefore, when the light amount adjusting blade 103 is integrally molded by injection molding, the flowability of the resin does not decrease in the area of the flat portion 206, so that the molding accuracy of the light amount adjusting blade 103 can be increased.

  Next, an example in which the light amount adjusting blade 103 is provided with the spring hook 208 will be described. FIG. 9A is a perspective view of the light amount adjusting blade 103 provided with the spring hook 208. FIG. 9B is a plan view of FIG. 9A. The light amount adjusting blade 103 corresponds to the light amount adjusting blade 103 in FIG. 2A, but the other light amount adjusting blades 103 in the first pattern (the light amount adjusting blade 103 in FIG. 2B or FIG. 2C). The blade 103) may be provided with a spring hook 208. Further, a spring hook 208 may be provided on the light amount adjusting blade 103 in FIGS. 4A to 4C, or a spring may be provided on the light amount adjusting blade 103 in FIGS. 7A to 7C as described later. A hanging portion 208 may be provided.

  The spring hook portion 208 is a member for hooking a torsion spring described later, and is provided on a surface facing the base member 102. When the light amount adjusting blade 103 is integrally formed by injection molding, the light amount adjusting blade 103 provided with the spring hook 208 is generated as an integrally molded product. FIG. 10A is a perspective view of the light amount adjusting blade 103 corresponding to the above-described third pattern (a pattern in which the partial contact portion 205 having the plurality of protrusions 205B is formed). FIG. 10B is a plan view of FIG. As shown in FIGS. 10A and 10B, a spring hook 208 is provided on the surface of the third pattern in which the light amount adjusting blade 103 faces the base member 102. The light amount adjusting blade 103 provided with the spring hook portion 208 is an integrally molded product made of a synthetic resin.

  FIG. 11 is a perspective view of the back surface (the surface opposite to the surface of the base member 102 on which the light amount adjusting blades 103 face) of the light amount adjusting device 100 in a state where the components are combined. FIG. 12 is an enlarged view of a part of FIG. When each of the light amount adjusting blades 103 is combined with the base member 102, the spring hook portion 208 provided on each of the light amount adjusting blades 103 moves from the through groove 122 to the rear surface of the base member 102 (the surface on which the respective light amount adjusting blades 103 face). From the opposite side). On the back surface of the base member 102, a base-side spring hook portion 301 and a spring shaft 302 are provided corresponding to each of the spring hook portions 208. The spring hook 208 is provided on each of the nine light quantity adjusting blades 103. Therefore, nine base-side spring hook portions 301 and spring shafts 302 are provided in an annular shape at predetermined rotation angles near the center of the opening area on the back surface of the base member 102. A torsion spring 303 as an elastic member is attached to the spring shaft 302. The torsion spring 303 is hung around a base side spring hooking portion 301 near one end, and is hooked around a spring hooking portion 208 protruding from the base member 102 near the other end. A spring hook 208 provided on each light amount adjusting blade 103 is guided by the through groove 122 and is displaced in the inner circumferential direction or the outer circumferential direction. In a state where the driving force of the actuator 101 is not acting, the biasing force of the torsion spring 303 restricts the spring hooking portion 208 to a position in the through groove 122 where the aperture of the light amount adjusting device 100 is opened. As a result, the aperture of the light amount adjusting device 100 is opened.

  An optical device (a camera or the like) incorporating the light amount adjustment device 100 repeatedly controls opening and closing of the aperture. If the opening / closing control of the aperture is repeatedly performed, the adjustment accuracy of the aperture may be reduced due to a reciprocal difference between the respective light amount adjusting blades 103 and the like. The torsion spring 303 functions as a backlash spring for each of the light amount adjusting blades 103, and applies an urging force so that the posture of each of the light amount adjusting blades 103 in the open state is regulated at a predetermined position. In addition, a member having elasticity other than the torsion spring 303 may be applied as an elastic member that applies an urging force to each light amount adjusting blade 103.

  When the driving force of the actuator 101 is transmitted to the drive ring 104, the drive ring 104 rotates, the drive pin 202 is guided by the cam groove 121, and the aperture changes to the minimum aperture state. As the apertures are closed, the spring hooks 208 provided on each light amount adjusting blade 103 move toward the inside of the through groove 122. Since the torsion spring 303 is hung on the spring hook 208, when the spring hook 208 moves inside the through groove 122 (when the aperture is closed), the urging force acting on the spring hook 208 increases. . When the aperture of the light amount adjusting device 100 is closed, each light amount adjusting blade 103 is rotated by the driving force of the actuator 101 against the urging force acting on the spring hook 208. When a strong urging force acts on a spring hook 208 provided on the base 204 side of each light amount adjusting blade 103 and rotates each light amount adjusting blade 103 against the urging force, the tip of each light amount adjusting blade 103 The vicinity of the portion 207 warps in the optical axis direction (thrust direction). When the vicinity of the distal end portion 207 of the light-amount adjusting blade 103 warps in the thrust direction, sliding friction generated by contact with another light-amount adjusting blade 103 increases.

  FIG. 13 is a diagram illustrating an example of the light amount adjusting device 100 when the aperture is in the minimum aperture state. When the aperture is in the minimum aperture state, each light amount adjusting blade 103 has a large warp in the vicinity of the front end portion 207, and sliding friction due to contact with another light amount adjusting blade 103 when each light amount adjusting blade 103 rotates. Becomes larger. Therefore, among the light amount adjusting blades 103, the partial contact portion 205 is formed at least in a region where the light amount adjusting blades 103 are in contact with the other light amount adjusting blades 103 when the stop is in the minimum aperture state. FIG. 13 shows an example in which the partial contact portion 205 is formed on one light amount adjusting blade 103 for easy understanding. A contact portion 205 is formed. The partial contact portion 205 of the other light amount adjusting blade 103 is shown transparently in FIG. In FIG. 13, the line contact portion of the partial contact portion 205 is provided along the sliding direction of each light amount adjusting blade 103 so as to reduce the sliding load when shifting to the minimum aperture state.

  Since the partial contact portion 205 is formed near the distal end portion 207 of each light amount adjusting blade 103, even if the distal end portion 207 of the light amount adjusting blade 103 greatly warps due to the urging force of the torsion spring 303, other light amount adjusting operations are performed. Sliding friction caused by contact with the blade 103 can be reduced. When the stop is in the minimum stop state, the area of the light amount adjusting blade 103 that is in contact with another light amount adjusting blade 103 is the smallest. When the area of the partial contact portion 205 formed on the light quantity adjusting blade 103 is reduced, the area of the flat portion 206 is increased, and the flow of the resin during injection molding is stabilized. This makes it possible to improve the precision of molding the light quantity adjusting blade 103, which is an integrally molded product made of a synthetic resin.

  FIG. 14 shows an example of each light amount adjusting blade 103 when the aperture is in the open state. When the aperture is in the open state, the area of the opening 300 is the largest. A partial contact portion 205 is formed on a blade portion 203 of each light amount adjusting blade 103 in a region where the light amount adjusting blade 103 is in contact with another light amount adjusting blade 103 when the aperture is in an open state. Further, each light amount adjusting blade 103 is provided with a spring hooking portion 208. Even if the opening and closing control of the aperture is repeatedly performed, the biasing force of the torsion spring 303 causes each light amount adjusting blade 103 to open and close. Posture becomes constant. Therefore, a decrease in the adjustment accuracy of the aperture is suppressed.

  FIG. 15 shows an example of each light amount adjusting blade 103 squeezed from the state of FIG. 14 to the minimum stop state. When the diaphragm is in the minimum diaphragm state, the area of the opening 300 is the smallest. When the diaphragm is in the minimum diaphragm state, the distal end portion 207 of each light amount adjusting blade 103 is largely warped by the urging force of the torsion spring 303, but the partial contact portion 205 is formed near the distal end portion 207. The sliding friction due to the contact with the light amount adjusting blade 103 is reduced. By forming a partial contact portion 205 in a region of the blade portion 203 of each light amount adjusting blade 103 that comes into contact with another light amount adjusting blade 103 when the diaphragm is in the open state, the diaphragm can be moved from the open state to the minimum diaphragm state. In all states, the above-mentioned sliding friction can be reduced. Further, since the partial contact portion 205 is formed in a part of the blade portion 203, the precision of molding the light amount adjusting blade 103 during the injection molding is reduced due to the deterioration of the resin flow. Is suppressed.

  FIGS. 9 to 15 illustrate an example in which each light amount adjusting blade 103 is provided with the spring hooking portion 208. However, each light amount adjusting blade 103 may not be provided with the spring hooking portion 208. Further, the elastic force of the torsion spring 303 for applying the urging force to the spring hook 208 may be equal to or less than a predetermined elastic force as long as the posture of each light amount adjusting blade 103 in the open state of the aperture can be regulated. When the elastic force of the torsion spring 303 is increased, the load applied to the actuator 101 when each light amount adjusting blade 103 is rotated is increased. Therefore, it is preferable to use a torsion spring 303 having a weaker elastic force. .

  In the example described above, the partial contact portion 205 of the blade portion 203 has been described as being formed by injection molding. However, the partial contact portion 205 may be formed on the blade portion 203 by a method other than injection molding. FIG. 16 shows a plan view and a cross-sectional view showing a state in which two light amount adjusting blades 103 in another example are overlapped. The light amount adjusting blade 103 in FIG. 16 has a partial contact portion 205 (an uneven portion) formed separately from a resin sheet (not shown). In this case, for example, a step of performing electroless plating of nickel on a resin sheet (not shown) is performed. Then, a step of partially forming a resist masking layer in the form of a dot punching pattern in which the pattern of the partial contact portion 205 is formed on the resin sheet is performed. As the above-described dot punching pattern, a pattern in which the interval between the adjacent protrusions 205B is 20 μm and the tips of the protrusions 205B have a pitch of 25 μm may be used. Then, a step of forming a nickel alloy plating film on a surface other than the resist masking layer on the electroless plating film by an electrolytic plating method is performed. The film thickness during film formation may be about 10 μm. Then, a step of immersing the resin sheet on which the nickel alloy plating has been formed into a transalkaline solution such as sodium carbonate to remove the resist masking layer is performed. As a result, the resist masking layer is completely melted, and the light amount adjusting device 100 in which the partial contact portion 205 is formed on the blade portion 203 is generated. As the plating film, nickel or the like is preferably used, but any plating may be used as long as it is a metal material. Further, a resin sheet on which a pattern of a plating film (a pattern of irregularities) is formed may be punched out and black painted. The rotation center pin 201 and the drive pin 202 may be provided on the base 204 of the light amount adjusting blade 103 by outsert molding or the like.

  In each of the above-described examples, in the light amount adjusting device 100, the apex of the undulating portion 205A (or the tip of the protrusion 205B) of the partial contact portion 205 may be at a position higher or lower than the plane portion 206. Is also good. In this regard, the vertex of the undulating portion 205A of the partial contact portion 205 (or the tip of the protrusion 205B) is preferably located at a position lower than the flat portion 206. That is, in the thickness direction of the blade portion 203, the height of the line contact portion or the protrusion 205B in the partial contact portion 205 is preferably lower than the height of the flat portion 206. In this case, the sliding friction with another light amount adjusting device 100 is reduced, and the warpage of the light amount adjusting device 100 is reduced. Further, of the two surfaces of the light amount adjusting blade 103, the surface on which the partial contact portion 205 is formed is a surface that partially contacts the other light amount adjusting blade 103, and the other light amount adjusting blade 103 in the minimum aperture state. Is preferably formed in a region that receives a warping force from Thereby, the effect of reducing the sliding friction when the light amount adjusting blade 103 is rotated from the minimum aperture state is enhanced.

  In the above-described example, the direction of the urging force that the torsion spring 303 acts on the spring hook 208 has been described as the direction in which each light amount adjusting blade 103 is in the open state, but the direction of the urging force is in the above-described direction. It is not limited, and may be biased in the closing direction. Further, the urging force does not need to be applied to each light amount adjusting blade 103. In this case, the torsion spring 303 and the spring hook 208 need not be provided. In addition, the partial contact portion 205 (concavo-convex portion) and the flat portion 206 of the light amount adjusting blade 103 may be subjected to graining, satin finish, or the like in order to reduce the reflectance.

  As described above, when each of the light amount adjusting blades 103 is an integrally molded product made of a synthetic resin, a resin containing silicon is used as a component that increases slidability and enhances molding fluidity. Is also good. In the case of a resin containing silicon, since the slidability is improved, for example, the silicon may be concentrated on the surface layer of the partial contact portion 205 (the uneven portion) in the light amount adjusting blade 103.

Reference Signs List 100 light amount adjusting device 103 light amount adjusting blade 201 rotation center pin 202 drive pin 203 blade portion 204 base portion 205 partial contact portion 206 plane portion 205A undulating portion 205B protrusion

Claims (12)

Each of the plurality of light-amount adjusting blades overlaps with another light-amount adjusting blade to form a light-passing opening, and the size of the light-passing opening is changed by rotating the plurality of light-amount adjusting blades. So,
The plurality of light amount adjusting blades,
A blade part forming an edge of the light passage opening;
In some regions of the blade portion, having an uneven portion formed so that the contact area with the blade portion of the other light amount adjustment blade,
The light amount adjusting device according to claim 1, wherein the uneven portion is provided at least in an area that comes into contact with the other light amount adjusting blade when the light passage opening has a minimum aperture diameter. The part of the area is in contact with the other light amount adjusting blade when the light passage opening is in the open state, and is in the area in contact with the other light amount control blade when the light passage opening is in the minimum aperture state. Being,
The light amount adjusting device according to claim 1, wherein: The part of the region is in contact with the other light amount adjusting blade when the light passage opening is in the intermediate stop state, and is in contact with the other light amount adjustment blade when the light passage opening is in the minimum stop state. Territory,
The light amount adjusting device according to claim 1, wherein: The uneven portion is formed of a metal plating film,
The light amount adjusting device according to claim 1, wherein: The uneven portion is a plurality of line contact portions arranged in parallel in a direction intersecting at a predetermined angle or more with a direction toward the tip of the blade portion,
The light amount adjusting device according to any one of claims 1 to 4, characterized in that: The uneven portion has a plurality of line contact portions arranged in parallel in a direction along a direction toward the tip of the blade portion,
The light amount adjusting device according to any one of claims 1 to 4, characterized in that: The uneven portion is a plurality of protrusions,
The light amount adjusting device according to any one of claims 1 to 4, characterized in that:   The light amount adjusting device according to any one of claims 1 to 7, wherein a back surface side of the uneven portion has a planar shape. In each of the plurality of light amount adjustment blades, a stop is provided for stopping an elastic member that applies an urging force in a direction in which the diaphragm is in an open state or in a closing direction,
The light amount adjusting device according to any one of claims 1 to 8, wherein: Of the blades, a region other than the region where the uneven portion is formed has a planar shape, and the uneven portion has a plurality of thinner portions than a region other than the region where the uneven portion is formed. That a line contact portion or a plurality of convex portions are formed,
The light amount adjusting device according to claim 1, wherein: The plurality of light amount adjusting blades include the blade portion, a rotation center portion serving as a rotation center of the blade, a blade base portion provided with the rotation center portion, and the blade portion having a smaller thickness than the blade base portion. Integrally molded with synthetic resin,
The light amount adjusting device according to any one of claims 1 to 10, wherein:   An optical apparatus comprising the light amount adjusting device according to any one of claims 1 to 11.

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