JP5064757B2 - Light control device - Google Patents

Description

  The present invention relates to a light amount adjusting device mounted on, for example, a lens barrel of an imaging device.

  As this type of conventional light amount adjusting device, for example, there is a device including a cam plate, a rotary plate, a plurality of diaphragm blades, a case member, a detector, and a drive source.

  The rotary plate is disposed so as to be rotatable around the optical axis. The plurality of diaphragm blades are disposed between the cam plate and the rotary plate, are fitted in the cam hole portion of the cam plate and the hole portion of the rotary plate, and operate so as to change the opening area by the rotation of the rotary plate. The case member houses the rotary plate and the aperture blade between the cam plate. The drive source is fixed to the case member and rotationally drives the rotary plate. The detector determines whether the aperture blade is at the open reference position by detecting the rotational position of the rotary plate. The driving source and the detector are connected to a diaphragm driving circuit with a flexible printed circuit board fixed to a terminal portion (Patent Document 1).

Further, after fixing a flange portion to be attached to the case member to a drive source for driving the diaphragm blades and rotating the flange portion around the output shaft of the drive source, the flange portion is fixed to the case member with a screw or the like. What has been proposed is proposed (Patent Document 2).
JP-A-6-95205 JP 2004-191772 A

  In the above-mentioned patent document 1, the detector is fixed to the flexible printed circuit board and disposed in the recess provided in the case member. However, since the detector is not fixed in the radial direction, the sensor portion may be separated from the detection piece of the rotary plate. . In this case, an error occurs in the aperture area by the diaphragm blades, deviating from the normal detection timing.

  Further, in Patent Document 2, since the flange portion fixed to the drive source is rotated and incorporated, the walls and members that obstruct the rotation operation cannot be arranged in the rotation direction of the flange portion, and the layout of the apparatus is not possible. Will be restricted.

  Therefore, an object of the present invention is to provide a light amount adjusting device that can fix a position detector with high accuracy and can save space.

To achieve the above object, the light amount adjustment device of the present invention, the rotor, the cover member you accommodating bobbin and a yoke, said cover member is fixed on one side, drives the diaphragm blades on the other side And a position detector that detects the position of the drive member, and the case member is formed with a hole through which the rotation shaft of the rotor is inserted. The one surface side of the cover member is formed with a protruding portion for fixing the cover member and a storage portion for storing the position detector, and at one end portion of the cover member, abutting the protruding portion and fastening A projecting portion is formed on the other end of the cover member to press the position detector housed in the housing portion, and the projecting portion is closer to the hole portion. The protruding height of the It is formed to be lower than Dedaka is, between the portion for housing the bobbin and the seat portion of the cover member is characterized Rukoto thin meat portion is formed.

  According to the present invention, the position detector can be accurately positioned and fixed with respect to the detection piece of the drive member by the urging force of the cover member. Thereby, the fluctuation | variation of the detection timing by the position shift of a position detector can be avoided.

  In addition, since the cover member is configured to hold the case member in the axial direction and the drive unit is assembled in the axial direction without rotating, it is not necessary to provide a flange portion or the like for fixing the drive unit. Space can be realized.

  Hereinafter, an example of an embodiment of the present invention will be described with reference to the drawings.

  First, with reference to FIG. 6, a lens interchangeable autofocus single-lens reflex camera equipped with a light amount adjusting device as an example of an embodiment of the present invention will be described.

  In this camera, as shown in FIG. 6, a lens body 300 is detachably attached to a camera body 200. The camera body 200 includes a power switch 203, a release switch 204, and a camera CPU 201. The lens body 300 includes a lens CPU 301, a focusing device 306, and a diaphragm device 307.

  The camera CPU 201 is composed of a microcomputer and controls the distance measuring device 208, the photometric device 205, the exposure device 206, the storage device 207, the display device 209, and the like. The camera CPU 201 communicates with the lens CPU 301 when the lens contact 302 and the camera contact 202 are connected when the lens body 300 is mounted.

  The power switch 203 can be operated from the outside, and the camera CPU 201 is activated by turning on the power switch 203 so that power can be supplied to each actuator and sensor in the system and the system can be operated.

  The release switch 204 is a two-stroke switch that can be operated from the outside, and its operation signal is input to the camera CPU 201. If the first stroke SW of the release switch 204 is ON, the camera CPU 201 drives the focusing lens to the focusing device 306 based on the determination of the exposure amount by the photometry device 205 and the distance measurement calculation result of the subject by the distance measurement device 208. Performs in-focus operation and in-focus determination according to commands. Thereby, the photographing preparation state is entered.

  When the camera CPU 201 detects that the second stroke SW of the release switch 204 has been operated to ON, the camera CPU 201 transmits a drive command for the diaphragm device 307 to the lens CPU 301 in the lens body 300. Then, the aperture device 307 is driven, and an exposure start command is transmitted to the exposure device 206 to perform an actual exposure operation. When an exposure end signal is received, a recording start command is transmitted to the storage device 207 to store a captured image. Let the process do.

  The display device 209 displays various shooting conditions such as an aperture value and shutter speed, the number of shots, the remaining battery level, and various modes according to commands from the camera CPU 201.

  The lens CPU 301 controls operations of various device circuits such as the focusing device 306 and the diaphragm device 307 in the lens body 300. The lens CPU 301 communicates with the camera CPU 201 when the lens body 300 is attached to the camera body 200 and the lens contact 302 and the camera contact 202 are connected.

  The focusing device 306 includes a focusing lens, a lens holding member thereof, a focusing lens driving unit for driving the focusing lens to a target position, and a driving force by the focusing lens driving unit as a moving force of the focusing lens. A transmission mechanism for transmitting. The focusing device 306 includes a focusing lens driving circuit that is controlled by the lens CPU 301 according to the movement amount information of the focusing lens transmitted from the camera CPU 201 and sends a driving command to the focusing lens driving unit.

  The aperture device 307 is configured to set an aperture area, a drive unit for driving the aperture mechanism, and a drive circuit that is controlled by the lens CPU 301 in accordance with an aperture operation command transmitted from the camera CPU 201 and sends a drive command to the drive unit. With.

  Here, the light amount adjusting device as an example of the embodiment of the present invention is configured by an aperture mechanism and a drive unit in the aperture device 307. FIG. 1 is an exploded perspective view for explaining a light amount adjusting device as an example of an embodiment of the present invention, and FIG. 2 is a perspective view for explaining a drive unit of the light amount adjusting device shown in FIG. FIG. 3 is a view for explaining an assembly method of the diaphragm mechanism and the drive unit of the light quantity adjusting device shown in FIG. 1, and FIG. 4 is an assembly completion diagram of the diaphragm mechanism and the drive unit of the light quantity adjusting device shown in FIG. 5 is a partial sectional view of FIG.

  As shown in FIG. 1, the light amount adjusting device as an example of the embodiment of the present invention includes a cover member 1, a rotor 2, bobbins 5 a and 5 b, a yoke 9, a bearing member 10, a position detector 12, a case member 13, A rotary plate 14, a diaphragm blade 15, and a cam plate 16 are provided. In this embodiment, a cover unit 1, a rotor 2, bobbins 5a and 5b, a yoke 9, a bearing member 10 and the like constitute a drive unit, and a position detector 12, a case member 13, a rotary plate 14, an aperture blade 15, A diaphragm mechanism is constituted by the cam plate 16 or the like.

  The cover member 1 is made of an elastic material such as synthetic resin, and houses the rotor 2 and the bobbins 5a and 5b. A bearing hole 1a is formed in a substantially central portion of the cover member 1, and holes 1b-1 to 1b-4 through which the terminals of the bobbins 5a and 5b are inserted are formed around the bearing hole 1a. Further, on both sides of the cover member 1, there are provided protruding pieces 1 c for pressing the position detector 12 and seats 1 d for pressing and fixing the cover member 1 to the case member 13.

  The projecting piece 1 c is provided with holes 1 c-1 to 1 c-3 through which the terminal portion 12 a of the position detector 12 is inserted, and a protrusion 1 j (pressing portion: see FIG. 2) that contacts the end surface of the position detector 12. It has been. The seat 1d is provided with fastening member insertion holes 1d-1 and fitting pieces 1e-1 and 1e-2 for positioning in the case member 13 by fitting. Also, a thin piece portion (thin portion) 1f is provided near the bearing hole 1a of the seat portion 1d.

  Further, the cover member 1 is fitted with an elastic piece 1k having a locking claw portion (locking portion) 1k-2 for snap-fit coupling to the case member 13 and a yoke 9 for positioning. 1g-1, 1g-2, 1h-1 to 1h-4 are provided.

  The rotor 1 is formed of a permanent magnet, and a disk-shaped core 3 is fixed to the inner peripheral portion by adhesion or the like. A rotating shaft 4 is fitted and fixed to the core 3 by press fitting or the like, and an end portion of the rotating shaft 4 on the cover member 1 side is rotatably supported in a bearing hole 1a of the cover member. Further, a washer 7 is interposed between the core 3 and the bearing member 10 to reduce sliding friction between the end surface of the core 3 and the end surface of the bearing member 10. The washer 7 is formed of a material having high lubricity.

The bobbins 5a and 5b are made of synthetic resin or the like and have terminal portions for power feeding. In addition, coils 6a and 6b are attached to the bobbins 5a and 5b, and coil lead wires are wound around the terminal portions and subjected to plating with solder. Further, an insulating sheet member 8 is interposed between the coils 6a and 6b and the yoke 9 so as to prevent both from conducting. The seat member 8 is formed with a relief hole portion 8a of the bearing member 10 and relief hole portions 8b-1 and 8b-2 of the yoke 9.

  The yoke 9 is made of a soft magnetic material, and stator portions 9b-1 and 9b-2 bent so as to face the rotor 2 in the radial direction, and a hole portion 9a for fixing the bearing member 10 by press fitting or the like. And it has fitting surface portions 9c-1 to 9c-6 for fitting with the cover member 1.

  The bearing member (bearing portion) 10 is made of a magnetic material, and has a bearing hole 10a that rotatably supports the end of the rotating shaft 4 on the opposite side of the cover member 1 and a flange portion 10b. A pinion 11 is fixed to the tip of the rotating shaft 4 protruding from the bearing hole 10a. The pinion 11 has a hole portion 11a for fixing the rotary shaft 4 by press fitting or the like, and a gear portion 11b for transmitting the rotational force of the drive unit to the rotary plate 14.

  The position detector 12 uses a position detection element such as a photo interrupter and detects the rotational position of the rotary plate 14. The position detector 12 is provided with a terminal portion 12a.

  The case member 13 is made of synthetic resin or the like and has a protruding portion 13a protruding in the optical axis direction. The case member 13 has a receiving surface portion 13a-3 with which the back surface of the seat portion 1d of the cover member 1 abuts, and fitting end surfaces 1e-1-a, 1e-2-a of the fitting piece portions 1e-1, 1e-2. Is provided with a fitting protrusion 13a-2-a. The fitting protrusion 13a-2 is also provided on the back surface.

  Further, the case member 13 is fitted with a screw hole portion 13a-1 into which the fastening member 17 inserted into the fastening member insertion hole 1d-1 is tightened, an insertion hole portion 13b of the pinion 10, and a flange portion 10b of the bearing 10. A hole 13c and a seating surface 13d for contacting the end surface of the yoke 9 are provided.

  Further, the case member 13 is provided with a housing part 13e for housing the position detector 12, a relief hole 13g for the shielding plate part 14a of the rotary plate 14, and an insertion hole 13f for the elastic piece part 1k. Further, the case member 13 has insertion grooves 13h-1 to 13h-3 of the snap fit portions 16b-1 to 16b-3 of the cam plate 16, fitting holes of the positioning shafts 16a-1 and 16a-2, and a groove 13i-. 1,13i-2 is applied. Furthermore, the case member 13 is provided with a fitting hole 13j into which the fitting ribs 14b-1 to 14b-6 of the rotary plate 14 are fitted.

  The rotary plate (drive member) 14 is formed of synthetic resin or the like, and is provided with a shielding plate portion 14a as a detection piece for shielding the projection light of the position detector 12. Further, the rotary plate 14 is provided with fitting rib portions 14b-1 to 14b-6 for fitting in the fitting hole portion 13j and rotating the rotary plate 14 about the optical axis.

  Further, the rotary plate 14 is provided with a gear portion 14 c that meshes with the gear portion 11 b of the pinion 11 and transmits a rotational driving force to the rotary plate 14. Furthermore, the rotary plate 14 is fitted with a fitting hole 14d for fitting the fitting shafts 15a-1, 15b-1, 15c-1, 15d-1, 15e-1, 15f-1 of the diaphragm blade 15. -1 to 14d-6 are provided.

  Further, the rotary plate 14 has projections 14e-1 to 14e-3 (14e-3 not shown) for contacting the end surface of the case member 13 in the optical axis direction to determine the position of the rotary plate 14 in the optical axis direction. ) Is provided. The protrusions 14e-1 to 14e-3 are arranged approximately equally around the optical axis. An opening 14 f is provided at the center of the rotary plate 14.

  The aperture blade 15 is formed of a synthetic resin or a metal thin plate or the like, and is fitted with fitting shaft portions 15a-1, 15b-1, 15c-1, 15d-1, 15e fitted into the fitting holes 14d-1 to 14d-6. -1,15f-1. Further, the diaphragm blade 15 has fitting shaft portions 15a-2, 15b-2, 15c-2, 15d-2, 15e-2, 15f-2 (15b) that fit into the cam holes 16c to 16h of the cam plate 16. -2, 15c-2, and 15d-2 are not shown).

  The cam plate 16 has cam holes 16 c to 16 h and shaft portions 16 a-1 and 16 a-2 for positioning with the case member 13. Further, the cam plate 16 is provided with snap fit portions 16b-1 to 16b-3 and an opening hole portion 16k for snap fitting the cam plate 16 to the case member 13.

  Next, the assembly procedure of the drive unit will be described.

  First, the outer diameter portion of the bearing member 10 is fixed to the hole 9 a of the yoke 9 by press fitting or the like, and the bearing member 10 is attached to the yoke 9. In this state, the flange portion 10b of the bearing member 10 contacts the end surface of the yoke 9, and the bearing member 10 is positioned with respect to the yoke 9. Further, the hole portions 8 b-1 and 8 b-2 of the sheet member 8 are inserted into the stator portions 9 b-1 and 9 b-2 of the yoke 9, and the sheet member 8 is laid on the yoke 9.

  Next, the stator 9b-1 and 9b-2 of the yoke 9 are inserted through the hollow holes (not shown) of the bobbins 5a and 5b to which the coils 6a and 6b are attached. Next, the washer 7 is inserted through the rotating shaft 4 of the rotor unit in which the rotor 3 and the rotating shaft 4 are integrated, and the tip of the rotating shaft 4 is fitted into the hole 10 a of the bearing member 10.

  Next, the yoke 9 is attached to the cover member 1. At the time of such attachment, the fitting surface portions 9c-1-a to 9c-4-a and 9c-5 and 9c-6 of the yoke 9 are fitted to the fitting portions 1h-1 to 1h-4, 1g-1, 1g-. 2 respectively. As a result, the state shown in FIG. 2 is obtained. Here, when the fitting surface portion and a part of the fitting portion, for example, the fitting surface portions 9c-5 and 9c-6 and the fitting portions 1g-1 and 1g-2 are set to be press-fitted, the yoke 9 is attached to the cover member 1. It is fixed, and there is no need to inadvertently disassemble and reassemble during assembly. And the assembly of a drive unit is completed by fixing the pinion 11 to the front-end | tip part of the rotating shaft 4 by press injection.

  Next, a procedure for attaching the cover member 1 of the drive unit to the case member 13 of the aperture mechanism will be described with reference to FIGS.

  First, as shown in FIG. 3, the cover member 1 of the drive unit is moved to the case member 13 of the diaphragm mechanism from the optical axis direction. At that time, the position detector 12 is housed in the housing portion 13 e of the case member 13. Next, the cover member 1 is further moved closer to the case member 13, and the fitting end surfaces 1 e-1-a and 1 e-2-a are fitted to the fitting protrusions 13 a-2-a and 13 a-2 b of the case member 13. Fit each one. Further, the outer diameter of the flange portion 10 b of the bearing member 10 is fitted into the hole portion 13 c of the case member 13.

  By these fittings, the cover member 1 is positioned on the case member 13, and the terminal portions 12a are inserted into the holes 1c-1 to 1c-3 simultaneously with the fitting. When the cover member 1 is further moved closer to the case member 13, the end surface of the seat portion 1d comes into contact with the receiving surface portion 13a-3. The receiving surface portion 13a-3 is an inclined surface, and as shown in FIGS. 1 and 3, a height difference α is provided in a line direction connecting the center of the hole portion 13a-1 and the center of the hole portion 13c. The hole 13c side is lower.

  Next, when the cover member 1 is tightened into the case member 13 by the fastening member 17, the thin piece portion 1f is elastically deformed so that the end surface of the seat portion 1d follows the receiving surface portion 13a-3 having a height difference. Since the height difference α is lower on the hole 13c side than the hole 13a-1, the elastic deformation generates a force with which the end surface 9e of the yoke 9 abuts against the seat surface 13d. In this state, the positions of the yoke 9 and the case member 13 in the optical axis direction are determined, and the position of the pinion 11 is arranged at an appropriate position.

  Thereby, good meshing between the gear portion 11b of the pinion 11 and the gear portion 14c of the rotary plate 14 is maintained, and an accurate opening diameter by the aperture blade 15 is obtained. The protrusion 1d-2 provided on the seat surface 13d receives the end surface of the seat 1d by the end surface of the fastening member 17 pressing the protrusion 1d-2 when the fastening member 17 is tightened. It is intended to actively follow the surface portion 13a-3 and is provided closer to the thin piece portion 1f.

  On the other hand, in the state where the cover member 1 is attached to the case member 13, as shown in FIG. 5, the locking applied to the slope member 1 k-1 of the locking claw portion 1 k-2 of the elastic piece 1 k and the case member 13. The nail | claw part 13k contacts. At this time, since the position of the inclined surface portion 1k-1 is set so that the elastic piece portion 1k has a slight amount of deflection, referring to FIG. 3, the contact force of the end surface 9e of the yoke 9 to the seat surface 13d The cover member 1 is held by the case member 13 while having (biasing force).

  Furthermore, in this state, as shown in FIG. 5, the projection 1j of the cover member 1 contacts the end surface 12b of the position detector 12, and the protruding piece 1c presses the position detection element 12 with a slight amount of bending. keeping.

  Here, as shown in FIGS. 4 and 5, P is the approximate center position of the thin piece 1 f of the cover member 1 that is elastically deformed, Q is the position where the end surface 9 e of the yoke 9 is in contact with the seat surface 13 d, and the elastic piece Let R be the position where the slope 1k-1 of the 1k locking projection 1k-2 contacts the locking claw 13k. Further, S is a position where the projection 1j of the protruding piece 1c contacts the end surface 12b of the position detector 12.

  Further, the vertical component force f1a of the force f1 that the yoke member 9 presses the seating surface 13d at the point Q with respect to the line segment PQ is f1a, the vertical component force with respect to the line segment PR of the force f2 that the cover member 1 receives at the point R is f2a, and the cover. A vertical component force of the force f3 received by the member 1 at the point S with respect to the line segment PS is defined as f3a.

  When the length of the line segment PQ is L1, the length of the line segment PR is L2, and the length of the line segment PS is L3, the relationship f1a · L1 + f2a · L2> f3a · L3 is satisfied.

  By satisfying at least the above-mentioned relationship, the cover member 1 is lifted from the case member 13 against the force received by the projection 1j of the projecting piece 1c (the contact force of the end surface 9e against the seat surface 13d is not obtained). Can be avoided. Therefore, good meshing between the gear portion 11b of the pinion 11 and the gear portion 14c of the rotary plate 14 is maintained, and an accurate opening diameter by the aperture blade 15 is obtained.

  As described above, in this embodiment, the position detector 12 can be accurately positioned and fixed with respect to the shielding plate portion 14 a of the rotary plate 14 by the urging force of the cover member 1. Thereby, the fluctuation | variation of the detection timing by the position shift of the position detector 12 can be avoided.

  Further, the cover member 1 is configured to hold the case member 13 in the optical axis direction so that the drive unit is incorporated in the optical axis direction without rotating. Thereby, it is not necessary to provide a flange portion or the like for fixing the drive unit, and space saving can be realized.

  In addition, this invention is not limited to what was illustrated to the said embodiment, In the range which does not deviate from the summary of this invention, it can change suitably.

  For example, in the above embodiment, the case where the elastic piece 1k is provided on the cover member 1 is illustrated. However, if the relationship of f1a · L1> f3a · L3 is satisfied, the elastic piece 1k may be omitted. Good.

  Further, the receiving surface portion 13a-3 of the case member 13 is not necessarily an inclined surface. For example, the receiving surface portion 13a-3 provided with the protruding portion and the end surface of the seat portion 1d abut against each other with a pressing force to elastically deform the thin piece portion 1f and attach the end surface 9e of the yoke 9 to the seat surface 13d. You may make it contact | abut with power. Moreover, you may provide the said projection part in the seat part 1d side instead of the receiving surface part 13a-3 side.

  Further, the contact between the end surface 9e of the yoke 9 and the seat surface 13d of the case member 13 may be contact by a plurality of protrusions. Further, when the cover member 1 and the yoke 9 are set to be press-fitted, the yoke 9 is fixed to the cover member 1, so that the contact portion with the seating surface 13 d is not the end surface 9 e of the yoke 9 but one of the cover members 1. It is good also as a part.

It is a disassembled perspective view for demonstrating the light quantity adjustment apparatus which is an example of embodiment of this invention. It is a perspective view for demonstrating the drive unit of the light quantity adjustment apparatus shown in FIG. It is a figure for demonstrating the assembly method of the aperture mechanism and drive unit of the light quantity adjustment apparatus shown in FIG. FIG. 2 is an assembly completion diagram of a diaphragm mechanism and a drive unit of the light amount adjusting device shown in FIG. 1. FIG. 5 is a partial cross-sectional view of FIG. 4. It is a block diagram which shows the structure of the lens interchangeable autofocus single-lens reflex camera which mounts the light quantity adjustment apparatus shown in FIG.

Explanation of symbols

1 Cover member 1d-2 Thin piece (thin part)
1j Protruding part (pressing part)
1k Elastic piece 1k-2 Locking claw part (Locking part)
2 Rotor 3 Core 4 Rotating shaft 6 Coil 7 Washer 8 Sheet member 9 Yoke 10 Bearing member (bearing portion)
11 Pinion 12 Position detector 13 Case member 14 Rotary plate (drive member)
15 Diaphragm blade 16 Cam plate

Claims (3)

A cover member you accommodating the rotor, a bobbin and a yoke,
Is the cover member is fixed on one side, and the case member which drive member is arranged to drive the diaphragm blades in the other side,
A position detector for detecting the position of the drive member ;
The case member is formed with a hole through which the rotation shaft of the rotor is inserted,
On the one surface side of the case member, a protruding portion to which the cover member is fixed and a storage portion for storing the position detector are formed,
On one end of the cover member is formed a seat that is brought into contact with the projecting portion and fastened,
On the other end of the cover member, an overhanging piece for pressing the position detector stored in the storage is formed,
The protruding portion is formed such that the protruding height on the side close to the hole portion is lower than the protruding height on the side far from the hole portion,
Between the portion for housing the bobbin and the seat portion of the cover member, the light amount adjusting device according to claim Rukoto thin meat portion is formed. An elastic piece portion is formed between the protruding piece portion of the cover member and the portion that houses the bobbin,
Between the hole portion of the cover member and the storage portion, an insertion hole through which the elastic piece portion is inserted is formed,
The cover member, when the elastic piece portion is inserted into the insertion hole, the light amount adjustment according to claim 1, characterized in Rukoto are locking claws formed for engaging the elastic piece portion apparatus. P is a substantially center position of the thin piece portion, Q is a position where the yoke is in contact with the case member due to elastic deformation of the thin piece portion, and R is a locking position between the elastic piece portion and the locking claw portion. A position where the protruding piece portion presses the position detector stored in the storage portion is S,
The vertical component force f1a of the force f1 that the yoke abuts at the position Q with respect to the line segment PQ is f1a, the vertical component force of the force f2 that the cover member receives at the position R with respect to the line segment PR is f2a, and the cover member is the position. The vertical component force of the force f3 received by S with respect to the line segment PS is f3a,
When the length of the line segment PQ is L1, the length of the line segment PR is L2, and the length of the line segment PS is L3, the relationship of f1a · L1 + f2a · L2> f3a · L3 is satisfied The light quantity adjusting device according to claim 2.

Images