KR101024840B1 - Diaphragm device - Google Patents

Abstract

The diaphragm apparatus of this invention reduces the thickness dimension of the whole diaphragm apparatus by shortening the dimension of the actuator axial direction very much.

A base frame 11, an aperture wing 30 disposed on the base frame, a rotary actuator 100 for driving the aperture wing, and an operation transmission mechanism 120 for transferring the operation of the actuator to the aperture wing. . The actuator is formed by inserting both shaft ends 135 and 134 into a cylindrical casing 110 having a bottom surface, a bearing hole 19 formed in the base frame, and a bearing hole 117 formed in the bottom wall of the casing. Rotor 130 supported to rotate at, and the drive coil 140 to rotate the rotor by applying a magnetic force to the magnet 138 of the rotor, the drive coil is composed of a bobbinless air core coil, An escape hole 18 is formed in the base frame to allow the coil to be close to the base frame side by avoiding interference with the drive coil.

Description

Aperture Device {DIAPHRAGM DEVICE}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to diaphragm devices for optical devices such as video cameras, still cameras, surveillance cameras, and the like.

As this type of aperture device, what is described in patent document 1 is known.

The diaphragm device is provided to slide on a base frame and a base frame having a flat plate shape having an opening that serves as an optical path, and a base frame. In addition, the diaphragm wing which adjusts the amount of light passing through the opening by being slide-driven, and the base of the rotor itself in the direction orthogonal to the base frame to drive the diaphragm wing. A rotary actuator (motor) attached to the frame, and a motion transfer mechanism for converting and rotating the rotation of the rotor into a sliding motion of the iris blade, And the actuator comprises the rotor provided with a magnet, and a stator for applying rotational force to the rotor. A coil wound around the outer periphery of a coil bobbin of a U-shape, and the rotor is inserted into the coil bobbin at the side opening of the coil bobbin, and the shaft end of the rotor ( I) is supported to rotate by a bearing disposed in the coil bobbin.

Patent Document 1: Japanese Patent Application Laid-Open No. 11-183962

By the way, since the conventional diaphragm device of patent document 1 uses the coil bobbin for winding a coil, and supports the shaft end of a rotor by the bearing arrange | positioned in a coil bobbin, the dimension of the rotor axial direction of an actuator There was a limit to shortening, and as a result, there was a problem that the thickness of the entire aperture device was large.

The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a diaphragm device which aims to reduce the thickness of the entire diaphragm device by greatly shortening the size in the rotor axial direction of the actuator.

The diaphragm device of Claim 1 is provided so that it may slide on the said base frame, and the base frame of the flat shape provided with the opening part used as an optical path, A slide vane adjusts the amount of light passing through the opening, and a direction in which the axis of rotation of the rotor itself is orthogonal to the base frame to drive the aperture vane. A rotational actuator attached to the base frame toward the head and a motion transmission mechanism for converting the rotational motion of the rotor into a sliding motion of the aperture blade, and transmitting the motion; The actuator is connected to the base frame toward an opening end and further includes a bottom surface. It is supported to rotate in the casing by inserting both shaft ends into a cylindrical casing, a bearing hole formed in the base frame, and a bearing hole formed in the bottom wall of the casing, respectively. A cylindrical shape which is mounted on the main body of the rotor and the outer periphery of the main body of the rotor and magnetized so that the magnetic poles are parallel to each other in the circumferential direction thereof. A conducting wire is wound around a magnet and a central opening, and the side of the rotor comprising the main body and the magnet of the rotor is parallel to the axis of rotation of the rotor. The casing is disposed by positioning a winding surface of the coil, and accommodates a part of the circumferential direction of the magnet in the central opening. And a drive coil for rotating the rotor by applying magnetic force to the magnet by energizing the drive coil, wherein the drive coil is a bobbinless hollow core coil. In addition, the base frame is characterized in that the escape hole which makes it possible to bring the air core coil closer to the base frame side by avoiding interference with the air core coil.

The invention according to claim 2 is the diaphragm device according to claim 1, wherein a mouth wall parallel to the rotor is formed in the casing, and a convex portion into which the center opening of the hollow core coil of the bobbinless is inserted is formed in the mouth wall. It is characterized by being.

According to a third aspect of the present invention, there is provided the diaphragm according to claim 2, wherein a magnetic suction force is applied to the rear surface of the mouth wall between the magnet and the magnet when the air core coil is not energized. It is characterized in that an adsorption piece is provided which constantly determines the rotational position of the rotor.

According to the invention of claim 1, the bobbin is removed using a bobbinless air core coil for the drive coil, the one shaft end of the rotor is supported by a bearing hole formed in the base frame, and the air core coil and The thickness of the entire diaphragm including the axial dimension of the actuator can be reduced by forming the escape hole for avoiding the interference and making the hollow core close to the base frame.

According to the invention of claim 2, the coil can be stably supported by inserting the bobbinless hollow core coil into the convex portion formed on the mouth wall. It may also be easy to attach, including the positioning of the coil.

According to the invention of claim 3, since the adsorption piece is attached using a mouth wall for supporting the coil, the configuration can be simplified.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.

1 is a schematic side cross-sectional view of an aperture device as an embodiment. Fig. 2 is a plan view showing a state before attaching an actuator of the diaphragm device. Fig. 3 is a bottom view showing a state before attaching an actuator of the aperture device. Fig. 4 is a plan view of a portion to which an actuator of the same diaphragm is attached. Fig. 5 is a configuration diagram of the actuator, where (a) is a plan view and (b) is a side sectional view. Fig. 6 is a configuration diagram of the casing of the actuator, where (a) is a plan view and (b) is a side sectional view. Fig. 7 is a bottom view of the actuator, in which (a) shows a state before attaching the wiring board, and (b) shows a state with the wiring board attached.

As shown in Figs. 1 to 3, the diaphragm device 10 includes a base frame 11 in the shape of a flat plate. The base frame 11 has an annular wing attachment portion 12, which is a main portion thereof, and an actuator attachment portion of a substantially rectangular shape projecting outward from the wing attachment portion 12. Part 13 is formed. The wing attachment portion 12 is formed with a circular central opening 14 serving as an optical path, and has a shallow annular groove around the opening 14. (15) is formed. In addition, three small pins 17 are formed on the outer upper surface of the shallow annular groove 15 at intervals of 120 ° in the circumferential direction. In addition, a contact window 16 is opened in a portion extending from the wing attachment portion 12 to the actuator attachment portion 13, and a bearing hole (bearing hole) (in the actuator attachment portion 13). 19 and the escape hole 18 which avoids the interference between the air core coil mentioned later is formed.

On the upper surface of the wing attachment part 12 of the base frame 11, three aperture blades 30 for adjusting the amount of light passing through the central opening 14 are placed at intervals of 120 ° in the circumferential direction ( Viii) These diaphragm wings 30 are substantially C-shaped in plan view, and have a shaft hole (base) of a proximal end in the pin 17 on the upper surface of the wing attachment portion 12 in the base frame 11. 31 is inserted so that the pin 17 is rotated along the upper surface of the base frame 11 with the pin 17 as a point, and interlocked on the base frame 11, respectively. By rotating, the diaphragm mouth on the center opening 14 can be adjusted. In addition, a long hole 32 is formed in the vicinity of the shaft hole 31 at the proximal end of the diaphragm wing 30.

In addition, in the shallow annular groove 15 around the center opening 14 of the base frame 11, a driving ring 20 for driving the three aperture blades 30 in association with each other is accommodated so as to rotate. have. The drive ring 20 has a thin disk shape and includes three driving pins 22 protruding upward at three intervals of 120 ° in the circumferential direction and one in the circumferential direction. It is provided with the lever 21 which protrudes radially outward. The three drive pins 22 are coupled to the long holes 32 of the respective aperture blades 30, and the aperture rings 30 rotate so that the aperture blades 30 interlock with each other. In addition, the lever 21 extends into the communication window 16 of the base frame 11, and a long hole 25 is formed in the portion thereof.

In addition, a cover 80 may be covered on the upper side of the base frame 11 in a state where the driving ring 20 or the aperture blade 30 is accommodated, and the cover 80 is fixed to the base frame 11 with screws. It is. In addition, the lower surface of the actuator attachment portion 13 of the base frame 11, as shown in Figs. 1 and 4, rotates the rotation axis of the rotor 130 itself. 11, a rotary actuator 100 for driving the iris blade 30 is attached with a screw.

As shown in FIGS. 1 and 5 to 7, the actuator 100 is screwed to the base frame 11 toward the opening end of the lower surface of the actuator attachment portion 13 of the base frame 11. Casing 110 having a tubular shape connected to the bottom and bearing holes 19 and casing 110 formed in the actuator attachment portion 13 of the base frame 11. The rotor 130 supported to rotate in the casing 110 is provided by inserting both shaft ends 135 and 134 into the bearing holes 117 formed in the bottom wall 111 of the structure.

The casing 110 including the bottom wall 111 and the circumferential wall 112 cut in two places in the circumferential direction has an end portion at the open end side in the circumferential wall 112 as shown in FIG. It is fixed to the base frame 11 by fastening with a screw (bracket 113) formed so as to face outward.

On the outer circumference of the main body 131 of the rotor 130, a cylindrical magnet 138 magnetized so that the magnetic poles are arranged side by side in the circumferential direction. Is mounted, and the magnet 138 is integrally formed with the main body 131 of the rotor by inserting a groove of its end face into the rib 136 of the rotor main body 131. It is coupled to rotate.

On the side of the rotor 130, a winding coil 140 of a quadrangular ring shape is disposed with the winding surface of the coil in parallel with the rotation axis of the rotor 130. As shown in FIG. The drive coil 140 is a coil wound around a central opening of a quadrangle, and is configured as a bobbinless hollow core coil.

The drive coil 140 is mounted to the casing 110 so as to receive a part of the circumferential direction of the magnet 138 in the central opening, and energizes the magnet 138 to exert a magnetic force on the rotor ( 130) can be rotated. In addition, the drive coil 140 inserts its own rectangular central opening into the front convex portion 115 of the mouth wall 114 formed in the casing 110 substantially in parallel with the rotor 130, and also the casing. It is located in the casing 110 by inserting one side (lower end) of the quadrangular ring into the recess 116 (see FIG. 6 (b)) formed on the top surface of the bottom wall 111 of 110. It is attached in the determined state.

In this way, a part of the driving coil (ong core coil) 140 attached to the casing 110 is inserted into the escape hole 18 to avoid interference with the base frame 11, whereby the driving coil 140 is connected to the base frame ( 11) It is installed in a very close position.

Further, at one end of the rotor 130 of the actuator 100, a lever 132 is formed in a shape extending in the radial direction of the rotor 130. The driving pin 133 is formed on the front end surface of the lever 132, and the driving pin 133 is formed of the base frame 11 through the communication window 16 of the base frame 11. It is coupled to the long hole 25 of the lever 21 of the drive ring 20 arranged on the upper surface side. As a result, the drive ring 20 is rotated by the rotation of the lever 132 of the actuator 100. Therefore, the element from the lever 132 of the actuator 100 to the drive ring 20 causes the rotation of the rotor 130 of the actuator 100 to be a rotary slide of the aperture blade 30. An operation transmission mechanism 120 for converting and transmitting the same is configured.

In the casing 110 of the actuator 100, a cylindrical metal body 160 is formed so as to surround the rotor 130, the drive coil 140, and the like. ), The rotational position of the rotor 130 is set by applying a magnetic attraction force between the magnet 138 and the magnet 138 when the driving coil 140 is energized. Adsorption magnet pieces (adsorption pieces) 150 which are fixed regularly are attached. In addition, on the outer surface of the bottom wall 111 of the casing 110, a wiring board 170 for connecting the terminal of the conducting wire of the driving coil 140 to the external wiring is provided with a bottom wall ( 111) It is attached to the support convex part 118 of the outer surface.

In this case, as shown in FIG. 7, the terminal of the conducting wire of the driving coil 140 is drawn out to the outside through a small hole 119 of the bottom wall of the casing 110, and thus the conductor of the wiring board 170. It is connected to one end 171a of the body 171 by soldering, and the external wiring can be soldered to the other end 17lb of the conductor 171 of the wiring board 170. have.

Next, the operation will be described.

When the power is applied to the drive coil 140, the rotor 130 rotates. When the rotor 130 rotates, the drive ring 20 is rotated by the movement of the lever 132, the aperture blade 30 is interlocked by the rotation of the drive ring 20 is rotated to adjust the aperture diameter. . When the energization is stopped, a suction force is generated between the suction magnet piece 150 and the magnet 138 of the rotor 130 in the free state, whereby the rotor 130 is supported at a predetermined position. By this, the iris blade 30 is supported at a predetermined aperture position.

According to this diaphragm device, the bobbin is removed using a bobbinless air core coil for the drive coil 140, and the bearing hole (1) in which the shaft end 135 of the rotor 130 is formed in the base frame 11 ( 19) and the base coil 11 is provided with an evacuation hole 18 for avoiding interference with the drive coil 140 to close the drive coil 140 to the base frame 11. As a result, the thickness dimension H (Fig. 1) of the entire diaphragm including the axial dimension of the actuator 100 can be reduced, thereby contributing to compactness.

In addition, since the bobbinless hollow core coil (driving coil) 140 is inserted into the convex portion 115 formed in the mouth wall 114, the coil 140 can be stably supported, thereby positioning the coil 140. It may be to include easy to attach. Moreover, since the adsorption magnet piece 150 is attached using the mouth wall 114 which supports the coil 140, the structure is simplified.

Moreover, although the case where the diaphragm wing | blade 30 is arrange | positioned by 3 sheets and 120 degrees space | interval is shown in the said Example, the number of the diaphragm wings may be other than three sheets. For example, five or six sheets may be arranged at equal intervals in the circumferential direction.

1 is a schematic side cross-sectional view of an aperture device according to an embodiment of the present invention.

Fig. 2 is a plan view showing a state before attaching an actuator of the diaphragm device.

Fig. 3 is a bottom view showing a state before attaching an actuator of the aperture device.

Fig. 4 is a plan view of a portion to which an actuator of the same diaphragm is attached.

Fig. 5 is a configuration diagram of the actuator, where (a) is a plan view and (b) is a side sectional view.

Fig. 6 is a configuration diagram of the casing of the actuator, where (a) is a plan view and (b) is a side sectional view.

Fig. 7 is a bottom view of the actuator, in which (a) shows a state before attaching the wiring board, and (b) shows a state with the wiring board attached.

Explanation of symbols on the main parts of the drawings

11 base frame 14 center opening

18: escape hole 19: bearing hole

30: aperture wing 100: actuator

110 casing 114 wall

115: convex 117: bearing hole

120: operation transmission mechanism 130: rotor

131: main body of the rotor 138: magnet

140: drive coil (Bobbinless core coil)

150: adsorption magnet piece

Claims (3)

A base frame having a flat plate shape having an opening that serves as an optical path, An aperture blade installed to slide on the base frame and slide-driven to adjust an amount of light passing through the opening; A rotary actuator in which a rotation axis of the rotor itself is attached to the base frame in a direction orthogonal to the base frame to drive the aperture blades; , A motion transfer mechanism for converting and rotating the rotor into a slide motion of the aperture blade Respectively, The actuator is, A casing casing connected to the base frame toward an opening end and having a bottom surface; A main body of the rotor supported to rotate in the casing by inserting both shaft ends into bearing holes formed in the base frame and bearing holes formed in the bottom wall of the casing, respectively; A cylindrical magnet mounted on the outer periphery of the main body of the rotor and magnetized so that the magnetic poles are aligned in the circumferential direction thereof; A winding wire is wound around the central opening, and the winding surface of the coil is parallel to the axis of rotation of the rotor on the side of the rotor including the main body of the rotor and the magnet. The rotor is disposed so as to be positioned, and is mounted to the casing so as to receive a part of the circumferential direction of the magnet in the central opening, and energizes the magnet to rotate the rotor by applying a magnetic force to the magnet. With driving coil Composed, The drive coil is composed of a bobbinless hollow core coil, An aperture device is formed in the base frame to avoid the interference with the air core coil and to allow the air core coil to be close to the base frame side. The method according to claim 1, An aperture wall parallel to the rotor is formed in the casing, and a convex portion in which the central opening of the hollow core coil of the bobbinless is inserted is formed in the mouth wall. The method of claim 2, Adsorption piece which sets the rotational position of the rotor uniformly by exerting a magnetic attraction force between the magnet and the magnet when the hollow core coil is energized on the back surface of the mouth wall. A diaphragm device characterized by being provided.

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