JP2010057234A - Direct-acting actuator - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a direct-acting actuator which enables the user to efficiently perform checking of the assembly condition or the adjustment, or the checking work of initial setting, such as origin setting of a press-starting position of a working body through manual operation, without having to use a driving power source, when the actuator is to be couple to a working body which pushes and pulls the tip of an output shaft 4. <P>SOLUTION: The direct-acting actuator includes an extension (or extensions) 322, by extending one or both ends of a rotor 3 located outside a casing 1a, and this extension 322 is structured as a rotating shaft which can transmit rotation, being formed around outer circumference of the output shaft 4. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a linear motion actuator in which an output shaft screwed into a central shaft hole of a rotor is driven to reciprocate by a screw feed mechanism accompanying rotation of the rotor.

In general, this type of direct acting actuator (motor) has an output shaft composed only of a screw shaft (screw shaft) (Patent Document 2), a screw shaft, and a rotor or motor case (casing). It is formed of a non-circular bearing that is non-circularly supported by a rotation-preventing bearing, or a rotation-preventing shaft portion provided with a rotation-preventing pin, both of which are screw threads formed in a central shaft hole of a rotor (rotor). The screw is engaged with the engraved portion and moved forward and backward by forward and reverse rotation of the rotor (see Patent Document 1 and FIG. 3).
When the output shaft consists only of the screw shaft, the output shaft moves forward and backward when the motor case side is set on the base, and the motor case itself moves forward and backward when the output shaft is fixed. (See Patent Document 2 and FIG. 1).

  By the way, the output shaft that moves forward and backward in this way is employed in, for example, a device (see Patent Document 2 and FIG. 1) in which the distal end portion is connected to an operating body and the operating body is pushed and pulled. At the time of connection, it is necessary to perform initial set adjustment and confirmation such as confirmation of the assembly condition and setting of the origin of the pushing start position of the operating body.

However, in the conventional initial set adjustment and confirmation work, if the rotation-preventing shaft portion that is D-cut on both sides is structured to be prevented from rotating by the rotor, the rotation-preventing shaft portion can be rotated using a tool. Although the output shaft can be adjusted by rotating the rotor manually even in a non-energized state, in other configurations including those of Patent Documents 1 and 2, due to factors such as damage to the threads Since it cannot be clamped and must be performed exclusively by the ON / OFF switching operation of the motor power supply, it takes time for the setting work and impairs the work efficiency.
In addition, even if the non-rotating shaft part that has been D-cut on both sides as described above is supported by the rotor, the cut surface will be damaged when the detent shaft part is clamped with a tool. Therefore, there is a possibility that manual adjustment is avoided because there is a risk of damaging the fit with the bearing.

Japanese Patent Laid-Open No. 10-38075 JP 2004-308690 A

  The present invention has been devised to eliminate the above-mentioned problems. When the tip of the output shaft is connected to an actuating body that pushes and pulls, it is possible to confirm the assembly condition and to push the actuating body. It is an object of the present invention to provide a direct acting actuator that can perform an initial set adjustment and confirmation work such as setting the origin of a movement start position manually and efficiently without using a drive power source.

  In order to solve the above problems, the technical means adopted by the present invention includes a rotor disposed in a casing so as to be rotatable by excitation of a coil, and a threaded portion formed in a central shaft hole of the rotor. And a linear motion type actuator having an output shaft provided so as to be able to advance and retreat in accordance with its rotation, wherein either one or both ends of the rotor are extended to the outside of the casing. The rotation shaft formed on the outer periphery of the output shaft is capable of transmitting rotation.

When the linear actuator in the present invention is connected to the operating body that pushes and pulls the tip of the output shaft, adjustment of the initial set such as confirmation of the assembly state and setting of the origin of the pushing start position of the operating body is performed. Although the rotating shaft that extends outside the casing is exposed, the rotor is directly rotated and output manually by simply holding the rotating shaft and rotating it. The shaft can be moved in and out, and the initial setting work can be performed without using a drive power supply. The risk of damaging the output shaft screw during the work is eliminated, and the setting work is easy and quick. Can improve the working efficiency. Moreover, the rotating shaft is not only used as a manual operation, but it is also possible to attach sensor fins to check the rotation state and easily locate the origin where the actuator itself starts operating, and to move the output shaft in and out. It is also possible to interlock and connect to the operating body as a rotation transmission shaft synchronized with the operation, and the range of use can be expanded. In particular, it is effective for a motor having a detent torque, such as a stepping motor of PM type or HB type.

DESCRIPTION OF THE PREFERRED EMBODIMENTS A linear actuator that exemplifies an embodiment of the present invention as a preferred embodiment will be described below in detail with reference to the drawings.
1 is an overall configuration diagram of the linear actuator, FIG. 2 is a rear view thereof, and FIG. 3 is a front view thereof. As shown in these drawings, 1 is a linear motion actuator having a PM type stepping motor structure. The linear motion actuator 1 has a cylindrical body portion as a yoke (stator) including a set of coil bobbins 21 and an excitation coil 22. 11, a casing 1 a composed of an end side portion 12 and a front side portion 13, and an inner peripheral side of the cylindrical body portion 11, and a bearing 14 is rotatably supported on the end side portion 12 and the front side portion 13. The entire region excluding the rotor 3 magnetized in multiple poles and the connecting portion 41 at the tip is formed as a male screw, and is screwed into the central shaft hole 32a of the rotor 3 so as to be able to move forward and backward. And a bolt-shaped output shaft 4.
The cylindrical body 11 is formed of iron, magnetic stainless steel, or the like, and a plurality of concave and convex pole teeth (not shown) are formed at a constant pitch on the inner peripheral surface corresponding to the magnetic pole interval of the rotor 3. A two-phase coil unit is configured.

The rotor 3 has a cylindrical first rotor collar 31 made of resin, such as resin, brass, copper or aluminum having a shaft hole 32a at the center thereof, and a second rotor disposed on the inner peripheral surface thereof. The collar 32 and a ring-shaped magnet 33 that is arranged on the outer peripheral surface of the first rotor collar 31 and has S poles and N poles alternately magnetically attached thereto.
The shaft hole 32a is formed in the second rotor collar 32 which is the center inside of the rotor 3, and an inner diameter space larger than the outer diameter of the output shaft 4 is formed in the shaft hole 32a. In addition, a threaded portion 321 as an internal thread that is screwed into the output shaft 4 is formed in one side (front side) region thereof.

  Further, the second rotor collar 32 is inserted into the cylinder of the first rotor collar 31 from the front side through a non-illustrated non-illustrated engaging means, and is engaged with a step formed on the inner cylinder. In the casing 1a, it is rotatably supported by bearings 14 provided on the end side portion 12 and the front side portion 13 in the casing 1a.

The second rotor collar 32 is formed with an extension portion 322 that is extended from the end side portion 12 that is the outside of the casing 1 a with a predetermined length and width. The extension portion 322 is formed on the output shaft 4. It functions as a cylindrical rotary shaft formed on the outer periphery and capable of transmitting rotation. That is, when the rotor 3 is rotated by the drive power supply, the extending portion (rotating shaft) 322 is naturally rotated, and the output shaft 4 is also moved forward and backward so that a so-called synchronized double shaft structure is formed. Yes, when the energization part (rotating shaft) 322 is sandwiched with fingers or tools and manually rotated during non-energization, the rotation of the rotor 3 is transmitted and the output shaft 4 can be moved forward and backward. It has a configuration.
The extending portion (rotating shaft) 322 shown in the present embodiment is provided on the end side portion 12 with a length and width that can be clamped with a finger or the like so that the output shaft 4 can be moved forward and backward by manual operation without using a driving power source. However, if the purpose is to transmit the rotation to the operating body, it can be formed to extend from the front side portion 13 as indicated by the temporary wire.

As an application example thereof, for example, a configuration in which a display unit of a game machine such as a pachinko machine or a throttle machine simultaneously performs an appearance operation and a rotation operation is preferable.
The rotor collar in this example is formed of a strong metal member so that the first rotor collar 31 is formed of a resin member, and the second rotor collar 32 is not easily damaged even when sandwiched with a tool or the like. Although it was formed by two members using a thing, both may be formed integrally, and extension part (rotating shaft) 322 may be extended and formed in either one or both of rotors 3, In addition, the extension length and outer shape may be changed to an arbitrary shape such as a circle or a square, and the surface may be knurled, cut, or the like.

  In the form of the embodiment of the present invention configured as described above, when the tip of the output shaft 4 is connected to the actuating body that pushes and pulls, the assembly condition is confirmed and the pushing start position of the actuating body is determined. In the linear motion actuator 1 according to the present invention, either or both ends of the rotor 3 are extended to the outside of the casing 1a. The extending portion 322 is configured to function as a tubular rotating shaft formed on the outer periphery of the output shaft 4 and capable of transmitting rotation.

  Therefore, by simply holding the extending portion (rotating shaft) 322 and rotating it, the rotor 3 can be rotated directly by hand and the output shaft 4 can be moved in and out. Work can be performed, and the fear of damaging the threads of the output shaft 4 during work is eliminated, and the set work can be performed easily and in a short time, thereby improving work efficiency. In addition, the extending portion (rotating shaft) 322 is not only used as a manual operation, but also a sensor fin for confirming the rotation state and easily positioning the origin at which the linear actuator 1 starts operating. It is also possible to interlock and connect to the operating body as a rotation transmission shaft that synchronizes with the movement of the output shaft 4 and the like, and the range of use can be expanded. In particular, it is effective for a motor having a detent torque, such as a stepping motor of PM type or HB type.

  The rotor 3 is composed of a first rotor collar 31 in which a ring-shaped magnet in a PM type or HB type motor is sheathed, and a second rotor collar 32 that is fitted into the center hole of the first rotor collar 31. Since the extending portion (rotating shaft) 322 is formed by extending the second rotor collar 32, the first rotor collar 31 and the second rotor collar 32 are formed of different materials. Only the second rotor collar 32 is formed of a metal member and can be provided as a durable one that is not easily damaged even if it is clamped by a tool or the like, and is formed on either the front side or the end side. Several different types such as those formed on both sides can be prepared and assembled according to the purpose.

In addition, the rotor 3 is a rotor collar in which the first rotor collar 31 and the second rotor collar 32 are integrally molded, and the extending portion (rotating shaft) 322 is also integrally molded with the rotor collar, thereby reducing the number of parts. As a result, the assembly process can be simplified. In this embodiment, the stepping motor is exemplified as the direct acting actuator, but the present invention is not limited to this, and it is needless to say that the present invention can be applied to various types such as a brushless DC motor.

The whole cross-section block diagram of a linear actuator. The rear view of a linear motion actuator. The front view of a linear actuator.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Linear motion actuator 1a Casing 11 Cylindrical trunk | drum 12 End side part 13 Front side part 14 Bearing 21 Coil bobbin 22 Excitation coil 3 Rotor 31 1st rotor collar 31a Ring 32 2nd rotor collar 32a Shaft hole 321 Screw part 322 Extension Protruding portion 33 Ring-shaped magnet 4 Output shaft 41 Connecting portion

Claims (4)

A rotor that is rotatably arranged by excitation of a coil in the casing, and a threaded portion formed in a central shaft hole of the rotor, and is provided so as to be able to move forward and backward with its rotation. A direct acting actuator having an output shaft,
One or both of the end portions of the rotor are extended to the outside of the casing to form a rotation shaft formed on the outer periphery of the output shaft and capable of transmitting rotation. The linear actuator according to claim 1, wherein the rotary shaft is configured to be capable of moving the output shaft forward and backward by a manual rotation operation when power is not supplied. 3. The rotor according to claim 1, wherein the rotor includes a first rotor collar on which a ring-shaped magnet is sheathed, and a second rotor collar that is fitted into a center hole of the first rotor collar, and the rotation shaft is The linear actuator is formed by extending the second rotor collar. 3. The linear actuator according to claim 1, wherein the rotor is formed of a rotor collar on which a ring-shaped magnet is externally mounted, and the rotating shaft is integrally formed with the rotor collar.