KR100850595B1 - Method and Apparatus for Preventing Overloaded Motors - Google Patents

Abstract

The present invention relates to a motor used for an injection molding machine or a general purpose, the motor (2) is fixed to one side of the body (1), the flow rotating body (4) is installed on the motor shaft (3), one side of the rotating shaft A true concave-convex portion (6) having a fixed rotating body (5) connected thereto (11) but having an inclined portion (10) formed at a predetermined angle on a surface of abutting portion of the fixed rotating body (5) and the floating rotating body (4). ) To form and combine, and to form a fastening hole in the interior of the flow rotating body (4) by inserting the spring (7) and the fastener (8) fastening to the fixed rotating body (5) with a fixing bolt (9) By the force of the spring (7) is to make the flow rotating body 4 is coupled to the fixed rotating body (5).

The present invention as described above is a simple structure that is easy to manufacture and can be prevented from overloading the motor by a simple mechanical configuration, thereby is a useful invention that can extend the life of the motor.

Description

Method for preventing overload of motor and its device {Method and Apparatus for Preventing Overloaded Motors}

1 is a schematic block diagram illustrating a process of the present invention.

2 is a schematic overall perspective view of the present invention

Figure 3 is an enlarged perspective view of the main portion of the present invention

Figure 4 is a schematic perspective view showing a coupled state of the present invention overload protection device

Figure 5 is a schematic side cross-sectional view showing a combined state of the present invention

Figure 6 is an enlarged cross-sectional view of the main portion showing a state before operation of the present invention

Figure 7 is an enlarged cross-sectional view of the main portion showing the state after the automatic of the present invention

8 is a cross-sectional view taken along the line A-A shown in FIG. 5 of the present invention;

** Description of symbols for the main parts of the drawing **

1. Body 2. Motor 3. Motor Shaft

4. Flowing Rotating Body 5. Fixed Rotating Body 6. Unevenness

7. Spring 8. Fixture 9. Fixing Bolt

10. Inclined part 11.Rotary shaft

The present invention relates to a motor used for an injection molding machine or a general purpose, to provide an overload prevention device to the motor to continue to operate the motor when the overload occurs to prevent the motor from being damaged.

In general, a motor for an injection molding machine motor or various machines is provided with a pulley installed on the motor shaft to transfer power by using a belt. At this time, the motor shaft may not rotate smoothly because an abnormality occurs in a rotating body of another device. In this case, the motor is overloaded, which causes the motor to break.

As described above, when the motor is damaged due to overload, there is a disadvantage in that the work line is stopped, resulting in enormous damage, and there is a big problem in that unnecessary expense and work time are wasted by replacing the damaged motor.

On the other hand, in order to solve the problems described above, a method of stopping the motor when an overload occurs by installing a sensor in the motor has been proposed in the prior art, the above method has a problem that the structure is complicated and can not be used in a simple machine.

The present invention has been invented to solve the above problems, the fixed rotating body is installed on the shaft of the motor, the flow rotating body is installed on one side of the fixed rotor and the surface of the contact portion of the fluid rotating body at a constant angle One side is formed by inclined concave-convex portion to be coupled to the inside of the flow rotating body by fastening the spring fixed to the fixed screw by the fixing screw, so that the fixed rotation to the fixed rotating body, the present invention by the accompanying drawings It will be described in detail as follows.

Step in which the motor rotates:

Rotating the flow rotor and the fixed rotor engaged therewith:

The stage of rotation of the rotating shaft:

Overloading the rotating shaft:

Stopping phase due to overloading the fixed rotor:

Step of moving the flow rotating body by the inclined portion of the concave and convex fastened to the flow rotating body and the fixed rotating body:

Steps where the spring is compressed:

Step out of the flow rotor from the stationary rotor:

Rotation stage in which the floating rotor rotates away from the stationary rotor:

When the inclined portion of the concave-convex portion fastened to the flow rotating body and the fixed rotating body is returned to the original state by the elastic force of the spring:

Step of moving the flow rotating body by the inclined portion of the concave and convex fastened to the flow rotating body and the fixed rotating body by the force of the motor again:

It consists of a repetitive rotation step.

Referring to the configuration of the present invention as described above is as follows.

The motor 2 is fixedly installed on one side of the body 1, but the floating rotor 4 is installed on the motor shaft 3, and the fixed rotor 5 connected to the rotating shaft 11 is installed on one side thereof. On the surface of the abutting portion of the fixed rotating body 5 and the flow rotating body 4 to form a concave-convex portion 6 with one inclined portion 10 is formed at a predetermined angle to be coupled, The clamping hole is formed therein to insert the spring (7) and the fastener (8) to fasten to the fixed rotating body (5) with the fixing bolt (9) by the force of the spring (7) flow rotating body (4) Is to be coupled to the fixed rotating body 5, reference numeral 12 shows a key for power transmission.

The operation of the present order as described above is as follows.

Fix the body (1) in which the motor (2) is installed in the injection molding machine or various machines.

When the motor 2 is operated in the above state, the motor shaft 3 rotates so that the flow rotating body 4 installed on the motor shaft rotates together.

That is, the uneven parts 6 are formed at regular intervals at the contact portions of the flow rotating body 4 and the fixed rotating body 5 formed in a circular shape, and are inclined in the direction in which the power of each uneven part 6 is transmitted. Since the fixed rotor 5 and the floating rotor 4 are coupled to each other at a constant pressure by forming the unit 10, the fixed rotor 5 rotates at the same time as the rotating rotor 4 rotates. .

When the overload occurs on the rotary shaft 11 connected to the fixed rotary body in the above state, the rotation of the rotary shaft 11 is not smooth, and thus the fixed rotary body 5 also is not smoothly rotated together.

In this case, when the rotation is not smooth, pressure is applied to the flow rotating body 4 that is rotating at a constant rotational speed by the motor 2, whereby the flow rotating body 4 and the fixed rotating body 5 are rotated. Since the pressure is generated in the concave-convex portion 6 in contact with each other, the inclined portion 10 formed in the concave-convex portion of the flow rotating body 4 causes the difference in the rotational force in the inclined portion formed in the concave-convex portion of the fixed rotating body 5. do.

As described above, the inclined portion formed in the uneven portion of the flow rotating body 4 has a strong force to rotate by the rotational force of the motor 2, so that the pressure pushes the inclined portion formed in the uneven portion of the fixed rotating body 5, As a result, the flow rotating body 4 moves outward from the inclined portion of the uneven portion of the uneven portion while pressing the spring 7 which is fastened therein, and moves away from the uneven portion of the fixed rotating body 5. The rotating rotor 4 continues to rotate by the rotational force.

At this time, the fastener 8 screwed to the fixed rotating body 5 is moved to the left and right by the elasticity of the spring 7 in the fastening hole formed in the flow rotating body (4).

As such, when the overload occurs in the rotating shaft 11, the above-described operation continues and the moving rotor 4 continuously moves from side to side, thereby constantly rotating by the motor 2, thereby overloading the motor 2. This can be prevented.

As described above, in the present invention, the fixed rotor is installed on the shaft of the motor, and the floating rotor is installed on one side thereof, and the one side is inclined at a predetermined angle on the surface of the contact portion of the fixed rotor and the movable rotor. The inside of the flow rotating body is fastened to the fixed rotating body by fastening the spring by fastening the fixing screw, and the flow rotating body is fixed to the fixed rotating body, the structure is simple, easy to manufacture and simple mechanical configuration to overload the motor Can be prevented from occurring, and this is a useful invention that can extend the life of the motor.

Although the present invention has been described in detail only with respect to the described embodiments, it will be apparent to those skilled in the art that various modifications and changes can be made without departing from the spirit of the present invention, and such variations and modifications do not change the appended claims. Is a matter of course.

Claims (3)

Step in which the motor rotates: Rotating the flow rotor and the fixed rotor engaged therewith: The stage of rotation of the rotating shaft: Overloading the rotating shaft: Stopping phase due to overloading the fixed rotor: Step of moving the flow rotating body by the inclined portion of the concave and convex fastened to the flow rotating body and the fixed rotating body: Steps where the spring is compressed: Step out of the flow rotor from the stationary rotor: Rotation stage in which the floating rotor rotates away from the stationary rotor: When the inclined portion of the concave-convex portion fastened to the flow rotating body and the fixed rotating body is returned to the original state by the elastic force of the spring: The moving of the flow rotating body by the inclined portion of the concave-convex fastened to the flow rotating body and the fixed rotating body by the force of the motor again: Motor overload prevention method characterized in that consisting of a repeating rotation step. The motor 2 is fixedly installed on one side of the body 1, but the floating rotor 4 is installed on the motor shaft 3, and the fixed rotor 5 connected to the rotating shaft 11 is installed on one side thereof. On the surface of the abutting portion of the fixed rotating body 5 and the flow rotating body 4 to form a concave-convex portion 6 with one inclined portion 10 is formed at a predetermined angle to be coupled, The clamping hole is formed therein to insert the spring (7) and the fastener (8) to fasten to the fixed rotating body (5) with the fixing bolt (9) by the force of the spring (7) flow rotating body (4) The overload protection device of the motor, characterized in that the coupling to the fixed rotor (5). The overload protection device for a motor according to claim 2, wherein an overload protection device is provided on a motor shaft provided in the motor.

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