KR101092324B1 - Heat sink hole of rotor for outer rotor type motor - Google Patents

Abstract

Disclosed is a rotor heat dissipation structure of an outer rotor type motor, in which a structure for heat dissipation during rotation of an outer rotor type motor is easily formed on the bottom of the rotor, and at the same time, the heat dissipation effect is maximized to facilitate processing of the rotor and improve reliability. According to the present invention, a rotor having a yoke surface to which a permanent magnet for attaching a magnetic field to the winding field of the stator is attached while rotating from the outside in a manner of accommodating the stator of the winding field, and fastening the rotor and the rotating shaft. A rotor heat dissipation structure of an outer rotor-type motor, which includes a shaft bushing which is mediated for the purpose, comprising: a smooth stepped portion projecting inwardly from a bottom portion of the rotor; And it provides a rotor heat dissipation structure of the outer rotor type motor including; a plurality of through-holes formed to be aligned on one side of the smooth step. Thus, the structure for the heat dissipation during the rotation of the outer rotor-type motor is easily formed on the bottom of the rotor and at the same time the heat dissipation effect is maximized, so that the processing of the rotor is easy and the reliability is improved.

Motor, rotor, heat dissipation, warp, through hole

Description

Heat dissipation structure of outer rotor type motor {HEAT SINK HOLE OF ROTOR FOR OUTER ROTOR TYPE MOTOR}

1 is a perspective view of a conventional rotor.

2 is a cross-sectional view of FIG.

3 is a perspective view of a rotor according to the present invention.

4 is a cross-sectional view of FIG.

<Description of the symbols for the main parts of the drawings>

10: rotor 20: yoke face

30: permanent magnet 40: bushing

50: smooth step 51: smooth surface

52, 54: slope 53: through hole

The present invention relates to a rotor heat dissipation structure of the outer rotor type motor, and more particularly, to improve the heat dissipation structure formed on the bottom surface of the rotating rotor to improve the heat dissipation effect and at the same time prevent the decrease in the strength of the rotor according to the heat dissipation structure. It relates to a rotor heat dissipation structure of an outer rotor type motor.

In general, among the types of motors according to various motor start-up methods, induction electric motors induce electric currents in secondary windings by electromagnetic induction of primary windings connected to a power source, and mutually By obtaining the rotational force by the action, it is divided into inner rotor type and outer rotor type according to the relative position of the stator and the rotor.

Inner rotor-type induction motors have a limited rotor radius as the rotor rotates through the inside of the stator, which reduces the utility of the internal space with the disadvantage of less torque produced in the same volume. Recently, an outer rotor type induction motor has been disclosed in which a rotor is provided outside the stator to increase torque at the same volume and utilize the internal space of the stator for other purposes.

The outer rotor type induction motor has a characteristic in which a rotor composed of a drive shaft, a magnet, a rotor case, etc., rotates outside the stator composed of an iron core, a core, a base, a bearing, and the like, that is, the rotor rotates around the stator.

The outer rotor type induction motor is recently employed as a drive motor of a drum washing machine, and the rotor of the outer rotor type induction motor used in such a drum washing machine is shown in FIG. 1.

In the conventional outer rotor-type induction motor, the rotor 100 is manufactured by pressing or the like shape of the iron plate frame 110, the piece of permanent magnet 130 to the back yoke 120 of the iron plate frame 110 After positioning, the permanent magnets 130 are fixed to the back yoke 120 by fixing resin.                         

Then, the connection member 140 installed on the bottom surface of the iron plate frame 110 is fastened with a bolt 145 to couple the connection member 140 to the iron plate frame 110.

On the other hand, the rotor 100 is formed by cutting a plurality of blades 150, the blades 150 to discharge the heat generated inside the iron plate frame 110 by moving the air during the rotation of the rotor 100 ( 155) to discharge.

According to the formation of the blade 150 and the discharge hole 155 as described above, the iron plate frame 110 is to be significantly reduced in strength, protruding to counter the torsion during rotation to reinforce this strength Embossing 160 of the shape must be processed.

However, the above-described processing of the blade 150 and the discharge hole 155 in the rotor 100 of the conventional rotor-type motor having the cross-sectional structure shown in Figure 2, and processing of the embossing 160 for strength reinforcement As a result, the shape of the bottom surface of the iron plate frame 110 is complicated and the number of machining operations is increased, thereby making it difficult to manufacture the rotor.

The present invention has been invented in view of the above problems, and an object of the present invention is that the structure for heat dissipation during rotation of the outer rotor type motor is easily formed at the bottom of the rotor, and at the same time, the heat dissipation effect is maximized to facilitate the processing of the rotor. And to provide a rotor heat dissipation structure of the outer rotor type motor with improved reliability.

In order to achieve the above object, the present invention, a rotor having a yoke surface is attached to the permanent magnet for magnetic action with the winding field of the stator while rotating in the outside in a manner to accommodate the stator of the winding field, the rotor And a shaft bushing configured to fasten the rotating shaft, wherein the rotor heat dissipation structure of the outer rotor type motor formed on the bottom of the rotor comprises: a smooth stepped portion projecting inwardly from the bottom of the rotor; And it provides a rotor heat dissipation structure of the outer rotor type motor including; a plurality of through-holes formed to be aligned on one side of the smooth step.

The smooth stepped portion is formed to face the inclined while extending from the bottom portion, one side inclined surface is formed through the hole; And a smoothing part forming an upper end of the inclined surface.

In addition, the outer end of the yoke surface is bent end portion is formed in a circular cross-section, the bent portion is formed smaller than the height of the permanent magnet, the inclined surface for setting the position of the permanent magnet at the connection portion of the bottom surface of the yoke surface and the rotor Is formed, and an insert portion for insert molding is formed on the rotor on an outer circumferential surface of the rotor bushing so that the rotor and the shaft bushing are integrally formed.

According to the present invention, the stator is fixed to the inside to form a through-hole only in the direction of rotation of the rotor for heat dissipation generated inside the rotor due to the characteristics of the outer rotor type motor rotates from the outside to induce air discharge by the negative pressure inside the rotor inside It has a feature to radiate heat.

A rotor of the present invention having such features is shown in FIG. 3.

The rotor 10 of the present invention has a yoke surface 20 to which a permanent magnet 30 for magnetic action with the winding field of the stator is attached while rotating from the outside in a manner to accommodate the stator of the winding field.

In addition, the shaft bushing 40 is coupled to the center of the rotor 10 in order to fasten the rotor 10 and the rotating shaft.

The shaft bushing 40 has an injection coupling part 45 formed at an outer side thereof, and is integrally inserted into and ejected from the bottom part 15 of the rotor 10 so that the shaft bushing 40 is positioned at the center of the rotor 10. It is firmly combined.

Outside the shaft bushing 40 coupled as described above, the bottom surface portion 15 of the rotor 10 is formed with a smooth stepped portion 50 protruding inward, and one side of the smoothed stepped portion 50 A plurality of through holes 53 are formed in alignment.

In more detail, the smooth stepped portion 50 is formed to face each other with an inclination while extending from the bottom portion 15, and has one inclined surface 52, 54 on which one through hole 53 is formed, and the At the upper ends of the inclined surfaces 52 and 54, the smooth surface 51 is formed to extend.

In addition, the outer end of the yoke surface 20 is bent end portion is formed in a circular cross-section, the bent portion 22 is formed smaller than the height of the permanent magnet 30, the yoke surface 20 and the rotor 10 The connection portion of the bottom portion 15 of the contact surface 24 for setting the position of the permanent magnet 30 is formed.

In the inclined surfaces 52 and 54 of the smooth stepped portion 50, the first inclined surface 52 has a through hole 53 formed only in one direction, and the formation position of the through hole 53 is a rotation direction of the rotor 10. It is formed only in the forward direction based on the reference so that the negative pressure of the air generated inside the rotor 10 when the rotor 10 rotates and the incoming air at the time of rotation do not cross.

The operation of the present invention formed as described above will be described.

As shown in Figure 4, the stator 60 is installed inside the rotor 10 of the subject innovation bar, which is formed by winding the field for magnetic interaction with the permanent magnet 30 of the rotor 10 have.

When the rotor 10 rotates by magnetic action between the stator and the permanent magnets 30 of the rotor 10, the rotor 10 rotates in one direction and air outside the rotating rotor 10 at this time. Flow occurs.

The outer surface of the bottom portion 15 of the rotor 10 forms a lower surface of the smooth stepped portion 50, and air collides with both sides of the inclined surfaces 52 and 54 of the smoothed stepped portion 50.

At this time, the air flow outside the impact on the second inclined surface 54 collides in the opposite direction in which the through hole 53 is formed, and flows independently of the first inclined surface 52 in which the through hole 53 is formed. Due to the difference in air flow between the opposing inclined surfaces 52 and 54, the direction of air flow is constantly determined outside the rotor 10.

On the other hand, when the rotor 10 rotates, for example, when the rotor 10 of the present invention is installed in a device such as a washing machine to perform a dehydration stroke for high speed rotation, negative pressure is generated inside the rotor 10. The negative pressure inside the rotor 10 causes the air flow to be forced outward from the inside of the rotor 10.

Due to the difference between the air flow force due to the negative pressure inside the rotor 10 and the air flow on the inclined surfaces 52 and 54 of the smooth step 50, the air inside the rotor 10 is transferred through the through hole 53. The unilateral discharge is not reversed, which is determined by the negative pressure of the rotor 10 and the one-way flow of the air flow impinging the inclined surfaces 52 and 54.

On the other hand, the smooth surface 51 of the smooth stepped portion 50 protrudes from the inner bottom surface of the rotor 10 to reinforce the strength of the bottom portion 15 due to the torsional force generated when the rotor 10 rotates. This will prevent deformation of the tongue.

As described above, in the present invention, when the rotor 10 is rotated, the inside of the rotor 10 is forcedly discharged by heat flow by one-way air flow, and the torsion during rotation of the rotor 10 is a stepped surface of the smooth step 50. It is dispersed by and deformation is prevented.

By the rotor heat dissipation structure of the outer rotor type motor of the present invention, the structure for heat dissipation during the rotation of the outer rotor type motor is easily formed on the bottom of the rotor and at the same time maximize the heat dissipation effect is easy to process the rotor and improve the reliability It works.

While the invention has been shown and described with respect to specific preferred embodiments thereof, the invention is not limited to the embodiments described above, and is commonly used in the art to which the invention pertains without departing from the spirit of the invention as claimed in the claims. Anyone with knowledge will be able to make various variations.

Claims (3)

Rotor 10 having a yoke surface 20 is attached to the permanent magnet 30 for magnetic action with the winding field of the stator 60 while rotating from the outside in a manner to accommodate the stator 60 of the winding field and In the rotor heat dissipation structure of the outer rotor-type motor including a shaft bushing (40) for fastening the rotor (10) and the rotary shaft, which is formed on the bottom of the rotor (10), A smooth stepped portion 50 protruding inward from the bottom portion 15 of the rotor 10; And Includes; a plurality of through-holes 53 are formed in alignment in the smooth step 50 The smooth stepped portion 50, Inclined surfaces 52 and 54 extending from the bottom portion 15 and having an inclined surface; And It includes a smooth surface 51 to form an upper end of the first inclined surface 52, The through-hole (53) of the rotor heat dissipation structure of the outer rotor type motor, characterized in that formed on only the second inclined surface 54 of the rotation direction of the rotor (10). delete The method of claim 1, The outer end of the yoke surface 20 is bent end 22 is formed in a circular cross-section is formed bent portion 22 smaller than the height of the permanent magnet 30, A contact surface 24 for setting the position of the permanent magnet 30 is formed at the connection portion of the yoke surface 20 and the bottom surface portion 15 of the rotor 10, The outer circumferential surface of the shaft bushing 40 is formed with an injection coupling portion 45 for insert molding in the rotor 10, the rotor 10 and the outer shaft, characterized in that the shaft bushing 40 is integrally formed Rotor heat dissipation structure of rotor type motor.

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