KR20060053625A - Cooling structure of outter rotor motor for drum type washing machine - Google Patents

Abstract

The present invention is a cylindrical rotor 10, one side of which is opened from the outside of the stator is coupled, the heat dissipation of the outer rotor motor for a drum washing machine in which a plurality of heat radiating holes (1) radially continuous formed in the lower portion of the rotor (10) Regarding the structure, the lower portion of the rotor 10 is cut into a channel shape to form a cutting surface 1A, and the inside of the cutting surface 1A is bent outward to the cooling fins connected to the heat radiating holes 1. (2) was formed.

The present invention as described above, during the forward and reverse rotation of the rotor 10 according to the operation of the drum washing machine, the heat is discharged through the surface of the rotor 10 and the rectangular heat radiating hole (1) at the same time integrally with the heat radiating hole (1). The contact area with the air is increased by the cooling fins 2 connected to each other vertically, so that the drum washing machine has an excellent cooling effect even when the drum washing machine is continuously operated.

Therefore, the present invention prevents the efficiency decrease by preventing overheating of the outer rotor motor 50 for the drum washing machine, thereby preventing damage to the components due to overheating.

Drum washing machine, outer rotor motor, heat sink, cooling fins

Description

Heat dissipation structure of outer rotor motor for drum washing machine {COOLING STRUCTURE OF OUTTER ROTOR MOTOR FOR DRUM TYPE WASHING MACHINE}

1 is a perspective view of a main part showing an example of a drum washing machine having a conventional structure;

2 is a perspective view of a rotor constituting an outer rotor motor for a drum washing machine having a conventional structure;

3 is a bottom perspective view of the present invention;

4 is a cross-sectional view of the present invention shown in FIG.

5 is a bottom view of the present invention,

6 is a view showing the operation of the present invention.

<Explanation of symbols for main parts of drawing>

1: heat sink 1A: cutting surface

2: cooling fin 10: rotor

The present invention relates to a drum washing machine, and in particular, by forming the cooling fins vertically from one side of the heat radiating hole of the rotor constituting the outer rotor motor for the drum washing machine, the contact area with air is increased while the cooling effect is increased accordingly. It is configured to be.

In general, a drum washing machine rotates a cylindrical drum from inside a washing tank, while washing is performed by dropping laundry from the top of the drum to the bottom in this process.

In the drum type washing machine, the damage caused by the twisting of the laundry is relatively less than that of the pulsator type washing machine or the edge data type washing machine, and the amount of the washing water used is the pulsator type washing machine or the edge data type washing machine. It is relatively small compared with.

As shown in FIG. 1, the drum type washing machine is rotatably provided with a drum 120 that provides a laundry space in a storage tank 110 installed horizontally from an upper portion of the base 130. The upper portion of the reservoir 110 is provided with a detergent supply barrel 140 for supplying a laundry detergent and the like, including a laundry aid such as fabric softener.

In addition, the tension coil spring is coupled between the upper cabinet and the reservoir 110 in order to absorb the vibration and shock generated by the rotation and stop of the drum 120 or the fall of the laundry during the washing and dehydration process, the lower part of the cabinet By connecting the oil damper 160 between the lower portion and the reservoir 110, the elasticity of the tension coil spring and the damping action of the oil damper 160 to reduce the vibration or impact.

The drum washing machine 200 having the structure as described above typically has a drying function to allow the laundry to be dried after the end of washing and dehydrating stroke, and thus the drum washing machine 200 is disposed between the top and the back of the drum washing machine 200. As the chamber 170 having the heat transfer heater and the drying device including the blower fan 175 and the condensation duct 180 are combined, the air inside the drum is repeatedly circulated, and the hot air into the drum 120 in the process. At the same time to spray the condensation of moisture contained in the air to dry the laundry.

On the other hand, the back of the water tank of the drum washing machine 200 is provided with a motor for driving the drum 120, such a drive motor is a mutual interaction between the rotating magnetic field generated in the stator portion and the induction magnetic field generated in the rotor portion While the rotational force is generated by the action, various designs such as three-phase induction motor and three-phase winding-type induction motor including single phase are possible, and induction electromotive-type motors having constant speed and long life are widely used.

As described above, a basic configuration of an induction electric motor used as a driving motor of the drum washing machine 200 includes a housing, a stator that generates induction magnetism by receiving power from the outside through a coil wound and fixed to the housing, and The rotating shaft is supported by a bearing installed in the housing and consists of a rotor and the like that rotate together with the rotating shaft coupled by an induction magnet generated from the stator.

Such an induction electric motor is a current induced in the secondary winding by the electromagnetic induction of the primary winding connected to the power source, and obtains a rotational force by the interaction of the current and the rotating magnetic field induced in the secondary winding, the relative between the stator and the rotor According to the position, it is divided into inner rotor type and outer rotor type.

On the other hand, the inner rotor type induction motor is limited in the rotor diameter as the rotor rotates through the inside of the stator, thereby reducing the torque generated in the same volume and the utilization of the internal space is reduced.

Therefore, in recent years, an outer rotor-type induction motor has been disclosed that can increase torque in the same volume by increasing the outer rotor of the stator and increase the utilization of the inner space of the stator.

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

Such a rotor is processed in a cylindrical shape according to the drawing method by the press as shown in Figure 2, the inner peripheral surface is formed with a yoke portion (110A) having a step, the permanent magnet ( 103 is coupled to each other, and a rotation shaft connecting member 105 having a serration groove 105A is coupled to a central portion thereof so as to insert the rotation shaft of the drum.

On the other hand, during the operation of the motor, as heat is generated, radially continuous heat radiating holes 101 are formed in the lower portion of the rotor 110 so as to circulate air through the heat radiating holes 101 to rotate the rotor 110. Allow the heat of each component including the heat to be released to the outside.

However, in the conventional rotor 110 configured to cool through the heat radiating hole 101 as described above, the heat generated during the operation of the motor is not effectively released due to the limited contact area with air. The efficiency is sharply lowered.

Therefore, the drum washing machine employing the rotor 110 of the conventional structure has a problem that the efficiency is drastically reduced when the continuous operation for a long time, the washing is not made smoothly accordingly.

The present invention is to solve the above-described problems, the technical problem of the present invention, the contact area with the air by forming a cooling fin vertically from one side of the heat radiating hole of the rotor constituting the outer rotor motor for drum washing machine. In addition, to provide a means to increase the cooling effect accordingly.

Technical problem of the present invention as described above,

In the outer rotor motor for a drum washing machine is coupled to the cylindrical rotor of which one side is opened from the outside of the stator, a plurality of heat dissipation holes radially continuous in the lower portion of the rotor,

By cutting the lower part of the rotor into a channel shape to form a cut surface, by bending the inner side of the cut surface in the outward direction by providing a heat dissipation structure of the outer rotor motor for a drum washing machine, characterized in that continuously forming a cooling fin connected to the heat radiating hole. Is achieved.

Hereinafter, a heat dissipation structure of an outer rotor motor for a drum washing machine according to the present invention will be described in detail with reference to the accompanying drawings.

Figure 3 is a bottom perspective view of the present invention, Figure 4 is a cross-sectional view of the present invention shown in Figure 3, the heat dissipation structure of the outer rotor motor for a drum washing machine according to the present invention is coupled to the outside of the stator outer rotor for a drum washing machine It is formed radially from the lower portion of the rotor 10 constituting the motor to be radiated by heat exchange in contact with the external air.

Accordingly, the heat dissipation structure of the outer rotor motor for a drum washing machine according to the present invention prevents the efficiency of the outer rotor motor due to overheating during the operation of the drum washing machine and prevents damage to components.

As described above, the present invention is processed into a cylinder in which an engaging surface with the stator is opened by a draw method by a press as in a rotor manufacturing process having a conventional structure, and a yoke portion 10A having a step is formed at an inner circumferential surface thereof. The permanent magnets 13 are continuously arranged at equal intervals through the yoke portion 10A.

At the same time, the rotation shaft connecting member 15 having the serration groove 15A formed therein is coupled to the center of the rotor 10 by insert molding.

Subsequently, in the heat dissipation structure of the outer rotor motor for a drum washing machine according to the present invention, by cutting the lower part of the rotor 10 into a channel shape, as shown in FIG. 5, the cut surfaces 1A are radially centered around the center of the rotor 10, respectively. The inner side of the cut surface 1A is bent outward.

Accordingly, each of the rectangular heat dissipation holes 1 providing radial flow paths from the lower part of the rotor 10 is radially formed, and the cooling fins 2 are respectively connected to the heat dissipation holes 1. It has a vertically continuous structure.

The cooling fin 2 increases the heat dissipation effect by increasing the contact area with air, and prevents the efficiency decrease of the outer rotor motor for a drum washing machine due to overheating.                     

The operation of the present invention having the above configuration will be described below with reference to FIG.

The heat dissipation structure of the outer rotor motor for a drum washing machine according to the present invention is coupled to the outside of the stator to form a continuous radially from the lower portion of the rotor 10 constituting the outside of the outer rotor motor for the drum washing machine. Allow heat dissipation by heat exchange.

In the present invention as described above, during the forward and reverse rotation of the rotor 10 according to the operation of the drum washing machine, heat is discharged through the surface of the rotor 10 and the rectangular heat radiating holes 1, and at the same time, the heat radiating holes 1 and The contact area with air is increased by the cooling fins 2 connected to each other vertically, so that the drum washing machine has an excellent cooling effect even when the drum washing machine is continuously operated, thereby preventing overheating of the outer rotor motor 50 for the drum washing machine. do.

Therefore, the heat dissipation structure of the outer rotor motor for a drum washing machine according to the present invention prevents overheating during continuous operation for a long time due to the excellent heat dissipation effect, thereby preventing the efficiency reduction of the outer rotor motor for the outer drum washing machine. To prevent damage to the internal components.

As described above, the heat dissipation structure of the outer rotor motor for a drum washing machine according to the present invention is the cooling fins 2 from one side of the heat dissipation hole 1 continuously formed radially from the lower portion of the drum rotor outer rotor motor 50. Each of them is formed vertically to increase the contact area with air, thereby increasing the cooling effect.

Accordingly, the heat dissipation structure of the outer rotor motor for a drum washing machine according to the present invention increases heat dissipation effect, thereby preventing overheating of the outer rotor motor 50 for a drum washing machine even in a continuous operation for a long time, thereby preventing a decrease in efficiency. In addition, there are many effects such as preventing damage to internal components due to overheating.

The present invention has been shown and described above with respect to specific preferred embodiments.

However, the present invention is not limited to the above-described embodiments, and various modifications may be made by those skilled in the art without departing from the gist of the present invention as claimed in the claims.

Claims (2)

In the outer rotor motor for a drum washing machine is coupled to the cylindrical rotor 10, the one side of which is opened from the outside of the stator, radially continuously formed a plurality of heat dissipation holes (1) in the lower portion of the rotor (10), The lower portion of the rotor 10 is cut into a channel shape to form a cutting surface 1A, and the inside of the cutting surface 1A is bent outward to continuously form the cooling fins 2 connected to the heat radiating holes 1. Heat dissipation structure of the outer rotor motor for a drum washing machine, characterized in that. The heat dissipation structure of an outer rotor motor for a drum washing machine according to claim 1, wherein the cooling fins (2) are bent vertically from the surface of the rotor (10), respectively.

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