KR20030026485A - Construction for radiation of motor vacuum cleaner - Google Patents

Abstract

PURPOSE: An armature coil is cooled efficiently by using air flowing along a guide vane of a diffuser, thereby improving life span of a motor and reliability. CONSTITUTION: A vacuum cleaner motor comprises a stator having a stator core(6) and a stator coil(7), an armature(8) having an armature core(9) and armature coil(10), and a brush(11). A bearing support(15) and an air collecting plate mounted in the front of the armature coil are separated. Air is used to cool the stator coil. The air is moved to the central part of the motor along the curvature of a guide vane of a diffuser mounted in the front of the motor. Cooling holes are formed in both side of the bearing support to cool the stator coil. Air flowing guide portion is formed in a certain angle in one end of the cooling holes to flow air fluently.

Description

Construction for radiation of motor vacuum cleaner

The present invention relates to a heat dissipation structure of a cleaner motor, and more particularly, by forming a cooling hole in a bearing supporter among components of a conventional motor, and using the air flowed along a guide vane of a diffuser. The present invention relates to a cleaner motor heat dissipation structure that extends the life of a motor by effectively cooling the temperature of an armature coil that has a great influence on the lifespan reliability and the life, and at the same time, lowers the insulation level of the motor. .

Generally, the motor used for a vacuum cleaner is a universal motor which is a single series-wound motor which can use both an AC power supply and a DC power supply. The said universal motor is as shown in FIG. Similarly, a stator 5 formed of a stator core 6 and a stator coil 7, an armature core 9 and an armature coil 10. It consists of a rotor (8) (Armature), a commutator (17), and a brush (11) formed of a), the motor is driven by a single-phase (AC) power source, in series with the single-phase power source The armature coil 10 is connected via the field coil 7, the brush 11, and the commutator 17.

Referring to the rotation of the universal motor configured as described above, in Figures 2 to 3, a torque is generated by the magnetic field flux by the field coil 7 and the armature current of the armature coil 10, the motor As the brush 11 rotates the commutator 17, the brush 11 commutates the current flowing through the armature coil 10 so that the torque and the rotation speed in the same direction are always generated. At this time, the fan (2) (3) connected to the motor shaft 13 is rotated in the same manner as the motor by receiving the rotational force of the motor, the air introduced from the outside through the rotation of the fan (2) (3) The pressure of the air is increased by the strong centrifugal force due to the impeller (2) rotation, the air raised at a high pressure as described above is dependent on the centrifugal force due to the rotation of the diffuser (3) shown in FIG. The air pressure rises once again. The air whose pressure is increased in this way flows and collects toward the center of the motor along the curved surface of the guide vane 4 of the diffuser 3, and according to the shape of the air collection plate 14, the stator 5 or the rotor of the motor. The electrons 8 are cooled and then discharged to the outside through the exhaust port 16 of the motor.

However, even if the air flowing along the curved surface of the guide vane 4 of the diffuser 3 cools the stator 5 or the rotor 8 of the motor according to the shape of the air collection plate 14, the rotation shaft of the motor As shown in FIG. 5 when the motor is viewed from the front with respect to (13), since the bearing supporter 15 almost covers the armature coil 10, the armature has a great influence on the lifetime reliability and the lifetime of the motor. The cooling effect of the coil 10 is not great.

In particular, the electrical loss (copper loss and iron loss) except for the mechanical loss substantially occurring in the universal motor is almost similar to the stator 5 and the rotor 8. The double stator 5 has a large heat dissipation area and a stator coil, As the field coil 7 is wound in the vertical direction as shown in FIG. 3, and the upper portion of the field coil 7 is in contact with an air guide, Although the temperature rise problem does not greatly occur, since the rotor 8 rotates at a high speed, iron loss and copper loss are also present with the stator 5 relatively, so that the armature coil 10 There is a problem that there is a big obstacle due to the configuration of the cleaner motor to increase the temperature excessively.

In addition, the bearing supporter 15 is less likely to come into contact with relatively low temperature air, resulting in poor cooling characteristics of the armature coil 10, and at the same time shortening the life of the motor and increasing the insulation level of the motor to extend the life. There was a troublesome problem such as having to adjust the material of the armature coil 10 again by adjusting upward.

The present invention devised to solve the conventional problems as described above, by using the air flowing along the guide vane of the diffuser, the motor according to the effective cooling of the temperature of the armature coil which has a large impact on the life reliability and life of the motor The purpose is to extend the life of the.

In addition, by cooling the temperature of the armature coil as described above, there is another object to lower the insulation grade of the motor.

The object of the present invention is that the air flowing into the armature coil and the bearing supporter located on the front surface of the air collection plate among the components of the universal motor for cleaners, and the air introduced into the cooling hole into the armature coil. The bar can be solved by the cleaner motor heat dissipation structure of the present invention formed by the air flow guide portion bent at an angle to one end of the cooling hole to smooth the flow, will be described in detail with reference to the accompanying drawings.

1 is a half sectional view showing a cross section of a conventional cleaner fan and a motor.

FIG. 2 is a connection diagram of the motor shown in FIG. 1. FIG.

Figure 3 is a rotation state of the motor according to the current flow of the stator and the rotor of the components of the conventional cleaner motor.

4 is a perspective view showing a three-dimensional shape and a flow path of the diffuser and the guide vane of the fan unit coupled to the motor shaft.

5 is a front view of a conventional motor equipped with a bearing supporter.

Figure 6 is a cross-sectional view showing a state in which the cleaner fan and the motor of the present invention are coupled to each other.

7 is a front view of a motor equipped with a bearing supporter in which cooling holes are formed.

8A is a front view and a side view of a bearing supporter in which cooling holes of a rectangular shape are formed.

8B is a front view and a side view of each bearing supporter in which a predetermined width of the arcuate cooling holes are formed.

9 is another embodiment of the present invention.

10 is another embodiment of the present invention.

Figure 11 is a state diagram of the process of cooling the armature coil and the rotor as a whole in the present invention cleaner motor radiating structure.

Explanation of symbols on the main parts of the drawings

1. Housing 2. Impeller 3. Diffuser 4. Guide vane

5. Stator 6. Field core 7. Field coil 8. Rotor

9. Armature core 10. Armature coil 11. Brush 12. Bearing

13. Shaft 14. Air collection plate 15. Bearing supporter 16. Exhaust vent

17. Commutators 20, 20a, 20b, 20c. Cooling hole 21. Air flow guide

22. Bearing Support Plate

6 is a cross-sectional view of the cleaner fan motor of the present invention, FIG. 7 is a front view of a motor equipped with a bearing supporter having cooling holes, and FIGS. 8A and 8B are front views of respective bearing supporters having cooling holes of a certain type. Figures and side views are shown.

The cleaner motor heat dissipation structure according to the present invention includes a stator 5 formed of a field core 6 and a field coil 7, an armature core 9, and an armature coil. An air collection plate composed of a rotor (8) formed of an armature coil (10), a commutator (17), and a brush (11), mounted on the front surface of the armature coil (10). A vacuum cleaner motor in which 14 and bearing supporter 15 are configured to be separated from each other;

The bearing supporter to cool the armature coil 10 of the rotor 8 by using air flowed to the center of the motor along the curved surface of the guide vane 4 of the diffuser 3 positioned in front of the motor ( 15) Cooling holes 20 are formed at predetermined positions on both sides, and air flows so that air flowing into the cooling holes 20 at one end of the cooling holes 20 is desired to flow to the armature coil 10. Guide portion 21 is a configuration formed bent at a certain angle.

Hereinafter, the cleaner motor heat dissipation structure of the present invention will be described in detail.

In the cleaner motor heat dissipation structure of the present invention, as shown in FIGS. 6 to 7, the air flowing along the curved surface of the guide vane 4 of the diffuser 3 positioned in front of the motor is rotated by the rotor 8. In order to be able to cool the armature coil (10) of the ()) formed in each of the bearing supporter (15) both sides of the bearing supporter (15) separated from each other to form a predetermined size of the cooling hole (20), respectively, the cooling hole (20) The air flow guide portion 21 is bent at a predetermined angle to allow air flowing from the guide vane 4 of the diffuser 3, which is a fan portion, to flow smoothly into the armature coil 10 at one end.

At this time, the air flow guide portion 21 bent at one end of the cooling hole 20 of the bearing supporter 15 is bent into the motor toward the armature coil 10 as shown in FIGS. 8A and 8B. While being formed, it is inclined about 0 ° to 70 ° with respect to the bearing supporter 15 surface.

Further, the cooling holes 20 and 20a formed on both sides of the bearing supporter 15 in a constant size are formed in a rectangular shape shown in FIG. 8A or an arch shape having a predetermined width shown in FIG. 8B.

9 is a view showing another embodiment of the present invention, the cleaner motor heat dissipation structure, which is formed by integrally forming a bearing supporter (15) and the air collection plate (14) separated from each other among the components of a known motor The field support core (6) and the field coil (7) of which some air in the air flowing through the guide vanes (4) is formed on the left and right sides of the bearing supporter plate (22), the stator (5). The stator cooling holes 20b are formed to have a predetermined size so as to be cooled, and both sides of the bearing supporter plate 22 have a predetermined size to allow the remaining air in the air to cool the armature coil 10. The armature coil cooling holes 20c are formed.

Here, as shown in Fig. 9, the stator cooling holes 20b are formed in an arch shape with a predetermined width, and the armature coil cooling holes 20c are rectangular in shape as shown in Fig. 9. In particular, the stator cooling holes 20b and the armature coil cooling holes 20c are formed opposite to each other to form another embodiment of the present invention, as shown in FIG.

Hereinafter, the heat radiation state of the cleaner motor of the present invention will be described.

Figure 11 shows a state diagram of the process of cooling the armature coil and the rotor as a whole in the cleaner motor radiator structure of the present invention.

In the vacuum cleaner motor of the present invention, AC power among the vacuum cleaner fan and the motor shown in FIG. 6 is supplied to the armature coil 10 of the rotor 8 through a brush 11 located behind the rotor 8. When supplied to the field coil (7) of the stator (5), a magnetic force line is generated in each of the armature coil 10 and the field coil (7), the rotor 8 by the suction force and the repulsive force between the magnetic field lines The rotor 8 rotates together with the shaft 13 while the armature core 9 of the is rotated.

When the rotor 8 and the shaft 13 rotate at a high speed, the fan denier infeller 2 and the diffuser 3 coupled to the motor shaft 13 also receive the rotational force of the motor and rotate at high speed. As the suction force is generated and the outside air is sucked into the infeller 2 and the diffuser 3, the air sucked through the fan 2 and 3 part is a strong centrifugal force of the impeller 2. By the pressure of the air is increased, the air is raised to the high pressure is the pressure of the air once again by the centrifugal force of the diffuser (3).

As described above, the air whose pressure is increased in the fan (2) (3) part flows along the curved surface of the guide vane (4) of the diffuser (3) to the bearing supporter (15) located behind the diffuser (3). While being flowed, some air flows through the bearing supporter 15 to the stator 5 by the shape of the air collection plate 14 located behind the supporter 15 to cool the stator 5, and another part of the air. As shown in FIG. 11, the air flows into the armature coil 10 through the cooling holes 20 formed in the bearing supporter 15, and at this time, the cooling holes 20 formed in the bearing supporter 15. At one end, air flows directly into the armature coil 10 through a flow path of the airflow guide portion 21 that is bent at an angle to cool the rotor 8 while cooling the heat generated in the armature coil 10. Cooling the whole, the stator (5) and the rotor (8) Serious air is discharged through the air exhaust port 16 located at the rear motor to the outside.

As described above, in the cleaner motor heat dissipation structure of the present invention, a cooling hole 20 having a predetermined size is formed in the bearing supporter 15 supporting the bearing inserted into the motor shaft 13, and one end of the cooling hole 20 is provided. The air flow guide portion 21 is bent at a predetermined angle so that air introduced into the cooling hole 20 flows into the armature coil 10 so that the guide vane of the fan densely diffuser 3 It is an excellent invention that can effectively extend the life of the motor by effectively cooling the temperature of the armature coil (10) having a lot of influence on the service life reliability and life of the motor by using the air flowing along 4).

The cleaner motor heat dissipation structure according to the present invention includes a cooling hole having a predetermined diameter and air introduced into the cooling hole in the armature coil and a bearing supporter located on the front surface of the air collection plate among the components of a known universal cleaner motor. By forming an air flow guide portion bent at an angle at one end of the cooling hole so that the flow of the furnace is desired, the air flowed along the guide vane of the diffuser effectively cools the temperature of the armature coil, which greatly affects the lifetime reliability and life of the motor. There is an excellent effect that can extend the life of the motor.

In addition, according to the present invention as described above, by cooling the temperature of the armature coil, there is also an excellent effect that can lower the insulation grade of the motor.

Claims (9)

A stator formed of a field core and a stator coil, a rotor formed of an armature core and an armature coil, a commutator, and a brush In the vacuum cleaner motor consisting of, the air collecting plate and the bearing supporter mounted on the front of the armature coil is separated from each other; Cooling holes are formed on both sides of the bearing supporter so as to cool the armature coil of the rotor using air flowed to the center of the motor along the curved guide vane of the diffuser positioned in front of the motor. Cleaner motor heat dissipation structure, characterized in that the air flow guide portion is bent at a predetermined angle so that the air flowing into the cooling hole at one end of the cooling hole to flow to the armature coil. The heat dissipation structure of the cleaner motor according to claim 1, wherein the air flow guide part is bent into the motor to face the armature coil. The vacuum cleaner motor heat dissipation structure according to claim 1, wherein the air flow guide part is inclined by about 0 ° to 70 ° with respect to the bearing supporter surface. The vacuum cleaner motor heat dissipation structure according to claim 1, wherein the cooling hole of the bearing supporter is formed in a rectangular shape. The vacuum cleaner motor heat dissipation structure according to claim 1, wherein the cooling hole of the bearing supporter is formed in an arch shape having a predetermined width. According to claim 1, wherein the bearing supporter (bearing supporter) and the air collecting plate separated from each other integrally formed to form a bearing supporter plate of a certain shape, while the air flowed through the guide vane on both sides of the bearing supporter plate A certain size of stator cooling holes are formed to cool the field cores and the field coils, which are part of the stator, and both sides of the bearing supporter plate have a predetermined size to allow the remaining air in the air to cool the armature coil. Cleaner motor heat dissipation structure, characterized in that the armature coil cooling holes are formed. 7. The cleaner motor heat dissipation structure according to claim 6, wherein the stator cooling holes formed in the bearing supporter plate are formed in an arch shape having a predetermined width. 7. The cleaner motor heat dissipation structure according to claim 6, wherein the armature coil cooling hole formed in the bearing supporter plate has a rectangular shape. The cleaner motor heat dissipation structure according to claim 6, wherein the stator cooling hole shape and the armature coil cooling hole shape respectively formed in the bearing supporter plate are formed in opposite shapes.