KR930004109Y1 - Fan of vacuum cleaner - Google Patents

Abstract

No content.

Description

Blower fan of vacuum cleaner motor

1 is a partial cutaway view showing an embodiment of a vacuum cleaner motor to which the present invention is applied.

2 is a partial assembly perspective view showing a windmill according to the present invention.

3 is a view schematically showing the wing arrangement of the main windmill and the auxiliary windmill in FIG.

4 is a front view showing the wing shape of the auxiliary windmill shown in FIG.

* Explanation of symbols for main parts of the drawings

1: lead line 2: brush

3: motor body 4: commutator

5: rotor 6: wing fuselage

7: windmill 71: windmill

711: wing fixing plate 712: shielding plate

713: main wing 714: air vent

72: auxiliary windmill 721: auxiliary wing

722: rotating shaft insertion hole 8: guide wall

9: bolt 10: brush fixture

11: shaft part

The present invention relates to a blower fan of a vacuum cleaner motor, and more particularly to a blower fan of a vacuum cleaner motor to improve the structure of the windshield to improve the suction force of the vacuum cleaner.

The vacuum cleaner has a configuration in which a blower fan driven when the motor housed therein rotates at high speed generates a suction force to attract external dust or the like.

In general, a motor used in a vacuum cleaner is generally used to use a universal motor that can be used for both alternating current and direct current because it should be capable of rotating at high speed without being affected by the frequency change regardless of the type of power source.

The suction force in the vacuum cleaner of the above-described configuration is greatly influenced by the efficiency of the motor and the structure of the windmill driven by the motor to generate the suction force.

Therefore, the suction force of the vacuum cleaner can be improved by improving the structure of the windmill of the vacuum cleaner and the structure of the windmill body accommodating the windmill.

Windmills are usually arranged in a spiral arrangement between a plurality of wings between a wing fixing plate and a shield plate.

In addition, depending on the appearance of the windmill, the wing fixing plate and the shielding tube are in the form of a flat plate, and the shielding plate is in the form of a funnel.

The wings of the windmill, in which the shield plate is formed on a funnel, have a central side longer than an outer circumferential side.

Conventionally, as a method of improving the suction force of a vacuum cleaner, the above two windmills have been stacked or the size of the wings has been increased.

However, the above method also increases the size of the vacuum cleaner as well as increases the air resistance at the wing, which causes a problem of employing a motor having good power efficiency.

An object of the present invention is to provide a blower fan of a vacuum cleaner motor that can increase the suction power of the vacuum cleaner by only improving the structure of the windmill without increasing the volume of the vacuum cleaner.

In order to realize the above object, the present invention is a conventionally equipped blower fan in which a main windmill and an auxiliary windmill are arranged successively, wherein the auxiliary wing of the auxiliary windmill is formed so that the outer circumferential side thereof is longer than the center side side, and the airflow is sucked. We propose a blower fan of a vacuum cleaner motor that reduces the frictional loss of the motor and reduces the load on the motor.

Hereinafter, a preferred embodiment of the present invention with reference to the accompanying drawings.

1 is a partial cutaway view showing an embodiment of a vacuum cleaner motor to which the present invention is applied, in which a plurality of brushes 2 connected to the lead wire 1 are paired with each other inside the motor body 3. The ones are arranged symmetrically so as to be in close contact with the commutator 4 so as to supply power to the rotor 5.

A windmill body 6 is disposed at one end of the motor body 3 and a guide wall for guiding the flow direction of the air drawn by the windmill 7 and the windmill 7 therein ( 8) is housed.

In addition, the brush 2 is position-maintained by the brush fixture 10 fixed to the predetermined position of the motor body 3 by the normal bolt 9.

Here, one end of the rotating shaft which is placed at the center of the rotor 5 and becomes invisible from the outside is rotatably supported by the shaft support part 11 arranged on one side of the motor body 3, and the other end of the rotating shaft is windmill 7. It is connected to and driven to rotate it.

FIG. 2 is a perspective view illustrating the structure of the windmill 7 illustrated in FIG. 1, wherein the main windmill 71 includes a wing fixing plate 711 and a shielding plate 712, and a plurality of wings 713 therebetween. ) Are arranged in a spiral shape.

And a separate auxiliary windmill 72 is installed on the rear side of the wing fixing plate 711.

A vent hole 74 is formed in the central portion of the wing fixing plate 711, so that the air flow suctioned from the main windmill 71 is guided to the auxiliary windmill 72 side.

In addition, the auxiliary windmill 72 has a plurality of auxiliary wings 721 formed around the shaft hole 722 to which the rotating shaft of the rotor 5 is connected to have a longer outer peripheral side than the central side. It is.

As shown in FIG. 3, the auxiliary wings 721 are disposed to be offset from the wings 713 of the main windmill 71 so as to be synchronously rotated integrally with each other.

The reason why the vanes 713 of the main windmill 71 and the auxiliary wings 721 of the auxiliary windmill 72 are alternately arranged is to provide a load applied to the motor during operation and to improve the suction force. To do this.

4 is a front view illustrating the shape related to the wing 721 of the auxiliary windmill 72 in more detail, wherein the longer side is positioned in the outer circumferential direction and the shorter side is arranged toward the center side of both side edges.

In this way, when the side length of the auxiliary wing 721 becomes wider from the center to the outer circumferential side, the inclination is caused by the wind pressure in the flow direction of the air to be sucked, so that the frictional loss of the airflow is reduced, and the resistance of the airflow is significantly higher than before. It becomes small. Therefore, the suction force of air is greatly improved.

In the present invention configured as described above, as the power applied through the lead wire 1 is supplied to the commutator 4 via the brush 2, the rotor 5 has a polarity that repels the magnetic force of the stator to rotate The driving is the same as a conventional vacuum cleaner motor, but in the present invention, when the windmill 7 rotates, it is sucked by the vane 713 of the main windmill 71 and the auxiliary wing 721 of the auxiliary windmill 72. Air flow is to be formed, in this case, the air flow sucked from the main windmill 71 is sucked again while passing through the auxiliary windmill 72, in this process by reducing the resistance of the air by the characteristic structure of the auxiliary wing 721 vacuum The suction power of the cleaning device is greatly improved.

Therefore, the present invention can increase the suction power without increasing the size of the windmill or the size of the vacuum cleaner, so that the vacuum cleaner does not need to increase the power of the motor.

Claims (1)

In the blower fan for the vacuum cleaner comprising a plurality of wings arranged in a spiral between the wing fixing plate and the shielding plate, which windmill is arranged in succession with the main windmill and the auxiliary windmill, The auxiliary wing 721 of the auxiliary windmill 72 on the rear side is formed longer than the center side of the outer peripheral side to prevent friction of the air flow is sucked and the auxiliary wing 721 is the wing of the main windmill 71 A blower fan for a vacuum cleaner motor, characterized in that the airflow sucked in an arrangement that is shifted from the position 713 is configured so that the motor does not apply a load.