KR20020043278A - Motor combined with fan - Google Patents

Abstract

The fan integrated motor according to the present invention includes a motor for providing rotational power by applying external power, and external air passing through the suction end to preferentially contact the motor so that cooling of the motor is performed more efficiently. When viewed in the advancing direction is characterized in that composed of a suction fan installed in the rear of the motor.

According to the present invention, an improved fan-integrated motor is used, unlike the prior art, so that the cooling performance of the motor can be maintained better when the same power is applied, and thus the efficiency and life of the motor can be further extended. It becomes possible.

In addition, since no configuration is placed behind the suction fan based on the flow direction of the outside air, another component for improving the flow path of the vacuum cleaner can be added more freely.

On the other hand, the substrate used for controlling the vacuum cleaner is arranged around the motor, whereby the substrate is cooled to the outside air at a low temperature before passing through the fan, thereby reducing the deterioration of the component.

Description

Motor combined with fan {Motor combined with fan}

The present invention relates to a fan-integrated motor that can cool the motor by using the outside air sucked due to the rotation of the fan, and more particularly, the heat generated by the friction force generated during the conversion of electrical energy into mechanical rotational force in the motor. The present invention relates to a fan-integrated motor that can more efficiently cool the heat sink.

In particular, the pen-integrated motor according to the present invention proposes a fan-integrated motor suitable for use in a vacuum cleaner that sucks the outside air at a high speed with the suction force of the motor, at the same time to suck the external dirt at the same time to separate and remove the dirt. I would like to.

Referring to the motor used in the conventional vacuum cleaner as follows.

1 is a view schematically illustrating an external air suction structure of a conventional vacuum cleaner.

Referring to FIG. 1, a suction structure of a conventional vacuum cleaner is configured to allow electrical energy to be converted into mechanical rotational motion so that the outside air is sucked by the fan motor 10 and the fan motor 10 for sucking the outside air. A suction port 20, a dirt separation membrane 30 for filtering dirt from the outside air mixed in the outside air sucked by the suction port 20, and a discharge port for discharging the outside air that is cleaned by removing the dirt from the dirt separation membrane 30 It consists of 40.

Referring to the operation of the suction structure of the vacuum cleaner in more detail, the suction port 20 is formed as a passage through which the outside air is sucked due to the suction force generated in the fan motor 10, the suction port 20 is Soil is sucked at a high speed, and the dirt contained in the outside air is formed in the shaft so that it can be sucked at the same time.

In addition, the outside air sucked through the suction port 20 passes through the fan motor 10 after the dirt contained in the outside air is removed through the dirt separation membrane 30, and then cools the heat generated by the motor. 40).

FIG. 2 is a view schematically illustrating the structure of a conventional fan motor as shown in FIG. 1.

Referring to FIG. 2, a conventional fan motor is fastened to a stator 11 that is stationary, a rotor 12 that rotates relative to the stator 11 to provide rotational force, and the rotor 12. And a rotation shaft 13 for transmitting the rotational force of the rotor 12, a fan 14 coupled to one end of the rotation shaft 13 to suck outside air by the rotational force of the rotation shaft 13, and the fan 14. Intake stage 17 through which the outside air is sucked by the rotational force of the), diffuser 15 for reducing the flow rate of the outdoor air converted at high speed due to the centrifugal force generated by the rotational force of the fan 14, and the diffuser 15 Guide vanes 16 for cooling the stator 11 and the rotor 12 to guide the outside air passing through the stator 11 and the rotor 12 of the motor, and the stator 11 and the While passing through the electrons (12) to the discharge stage (18) for exhausting the outside air absorbed heat It becomes bait.

The operation of the conventional fan motor as described with reference to Figure 2 will be described in detail.

Electrical energy transmitted from the outside is converted into rotational force due to the relative movement of the rotor 12 in addition to the stator 11, this rotational force is transmitted to the fan 14 through the rotation shaft 13, the fan ( When the 14 is rotated, the outside air is sucked through the suction end 17.

The outside air sucked through the suction end 17 is decelerated through the diffuser 15, and the outside air passing through the diffuser 15 passes through the guide vane 16 and the rotor 12 and the stator 11. Guided to the side) to cool the heat generated in the rotor 12 and the stator 11 is discharged to the outside through the discharge end 18.

However, in the conventional fan motor structure, when looking at the flow of the outside air, the pressure energy obtained while passing through the fan 14 and the diffuser 15 is eventually converted into heat, so that the rotor 12 and the stator 11 There is a problem that the cooling of the high temperature outside air is not made sufficiently, and furthermore, since the outside air reaches the fan motor 20 after passing through the dirt separation membrane (see 30 in FIG. 1), the dirt separation membrane 30 When dirt accumulates, there is a problem that the cooling performance of the fan motor 20 is further slowed down.

On the other hand, due to the guide vane 16 to be forcibly guided to the motor portion in the flow direction of the outside air, there is a problem that the flow path loss occurs, the original performance of the fan motor 20 is further reduced.

In addition, the conventional method of providing a separate fan for cooling only the motor as another motor of the vacuum cleaner has been proposed, but this method has the disadvantage of consuming additional electrical energy and additional installation cost.

The present invention has been made to solve such a problem, and by modifying the structure of the fan motor to properly adjust the direction of the outside air sucked into the fan, it is possible to reduce the flow loss caused by inappropriate flow of the outside air, and also, the motor It is an object of the present invention to provide a fan-integrated motor capable of appropriately cooling the motor even if a fan that has been separately installed to cool the motor is not installed.

1 is a view schematically illustrating an outside air suction structure of a conventional vacuum cleaner.

2 is a diagram schematically illustrating a structure of a conventional fan motor.

3 is a diagram illustrating a configuration of a fan integrated motor according to the present invention.

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

10: fan motor 11: stator

12: rotor 13: rotation axis

14: fan 15: diffuser

16: guide vane 17: suction end

18: discharge stage 20: suction port

30: dirt separation membrane 40: discharge port

51: suction stage 52: motor

52a: stator 52b: rotor

53: rotating shaft 54: suction fan

55: scroll

In order to achieve the above object, the fan-integrated motor according to the present invention includes a motor for providing rotational power by applying external power, and external air passing through the suction end to the motor for cooling the motor more efficiently. It is characterized in that it consists of a suction fan installed in the rear of the motor when viewed in the direction of advance of the outside air to reach first.

The present invention as mentioned is provided with a fan in the rear of the motor in the light of the flow direction of the outside air, such a fan-integrated motor will be described in detail according to its components.

3 is a view schematically illustrating a configuration of a fan integrated motor according to the present invention.

Referring to FIG. 3, the present invention provides a suction end 51 for sucking outside air, a motor 52 that provides rotational force and cools heat by outside air sucked through the suction end 51, and One end is fastened to the motor 52 to rotate the rotation shaft 53 for transmitting the rotational force due to the motor 52, and the other end of the rotation shaft 53 is used to rotate the rotation force from the rotation shaft 53 to the outside air Scroll to reduce the loss of flow by forming a suction fan 54 for suction and the flow of the outside air formed on the outer circumference of the suction fan 54 and discharged from the suction fan 54 naturally ( 55).

In addition, the motor 52 is for converting electrical energy into mechanical energy, and consists of a stator 52a and a rotor 52b.

Referring to the operation of the fan-integrated motor according to the present invention based on the configuration of the present invention as follows.

When electrical energy is input to the motor 52, a rotational force is generated due to the relative movement of the stator 52a and the rotor 52b. However, the stator 52a is fixed and the rotor 52b. ) Rotates.

The rotational movement of the rotor 52b is transmitted to the rotation shaft 53, and the rotational movement of the rotation shaft 53 is transmitted to the suction fan 54 which is fastened to the rotation shaft 53.

The suction fan 54 is rotated by receiving the rotational movement of the rotation shaft 53 as it is, the rotational movement of the suction fan 54 gives a centrifugal force to the outside of the suction fan 54 in a constant direction This one-way motion eventually acts as a driving force to inhale the outside air.

The outside air passing through the suction fan 54 through the scroll 55 provided on the outer circumference of the suction fan 54 may be discharged to the outside without losing flow.

In the fan-integrated motor according to the present invention, the direction of flow is as indicated by the arrow.

The scroll 55 is bent in the advancing direction of the outside air discharged through the suction fan 54 so that almost no loss occurs in the flow of the outside air, and the same motor 52 does not cause any loss in the flow of the outside air. And the flow rate and amount of the outside air that is also sucked by the suction fan 54, the flow rate is increased, so that the flow rate is increased, so that the flow amount is increased.

As can be seen through the configuration of the present invention as described above, in the present invention, the outdoor air sucked by the suction fan 54, the increase in temperature due to the pressure rise due to the centrifugal force provided by the suction fan 54 By passing through the motor 52 before it is present, the cooling performance of the motor 52 becomes better.

On the other hand, near the motor 52, that is, in front of the suction fan 54, the substrate necessary for the control of the entire device or the operation of the motor 52 is installed, thereby effectively dissipating heat generated from the components on the substrate to the outside. As a result, the failure of the product due to the deterioration of the parts can be suppressed, so that the product can be used longer.

Meanwhile, a guide vane (see 16 in FIG. 2) is conventionally used so that the flow direction of the outside air passing through the fan (see 14 in FIG. 2) is sharply bent, so that the flow loss generated in the flow of the outside air is increased. However, in the present invention, even if a structure such as a guide vane 16 for cooling the motor 52 is not separately installed, the inflow direction of the outside air is directed toward the motor 52 due to its own structure. The cooling efficiency of 52) is further improved.

In addition, the scroll 55 is installed on the outer circumference of the suction fan 54 so that the outdoor air passing through the suction fan 54 can be naturally discharged to the outside, so that the external air is suddenly changed in the flow direction. Due to this, the flow loss experienced can also be suppressed. This suppression of the flow loss results in a smoother suction of the outside air, resulting in higher efficiency of the vacuum cleaner to which the present invention is employed.

In the present invention as described above, when considering the flow direction of the outside air, the outside air passes through the motor and the heat generated by the motor is allowed to pass through the suction fan, so that the cooling performance of the motor is further increased. It will be apparent to those skilled in the art that the present invention is well understood, and that other embodiments will be readily made within the scope of the spirit of the present invention.

According to the present invention, an improved fan-integrated motor is used, unlike in the related art, so that the cooling performance of the motor can be better maintained when the same power is applied, and thus the efficiency and life of the motor can be further extended. do.

In addition, since no configuration is placed behind the suction fan based on the flow direction of the outside air, another component for improving the flow path of the vacuum cleaner can be added more freely.

On the other hand, the substrate used for controlling the vacuum cleaner is arranged around the motor, whereby the substrate is cooled to the outside air at a low temperature before passing through the fan, thereby reducing the deterioration of the component.

Claims (3)

A motor for applying rotational power to provide rotational force, In order to make the cooling of the motor more efficient, the fan integrated type comprising a suction fan installed at the rear of the motor when the outside air passing through the suction end is preferentially contacted with the motor in the traveling direction of the outside air. motor. The method of claim 1, A fan-integrated motor, characterized in that the scroll is formed on the outer circumference of the suction fan to reduce the flow loss of the outside air passing through the suction fan. The method of claim 1, And the substrate is provided in front of the suction fan to be cooled by the outside air that cools the motor.