KR20210026958A - Brushless motor apparatus provided with membrane protection structure - Google Patents

Abstract

According to the present invention, provided is a brushless motor device with a membrane protection structure. A brushless fan motor device includes a stator including a coil therein and a printed circuit board supplying a current to the coil, and a rotor rotatably installed on the stator. The brushless motor device includes an air outlet hole formed in the upper surface of the stator, and a membrane separably coupled to the air outlet hole and made of a material through which air molecules can pass and water molecules can pass. A membrane protective wall formed in a shape surrounding the side surface of the membrane is provided around the outlet hole, and a drainage channel formed by forming a structure in which a portion of the membrane protective wall is opened, so that water flowing into the membrane is to be drained, is included.

Description

Brushless motor apparatus provided with membrane protection structure

The present invention relates to a brushless motor device, and more particularly, to a ventilation structure of a stator of the brushless motor device.

The engine of a vehicle is exposed to high temperatures due to the high-temperature explosive gas. Accordingly, a cooling device is provided to prevent damage to the engine and to ensure stable operation. More specifically, when the mixer is burned in the cylinder of the engine, the maximum temperature of the combustion gas rises to about 2500°C. Some of this heat is transferred to the cylinder wall, cylinder head and piston, so it must be removed to some extent in consideration of the lubrication characteristics, and a cooling device is used for this. A water-cooled cooling system mainly used in vehicles uses a water pump to continuously circulate coolant when the engine is heated. The cooling water circulated by the water pump is cooled through heat exchange with air sucked by a cooling fan while passing through a radiator.

Meanwhile, in addition to the engine cooling fan, a condenser cooling fan for condensing the refrigerant passing through the condenser when the air conditioner is operated is installed in the front of the vehicle. These vehicle cooling fans are driven by fan motors.

The cooling fan motor of the vehicle rotates the cooling fan by receiving electricity from the vehicle's battery or generator (generator or alternator) and performing rotational motion. The cooling fan motor may be a conventional DC motor. The cooling fan motor includes a stator and a rotor.

As such, a cooling fan device including a cooling fan and a cooling fan motor as an apparatus for cooling the engine of a vehicle is disclosed in Korean Patent Application Publication No. 2014-0030661.

The recent cooling fan motor uses a brushless motor that has advantages in terms of structure and output. The brushless motor is composed of a stator and a rotor, and a coil and a power supply are provided in the stator. Accordingly, moisture should not flow into the stator. Accordingly, the stator of the brushless motor is formed in a watertight structure. However, heat is generated inside the stator of the brushless motor. It includes an air inlet and an outlet to dissipate heat generated inside the stator to the outside. In particular, a membrane made of a material through which water molecules cannot pass and air molecules can pass is installed at the outlet to prevent moisture from flowing into the stator through the air outlet hole. However, the membrane is a kind of fibrous material and has a problem that can be easily damaged by an external impact. The membrane installed in the conventional brushless motor device has a structure that is exposed to the outside, so it is easy to be damaged by an unexpected impact.

An object of the present invention was conceived to solve the above-described problems, and by improving the installation structure of the membrane provided in the stator housing, the membrane is prevented from being damaged by unexpected impacts, thereby providing a membrane protection structure with improved durability. It is to provide a brushless motor device.

In order to achieve the above object, a brushless motor device having a membrane protection structure according to an embodiment of the present invention includes a stator including a coil therein and a printed circuit board supplying current to the coil; And

A brushless fan motor device including a rotor rotatably installed on the stator,

An air outlet hole formed on the upper surface of the stator; And

A membrane made of a material that is detachably bonded to the air outlet hole and allows air molecules to pass through and water molecules to pass through; including,

A membrane protective wall formed in a shape surrounding the side surface of the membrane is provided around the outlet hole,

It is characterized in that a drainage passage formed by forming a structure in which a part of the membrane protective wall is opened is included so that water flowing into the membrane is drained.

The membrane protective wall is preferably formed integrally with the stator housing.

It is preferable that the membrane protective wall is formed not lower than the upper surface of the membrane.

The brushless motor device according to the present invention is provided with a membrane protective wall to prevent damage to the membrane around the air outlet hole formed on the upper surface of the stator housing, thereby providing an effect of preventing damage to the membrane due to unexpected impact. do. In addition, a drainage passage formed by opening a portion of the membrane protective wall provides an effect that water introduced into the membrane can be easily discharged.

1 is a perspective view of a brushless motor device according to a preferred embodiment of the present invention.
2 is an exploded perspective view of a main part of the brushless motor device shown in FIG. 1.
3 is a cross-sectional view taken along line III-III shown in FIG. 1.
4 is an enlarged view of the membrane protective wall shown in FIG. 1.

Hereinafter, preferred embodiments according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view of a brushless motor device according to a preferred embodiment of the present invention. FIG. 2 is an exploded perspective view of a main part of the brushless motor device shown in FIG. 1. 3 is a cross-sectional view taken along line III-III shown in FIG. 1. 4 is an enlarged view of the membrane protective wall shown in FIG. 1.

1 to 4, a brushless motor device 10 according to a preferred embodiment of the present invention is a motor that can be employed in a cooling fan device installed in a vehicle to cool heat generated from, for example, an engine of a vehicle. It's a device.

The brushless motor device 10 includes a stator 20 and a rotor 40.

The stator 20 includes a stator housing 24, a central shaft 60, a core 22, a printed circuit board 23, an air outlet hole 27, a membrane 50, and a membrane protective wall. It includes (30) and a drainage (32).

The stator housing 24 is made of a metal such as an aluminum alloy. The stator housing 24 has a plurality of radiating fin structures. The stator housing 24 may be manufactured by a die casting method. The stator housing 24 may include a lower housing 25 and an upper housing 26. The lower housing 25 and the upper housing 26 may be firmly coupled to each other by means such as screws or bolts.

The central shaft 60 is fixed to the stator housing 24. The central shaft 60 is formed to protrude upward from the stator housing 24. A stator 20 is fixed to the central shaft 60. In addition, the rotor 40 is rotatably coupled to the central shaft 60.

The core 22 is installed outside the stator housing 24. More specifically, the core 22 is fitted and fixed to the central shaft 60. A coil (not shown) is wound around the core 22. In the coil, electromagnetic force is generated by the current supplied by the printed circuit board 23.

The printed circuit board 23 is installed in the inner space of the stator housing 24. The printed circuit board 23 is electrically connected to a coil wound around the core 22. The printed circuit board 23 supplies current to the coil. The printed circuit board 23 includes a circuit formed by plating, photomasking, and etching, and a plurality of surface-mounted electrical and electronic devices. The printed circuit board 23 supplies a rectified direct current to the coil.

The air outlet hole 27 is a hole formed on the upper surface of the stator housing 24. The air outlet hole 27 is formed on the upper surface of the upper housing 26. The air outlet hole 27 is a hole penetrating the inside and outside of the stator housing 24.

The membrane 50 is detachably coupled to the air outlet hole 27. The membrane 50 is made of a material that allows air molecules to pass through and water molecules to pass through. The membrane 50 may be configured by employing a known material such as Gore-Tex. A membrane housing may be provided so that the membrane 50 can be easily coupled to the air outlet hole 27. The membrane 50 is in close contact with the stator housing 24 via the O-ring 52. The O-ring 52 is formed in an integrated structure with the membrane 50. The membrane 50 may be firmly fixed to the stator housing 24 with an elastic clip structure. The membrane protective wall 30 is formed around the air outlet hole 27. The membrane protective wall 30 is formed to protrude above the air outlet hole 27 and is configured to surround the air outlet hole 27. The membrane protective wall 30 is preferably formed integrally with the stator housing 24. The membrane protective wall 30 may be integrally formed with the stator housing 24 by a die casting method. It is preferable that the membrane protective wall 30 is formed not lower than the upper surface of the membrane 50. The membrane protective wall 30 serves to protect the membrane 50 installed in the air outlet hole 27 from being damaged by an unexpected external impact.

The drainage passage 32 is a passage opened by partially cutting the membrane protective wall 30. The drainage passage 32 is a passage connecting the membrane 50 installation area and the outside with respect to the membrane protective wall 30. Moisture flowing into the membrane 50 through the drainage channel 32 may be effectively discharged.

Hereinafter, the effect of the brushless motor device 10 including the above-described components will be described in detail.

The brushless motor device 10 may be used by coupling a cooling fan (not shown) to the rotor 40. For example, a cooling fan device (not shown) is installed at the rear of the radiator (not shown) to cool the heat generated by the engine of the vehicle. Describes how the cooling fan device works. Current is supplied to the printed circuit board 23. The printed circuit board 23 removes noise from the externally supplied current and then supplies a DC current to the coil. The coil generates an electromagnetic field. The permanent magnet 42 provided in the rotor 40 generates a rotational force by electromagnetic induction by an electromagnetic field generated by the coil. Accordingly, the rotor 40 rotates and the cooling fan rotates to discharge air to the rear of the radiator. As a result, external air flows from the front of the radiator to the rear, and heat exchange between the coolant and the air is performed. Accordingly, the cooling water is cooled. In this process, the brushless motor device 10 may be exposed to an environment such as rain or snow. In this case, moisture may be introduced into the air outlet hole 27. The membrane 50 blocks moisture from flowing into the stator housing 24 through the air outlet hole 27. In this process, the moisture introduced into the membrane 50 is temporarily accumulated and then quickly discharged through the drainage channel 32. In addition, in the process of assembling the brushless motor device 10, the membrane 50 installation site may be damaged by colliding with surrounding devices or facilities. In this environment, the membrane protective wall 30 protects the membrane 50 from being damaged.

As described above, in the brushless motor device according to the present invention, since a membrane protective wall is provided around the air outlet hole formed on the upper surface of the stator housing to prevent damage to the membrane, the membrane is prevented from being damaged by an unexpected impact. Provides a preventive effect. In addition, a drainage passage formed by opening a portion of the membrane protective wall provides an effect that water introduced into the membrane can be easily discharged.

As described above, the present invention has been described with reference to a preferred embodiment, but the present invention is not limited to such an example, and various types of embodiments may be embodied within the scope not departing from the technical spirit of the present invention.

10: brushless motor device
20: stator
22: core
23: printed circuit board
24: stator housing
25: lower housing
26: upper housing
27: air outlet hole
30: membrane protective wall
32: drainage
40: rotor
42: permanent magnet
50: membrane
52: O-ring
60: central axis

Claims (3)

A stator including a core having a coil wound thereon and including a printed circuit board supplying current to the coil therein; And
A brushless fan motor device including a rotor rotatably installed on the stator,
An air outlet hole formed on the upper surface of the stator; And
A membrane made of a material that is detachably bonded to the air outlet hole and allows air molecules to pass and water molecules to pass through; including,
A membrane protective wall formed in a shape surrounding the side surface of the membrane is provided around the outlet hole,
A brushless motor device with a membrane protection structure, characterized in that it includes a drainage passage formed by forming a structure in which a portion of the membrane protection wall is open so that water flowing into the membrane is drained. The method of claim 1,
The membrane protective wall is a brushless motor device with a membrane protective structure, characterized in that formed integrally with the stator housing. The method of claim 1,
The membrane protective wall is a brushless motor device with a membrane protective structure, characterized in that formed not lower than the upper surface of the membrane.

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