KR101779046B1 - Structure of Fan Shroud - Google Patents

Abstract

The present invention relates to a fan shroud assembly, and more particularly, to a shroud having a resistor mounting portion formed concavely in a thickness direction so as to mount a resistor assembly for adjusting the speed of a fan motor, The air flow portion is formed so that a predetermined region of the circumferential surface of the resistor mounting portion is lower than the shroud surface so that the resistor mounting portion can flow, thereby smoothly flowing the air of the cooling wind for cooling the resistor assembly and effectively cooling the resistor assembly that generates heat To a fan shroud assembly.

Description

A fan shroud assembly {Structure of Fan Shroud}

The present invention relates to a fan shroud assembly, and more particularly, to a shroud having a resistor mounting portion formed concavely in a thickness direction so as to mount a resistor assembly for adjusting the speed of a fan motor, The air flow portion is formed so that a predetermined region of the circumferential surface of the resistor mounting portion is lower than the shroud surface so that the resistor mounting portion can flow, thereby smoothly flowing the air of the cooling wind for cooling the resistor assembly and effectively cooling the resistor assembly that generates heat To a fan shroud assembly.

Generally, in front of an engine room of a vehicle, a condenser for condensing high-temperature refrigerant generated in a process of cooling the inside of the vehicle, a radiator for cooling high-temperature cooling water generated in the process of cooling the engine, And a fan shroud which is located behind the radiator and forcibly blows air to improve the cooling efficiency of the condenser and the radiator.

The fan shroud is configured to blow air into the heat exchanger to promote heat dissipation of an air-cooled heat exchanger such as a radiator or a condenser of an automobile.

FIG. 1 is a perspective view of a conventional fan shroud, and FIG. 2 is a sectional view of a conventional resistor mounting portion. 3 is a conventional fan shroud air inflow side perspective view.

1 to 3, the fan shroud assembly is used for cooling a heat exchange medium passing through a heat exchanger such as a radiator or a condenser of an automobile. The fan shroud assembly includes a shroud 10, a cooling fan 20, A fan motor M, and a resistor assembly 30.

In the shroud 10, a tuyeres 11 corresponding to the cooling fan 20 are formed. The fan motor M is disposed in the center of the blower opening 11 by a motor support ring which is fixed to the shroud 10 by a plurality of radially installed guide vanes.

Therefore, the air is blown through the blowing port 11 while the cooling fan 20 is rotated by the driving of the fan motor M, and the heat exchanger can be cooled by the blowing air.

The fan motor M is selectively driven to two or more stages of high speed and low speed. To regulate the speed of the fan motor M, a resistor assembly 30 is provided between the vehicle power source and the fan motor M. [ .

The resistor assembly 30 includes a resistor 31, a support flange 32 for fixing the resistor 31 to the shroud 10, and a connector 33 for supplying power to the resistor 31 Respectively. The connector 33 is connected to the fan motor connector 40 connected to the wiring from the fan motor M. [

Although not shown in the drawing, two of the wires on the vehicle power supply side are connected to the fan motor M side by wiring connection by the connectors 33 and 40, and one wire on the vehicle power supply side is connected to the resistor 31, and the register 31 and the fan motor M are connected to each other, thereby constituting a low-speed operation circuit. The voltage supplied to the fan motor M is selectively lowered by the low-speed operation circuit by the resistor 31, and the fan motor M can be selectively driven from high speed to low speed by this voltage adjustment .

As shown in FIG. 2, in the case of the resistor 31, heat is generated when the resistor 31 is energized, and the temperature rises to 220 degrees centigrade in the case of the heating point H having the highest temperature during the operation of the resistor 31.

More particularly, in order to prevent the thickness of the fan shroud from becoming thicker due to the mounting of the resistor 31, the shroud 10 is formed with a recessed resistor mounting portion 34 inwardly, and the resistor mounting portion 34 The register 31 is mounted. In this case, since the resistor 31 is surrounded by the resistor mounting portion 34 and there is almost no air flow, the resistor 31 is exposed to a high temperature at all times, and there is a concern that performance and durability are lowered.

SUMMARY OF THE INVENTION The present invention has been conceived to solve the problems as described above, and it is an object of the present invention to provide a shroud with a resistor mounting portion formed concavely in a thickness direction so that a resistor assembly for controlling a speed of a fan motor is mounted, The air flow portion is formed such that a predetermined region of the circumferential surface of the resistor mounting portion is stepped lower than the shroud surface so that air can flow to the cooling fan side so as to smooth the air flow of the cooling wind for cooling the resistor assembly, To provide a fan shroud assembly capable of effectively cooling the assembly and improving durability.

It is also an object of the present invention to provide a cooling system for a cooling module that prevents a register assembly that controls the speed of a fan motor from being heated to a high temperature, And a fan shroud assembly that can efficiently perform the fan shroud assembly.

A fan shroud assembly (10) of the present invention includes a shroud (100); A cooling fan 200 mounted on a tuyere 110 of the shroud 100; A fan motor 400 mounted on the shroud 100 to drive the cooling fan 200; And a resistor assembly (300) for adjusting the speed of the fan motor (400) and mounted to the shroud (100); Wherein the shroud 100 is formed with a resistor mounting portion 500 recessed in the thickness direction so that the resistor assembly 300 is mounted on the shroud 100, An air flow portion 510 is formed in which a predetermined area of the circumferential surface of the resistor mounting portion 500 is lower than the surface of the shroud 100 so that air can flow to the cooling fan 200 side.

Further, the air flow portion 510 is positioned on the air flow passage through which the cooling fan 200 sucks air from the periphery.

In addition, the air flow portion 510 is formed in a shape of one of concave, U, and V in the thickness direction of the fan shroud assembly 1.

In addition, the air flowing part 510 has a plurality of cross-sections formed at any one of the concave, U, and V shapes at regular intervals along the circumferential surface of the register mounting part 500.

The air flow unit 510 is formed on the air flow passage through which the cooling fan 200 sucks air from the periphery thereof and is formed facing the opposite sides of the resistor assembly 300.

The fan shroud assembly of the present invention is characterized in that the shroud is provided with a resistor mounting portion formed concavely in the thickness direction so as to mount a resistor assembly for controlling the speed of the fan motor, The air flow portion is formed so that the predetermined region of the peripheral surface of the mounting portion is stepped lower than the shroud surface so that the air flow of the cooling wind for cooling the resistor assembly is smoothly performed and the resistor assembly which generates heat is effectively cooled, .

In addition, the fan shroud assembly of the present invention prevents the resistor assembly, which controls the speed of the fan motor, from generating heat due to high temperature and prevents performance degradation, It is possible to efficiently perform cooling.

1 is a perspective view of a conventional fan shroud assembly;
2 is a sectional view of a conventional resistor mounting portion.
3 is a perspective view of a conventional fan shroud assembly air inflow side.
4 is a perspective view of an air inflow side of a fan shroud assembly according to the present invention.
5 is an air inlet side perspective view of yet another fan shroud assembly in accordance with the present invention.
6 is an air inlet side perspective view of another fan shroud assembly in accordance with the present invention.
FIG. 7 is a cross-sectional view taken along line AA 'of FIG. 4 and FIG.

Hereinafter, a fan shroud assembly according to the present invention having the above-described features will be described in detail with reference to the accompanying drawings.

FIG. 4 is a perspective view of an air inlet side of a fan shroud assembly according to the present invention, FIG. 5 is an air inlet side perspective view of another fan shroud assembly according to the present invention, and FIG. FIG. 7 is a cross-sectional view taken along line AA 'of FIG. 4 and FIG.

The fan shroud assembly 1 of the present invention is formed to include a shroud 100, a cooling fan 200, a fan motor 400, and a resistor assembly 300.

1, the shroud 100 has a tuyere 110 corresponding to the cooling fan 200, and the cooling fan 200 is mounted.

The fan motor 400 is disposed at the center of the fan 110 by means of a motor support ring 120. The motor support ring 120 is connected to the shroud 130 by a plurality of guide vanes 130, 100).

Accordingly, in the fan shroud assembly 1 of the present invention, when the fan motor 400 is driven, the cooling fan 200 is rotated, air is blown through the fan 110, and the heat exchanger is cooled have.

The fan motor 400 is selectively driven in two or more stages of high speed and low speed. In order to adjust the speed of the fan motor 400, (300) are connected by a wiring.

In other words, the resistor assembly 300 is mounted on the shroud 100 by adjusting the speed of the fan motor 400 by selectively increasing or decreasing the voltage supplied to the fan motor 400.

Particularly, in the shroud 100, a resistor mounting part 500 is formed to be recessed in the thickness direction so that the resistor assembly 300 is mounted, and air flows from the resistor mounting part 500 to the cooling fan 200 side. An air flow portion 510 is formed in which the predetermined region of the circumferential surface of the register mounting portion 500 is stepped lower than the surface of the shroud 100. [

At this time, the air flow portion 510 may be positioned on the air flow passage through which the cooling fan 200 sucks air from the surroundings.

As described above, the cooling fan 200 is a rotary fan that rotates by the fan motor 400 and conveys blowing air to the heat exchanger of the vehicle to cool the heat exchange medium circulating therein. The cooling fan 200, Thereby sucking the surrounding air and blowing it in the axial direction.

Accordingly, the fan shroud assembly 1 of the present invention is recessed inwardly so that the air sucked from the surroundings by the cooling fan 200 can pass through the resistor assembly 300, And an air flow unit 510 having a predetermined area of the circumference of the register mounting unit 500, which is formed at a lower level than the surface of the shroud 100.

Accordingly, the fan shroud assembly 1 of the present invention allows the air sucked into the cooling fan 200 through the air flow portion 510 to pass through the resistor assembly 300 mounted in the resistor mounting portion 500 The heat of the resistor assembly 300 may be cooled.

4, the air flowing part 510 is formed in the thickness direction of the fan shroud assembly 1 such that a predetermined area of the circumferential surface of the resistor mounting part 500 is formed lower than the surface of the shroud 100, The cross section may be formed in any one of "concave, U, V" shapes.

The air flowing part 510 is formed to be wider along the circumferential surface of the resistor mounting part 500 on the side adjacent to the cooling fan 200 so that the air sucked into the cooling fan 200 flows into the resistor assembly 300 And is formed so as to pass evenly.

5, since the air flow portion 510 may be difficult to process according to the shape of the cooling fan 200 and the shroud 100, the width of the stepped portion may be narrowed, As shown in FIG.

In other words, the air flow portion 510 may have a plurality of cross sections formed at any one of the concave, U, and V shapes at regular intervals along the circumferential surface of the register mounting portion 500.

The air flow portion 510 may be formed on the air flow passage through which the cooling fan 200 sucks air from the periphery and may be formed to face each other on both sides of the resistor assembly 300.

The air sucked into the cooling fan 200 passes through the resistor mounting part 500 through the air flow part 510 formed on one side of the resistor assembly 300 and then flows into the resistor assembly 300 And is sucked into the cooling fan 200 through the air flow portion 510 formed on the other side.

Referring to FIGS. 4 to 5, the operation of the fan shroud assembly 1 according to the present invention will be described.

The resistor assembly 300 operates to regulate the speed of the fan motor 400 and generates heat during operation.

The resistor assembly 300 mounted on the resistor mounting part 500 is not smoothly flowed by the circumferential surface of the resistor mounting part 500 which surrounds the periphery of the resistor mounting part 500. As a result, The air sucked into the cooling fan 200 is passed through the air flow portion 510 formed for the heat sink 500 to cool the resistor assembly 300.

The fan shroud assembly 1 of the present invention is characterized in that the air flow portion 510 is formed on both sides of the resistor assembly 300 so as to cool the resistor assembly 300 from one side of the resistor assembly 300 to the other side, So that the air sucked into the fan 200 is allowed to pass.

Accordingly, in the fan shroud assembly of the present invention, a resistor mounting portion formed concavely in the thickness direction is mounted on the shroud so as to mount a resistor assembly for controlling the speed of the fan motor, and air can flow from the resistor mounting portion to the cooling fan The air flow portion is formed so that a predetermined region of the circumferential surface of the resistor mounting portion is stepped lower than the shroud surface so that the air flow of the cooling wind for cooling the resistor assembly is smoothly performed and the resistor assembly that generates heat is effectively cooled to improve durability .

In addition, the fan shroud assembly of the present invention prevents the resistor assembly, which controls the speed of the fan motor, from generating heat due to high temperature and prevents performance degradation, It is possible to efficiently perform cooling.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. It goes without saying that various modifications can be made.

1: fan shroud assembly
100: Shroud
110:
120: motor support ring
130:
200: cooling fan
300: resistor assembly
400: Fan motor
500:
510: air flow

Claims (5)

Shroud 100;
A cooling fan 200 mounted on a tuyere 110 of the shroud 100;
A fan motor 400 mounted on the shroud 100 to drive the cooling fan 200; And
A resistor assembly 300 for adjusting the speed of the fan motor 400 and mounted on the shroud 100; Wherein the fan shroud assembly (1)
In the shroud 100,
A resistor mounting part 500 is formed to be recessed in the thickness direction so that the resistor assembly 300 is mounted,
A predetermined area of the circumferential surface of the resistor mounting part 500 located on the air flow path through which the cooling fan 200 sucks air from the periphery is formed in a predetermined thickness of the trench 110 And the air is formed on the path through which the resistor is mounted to the register mounting part 500 and the path through which the air is discharged through the resistor assembly 300 And an air flow portion (510).
delete The method according to claim 1 ,
The air flow portion 510
Wherein a cross-section in the thickness direction of the fan shroud assembly (1) is formed in one of "concave, U, V" shape.
The method of claim 3,
The air flow portion 510
Wherein a plurality of cross-sections formed in any one of the concave, U, and V shapes are formed at regular intervals along the circumferential surface of the register mounting portion (500).
The method of claim 1, wherein
The air flowing part 510 formed in a path through which air flows into the register mounting part 500 and the air flowing part 510 formed on a path through which air is discharged are arranged to face each other with respect to the resistor assembly 300 Wherein the fan shroud assembly is disposed in the fan shroud assembly.

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