KR20150071175A - Assembly of fan and shroud - Google Patents

Abstract

The present invention relates to an assembly of a fan and a shroud, and more specifically, to an assembly of a fan and a shroud, which cools a register assembly as a distance is formed between the register assembly and the shroud, and a cooling hole is formed in the shroud so that air of the outlet side moves to the inlet side through the distance and the cooling hole, and reduces corrosion dangerousness since external air is not directly in contact with the register assembly.

Description

[0001] The present invention relates to a fan and shroud assembly,

The present invention relates to a fan and shroud assembly, and more particularly, a gap is formed between a resistor assembly and a shroud, and a cooling hole is formed in the shroud, so that the air on the discharge side is moved to the inflow side through the gap and the cooling hole To fan and shroud assemblies that are capable of cooling resistor assemblies, and that external air can not directly contact the resistor assembly, thereby reducing the risk of corrosion.

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 and a shroud assembly disposed behind the radiator for forcibly blowing air to improve the cooling efficiency of the condenser and the radiator.

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

FIG. 1 is a perspective view of a conventional fan and shroud assembly, FIG. 2 is a cross-sectional view of a conventional resistor mounting portion, FIG. 3 is a front view of an air discharge side of a conventional fan and shroud assembly, Fig.

Referring to FIGS. 1 to 4, the fan and shroud assembly assembly includes a shroud 10, a cooling fan 20, a fan motor M, and a resistor assembly 30.

The shroud 10 is provided with a tuyere 11 corresponding to the cooling fan 20. The fan motor M is disposed at 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, a connector 33 for supplying power to the resistor 31, . 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, some 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 some of the wires on the vehicle power supply side are 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 resistor 31 is connected to the resistor 31, For the highest temperature point of operation, the temperature rises to 220 degrees Celsius.

As a result, when the resistor is not properly cooled and overheated, there is a risk of fire, peripheral components may be damaged, and particularly, the cover is broken and peripheral parts such as the radiator are damaged by the fragments , There is a possibility that the internal airtightness can not be maintained and the operation of the entire cooling module may become impossible.

Japanese Unexamined Patent Publication No. 2007-255399 (published on October 04, 2007) has been proposed to solve the above problems.

Japanese Laid-Open Patent Application No. 2007-255399 discloses that both the fan and the shroud assembly and the case that can accommodate the resistor are made of a metal material so that the heat of the resistor can be easily transferred to the shroud side, thereby preventing the resistor from overheating.

However, Japanese Laid-Open Patent Application No. 2007-255399 discloses that the entire shroud is made of a metal material, which is heavier than a resin material, hindering the lightening of the entire cooling module, and making the manufacturing and assembling process difficult.

In addition, when a component such as calcium chloride is contained in the air, structures such as a resistor may be corroded and the overall durability may be deteriorated.

Accordingly, there is a demand for a method capable of reducing the risk of corrosion and cooling the resistor appropriately without hindering the weight and size reduction of the fan and shroud assembly.

Japanese Patent Application Laid-Open No. 2007-255399 (2007.10.04)

SUMMARY OF THE INVENTION It is an object of the present invention to provide a method of manufacturing a semiconductor device in which a gap is formed between a resistor assembly and a shroud and a cooling hole is formed in the shroud, And to provide a fan and shroud assembly that is capable of cooling the resistor assembly as it is moved to the inlet side through the air inlet, thereby reducing the risk of corrosion because the external air is not directly in contact with the resistor assembly.

Particularly, it is an object of the present invention to provide a cooling device for an air conditioner in which a protrusion is formed in a shroud, air on a discharge side is guided at intervals, and cooling holes are formed long to be parallel to the air flowing in at intervals, And to provide a fan and shroud assembly capable of further enhancing performance.

It is also an object of the present invention to provide a flange portion formed on an extension of a body of a resistor assembly and protruding to support an extension in the shroud, thereby firmly fixing the resistor assembly to the shroud and providing a gap between the shroud and the resistor assembly And to provide a fan and shroud assembly capable of easily forming a fan and a shroud assembly.

The fan and shroud assembly 1000 of the present invention includes a shroud 100 in which a tuyere 101 is hollow, a fan 200 mounted in the shroud 100, A fan and shroud assembly (1000) comprising a means (300) and a resistor assembly (400) for adjusting a driving speed of the driving means (300), wherein the fan and shroud assembly (1000) (400) is fixed to the shroud (100) so as to form an interval (I) between the shroud (100) and the shroud (100) And the cooling hole 110 is formed in a hollow shape.

In addition, the fan and shroud assembly 1000 is characterized in that the air on the discharge side is moved to the inflow side through the gap I and the cooling holes 110 to cool the resistor assembly 400.

The fan and shroud assembly 1000 includes a body 410 having a connector portion 430 for supplying power to a resistor (not shown) of the resistor assembly 400, A second fixing hole 121 corresponding to the first fixing hole 421 is formed in the shroud 100 and a second fixing hole 421 corresponding to the interval A flange portion 120 for supporting the extension portion 421 is protruded so as to hold the first fixing hole 421 and the second fixing hole 121 by the fixing means 500, So that the resistor assembly 400 and the shroud 100 are fixed.

At this time, when the register assembly 400 is viewed from the front so that the air introduced at the interval I is moved to the cooling hole 110, the shroud 100 surrounds the remaining surface except one side And a protrusion 130 protruding from the protrusion 130 is formed.

In addition, the cooling holes 110 are formed long to be parallel to the air flow flowing in the interval I.

In addition, a plurality of the cooling holes 110 are formed.

Accordingly, the fan and shroud assembly of the present invention has a gap formed between the resistor assembly and the shroud. By forming a cooling hole in the shroud, the air on the discharge side is moved to the inflow side through the gap and the cooling hole, And the external air is not directly in contact with the resistor assembly, thereby reducing the risk of corrosion.

Particularly, the fan and shroud assembly of the present invention has protrusions formed in the shroud to guide the air on the discharge side at intervals, and to form the cooling holes so as to be parallel to the air flow flowing in at intervals, There is an advantage that the cooling performance of the resistor assembly can be further improved.

In addition, the fan and shroud assembly of the present invention has an extension formed in the body of the resistor assembly and a flange portion protruding to support the extension in the shroud, thereby firmly fixing the resistor assembly to the shroud, There is an advantage that the gap between the assemblies can be easily formed.

1 is a perspective view of a conventional fan and shroud assembly;
2 is a sectional view of a conventional resistor mounting portion.
3 is a front view of a conventional fan and shroud assembly air discharge side.
4 is a front view of a conventional fan and shroud assembly air inlet side.
5 is a perspective view of a fan and shroud assembly in accordance with the present invention.
6 is an exploded perspective view of a fan and shroud assembly according to the present invention.
7 is a cross-sectional view of a fan and shroud assembly in accordance with the present invention.

Hereinafter, the fan and shroud assembly 1000 of the present invention having the above-described characteristics will be described in detail with reference to the accompanying drawings.

The fan and shroud assembly 1000 of the present invention is configured to form a cooling module together with a heat exchanger such as a radiator, a condenser, and the like, and forced air is blown to increase the heat exchange efficiency of the heat exchanger.

The fan and shroud assembly 1000 of the present invention includes a shroud 100, a fan 200, a driving means 300, a fan 200, and a shroud 100.

The shroud 100 is a basic case for supporting the fan and shroud assembly 1000 of the present invention, and the air outlet 101 is hollowed to allow air to flow therein.

The shroud 100 includes a seat 102 and a stator 103 for supporting the driving means 300 in a central region thereof.

The fan 200 is mounted on the shroud 100 and rotates to blow air.

The driving means 300 is a means for driving the fan 200 and is seated in the seating portion 102 of the shroud 100.

The resistor assembly 400 is connected to the driving unit 300 through a connecting unit 440 to adjust a driving speed of the driving unit 300. The resistor assembly 400 includes a power supply unit A body 410 having a connector 430 for connection with the means 440, a resistor (not shown) provided inside the body 410, and a connecting means 440.

At this time, the resistor assembly 400 is spaced apart from the shroud 100 by a predetermined distance in a state of being mounted on the shroud 100, forming a gap I therebetween, A cooling hole 110 is formed in a region where the resistor assembly 400 is located.

5 and 6, when the fan and shroud assembly 1000 of the present invention is viewed from the front of the assembly of the resistor assembly 400, the resistor assembly 400 is mounted A cooling hole 110 is formed in which a certain region of the region of the light shroud 100 is hollow.

The fan and shroud assembly 1000 of the present invention is configured such that the air on the discharge side is moved to the inflow side through the gap I between the resistor assembly 400 and the shroud 100 and the cooling hole 110, The resistor assembly 400 is cooled.

7, the flow of the external air by the fan 200 is indicated by an empty arrow, and the flow of cooling the resistor assembly 400 is indicated by a black arrow.

The inlet side refers to the left side portion in FIG. 7 with respect to the shroud 100, and the discharge side refers to the right side portion in FIG. 7 with respect to the shroud 100.

The cold air flowing from the outside is forcedly blown by the rotation of the fan 200 and is discharged from the inflow side toward the discharge side. The discharge side, which is the engine room side with respect to the shroud 100, Even if cold air is introduced by the rotation of the fan 200, the discharge side maintains a higher pressure than the inflow side.

The fan and shroud assembly 1000 of the present invention uses the pressure difference between the inlet side and the outlet side as described above. The air on the outlet side is moved to the inlet side through the gap I and the cooling hole 110, 400 are cooled.

The fan and shroud assembly 1000 of the present invention extends from the body 410 to maintain an interval I between the resistor assembly 400 and the shroud 100 and includes a first fixing hole 421 And a second fixing hole 121 corresponding to the first fixing hole 421 is formed in the shroud 100 so that the gap I is maintained A flange portion 120 protruding to support the extension portion 421 is formed.

At this time, the resistor assembly 400 can be fixed to the shroud 100 by fixing means 500 passing through the first fixing hole 421 and the second fixing hole 121.

6, the fixing means 500 is in the form of a bolt, the flange portion 120 is formed with the second fixing hole 121, and the bolt-type fixing means 500 is inserted into the concave As shown in Fig.

The flange portion 120 protrudes toward the side where the resistor assembly 400 is mounted and supports the extension portion 421 of the body 410 so that the flange portion 120 corresponds to the shroud 100 of the resistor assembly 400 One side of the body 410 forms an interval I from the shroud 100.

The fan and shroud assembly 1000 of the present invention is characterized in that when the shroud 100 is viewed from the front with the resistor assembly 400 mounted thereon, A protrusion 130 protruding to cover the surface is formed.

The air on the discharge side is easily introduced into the gap I so that the air introduced through the gap I passes through the gap I and is not moved to the discharge side again, And a predetermined region of the shroud 100 is protruded.

In this case, the protrusion 130 is preferably protruded to surround three surfaces of the four sides of the resistor assembly 400 except for one side to which air is introduced at the interval I.

The protruding portion 130 is formed to be equal to or larger than the protruding degree of the flange portion 120.

The fan and shroud assembly 1000 of the present invention can clarify the mounting position of the resistor assembly 400 through the protrusion 130 and the air introduced into the gap I can flow through the cooling holes 110 in order to effectively cool the resistor assembly 400 during the air movement process.

In addition, the fan and shroud assembly 1000 of the present invention may have a plurality of cooling holes 110 formed so as to be parallel to an air flow flowing in the interval I.

In the present invention, parallel to the air flow introduced at the interval (I) means the plane direction of the protrusion 130 facing from the open side of the protrusion 130 formed to surround the resistor assembly 400 And in FIG. 6, it means the longitudinal direction of the protrusion 130.

6, the plurality of cooling holes 110 are spaced apart from each other by a predetermined distance in a direction perpendicular to the longitudinal direction of the protruding portions 130, which are both side directions in which the flange portions 120 are formed desirable.

6, the shroud 100 has three cooling holes 110 formed therein. However, the fan and shroud assembly 1000 of the present invention is not limited to the cooling holes 110, The shape and number may be further varied considering the degree of cooling required by the resistor assembly 400.

Accordingly, the fan and shroud assembly 1000 of the present invention has the gap I formed between the resistor assembly 400 and the shroud 100 and the cooling holes 110 formed in the shroud 100 It is possible to cool the resistor assembly 400 while the air on the discharge side is moved to the inflow side through the gap I and the cooling holes 110 and the external air is not directly contacted to the resistor assembly 400, There is an advantage.

Particularly, in the fan and shroud assembly 1000 of the present invention, the projecting portion 130 is formed in the shroud 100 so that the air on the discharge side is guided at the interval I, and the cooling holes 110 are formed at the interval I Is formed so as to be parallel to the incoming air flow, thereby facilitating the air flow and thus enhancing the cooling performance of the resistor assembly 400. [

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.

1000: Fan and shroud assembly
100: shroud 101: tuyere
102: seat part 103:
110: cooling hole
120: flange portion 121: second fixing hole
130: protrusion
200: Fan
300: driving means
400: resistor assembly
410: Body
420: extension part 421: first fixing hole
430:
440: Connection means
500: fixing means
I: Spacing

Claims (6)

A fan 200 mounted on the shroud 100; a driving means 300 for driving the fan 200; a driving means 300 for driving the fan 200; And a resistor assembly (400) for adjusting a driving speed of the fan assembly (400)
The fan and shroud assembly (1000)
The resistor assembly 400 is fixed to the shroud 100 so as to form a gap I between the shroud 100 and the shroud 100,
Wherein a cooling hole (110) is hollowed in an area of the shroud (100) where the resistor assembly (400) is located.
The method according to claim 1,
The fan and shroud assembly (1000)
Wherein the air on the discharge side is moved to the inlet side through the gap (I) and the cooling holes (110) to cool the resistor assembly (400).
3. The method of claim 2,
The fan and shroud assembly (1000)
A body 410 having a connector part 430 for supplying power to a resistor (not shown) of the resistor assembly 400, and a body 410 extending from the body 410 and having a first fixing hole 421, (421)
A flange portion 120 for supporting the extension portion 421 such that the second fixing hole 121 corresponding to the first fixing hole 421 is formed in the shroud 100 and the gap I is maintained, Respectively,
Characterized in that the fixing means (500) penetrates the first fixing hole (421) and the second fixing hole (121) to fix the resistor assembly (400) and the shroud (100) .
3. The method of claim 2,
The shroud (100)
When the register assembly 400 is viewed from the front to move the air introduced into the cooling hole 110 to the cooling hole 110, a protrusion 130 protruding to cover the remaining surface except for one side is formed Wherein the fan and shroud assembly comprises:
5. The method of claim 4,
Wherein the cooling holes (110) are elongated to be parallel to the air flow entering the gap (I).
6. The method of claim 5,
Wherein a plurality of the cooling holes (110) are formed.

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