KR102082260B1 - Assembly of fan and shroud - Google Patents

Abstract

The present invention relates to a fan and shroud assembly, and more particularly, a gap is formed between the resistor assembly and the 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. A fan and shroud assembly that can cool a resistor assembly and that outside air does not directly contact the resistor assembly can reduce the risk of corrosion.

Description

Assembly of fan and shroud

The present invention relates to a fan and shroud assembly, and more particularly, a gap is formed between the resistor assembly and the 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. A fan and shroud assembly that can cool a resistor assembly and that external air does not directly contact the resistor assembly can reduce the risk of corrosion.

In general, a condenser for condensing a high temperature refrigerant generated in the process of cooling the inside of the vehicle and a radiator for cooling the high temperature coolant generated in the process of cooling the engine located at the rear of the condenser. And a fan and shroud assembly located at the rear of the radiator to forcibly blow air to improve 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 an air-cooled heat exchanger such as a radiator or a condenser of an automobile.

1 is a perspective view of a conventional fan and shroud assembly, FIG. 2 is a cross-sectional view of a conventional resistor installation section, FIG. 3 is a front view of an air discharge side of a conventional fan and shroud assembly, and FIG. 4 is a conventional fan and shroud assembly. Front view of the air intake side of

1 to 4, the fan and shroud assembly assembly comprises a shroud 10, a cooling fan 20, a fan motor M, and a resistor assembly 30. The shroud 10 is formed with an air vent 11 corresponding to the cooling fan 20. The fan motor M is disposed at the center of the tuyeres 11 by the motor support ring, and the motor support ring is fixed to the shroud 10 by a plurality of guide vanes installed in the radial direction.

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Therefore, while the cooling fan 20 is rotated by the driving of the fan motor M, air is blown through the air outlet 11, and the heat exchanger can be cooled by the air blower. In addition, the fan motor M is selectively driven in two or more stages of high speed and low speed, and in order to adjust the speed of the fan motor M, the resistor assembly 30 is connected between the vehicle power supply side and the fan motor M. The wiring is connected.

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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. Equipped with. The connector 33 is connected to a fan motor connector 40 connected to the wiring coming from the fan motor M.

Although not shown in the drawings, some strands of the wiring on the vehicle power supply side are connected to the fan motor M side, and some strands of the wiring on the vehicle power supply side are connected by the wirings by the connectors 33 and 40. 31, and the resistor 31 and the fan motor M are connected to each other, whereby a low speed operation circuit is constructed.

By the low speed operation circuit by the resistor 31, the voltage supplied to the fan motor M is selectively adjusted low, and by this voltage adjustment, the fan motor M can be selectively driven from high speed to low speed. . The resistor 31 has a coil (not shown) formed therein, and a cover is formed. As shown in FIG. 2, in the case of the resistor 31, heat is generated as a resistor, and heat is generated when the resistor 31 is applied. During operation, the hottest heating point will rise to 220 degrees Celsius.

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Accordingly, if the resistor is not properly cooled and overheated, there is a risk of fire, and the peripheral parts may be damaged, and in particular, the cover may be damaged, and the debris may damage peripheral parts such as a radiator. In this case, there is a possibility that the inside of the cooling module is not maintained, and the entire cooling module may not be operated.

In order to solve the above problems, Japanese Patent Application Laid-Open No. 2007-255399 (published date: 2007.10.04) has been proposed. Japanese Laid-Open Patent Publication No. 2007-255399 uses a metal material for both the fan and the shroud assembly and the case accommodating the resistor, so that the heat of the resistor can be easily transferred to the shroud side, thereby preventing overheating of the resistor.

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However, Japanese Laid-Open Patent Publication No. 2007-255399 has a problem that the entire shroud is a metal material, which is heavier than the resin material, which hinders the weight of the entire cooling module and makes the manufacturing and assembly process difficult. In addition, in the case where components such as calcium chloride are contained in the air, components such as resistors may be corroded, and thus there is a problem that overall durability may be degraded. Accordingly, there is a need for a method capable of reducing the risk of corrosion and appropriately cooling the resistor without disturbing the weight and miniaturization of the fan and shroud assembly.

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

The present invention has been made to solve the above problems, an object of the present invention is to form a gap between the resistor assembly and the shroud, the cooling hole is formed in the shroud air on the discharge side gap and cooling holes It is to provide a fan and shroud assembly that can move through the inlet side to cool the resistor assembly, and the external air does not directly contact the resistor assembly to reduce the risk of corrosion.

Particularly, an object of the present invention is to form a protrusion on the shroud so that the air on the discharge side is guided at intervals, and the cooling holes are formed to be parallel to the air flow introduced at intervals to smooth the air flow, thereby cooling the resistor assembly. It is to provide a fan and shroud assembly that can further improve performance.

In addition, an object of the present invention is an extension is formed on the body of the resistor assembly, the flange portion protruding to support the extension in the shroud to secure the resistor assembly to the shroud while the gap between the shroud and the resistor assembly It is to provide a fan and shroud assembly that can be easily formed.

The fan and shroud assembly 1000 of the present invention includes a shroud 100 in which the air vent 101 is hollow, a fan 200 mounted on the shroud 100, and a drive for driving the fan 200. In a fan and shroud assembly (1000) comprising a means (300) and a resistor assembly (400) for adjusting the drive speed of the drive means (300), the fan and shroud assembly (1000) is comprised of the resistor assembly. 400 is fixed to the shroud 100 so as to form a gap I between the shroud 100 and a predetermined distance from the shroud 100, and the shroud 100 is located in the shroud 100 region where the resistor assembly 400 is located. Cooling hole 110 is characterized in that the hollow.

The fan and shroud assembly 1000 is characterized in that the resistor assembly 400 is cooled while the discharge side air is moved to the inlet side through the gap I and the cooling hole 110.

In addition, the fan and shroud assembly 1000 includes a body 410 in which a connector unit 430 is formed for the resistor assembly 400 to supply power to a resistor (not shown), and extends from the body 410. The first fixing hole 421 is hollow and includes an extension part 421, and the second fixing hole 121 corresponding to the first fixing hole 421 is formed in the shroud 100 and the gap ( The flange part 120 supporting the extension part 421 is formed to protrude so that the I part is maintained, and penetrates the first fixing hole 421 and the second fixing hole 121 by the fixing means 500. The resistor assembly 400 and the shroud 100 is fixed.
Here, the shroud 100 protrudes to surround the remaining surfaces except for one side when the front surface of the resistor assembly 400 is viewed in front such that the air introduced at the gap I moves to the cooling hole 110. Characterized in that the protrusion 130 is formed.

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In addition, the cooling holes 110 may be elongated to be parallel to the air flow introduced into the gap I, and a plurality of cooling holes 110 may be formed.

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Accordingly, the fan and shroud assembly of the present invention has a gap formed between the resistor assembly and the shroud, and a cooling hole is formed in the shroud so that the air on the discharge side moves to the inlet side through the gap and the cooling hole to cool the resistor assembly. It is possible to reduce the risk of corrosion since the outside air does not directly contact the resistor assembly.

In particular, the fan and shroud assembly of the present invention has a protrusion formed in the shroud to guide the air on the discharge side at intervals, and the cooling holes are formed to be parallel to the air flow introduced at the interval to smooth the air flow, There is an advantage that can further increase the cooling performance of the resistor assembly.

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

1 is a perspective view of a conventional fan and shroud assembly.
2 is a cross-sectional view of a conventional resistor installation unit.
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.
Figure 6 is an exploded perspective view of the 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 features as described above 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 forcibly blows air to increase the heat exchange efficiency of the heat exchanger. Here, 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.

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The shroud 100 is a basic case for supporting the fan and shroud assembly 1000 of the present invention, the blower 101 is molded so that air flows therein. The shroud 100 includes a seating portion 102 for mounting the driving means 300 in the central region and a stator 103 for supporting the seating portion 102. 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 on the seating portion 102 of the shroud 100.

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The resistor assembly 400 is connected to the driving means 300 and the connecting means 440 to adjust the driving speed of the driving means 300, the resistor assembly 400 is a power supply and the connection It includes a body 410 is formed with a connector portion 430 for connecting to the means 440, a resistor (not shown) provided in the body 410, the connection means 440.

Here, the register assembly 400 is spaced apart from the shroud 100 by a predetermined distance while being mounted on the shroud 100, so that a gap I is formed between the shroud 100. In the shroud 100, a cooling hole 110 is formed in a region where the resistor assembly 400 is located.

Referring to FIGS. 5 and 6, when the fan and shroud assembly 1000 of the present invention is viewed from the front of the assembled side of the register assembly 400, the resistor assembly 400 is mounted and covered. Cooling holes 110 in which a predetermined region of the wood 100 is hollow are formed. Through this, the fan and shroud assembly 1000 of the present invention is moved to the inlet side through the gap (I) and the cooling hole 110 between the resistor assembly 400 and the shroud 100 is the air on the discharge side The resistor assembly 400 is cooled.

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In FIG. 7, the flow of external air by the fan 200 is indicated by an empty arrow inside, and the flow of cooling the resistor assembly 400 is indicated by a black arrow inside. The inflow side refers to the left part in FIG. 7 based on the shroud 100, and the discharge side refers to the right part in FIG. 7 based on the shroud 100.

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Cool air introduced from the outside is forcedly blown by the rotation of the fan 200 and discharged from the inflow side to the discharge side. The discharge side of the engine room based on the shroud 100 is a state in which hot air is present. Even though cold air is introduced by the rotation of the fan 200, the discharge side maintains a high pressure compared to the inlet side.

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

On the other hand, the fan and shroud assembly 1000 of the present invention extends from the body 410 to maintain the gap (I) between the resistor assembly 400 and the shroud 100 and the first fixing hole 421 ) Includes an extension part 421 which is hollow, 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.

In this case, the resistor assembly 400 may be fixed to the shroud 100 by fixing means 500 passing through the first fixing hole 421 and the second fixing hole 121. In Figure 6, the fixing means 500 is in the form of a bolt, the flange portion 120 is the second fixing hole 121 is formed, the bolt-shaped fixing means 500 is inserted concave so as to be fastened. An example is shown.

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The flange portion 120 protrudes toward the side where the register assembly 400 is mounted to support the extension part 420 of the body 410, thereby corresponding to the shroud 100 of the register assembly 400. One side of the body 410 forms a gap I with the shroud 100. And the fan and shroud assembly 1000 of the present invention, when looking at the shroud 100 in a state in which the resistor assembly 400 is mounted to the front, the remaining surface except for one side to the shroud 100 Protruding portion 130 is formed to protrude to surround the.

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The protrusion 130 easily flows the air on the discharge side into the gap I, and the air introduced into the gap I does not move back to the discharge side through the gap I and the cooling hole 110. A portion of the shroud 100 protrudes to be moved to). Here, the protrusion 130 may protrude so as to surround the remaining three surfaces except for one surface on which air is introduced into the gap I among the four surfaces that are the circumference of the resistor assembly 400.

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The protrusion 130 is formed to be greater than or equal to the amount of protrusion of the flange portion 120. Through this, the fan and shroud assembly 1000 of the present invention can clarify the mounting position of the resistor assembly 400 through the protrusion 130, the air introduced into the gap (I) is a cooling hole ( By moving to 110 there is a manual that can effectively cool the resistor assembly 400 in the air movement process.

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And the fan and shroud assembly 1000 of the present invention is formed long so that the cooling hole 110 is parallel to the air flow introduced into the gap (I), a plurality can be formed. In the present invention, parallel to the air flow introduced into the gap I means the surface direction of the protrusion 130 opposite to the opening side of the protrusion 130 formed to surround the resistor assembly 400. And, in Figure 6, it means the longitudinal direction of the protrusion 130.

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In addition, as shown in FIG. 6, the cooling holes 110 are spaced apart from each other by a predetermined distance in a direction perpendicular to the longitudinal direction of the protruding portion 130 in both directions in which the flange portion 120 is formed. desirable. In FIG. 6, the shroud 100 illustrates an example in which three cooling holes 110 are formed, but the fan and shroud assembly 1000 of the present invention is not limited thereto. The shape and number may be formed in various ways in consideration of the degree of cooling required by the resistor assembly 400.

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Accordingly, in the fan and shroud assembly 1000 of the present invention, a gap I is formed between the resistor assembly 400 and the shroud 100, and a cooling hole 110 is formed in the shroud 100. As the air on the discharge side is moved to the inlet side through the gap I and the cooling hole 110, the resistor assembly 400 can be cooled, and external air does not directly contact the resistor assembly 400, thereby reducing the risk of corrosion. There is an advantage.

In particular, in the fan and shroud assembly 1000 of the present invention, the projection 130 is formed in the shroud 100 so that the air on the discharge side is guided at intervals I, and the cooling holes 110 at intervals I. It is formed to be parallel to the incoming air flow to facilitate the air flow, thereby increasing the cooling performance of the resistor assembly 400 has an advantage.

The present invention is not limited to the above-described embodiments, and the scope of application is not limited, and various modifications can be made without departing from the gist of the present invention as claimed in the claims.

1000: Fan and Shroud Assembly
100: shroud 101: blower
102: seating portion 103: stator
110: cooling hole
120: flange 121: second fixing hole
130: protrusion
200: fan
300: drive means
400: resistor assembly
410 body
420: extension part 421: first fixing hole
430 connector
440: connection means
500: fixing means
I: interval

Claims (6)

The shroud 100 having the air vents 101 formed therein, a fan 200 mounted on the shroud 100, a driving means 300 for driving the fan 200, and the driving means 300. A fan and shroud assembly comprising a resistor assembly 400 for adjusting a drive speed;
The register assembly 400 is fixed to the shroud 100 at a predetermined distance from the shroud 100 so as to form a gap I therebetween.
In the shroud 100 region where the register assembly 400 is located, a cooling hole 110 for inflow of outside air is formed.
Protrusions 130 protruding to surround the resistor assembly 400 on the other side except for one side so that the air introduced into the gap (I) between the resistor assembly 400 and the shroud can move to the cooling hole 110. ) Is formed in the shroud,
The fan and shroud assembly, characterized in that for cooling the resistor assembly (400) while the discharge side air is moved to the inlet side through the gap (I) and the cooling hole (110).
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Body 410 is formed with a connector portion 430 for the resistor assembly 400 to supply power to the resistor (not shown), and extending from the body 410 and the first fixing hole 421 is hollow A portion 421;
A flange part 120 supporting the extension part 421 so 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. Is formed to protrude;
Fan and shroud assembly, characterized in that for fixing the resistor assembly 400 and the shroud 100 through the first fixing hole 421 and the second fixing hole 121 by a fixing means (500) .
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The cooling hole (110) is a fan and shroud assembly, characterized in that formed in a direction parallel to the air flow flowing into the gap (I).
The method of claim 5, wherein
The cooling hole 110 is a fan and shroud assembly, characterized in that formed in plurality.

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