KR20120075942A - Structure of fan shroud - Google Patents

Abstract

PURPOSE: A fan shroud assembly is provided to maintain performance and to improve durability by improving the cooling efficiency of a resister because air flows in through a cooling hole. CONSTITUTION: A fan shroud assembly comprises a fan shroud. The fan shroud comprises a plenum(110), a ring unit(120), a motor mounting(130), and a stator(140). The ring unit is formed in an air discharging side of the plenum and a fan(200) is installed in the inside of the ring unit. The motor mounting is arranged in the central part of the ring unit to fix a fan motor(M). The stator connects the motor mounting and the ring unit. The fan shroud comprises a resister assembly(300) and a cooling hole(500). The resister assembly is mounted on the plenum. The cooling hole is formed along the peripheral surface of the resister assembly of the plenum.

Description

Fan Shroud Assembly {Structure of Fan Shroud}

The present invention relates to a fan shroud (Fan Shroud) for cooling the automotive heat exchanger through the air, and more particularly to a fan shroud assembly to increase the cooling efficiency of the resistor by applying a cooling hole to the resistor mounting portion.

In general, an engine, a cooling means for cooling the engine, an air conditioner, and the like are provided in an engine room of an automobile. The cooling device is for cooling an engine of an automobile, and includes a radiator for cooling the engine's cooling water and a fan for inducing air flow of the radiator to increase the heat radiation efficiency of the radiator surface and consequently to further promote the cooling water cooling efficiency. Fan Shroud.

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 a vehicle, and is a pusher type and a puller type according to the arrangement of the heat exchanger. type).

The pusher type is a type in which the axial flow fan forcibly blows air backwards in front of the heat exchanger. This type is used when there is a small space behind the heat exchanger in the engine room due to the low blowing efficiency for the heat exchanger. Is a type that allows air from the front of the heat exchanger to pass through the heat exchanger at the rear of the heat exchanger, and is applied to most automobiles due to its relatively high blowing efficiency compared to the pusher type.

1 is a perspective view of a conventional fan shroud, and FIG. 2 is a cross-sectional view of a conventional resistor installation unit. 3 is a conventional front fan shroud air inlet side front view, and FIG. 4 is a conventional front fan shroud air inlet side front view.

1 to 4, the fan shroud assembly is used for cooling the heat exchange medium passing through the inside of the heat exchanger such as a radiator, a condenser, for example, the shroud 10, the cooling fan 20, And 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, which is fixed to the shroud 10 by a plurality of guide vanes installed in the radial direction.

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.

The fan motor M is selectively driven in two or more stages of high speed and low speed. In order to adjust the speed of the fan motor M, the resistor assembly 30 is provided between the vehicle power supply side and the fan motor M. FIG. Wiring is connected.

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

Although not shown in the figure, by wiring connections by the connectors 33 and 40, two strands of the wiring on the vehicle power supply side are connected to the fan motor M side, and one strand of the wiring on the vehicle power supply side is the resistor 31. Is connected to each other, and the resistor 31 and the fan motor M are connected to each other to form a low speed operation circuit. By the low speed operation circuit by this register 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. .

As shown in FIG. 2, in the case of the resistor 31, heat is generated when the resistor 31 is energized. In the case of the heat generating point H having the highest temperature during the operation of the resistor 31, the temperature rises to 220 degrees Celsius. However, the conventional shroud 10 has a poor structure for cooling the resistor 31 because there is little air flow at the heat generating point (H).

Therefore, the resistor 31 is always exposed to high temperature, and there is a concern about a problem of deterioration in performance and durability.

The present invention has been made to solve the above problems, an object of the present invention is to provide a fan shroud assembly to cool the resistor by inducing the flow of air by applying a cooling hole around the resistor mounting portion on the shroud.

In addition, the present invention provides a fan shroud assembly that prevents foreign substances from flowing through the cooling hole by applying a guide plate spaced apart from the cooling hole.

Fan shroud assembly of the present invention is a rectangular plenum 110, the ring portion 120 is formed on the air discharge side of the plenum 110 and the fan 200 is installed therein, the motor (M) To include a shroud 100 consisting of a motor mounting 130 located in the center of the ring portion 120, and a stator 140 connecting the motor mounting 130 and the ring portion 120 A fan shroud assembly, wherein the fan shroud comprises: a resistor assembly (300) mounted on the plenum (110); And at least one cooling hole 500 formed along a circumferential surface of the resistor assembly 300 on the plenum 110. Characterized in that it comprises a.

At this time, the cooling hole 500 is characterized in that formed on the upper side of the resistor assembly (300).

In addition, the register assembly 300, the resistor 310 is installed from the plenum 110 to adjust the speed of the motor (M), and the register 310 to the plenum 110 It includes a support flange 320 for fixing, characterized in that the heat radiation fins 311 is formed on the opposite surface of the plenum 110 on the register (310).

Here, the fan shroud, the guide plate 610 which is installed at a predetermined distance from the cooling hole 500 to the vehicle engine room side, the connecting plate 620 connecting the guide plate 610 and the shroud 100. Guide portion 600 composed of; It characterized in that it further comprises.

In addition, the guide plate 610 is characterized in that formed larger than the size of the cooling hole (500).

The fan shroud structure of the present invention having the above configuration has the effect of maintaining performance and improving durability because the cooling efficiency of the resistor is increased by introducing air through the cooling holes.

In addition, the foreign matter that can enter through the cooling holes can be prevented through the guide plate and can be expected to waterproof.

1 is a perspective view of a conventional fan shroud
2 is a cross-sectional view of a conventional resistor installation unit
3 is a front view of a conventional fan shroud air discharge side
4 is a front view of a conventional fan shroud air inlet side
5 is a perspective view of the fan shroud of the present invention
Figure 6 is a perspective view of the register installation portion of the present invention
7 is a cross-sectional view of the register installation portion of the present invention.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the drawings.

Referring to FIG. 5, the fan shroud structure of the present invention includes a shroud 100, a fan 200, a fan motor M, a resistor assembly 300, a fan motor connector 400, a cooling hole 500, and a guide part. 600 is made.

The fan shroud of the present invention is fixed to the rear end of the heat exchanger to introduce cooling air into the heat exchanger, and a shroud 100, a fan motor M fixed to the shroud 100, and the fan motor M. The fan 200 is rotatably coupled to the configuration.

The shroud 100 guides the air blowing generated while the fan 200 rotates by the fan motor M and is fixedly installed in the heat exchanger of the vehicle while supporting the fan motor M as a driving source. It is a member.

The shroud 100 is formed on a plenum 110 having a substantially rectangular shape, an air discharge side of the plenum 110, a ring part 120 in which the fan 200 is installed, and the ring part. The motor mounting 130 is located in the center of the 120, and a plurality of stator 140 for connecting the motor mounting 130 and the ring portion 120.

The shroud 100 is provided with a blower 150 for guiding the blown air sucked into the center in the axial direction, and has a rectangular shape corresponding to the shape of the heat exchanger so that the rear surface may contact the entire rear surface of the heat exchanger. Molding is formed as a synthetic resin material.

Here, the air outlet 150 of the shroud 100 may be formed in a circular shape so as to reduce the wind pressure loss to increase the air blowing efficiency of the fan 200.

The fan 200 is integrally formed including a blade, a hub, and a band part. The hub is a part forming the center of the fan 200, and is coupled to the drive shaft of the fan motor M. The blades are rotary blades arranged radially, more specifically, radially extending on the outer periphery of the hub, a plurality of blades are arranged. The blade is configured to blow air in the axial direction by the rotation of the fan 200, the fan 200 of the present invention may be formed in various ways such that the blade is bent or formed at a predetermined angle. . The band portion may be configured to connect the end of the blade to support the blade.

The fan 200 is a rotary fan that rotates by the fan motor M and transmits blown air to a heat exchanger of the vehicle to cool the heat exchange medium circulating therein. Here, the fan 200 may be coupled to an end portion of the drive shaft protruding forward of the fan motor M to rotate in the same rotation direction. The hub has a container shape in which a surface facing the fan motor M is opened, and a center thereof is coupled to a drive shaft of the fan motor M to rotate the blade by the rotational force of the fan motor M. Play a role.

6 and 7, the resistor assembly 300 may be installed through the plenum 110 of the shroud 100. The fan motor M is selectively driven in two or more stages of high speed and low speed, and the resistor assembly 300 is provided between the vehicle power supply side and the fan motor M in order to adjust the speed of the fan motor M. The wiring is connected.

The resistor assembly 300 includes a resistor 310, a support flange 320 for fixing the resistor 310 to the plenum 110, and a connector 330 for supplying power to the resistor 310. ). The connector 330 is connected to the fan motor connector 400 connected to the wiring coming from the fan motor (M). The register 310 is installed to be exposed to the air inlet side, the open one end (inlet end) toward the periphery of the air outlet 110, the other open end (outlet end) toward the edge of the shroud 100 To be installed. The support flange 320 may be installed to penetrate the plenum 110 in a configuration for fixing the register 310 and the connector 330 on the shroud 100. The connector 330 is installed to be exposed to the air discharge side, is connected to the fan motor connector 400 is configured to receive the power to control the driving power of the fan motor (M).

Although not shown in the drawing, by wiring connections by the connectors 330 and 400, two strands of the wiring on the vehicle power supply side are connected to the fan motor M side, and one strand of the wiring on the vehicle power supply side is the resistor 310. Is connected to each other, and the low-speed operating circuit is constituted by the resistor 310 and the fan motor M being connected to each other. By the low speed operation circuit by this resistor 310, 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. .

At this time, the fan shroud structure of the present invention has the following configuration to cool the heat generated during the operation of the resistor 310.

The cooling hole 500 may be formed around the resistor assembly 300. At least one or more cooling holes 500 may be formed. The cooling hole 500 is formed through the plenum 110 of the shroud 100. The cooling hole 500 may be any shape as long as it can flow the air in the engine room side to the air inlet side of the fan shroud. The cooling unit 500 receives air from the engine room side that is relatively higher than the air inlet pressure of the fan shroud to cool the heat generating unit of the resistor 310.

The cooling hole 500 may be formed above the resistor assembly 300. The backflow wind flowing from the engine room side exits through the tuyeres 150. The register assembly 300 is positioned on the path of the backflow wind, and the counterflow flows from the top to the bottom of the resistor assembly 300. This is to allow the wind to flow easily.

In addition, the heat radiation fins 311 are formed in the resistor 310. The heat dissipation fin 311 has a shape of a general heat dissipation fin 311 protruding to the outside of the outer surface of the resistor 310. The heat dissipation fins 311 are formed on the outer surface of the resistor 310, but are formed in the countercurrent wind flow path on the resistor 310. That is, it may be formed on the outer surface of the register 310, but may be formed on the opposite surface of the plenum 110. The cooling fins of the resistor 310 are increased through the heat dissipation fins 311.

At this time, the fan shroud structure of the present invention in order to block foreign matter or moisture that can be introduced through the cooling hole 500 is the same as the following configuration.

A guide part 600 may be formed at the fan shroud air discharge side of the cooling hole 500. The guide part 600 may be integrally formed with the shroud 100 or may be coupled to the shroud 100 through a screw or a bolt.

The guide part 600 includes a guide plate 610 and a connecting plate 620. The guide plate 610 is formed at a predetermined distance apart from the fan shroud air discharge side of the cooling hole 500 on the plate body. The guide plate 610 is formed larger than the size of the cooling hole 500 to increase the blocking effect of foreign matter or moisture.

The guide plate 610 is fixed to the plenum 110 through a connecting plate 620. The connecting plate 620 is formed above the cooling hole 500 and the guide plate 610. Therefore, the rain and wash water may flow down through the connecting plate 620 to prevent the rain and wash water from penetrating through the cooling hole 500.

Hereinafter, the operation of the present invention configured as described above will be described with reference to the drawings.

As shown in FIG. 7, the resistor 310 generates heat during operation. The cooling wind flowing through the vent 150 does not cool the inner heat generating part of the resistor 310, thereby decreasing the cooling efficiency of the resistor 310.

At this time, when the cooling hole 500 is formed, the pressure of the engine room side is relatively higher than the pressure of the fan shroud air inflow side due to the operation of the fan shroud, and the engine room through the cooling hole 500 by the pressure difference. Air is introduced into the fan shroud air inlet side from the side to cool the inner heating portion of the resistor 310. In addition, a heat radiation fin 311 is formed in the air flow path of the resistor 310 to further increase the cooling efficiency of the resistor 310.

In addition, the guide plate 610 is to block foreign matter and moisture that can be introduced through the cooling hole 500, the connecting plate 620 flows down the rain and washing water flows in through the cooling hole 500 Will block.

The technical spirit should not be interpreted as being limited to the above embodiments of the present invention. Various modifications may be made at the level of those skilled in the art without departing from the spirit of the invention as claimed in the claims. Therefore, such improvements and modifications fall within the protection scope of the present invention, as will be apparent to those skilled in the art.

100: shroud 110: plenum
120: ring 130: motor mounting
140: stator 150: ventilation holes
200: fan M: fan motor
300: resistor assembly 310: resistor
320: support flange 330: connector
400: fan motor connector
500: cooling hole
600: guide portion 610: guide plate
620: connecting plate

Claims (5)

A plenum 110 having a rectangular shape, a ring portion 120 formed on the air discharge side of the plenum 110 and having a fan 200 installed therein, and the ring portion for fixing the fan motor M. In the fan shroud assembly comprising a motor mounting 130 located in the center of the 120, and a shroud 100 consisting of a stator 140 connecting the motor mounting 130 and the ring portion 120,
The fan shroud,
A resistor assembly 300 mounted on the plenum 110; And
At least one cooling hole 500 formed along a circumferential surface of the resistor assembly 300 on the plenum 110;
Fan shroud assembly comprising a.
The method of claim 1,
The cooling hole 500,
Fan shroud assembly, characterized in that formed on the upper side of the resistor assembly (300).
The method of claim 1,
The register assembly 300,
In order to adjust the speed of the fan motor (M), the resistor 310 is installed spaced apart from the plenum 110, and the support flange 320 for fixing the resistor 310 to the plenum 110 Include,
Fan shroud assembly, characterized in that the heat dissipation fin (311) is formed on the opposite surface of the plenum (110) on the register (310).
The method of claim 1,
The fan shroud,
Guide portion 600 consisting of a guide plate 610 which is installed at a predetermined distance from the cooling hole 500 to the vehicle engine room side, and a connecting plate 620 connecting the guide plate 610 and the shroud 100. );
Fan shroud assembly further comprising.
The method of claim 4, wherein
The guide plate 610 is a fan shroud assembly, characterized in that formed larger than the size of the cooling hole (500).

Images