KR20040057358A - Condenser having integrated receiver drier - Google Patents

Abstract

PURPOSE: A condenser integrally formed with a receiver drier is provided to prevent interference of the condenser with the radiator by placing the mounting pin in the receiver drier, to reduce manufacturing process and expense by integrally forming the lower end cap of the receiver drier, and to stabilize the mounting structure by increasing the distance between the condenser and the mounting pin. CONSTITUTION: A condenser is composed of plural header pipes with inlet and outlet pipes, plural tubes communicated and connected between the header pipes; and radiating fins inserted to the outsides of the tubes. A receiver drier is combined with the header pipe by a connecting pipe. A lower cap is combined with the lower part of the first header pipe of the condenser, and a first mounting pin is installed in the lower part of the lower cap. The second header pipe is communicated with the receiver drier, and a lower end cap(352) is combined with the lower part of a receiver tank(310) of the receiver drier. A second mounting pin(390) is protruded in the lower part of the lower end cap.

Description

Condenser having integrated receiver drier

The present invention relates to a condenser, and more particularly, to a receiver integrated condenser provided with mounting pins in the end cap of the receiver to prevent interference between the radiator and the condenser.

In general, a front end module (FEM) is a combination of a cooling module, a head lamp, a bumper, a carrier, and a horn. have. Among them, the cooling module is composed of a radiator, a receiver drier, a condenser, a cooling fan, and the like. The cooling module is mounted in the engine room of the vehicle and is coupled to the bracket of the vehicle body to position it.

Referring to FIG. 1, the cooling module includes a condenser 10 and a radiator 100 arranged side by side behind the condenser 10.

The condenser 10 is a heat exchanger in which a heat exchange medium compressed at high temperature and high pressure from a compressor flows in and exchanges heat with lower ambient air to be a liquid heat exchange medium.

To this end, the condenser 10 includes a plurality of header pipes 11 installed to face each other, a plurality of tubes 12 having both ends communicating with the header pipes 11, and an outer surface of the tube 12. A heat dissipation fin 13 interposed therebetween, and a cap 14 for sealing the upper and lower ends of the header pipe 11.

The receiver 1 connected to the header pipe 11 is connected. The receiver 1 includes a receiver tank 2 in communication with the header pipe 11 and an end cap 3 for sealing the upper and lower ends of the receiver tank.

The radiator 100 is a heat exchanger that receives heat by circulating the water jacket formed in the engine by cooling water forcedly circulated by the water pump, and releases heat to the outside by circulating it to the radiator 100 again.

To this end, the radiator 100 includes a header 110 disposed to be spaced up and down by a predetermined interval, a tank 140 coupled to the header 110, and a tube disposed in parallel between the header 110 ( 120, a heat dissipation fin 130 interposed on an outer surface of the tube 120, and a support 150 positioned on an outer surface of the outermost tube 120.

In this case, a mounting pin 19 protrudes a predetermined length from the bottom surface of the cap 14 coupled to the header pipe 11 of the condenser 10. The mounting pin 19 is directly coupled to the vehicle body, or a separate bracket is installed on the radiator 100 to be coupled thereto to fix the position.

However, in the conventional cooling module, since the gap G between the condenser 10 and the radiator 100 is narrow, the mounting pin 19 installed in the cap 14 of the condenser 11 is assembled when the cooling module is assembled. When the reference point is used, the interference between the tank 140 of the radiator 100 and the cap 14 of the condenser 10 occurs.

In addition, the position at which the condenser 10 is mounted cannot be flexibly adjusted due to the presence of the mounting pin 19, which makes it difficult to mount the cooling module in the engine room of the vehicle body.

An object of the present invention is to provide a receiver integrated condenser which has a mounting pin formed on the end cap of the receiver to improve the mounting of the cooling module.

1 is a perspective view showing a conventional cooling module,

2 is a perspective view showing a cooling module according to an embodiment of the present invention;

3 is a cross-sectional view showing a condenser equipped with the receiver of FIG. 2;

Figure 4 is an exploded perspective view showing the receiver of Figure 3,

Figure 5 is an exploded perspective view showing a part of the receiver of Figure 2 enlarged.

<Brief description of symbols for the main parts of the drawings>

30 ... condenser 31 ... first header pipe

32.2nd header pipe 33 ... tube

34.Heat-resistant 휜 38a ... Top cap

38b ... lower cap 39 ... first mounting pin

300 ... 310 310 ... Tank

Desiccant Assembly 330 Filter Assembly

351 ... top end cap 352 ... bottom end cap

380 ... connection pipe 390 ... 2nd mounting pin

In order to achieve the above object, the receiver integrated condenser according to an aspect of the present invention,

A condenser having a plurality of header pipes provided with an inlet and an outlet pipe, a plurality of tubes communicatively connected between the header pipes, and heat dissipation fins interposed on the outer surface of the tubes;

In the receiver integrated condenser comprising: a receiver connected by the header pipe and the connection pipe,

The condenser and the receiver are each equipped with a mounting means; characterized in that.

The mounting means may include a first mounting pin installed in the lower cap of the condenser and a second mounting pin installed in the lower end cap of the receiver.

2 illustrates a cooling module according to an embodiment of the present invention.

Referring to the drawings, the cooling module includes a condenser 20, a receiver 25 connected to the condenser 20, and a radiator 200 installed in parallel with the condenser 20. In addition, a plurality of cooling fans are further installed to blow air into the condenser 20 and the radiator 200 to increase heat exchange efficiency.

The condenser 20 is provided with a header pipe 21 made of a first header pipe 21a and a second header pipe 21b provided to face the first header pipe 21a. A plurality of tubes 22 are provided between the first and second header pipes 21a and 21b. On the outer surface of the tube 22, a heat dissipation fin 23 is interposed to enlarge the heat dissipation area.

The header pipe 21 is provided with a cap 24. That is, upper and lower caps 24a and 24b for sealing them are coupled to upper and lower ends of the first and second header pipes 21a and 21b, respectively.

The receiver 25 is connected to the header pipe 21 via a connecting pipe 28. The receiver 25 includes a receiver tank 26 and an end cap 27 for sealing the upper and lower ends of the receiver tank 26.

The radiator 200 is provided with an upper header 211 and a lower header 212 disposed to face up and down. Upper and lower tanks 241 and 242 are coupled to the upper and lower headers 211 and 212. The upper and lower headers 211 and 212 are provided with a plurality of tubes 220 connected at both ends thereof. A heat dissipation fin 230 is interposed on the outer surface of the tube 220 to expand the heat dissipation area. A support 250 is installed at the outermost portion of the plurality of tubes 220.

According to a feature of the invention, the lower cap 24b for sealing the lower end of the header pipe 21 of the condenser 20, and the end cap for sealing the lower end of the receiver tank 26 of the receiver 25 At 27, mounting means 29 are provided for fixing the position of the condenser 20 to the vehicle body.

More detailed description is as follows.

3 illustrates a condenser 30 having a receiver 300 according to an embodiment of the present invention, and FIG. 4 shows the receiver 300 separately.

3 and 4, the condenser 30 includes a first header pipe 31 and a second header pipe 32 provided to face the first header pipe 31. The first and second header pipes 31 and 32 may be formed by joining two members in a longitudinal direction.

End portions are connected between the first and second header pipes 31 and 32 so as to communicate with each other, and a plurality of tubes 33 spaced apart from each other by a predetermined interval are provided. The tube 33 can be made of a plate-shaped extruded tube. The tube 33 forms an overheating region, a condensation region, and a supercooling region of the heat exchange medium along a path through which the heat exchange medium flows. A heat dissipation fin 34 is interposed on the outer surface of the tube 33.

The first header pipe 31 is provided with an inlet pipe 35 coupled to the first header pipe 31 to introduce a heat exchange medium of a high temperature and high pressure into a gaseous phase from the compressor. In addition, the first header pipe 31 is provided with an outlet pipe 36 through which heat-exchanged heat exchange medium is discharged.

The first and second header pipes 31 and 32 are respectively provided with an upper cap 38a and a lower cap 38b for sealing them at upper and lower ends thereof. The first mounting pin 39 protrudes from the bottom of the lower cap 38b of the first header pipe 31.

Meanwhile, a plurality of baffles 37 are alternately installed in the first and second header pipes 31 and 32 to allow the heat exchange medium to flow in meander.

The second header pipe 32 is provided with a receiver 300 coupled to this to collect the heat exchange medium of the liquid phase flowing through the tube 33 and heat-exchanged.

The receiver 300 is provided with a receiver tank 310. The receiver tank 310 is cylindrical and has a hollow pipe shape. The outer circumferential surface of the receiver tank 310 is in communication with the second header pipe 32 by a connecting pipe 380.

The connection pipe 380 is a first flow in which the heat exchange medium of the condensed liquid flows in a meandering manner by the baffles 37 installed in the first and second header pipes 31 and 32 so that the condensation region can flow in. And second connecting pipes 381 and 382 and a third connecting pipe 383 for discharging the heat exchange medium from the receiver tank 310 to the subcooling region of the condenser 30. The number of the first to third connection pipes 381 to 383 may vary depending on the coupling structure with the second header pipe 32 coupled thereto.

At this time, the receiver tank 310 is connected by a connecting pipe 380 to the second header pipe 32 where no mounting means is installed.

The desiccant assembly 320 is inserted into the inner upper side of the receiver tank 310. The desiccant assembly 320 is provided with a cylindrical desiccant net 321. The desiccant net 321 is preferably a material having excellent heat resistance, such as a metal material such as SUS net, and the desiccant 322 is stored therein. Both ends of the desiccant net 321 are sealed by welding or the like in a state in which the desiccant 322 is embedded.

The filter assembly 330 is embedded in the lower side of the receiver tank 310. The filter assembly 330 is reticulated to filter foreign matter from the heat exchange medium flowing into the receiver tank 310.

Upper and lower end caps 351 and lower end caps 352 are installed at upper and lower ends of the receiver tank 310 to be sealed. The lower end cap 352 is provided with a plurality of O-rings (340), the second mounting pin 390 that can be fixed to the position when mounted on the vehicle body on the bottom surface is installed. .

5 is an enlarged view of the lower end of the receiver tank 310 of FIG.

Referring to the drawings, the lower end cap 352 is screwed to the lower portion of the receiver tank 310 is provided. At least one o-ring 340 is interposed in the lower end cap 352 to prevent leakage of the receiver tank 310 when coupled.

A second mounting pin 390 protrudes from the bottom of the lower end cap 352. The second mounting pin 390 is said to be advantageous in the manufacturing process is formed integrally with the lower end cap 352. To this end, the second mounting pin 390 is preferably to form the lower end cap 352 at the time of injection molding. The second mounting pin 390 has a length that can be inserted into a bracket of a vehicle body or a radiator to be mounted to fix the condenser 30 (see FIG. 3).

The cooling module having the above structure has a lower cap 38a coupled to the lower end of the first header pipe 31 of the condenser 30. A first mounting pin 39 is provided on the bottom of the lower cap 38a.

In addition, the receiver 300 is in communication with the second header pipe 32 in which the first mounting pin 39 is not installed, and the lower end of the receiver tank 310 of the receiver 300 has a lower end. Cap 352 is coupled. The second mounting pin 390 protrudes from the bottom of the lower end cap 322.

Accordingly, with the condenser and the radiator arranged behind it, the first mounting pin 39 is fixed to set the position of the condenser relative to the radiator, and then the lower cap 38b of the condenser and the lower tank of the radiator and The position of the condenser 30 may be fixed by fixing the second mounting pin 390 through a mounting coupling part formed on the bracket of the vehicle body or the radiator, which is a position that does not cause interference of the vehicle.

As described above, the cooling module of the present invention can obtain the following effects.

First, at least one mounting pin may be located in the receiver, thereby solving the condenser interference with the radiator.

Second, since the lower end cap of the receiver is molded integrally with the injection, it can simplify the manufacturing process and reduce the manufacturing cost.

Third, by increasing the distance between the mounting pins of the condenser, it has a more stable mounting structure.

Fourth, since the end cap area of the receiver tank is larger than the cap area coupled to the header pipe, it may have a wider design range in forming a mounting pin on the end cap.

Although the present invention has been described with reference to one embodiment shown in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

Claims (2)

A condenser having a plurality of header pipes provided with an inlet and an outlet pipe, a plurality of tubes communicatively connected between the header pipes, and heat dissipation fins interposed on the outer surface of the tubes; In the receiver integrated condenser comprising: a receiver connected by the header pipe and the connection pipe, The condenser and the receiver, each mounting means is installed; a receiver integrated condenser characterized in that the. The method of claim 1, The mounting means includes a first mounting pin installed on the lower cap of the condenser and a second mounting pin installed on the lower end cap of the receiver.