KR101304864B1 - Cooling module - Google Patents

Abstract

The present invention relates to a cooling module including a condenser having a subcooling region formed thereon, and more particularly, a conveying pipe for raising and supplying a refrigerant to the subcooling region outside the receiver dryer by a flange part. The internal structure of the receiver drier is simplified, and a condenser capable of improving the space utilization of the engine room by forming the transfer pipe as closely as possible to the receiver drier tank, and a fastening means that can be clipped to the flange part are installed in the radiator. The present invention relates to a cooling module that is easily combined with a condenser without requiring a bracket.

Description

Cooling module

The present invention relates to a cooling module including a condenser having a subcooling region formed thereon, and more particularly, a conveying pipe for raising and supplying a refrigerant to the subcooling region outside the receiver dryer by a flange part. The internal structure of the receiver drier is simplified, and a condenser capable of improving the space utilization of the engine room by forming the transfer pipe as closely as possible to the receiver drier tank, and a fastening means that can be clipped to the flange part are installed in the radiator. The present invention relates to a cooling module that is easily combined with a condenser without requiring a bracket.

In general, the condenser is a gaseous refrigerant of high temperature and high pressure flows into the liquid state while releasing liquefied heat by heat exchange, and then discharged. The liquid refrigerant is mixed.

However, when the gaseous refrigerant and the liquid phase refrigerant are mixed, only an equilibrium condition can be obtained in temperature and pressure. Therefore, in order to increase the condenser efficiency, the liquid refrigerant that has already been condensed and the gaseous refrigerant that has not yet condensed are separated and recondensed. It is preferable to induce supercooling by. In order to generate such subcooling, the condenser is generally equipped with a receiver drier. 1 shows a condenser equipped with a general receiver drier, and a refrigerant flow, a condensation region, and a subcooling region at this time. In FIG. 1, the condensation region is denoted by A1 and the subcooling region is denoted by A2.

On the other hand, in general, on the other hand, the recent development of automobiles is increasing the tendency to reduce the number of parts and processes in order to improve productivity. A technique for assembling, i.e., modularizing, has been proposed, and a representative example thereof is a front end module in which a bumper including a cooling module, a headlamp and a bumper beam stay is assembled and modularized. Figure 2 shows an example of such a front end module. The cooling module includes heat exchangers as described above, in particular the condenser is often a component of the cooling module coupled to this front end module.

In this case, in the case of the cooling module coupled to the front end module, the lower side is often covered by a peripheral material such as a bumper beam. However, as shown in FIG. 1, in general, in the case of a condenser having a subcooling region, the subcooling region is often located under the core, and thus, the heat exchange in the subcooling region is not performed smoothly, resulting in a decrease in the subcooling efficiency. there was.

In order to solve this problem, a technique related to the structure of the condenser for allowing the subcooling region to be disposed above has been conventionally disclosed.

In Korean Patent Laid-Open No. 2007-7022372 (hereinafter, referred to as Prior Art 1), as shown in FIG. 2 (A), the inner tube is connected to the receiver dryer to move the lower refrigerant to the upper portion, and the desiccant is connected to the tube. And a structure to be inserted is disclosed. By the way, in the case of actually implementing the structure according to the prior art 1, there is a problem that manufacturing is very difficult because the connection and arrangement of the desiccant and the inner tube is not stable. In addition, Korean Patent Laid-Open Publication No. 2003-0086067 (prior art 2) discloses a structure in which a lower refrigerant is moved upward by connecting an outer tube as shown in FIG. 2 (B). In this case, a structure such as a lower cap provided with a filter and a desiccant, which is used in a conventional receiver drier, can be introduced as it is, and there is an advantage in that a problem in the manufacture or insertion arrangement of the desiccant does not newly occur.

However, the prior art 2 has a problem that the space utilization in the engine room is reduced because the volume is increased because the external tube is further provided in the general receiver dryer, and in particular, all automotive parts are now miniaturized and compact. As a design contrary to the tendency that is becoming, there is a problem that it is difficult to apply in practice.

As such, various techniques have been disclosed in which a receiver coolant is pulled upward to form a supercooled region at the top of the condenser, but the prior arts achieve the main purpose as described above (the supercooled region formed on the condenser). However, there is a problem that the volume is increased by the external pipe, thereby reducing the space utilization in the engine room, or there is no problem in space utilization, but the fabrication of the internal structure itself is difficult or layout limitation to realize the main purpose. There is a problem such as following, and there has been a steady demand for a technology that can solve all these problems.

The present invention has been made in order to solve the above problems, an object of the present invention is to provide a conveying pipe for raising and supplying the refrigerant to the subcooling area on the outside of the receiver dryer by the flange portion of the receiver dryer, It is to provide a cooling module including a condenser to simplify the internal structure and to form the transfer pipe as closely as possible to the receiver dryer tank to improve the engine room space utilization.

In addition, an object of the present invention is to form a step between the connecting portion located at the height formed in the supercooled region and the flange portion through which the refrigerant flows upward through the transfer pipe to form a condenser that prevents the gaseous refrigerant from entering the subcooled region. It is to provide a cooling module including.

In addition, an object of the present invention is to provide a cooling module that is simply coupled to the condenser without the need for a bracket by being installed on the radiator fastening means that can be clipped to the flange portion.

The cooling module of the present invention includes a condenser and a radiator including a radiator, wherein the condenser 1 is spaced apart by a predetermined distance from the first header tank 110 and the second header tank 120. ); An inlet pipe 210 formed in the first header tank 110 or the second header tank 120 and a refrigerant flowing therein and an outlet pipe 220 discharging the refrigerant; A plurality of tubes 300 having both ends fixed to the first header tank 110 and the second header tank 120 to form a refrigerant flow path; A plurality of fins 400 interposed between the tubes 300; And a receiver dryer (600) installed at one side of the first header tank (110) or the second header tank (120) to communicate with the connection part (130), and to separate a gaseous refrigerant from a liquid refrigerant. And a first flange 750 in which the receiver dryer 600 communicates with a lower space of the receiver dryer 600 and has a first communication path 751 bent in the refrigerant flow direction. A flange portion 740 communicating with the upper space of the receiver dryer 600 and including a second flange 760 formed therein, the second communication path 761 being bent in the refrigerant flow direction; A transfer pipe 700 connected to the flange part 740 so that a lower space and an upper space communicate with each other outside the receiver dryer 600; And a partition plate 630 which is formed inside the receiver dryer 600 and adjusts a flow path such that the refrigerant introduced through the transfer pipe 700 is supplied to the subcooling region of the condenser 1. .

In addition, the condenser has an outlet pipe 220 formed above the inlet pipe 210 of the first header tank 110, and a first baffle 510 between the inlet pipe 210 and the outlet pipe 220. The second baffle 520 is formed at the same height as the first baffle 510 in the second header tank 120, so that a supercooling area is formed in the upper region of the condenser 1. do.

In addition, the partition plate 630 is formed at the same height as the first baffle 510 and the second baffle 520.

In addition, the condenser 1 is characterized in that the connecting portion 130 formed in the subcooling region of the connecting portion 130 is lower than the second flange 760, it is formed higher than the partition plate 630.

In addition, the transfer pipe 700 includes a first connection pipe 710 connected to communicate the lower space of the receiver dryer 600 and the first communication path 751 of the first flange 750; A second connection pipe 720 connected to communicate the upper space of the receiver dryer 600 with the second communication path 761 of the second flange 760; And a third connection pipe 730 extending in a height direction such that the first communication path 751 and the second communication path 761 are connected to the outside of the receiver drier 600. Including, but the connection portion of the first to third connection pipes (710 ~ 730) is characterized in that each is inserted and fixed to the flange portion 740.

In addition, the flange portion 740 has an upper predetermined region of the first communication path 751 and the second communication path 761 so that the third connection pipe 730 may be inserted and seated and fixed in the height direction. The diameter of the lower predetermined area of the receiver is reduced so that the first stepped portion 741 and the first connection pipe 710 and the second connection pipe 720 are inserted in the longitudinal direction so that the receiver can be fixed at a predetermined depth The diameter of a predetermined area of the first communication path (751) and the second communication path (761) adjacent to the dryer 600 is reduced, characterized in that the stepped second step portion 742 is formed.

In addition, the receiver dryer 600 has a cylindrical shape and has an opening portion 611 at a lower end thereof so that the receiver dryer tank 610 communicates with the first header tank 110 or the second header tank 120 and the connecting portion 130. ); And a filter unit 621 inserted into the receiver dryer tank 610 to filter foreign matter contained in the refrigerant, and supporting the filter unit 621 and coupled to the opening 611 of the receiver dryer tank 610. A lower cap assembly 620 comprising a lower cap 622; Characterized in that it comprises a.

In addition, in the coupling structure of the condenser and the radiator, any one of the pair of header tanks 800 of the radiator 2 protrudes toward the condenser 1 to surround the upper or lower surface of the flange portion 740. A flange coupling portion 910 formed; And a fixing part 920 having an end portion of the flange coupling part 910 protruding toward the flange part 740. The fastening means 900 of the clip type including a is installed is characterized in that coupled to the flange portion 740.

In addition, the flange coupling portion 910 is coupled to the lower surface of the second flange 760 and the upper surface of the first flange 750, the through hole is hollow so that the feed pipe 700 is sandwiched between the width direction. A first flange coupling part 911 in which a furnace 913 is formed; And a second flange coupling part 912 coupled to an upper surface of the second flange 760 and a lower surface of the first flange 750, and configured to seat and fix the flange part 740. And is formed to include a plurality of protrusions.

In addition, the fixing portion 920 is reduced in diameter in the direction in which the ends of the first flange coupling portion 911 and the second flange coupling portion 912 face each other to facilitate the detachment of the fastening means 900. It is characterized by the inclination.

In addition, the radiator 2 is seated and fixed on the upper and lower surfaces of the first header tank 110 or the second header tank 120 of the condenser 1 to the other header tank of the header tank in which the fastening means is formed. The seating portion 810 is characterized in that it is installed to protrude toward the condenser (1).

The condenser included in the cooling module of the present invention is provided with a conveying tube for raising and supplying a refrigerant to the subcooling region outside the receiver dryer by a flange part, thereby simplifying an internal structure of the receiver dryer, and By making it close to the receiver dryer tank as much as possible, there is an advantage that the space utilization of the engine room can be improved.

In addition, the condenser included in the cooling module of the present invention allows the gas phase refrigerant to enter the subcooling region by forming a step between the connecting portion located at the height formed in the subcooling region and the flange portion through which the refrigerant flows upward through the transfer pipe. There is an advantage that can be prevented.

In addition, the cooling module of the present invention has the advantage that the fastening means that can be clipped to the flange portion is installed on the radiator can be easily combined with the condenser without the need for a separate bracket.

1 is a view showing a conventional condenser having a subcooled region.
2 is a view showing a condenser having a conventional subcooling region formed thereon.
3 is a perspective view of a condenser according to the present invention.
4 is a cross-sectional view showing a condenser according to the present invention.
5 is a refrigerant flow diagram of a condenser in accordance with the present invention.
6 is a cross-sectional view showing another condenser according to the present invention.
7 is a cross-sectional view showing a flange portion provided in the condenser of FIG.
8 is a perspective view showing a coupling structure of the cooling module according to the present invention.
Figure 9 is a plan view showing a coupling structure of the cooling module according to the present invention.

Hereinafter, with reference to the accompanying drawings, a condenser, a condenser and a radiator of the present invention will be described in detail.

1 is a view showing a condenser having a conventional subcooling region, Figure 2 is a view showing a condenser having a conventional subcooling region formed thereon, Figure 3 is a perspective view showing a condenser according to the present invention, Figure 4 is a present Figure 5 is a cross-sectional view showing a condenser according to the invention, Figure 5 is a flow chart of the refrigerant of the condenser according to the invention, Figure 6 is a cross-sectional view showing another condenser according to the invention, Figure 7 is a flange portion provided in the condenser of Figure 6 8 is a perspective view illustrating a coupling structure of a cooling module according to the present invention, and FIG. 9 is a plan view illustrating a coupling structure of a cooling module according to the present invention.

The cooling module 100 of the present invention includes a condenser 1 and a radiator 2, and the condenser 1 is shown in Figs. 3 and 4, the condenser 1 of the present invention is large The first header tank 110, the second header tank 120, the inlet pipe 210, the outlet pipe 220, the tube 300, the fin 400 and the receiver dryer 600, in particular the transfer pipe 700. And a flange portion 740.

The first header tank 110 and the second header tank 120 are generally formed by a combination of a header and a tank, and are provided side by side at a predetermined distance.

The inlet pipe 210 and the outlet pipe 220 are formed in any one of the first header tank 110 or the second header tank 120 to allow the refrigerant to flow in or out.

Both ends of the tube 300 are fixed to the first header tank 110 and the second header tank 120 to form a flow path of the refrigerant, and are spaced at a predetermined interval and arranged in parallel. The fin 400 is bent up and down between the tubes 300 to increase the heat transfer area with the air flowing between the tubes 300.

The receiver dryer 600 is installed at one side of the first header tank 110 or the second header tank 120 to communicate with the connection unit 130 to separate the gaseous refrigerant and the liquid refrigerant.

In particular, as shown in Figure 4, the condenser (1) is a supercooled region is formed in the upper predetermined area is the liquid-liquid separated by gas receiver by the receiver dryer 600 to raise the liquid refrigerant sank at the bottom to supply to the subcooling region Transfer pipe 700 for is formed on the outside of the receiver dryer (600).

In addition, the receiver dryer 600 may communicate with a lower space of the receiver dryer 600 and may include a first flange 750 having a first communication path 751 formed therein, which is bent in a refrigerant flow direction, and the receiver dryer. A flange portion 740 communicating with an upper space of the 600 and including a second flange 760 formed therein, the second communication path 761 being bent in the refrigerant flow direction; .

The condenser 1 has an outlet pipe 220 formed above the inlet pipe 210 of the first header tank 110, and has a first baffle 510 between the inlet pipe 210 and the outlet pipe 220. ) Is formed, and a second baffle 520 is formed at the same height as the first baffle 510 in the second header tank 120 to form a subcooling region in the upper region of the condenser 1. .

At this time, the receiver dryer 600 is further provided with a partition plate 630 formed inside the receiver dryer 600 to control a flow path of the refrigerant introduced through the transfer pipe 700, wherein the partition plate ( 630 adjusts the flow path so that the liquid refrigerant introduced into the upper portion through the second communication path 761 of the second flange 760 through the transfer pipe 700 may be supplied to the subcooling region without sinking down. Done.

The partition plate 630 may be formed at the same height as the first baffle 510 and the second baffle 520.

As shown in FIG. 4, the condenser 1 has a connection portion 130 located at a height at which a refrigerant flowing upwardly through the second communication path 761 of the second flange 760 is formed in the subcooling region. After passing through the supercooling region, it is preferable to provide a step between the second flange 760 and the connecting portion 130 so that the gaseous refrigerant is not introduced.

Therefore, the connection part 130 located at the height formed in the subcooling area may be lower than the second flange 760 and higher than the partition plate 630.

On the other hand, the transfer pipe 700 is the first connection pipe 710 is connected to communicate with the lower space of the receiver dryer 600 and the first communication path (751) of the first flange (750); A second connection pipe 720 connected to communicate the upper space of the receiver dryer 600 with the second communication path 761 of the second flange 760; And a third connection pipe 730 extending in a height direction such that the first communication path 751 and the second communication path 761 are connected to the outside of the receiver drier 600. It may be formed to include.

The transfer pipe 700 is connected to the first connection pipe 710 and the second connection pipe 720 formed in the horizontal direction, the third connection pipe 730 formed in the vertical direction '' 'shaped To form a flow path.

In this case, each of the first to third connection pipes 710 to 730 may be inserted into and fixed to the flange portion 740, respectively.

Accordingly, the condenser 1 improves position fixability when installed in the receiver dryer 600 by the first connection pipe 710 and the second connection pipe 720 protruding out of the flange portion 740. You can.

As shown in FIG. 7, the flange portion 740 has an upper predetermined region and the first portion of the first communication path 751 so that the third connection pipe 730 may be inserted and seated and fixed in the height direction. The diameter of the lower predetermined area of the two communication paths 761 is reduced, and the first stepped portion 741 is stepped, and the first connecting pipe 710 and the second connecting pipe 720 are inserted in the longitudinal direction, and at a predetermined depth. In order to be fixed, diameters of the predetermined areas of the first communication path 751 and the second communication path 761 adjacent to the receiver dryer 600 may be reduced, so that a stepped second step 742 may be formed. have.

Accordingly, when the third connection pipe 730 is inserted into the flange portion 740, the third connection pipe 730 is not inserted into the lower end of the first communication path 751 or the upper end of the second communication path 761 at a predetermined height. It is fixed.

In addition, when the first connection pipe 710 and the second connection pipe 720 are inserted into the flange portion 740, the depth is inserted into the first communication path (751) or the second communication path (761). By being limited and fixed at a certain depth, the refrigerant introduced through the first connection pipe 710 may be smoothly flowed along the third connection pipe 730 to the second connection pipe 720.

Meanwhile, the receiver dryer 600 may be formed to include a receiver dryer tank 610 and a lower cap assembly 620.

The receiver dryer tank 610 has a cylindrical shape and has an opening 611 formed at a lower end thereof so as to communicate with the first header tank 110 or the second header tank 120 by the connection part 130.

The lower cap assembly 620 is inserted into the receiver dryer tank 610 to filter the foreign matter contained in the refrigerant 621 and the filter unit 621 to support the receiver dryer tank 610 It is formed to include a lower cap 622 coupled to the opening 611 of the seal.

At this time, the first connection pipe 710 is the refrigerant introduced into the receiver dryer 600 through the connection portion 130 passes through the filter portion 621 to be discharged to the first connection pipe 710. It is preferable that the filter unit 621 is formed in the receiver dryer tank 610 at a height where the filter unit 621 is located.

Referring to Figure 5 describes the flow of the refrigerant in the condenser 1 according to the present invention,

First, the refrigerant introduced through the inlet pipe 210 is cooled and liquefied while passing through the condensation region, and the refrigerant passing through the condensation region is introduced into the receiver dryer 600 through the connection part 130 located at the bottom thereof.

The refrigerant introduced into the receiver dryer 600 is gas-liquid separated into a gaseous refrigerant and a liquid refrigerant, and the liquid refrigerant that has sunk at the lower end passes through the filter unit 621 of the lower cap assembly 620 and passes through the first communication path 751. Is discharged through).

The refrigerant discharged through the first communication path 751 formed in the first flange 750 rises along the transfer pipe 700, and thereafter, a second communication formed in the second flange 760. It is introduced back into the receiver dryer 600 through the furnace 761.

Subsequently, only the liquid refrigerant flows into the subcooling region through the connection part 130 formed at a height at which the subcoolant region is formed and formed in a step with the second flange 760.

Finally, the refrigerant that has finished subcooling is discharged through the outlet pipe 220.

On the other hand, the condenser, the radiator and the cooling fan of the vehicle is generally packaged as a cooling module and mounted on the vehicle. In this case, in order to combine the condenser and the radiator, the brackets are installed on both sides to assemble each bracket through fixing means such as screws, which has a disadvantage of having to go through several steps and a lot of separate parts.

On the contrary, the condenser 1 may be easily assembled with the neighboring radiator 2 without a bracket by the flange portion 740 connecting the transfer pipe 700 formed on the outside.

In order to couple the cooling module 100 according to the present invention, the header tank 800 of the radiator 2 located at the rear of the receiver dryer 600 of the condenser 1 is formed on the condenser 1 side. A flange coupling part 910 which protrudes and is formed to surround the upper or lower surface of the flange part 740; And a fixing portion 920 having an end portion of the flange coupling portion 910 protruding toward the flange portion 740. The clip type fastening means 900 is installed to be coupled to the flange portion 740. .

The flange coupling part 910 is coupled to a lower surface of the second flange 760 and an upper surface of the first flange 750 and an upper surface of the second flange 760 and the upper surface of the second flange 760. It may be composed of a second flange coupling portion 912 coupled to the lower surface of the first flange 750.

As shown in FIG. 8, the first flange coupling part 911 may be fitted in the width direction, that is, the transfer pipe 700 may be interposed between the radiator 2 and the condenser 1. Through-hole 913 is formed so that the predetermined area hollow so that the end is divided into two.

The second flange coupling part 912 may be coupled to an upper surface of the second flange 760 and a lower surface of the first flange 750 so that the flange part 740 may be seated and fixed.

At this time, the fixing portion protruding from the end of the flange coupling portion 910 so that the clip can be coupled to the flange portion 740, the first flange coupling portion 911 to facilitate the detachment of the fastening means (900). ) And the end portions of the second flange coupler 912 are inclined to decrease in diameter as they face each other.

Accordingly, the fastening means may be detached from the flange part 740 by applying a force in the outward direction of the fixing part 920.

As shown in FIG. 8, the first header tank 110 of the condenser 1 is provided in the other header tank 800 of the radiator header tank coupled to the condenser 1 by coupling with the flange portion 740. ) or may be installed so as to project toward the second header tank 120, the upper and the seat and the fixed seat portion 810 is the condenser (1) that when.

When the upper and of the seating unit 810 of the first header tank 110 or the second header tank of the first header tank 110 or the second header tank (120) to (120) is seated and can be fixed And an outer circumferential surface of the end portion, the outer circumferential surface of the core portion consisting of the right side of the outer circumferential surface, ie, the tube 300 and the fin 400, so that the condenser 1 may be inserted and seated in the left to right direction of FIG. 7. Is preferably formed open.

The coupling method of the first header tank 110 or the second header tank 120 and the radiator 2 header tank in which the flange portion 740 is not formed is not limited to the method described above, and is more efficient. Any change can be made.

Accordingly, the condenser included in the cooling module of the present invention has an advantage in that a transfer pipe for raising and supplying the refrigerant to the subcooling region is formed outside the receiver dryer so that the structure of the receiver dryer does not need to be changed.

In addition, the condenser included in the cooling module of the present invention by combining the first to third connecting pipes formed separately to form a 'c'-shaped conveying pipe by the flange portion, thereby forming a cylindrical extrusion pipe as conventional Since the minimum bending area required for bending is not necessary, the transfer pipe can be further brought into close contact with the receiver dryer, thereby improving engine room space utilization.

In addition, the condenser included in the cooling module of the present invention allows the gas phase refrigerant to enter the subcooling region by forming a step between the connecting portion located at a height formed in the subcooling region and the second flange through which the refrigerant is introduced through the transfer pipe. The advantage is that it can be prevented.

In addition, the cooling module of the present invention has the advantage that the fastening means that can be clipped to the flange portion is installed on the radiator can be easily combined with the condenser without the need for a separate bracket.

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: condenser 2: radiator
100: cooling module
110: first header tank 120: second header tank
130:
210: inlet pipe 220: outlet pipe
300: tube
400: pin
510: first baffle 520: second baffle
600: Receiver Drier
610: receiver dryer tank 611: opening
620: Lower Cap Assembly
630: partition plate
700: transfer pipe
710: first connecting pipe 720: second connecting pipe
730: third connection pipe 740: flange
741: first stepped part 742: second stepped part
750: first flange 751: first communication path
760: 2nd flange 761: 2nd communication path
800: header tank 810: seating part
900: fastening means
910: flange coupling portion 920: fixed portion
911: first flange coupler 912: second flange coupler

Claims (11)

A pair of header tanks 800, a plurality of first tubes 820 fixed at both ends to the header tank 800, and a plurality of first pins 830 interposed between the first tubes 820. Radiator (2) formed to include;
Inlet pipes formed in the first header tank 110 and the second header tank 120 and the first header tank 110 or the second header tank 120 spaced apart from each other by a predetermined distance and introduced with refrigerant. 210 and an outlet pipe 220 through which the refrigerant is discharged, a plurality of tubes 300 fixed at both ends to the first header tank 110 and the second header tank 120 to form a refrigerant flow path, and A plurality of fins 400 interposed between the tubes 300, and is installed on one side of the first header tank 110 or the second header tank 120 to communicate with the connecting portion 130, and the gaseous refrigerant A condenser 1 including a receiver dryer 600 separating the liquid refrigerant; In the cooling module 100 is formed to include,
The receiver dryer 600
The first flange 750 communicates with the lower space of the receiver dryer 600 and is bent in the refrigerant flow direction, and communicates with the upper space of the receiver dryer 600. A flange portion 740 including a second flange 760 formed therein with a second communication path 761 bent in the refrigerant flow direction;
A transfer pipe 700 connected to the flange part 740 so that a lower space and an upper space communicate with each other outside the receiver dryer 600;
A partition plate (630) formed inside the receiver dryer (600) to adjust a flow path such that the refrigerant introduced through the transfer pipe (700) is supplied to the subcooling region of the condenser (1);
A first connection pipe 710 connecting the lower space of the receiver dryer 600 to the first communication path 751;
A second connection pipe 720 connecting the upper space of the receiver dryer 600 to the second communication path 761; And
A third connection pipe 730 extending in a height direction such that the first communication path 751 and the second communication path 761 are connected to the outside of the receiver drier 600; , ≪ / RTI &
Cooling module, characterized in that the connecting portion of the first to third connecting pipes (710 to 730) is inserted into the flange portion 740, respectively.
The method of claim 1,
The condenser
An outlet pipe 220 is formed above the inlet pipe 210 of the first header tank 110, and a first baffle 510 is formed between the inlet pipe 210 and the outlet pipe 220.
Cooling module, characterized in that the second header tank 120, the second baffle (520) is formed at the same height as the first baffle (510) is formed in the upper region of the condenser (1).
The method of claim 2,
The partition plate 630 is
Cooling module, characterized in that formed on the same height as the first baffle (510) and the second baffle (520).
The method of claim 2,
The condenser (1)
Cooling module, characterized in that the connecting portion 130 formed in the subcooling region of the connecting portion 130 is lower than the second flange (760), higher than the partition plate (630).
delete The method according to claim 1,
The flange portion 740 is
The diameter of the upper predetermined area of the first communication path 751 and the lower predetermined area of the second communication path 761 is reduced so that the third connection pipe 730 may be inserted and seated and fixed in the height direction. Losing first step portion 741,
The first communication path 751 and the second communication side adjacent to the receiver dryer 600 so that the first connection pipe 710 and the second connection pipe 720 are inserted in the longitudinal direction and fixed at a predetermined depth. Cooling module, characterized in that the second step portion 742 is formed by reducing the diameter of the predetermined area of the furnace (761).
The method of claim 1,
The receiver dryer 600
A receiver dryer tank 610 having an opening 611 formed at a lower end thereof in a cylindrical shape and communicating with the first header tank 110 or the second header tank 120 by a connection part 130; And
The filter unit 621 is inserted into the receiver dryer tank 610 to filter foreign matters contained in the refrigerant, and the filter unit 621 supports the filter unit 621 and is coupled to the opening 611 of the receiver dryer tank 610. A lower cap assembly 620 comprising a lower cap 622; Cooling module comprising a.
The method according to any one of claims 1, 2, 3, 4, 6, and 7 ,
The cooling module
To any one of the pair of header tanks 800 of the radiator 2
A flange coupling part 910 protruding toward the condenser 1 to surround an upper or lower surface of the flange part 740; And
A fixing part 920 having an end portion of the flange coupling part 910 protruding toward the flange part 740; Cooling module, characterized in that the fastening means (900) of the clip type including a coupled to the flange portion (740).
The method of claim 8,
The flange coupling portion 910 is
The first flange is coupled to the lower surface of the second flange 760 and the upper surface of the first flange 750, the through-hole 913 is formed to be hollow so as to sandwich the transfer pipe 700 in the width direction Coupling part 911; And a second flange coupling part 912 coupled to an upper surface of the second flange 760 and a lower surface of the first flange 750, and configured to seat and fix the flange part 740. The cooling module comprising:
The method of claim 8,
The fixing part 920 is
To facilitate the detachment of the fastening means 900
Cooling module, characterized in that the end of the first flange coupling portion 911 and the second flange coupling portion 912 is inclined to decrease in diameter toward the direction facing each other.
The method of claim 8,
The radiator 2 is
If the first and the header tank 110 or the second header tank 120, seating portion 810, which is mounted and fixed in the condenser (1) to the other header tank, the header tank to which the engaging means formed in said condenser (1) Cooling module, characterized in that installed to protrude to the side.

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