KR20170104230A - Condenser formed in two rows and cooling module having the same - Google Patents

Abstract

The present invention relates to a two-row condenser and a cooling module including the same, which is configured to form condensers in two rows, wherein an initial passage initially cooled as a heat exchange medium is introduced into a first condenser and a last passage cooled lastly before a discharge are formed, to cool the heat exchange medium having passed through the initial passage of the first condenser while the heat exchange medium passes through the last passage of the first condenser through a second condenser, and to arrange the first condenser more forward than the second condenser in a flow direction of cool air, thereby arranging the condensers in two rows in a case where an installment area of the condenser is reduced on a layout where the condenser is installed, so as to optimize a path where the heat exchange medium flows, thus being capable of improving a performance of the condenser.

Description

[0001] The present invention relates to a two-row condenser and a cooling module including the same,

The present invention relates to a two-row condenser and a cooling module including the same. More particularly, the present invention improves the performance of the condenser by arranging the condenser in two rows when the installation area of the condenser is reduced on the layout in which the condenser is installed, The present invention relates to a two-row condenser and a cooling module including the same.

Generally, a vehicle equipped with an internal combustion engine is equipped with an engine radiator in an engine room for cooling the engine, and a condenser for cooling the refrigerant for controlling the temperature of the air in the vehicle room during cooling. The radiator and the condenser And a fan shroud provided with a cooling fan for improving the cooling efficiency. Further, in the case of a diesel vehicle, an intercooler for increasing the output of the vehicle may be provided.

1, the cooling module 1 includes a fan shroud 10, a radiator 20 and a condenser 30 arranged side-by-side in a stacked manner, and the intercooler 40 is connected to a cooling module 1 Side-by-side type in the longitudinal direction.

In recent years, an intercooler is disposed at a lower side of a height direction of a cooling module in order to increase engine performance. An intercooler is disposed in a region of the fan shroud in a width direction, The layout of the air dam is changed.

However, when the layout of the cooling module 1 is formed as an air dam type, the height of the radiator 20 and the condenser 30 is reduced on the layout, and thus the performance of the heat exchangers is required to be improved. At this time, since there is a practical limit to improve the performance of the heat exchangers simply by changing the specifications of the radiating fins and the tube through which the heat exchange medium flows, it is necessary to increase the thickness of the heat exchangers or to research and develop heat exchangers formed of two rows. Particularly, a condenser needs to be developed for a two-row condenser because the flow path (path) configuration of the heat exchange medium is not easy due to the limited number of tubes.

KR 2010-0030332 A (2010.03.18)

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to provide a condenser in which the condenser is installed in two rows when the installation area of the condenser is reduced, A two-column condenser capable of improving the performance of the condenser, and a cooling module including the same.

In order to accomplish the above object, the present invention provides a two-column condenser having a plurality of flow passages formed therein and having a plurality of flow passages formed therein, A first condenser 200 in which a final flow path to be discharged to the outside is formed; A second condenser (300) connected to a first flow path of the first condenser (200), and a heat exchange medium flowing from the first flow path flows and is cooled along an internal divided flow path; And a heat exchanging medium that is connected to the second condenser 300 and has passed through the second condenser 300 is introduced and is subjected to gas-liquid separation. The liquid heat exchanging medium, which is connected to the last channel of the first condenser 200, A gas-liquid separator (400) for allowing the gas to flow into the last channel; Wherein the first condenser 200 and the second condenser 300 are stacked in parallel in the width direction and the first condenser 200 is arranged in the cooling air flowing direction And is disposed forward.

In addition, the first condenser 200 is formed to be divided into two separate flow paths, the first flow path is formed by the first path P1, the last flow path is formed by the fourth path P4, The condenser 300 is divided into two flow paths so that the second path P2 and the third path P3 are connected to each other so that the heat exchange medium flows through the first path P1, Passes through the third path P3 and the fourth path P4, and is cooled.

The first path (P1) and the second path (P2) are arranged on the same side in the height direction.

The inlet pipe 250 formed in the first path P1 and the outlet pipe 260 formed in the fourth path P4 are disposed on the same side in the longitudinal direction.

A second connection pipe 350 connects the third path P3 and the gas-liquid separator 400. The first connection pipe 270 connects the first path P1 and the second path P2. Liquid separator 400 and the third connection pipe 280 connecting the gas-liquid separator 400 and the fourth pass P4 are arranged on the same side in the longitudinal direction.

In addition, the number of tube rows through which the heat exchange medium of the passes flows is smaller than the number of tube rows in the order of the first pass (P1), the second pass (P2) and the third pass (P3) P4 is formed to be less than or equal to the tube number of the third path P3.

The cooling module (1000) of the present invention includes: a radiator (100) for cooling cooling water of an engine; The two-column condenser in which the first condenser (200) and the second condenser (300) are disposed in parallel to the front of the radiator (100) in the flow direction of the cooling air; An intercooler 500 disposed in parallel to the radiator 100 and the two-row condenser in the height direction; And a fan shroud 600 disposed in parallel to the rear of the radiator 100 and the intercooler 500 in the flow direction of the cooling air and having a cooling fan 610 for forcibly blowing the cooling air. And a control unit.

The radiator 100, the first condenser 200 and the second condenser 300 of the two-row condenser and the intercooler 500 are arranged in a manner corresponding to the width of the fan shroud 600 in the height direction and the longitudinal direction .

The radiator 100, the first condenser 200 and the second condenser 300 of the two-row condenser and the intercooler 500 are formed so as to partially overlap the region where the cooling fan 610 is formed when viewed in the width direction .

The two-row condenser and the cooling module including the same according to the present invention can improve the performance of the condenser even if the installation area is narrow or is reduced compared to the conventional one by arranging the condenser in two rows and optimizing the flow path of the heat exchange medium.

In addition, the condenser is formed in two rows, and the flow path of the heat exchange medium is optimized to simplify the configuration of the connection channel connecting the two rows.

1 is an assembled perspective view showing the arrangement of a conventional cooling module and an intercooler.
2 is an assembled perspective view illustrating the two-row condenser of the present invention.
3 is an exploded perspective view showing the flow of a heat exchange medium in the two-column condenser of the present invention.
4 is a conceptual view showing a cooling module including a two-row condenser of the present invention.
5 and 6 are an exploded perspective view and an assembled perspective view of a cooling module including a two-row condenser according to the present invention.

Hereinafter, the two-column condenser of the present invention having the above-described structure and the cooling module including the same will be described in detail with reference to the accompanying drawings.

FIG. 2 is an assembled perspective view showing a two-row condenser of the present invention, and FIG. 3 is an exploded perspective view showing a flow of a heat exchange medium in the two-row condenser of the present invention.

As shown in the drawing, the two-row condenser of the present invention has a plurality of flow paths formed therein, in which the heat exchanging medium is introduced from the outside and the first flow path is cooled first, and the heat exchanging medium is cooled A first condenser 200 in which a flow path is formed; A second condenser (300) connected to a first flow path of the first condenser (200), and a heat exchange medium flowing from the first flow path flows and is cooled along an internal divided flow path; And a heat exchanging medium that is connected to the second condenser 300 and has passed through the second condenser 300 is introduced and is subjected to gas-liquid separation. The liquid heat exchanging medium, which is connected to the last channel of the first condenser 200, A gas-liquid separator (400) for allowing the gas to flow into the last channel; Wherein the first condenser 200 and the second condenser 300 are stacked in parallel in the width direction and the first condenser 200 is arranged in the cooling air flowing direction And can be disposed forward.

The two-row condenser according to the present invention can include a first condenser 200, a second condenser 300 and a gas-liquid separator 400. The first condenser 200 and the second condenser 300 They may be formed in a side-by-side manner in a stacked manner in the width direction. A gas-liquid separator (400) for separating the liquid phase and the gaseous phase heat exchange medium in the heat exchange medium may be disposed at one side of the first condenser (200) and the second condenser (300).

The first condenser 200 has a first header tank 210 and a second header tank 220 formed in parallel to each other with a predetermined distance therebetween in the longitudinal direction. The plurality of first tubes 230 may be coupled to each other. A first fin 240 for improving heat exchange efficiency may be interposed between the first tubes 230. In the first condenser 200, baffles are formed at the same height in the first-first header tank 210 and the first-second header tank 220 so that the upper and lower tube rows are separated from each other And a plurality of flow paths may be formed. In this figure, the interior of the header tanks is defined by the baffles 211 and 221 so that two separate flow paths are formed on the basis of the longitudinal first partition line L1 in which the baffles are arranged . In addition, an inlet pipe 250 through which the heat exchange medium flows from the outside may be formed in the portion corresponding to the upper side flow passage in the first and second header tanks 220, An outlet pipe 260 through which the heat exchange medium is discharged to the outside may be formed at a portion corresponding to the flow path of the heat exchange medium. Thus, the upper flow path is formed as a first flow path through which the heat exchange medium flows from the outside and is first cooled, and the lower flow path can be formed as the last flow path that is finally cooled just before the heat exchange medium is discharged.

The second condenser 300 is formed with a second-first header tank 310 and a second-second header tank 320, which are spaced apart from each other by a predetermined distance in the longitudinal direction, and the two header tanks The plurality of second tubes 330 may be coupled to each other. A second fin 340 for improving the heat exchange efficiency may be interposed between the second tubes 330. Also, the second condenser 300 can be partitioned only inside the second-first header tank 310 by forming the baffle 311 in the second-first header tank 310 alone. That is, in the drawing, only the second-1 header tank 310 is divided by the baffle 311, and two flow paths are formed on the basis of the second partition line L2 in the longitudinal direction at the height where the baffle 311 is disposed And two flow paths are connected and communicated with each other in the second-second header tank 320. As shown in FIG. The upper side of the first-first header tank 210 partitioned by the baffle 211 is connected to the upper side of the second-first header tank 310 partitioned by the baffle 311, The heat exchange medium that has passed through the first flow path of the first condenser 200 can be introduced into the second condenser 300. The introduced heat exchange medium sequentially flows through the two channels of the second condenser 300 which is partitioned and connected to each other It can be cooled while flowing. The lower side of the second-1 header tank 310 partitioned by the baffle 311 may be connected to the gas-liquid separator 400.

The gas-liquid separator 400 is connected to the second condenser 300 and separates the gaseous heat exchange medium from the liquid-phase heat exchange medium from the heat exchange medium introduced from the second condenser 300 as described above. Liquid separator 400 is connected to the lower side of the first header tank 210 partitioned by the baffle 211 and connected to the first condenser 200 so that the gas-liquid separator 400 is connected to the first condenser 200 200). ≪ / RTI > Thus, only the liquid phase heat exchange medium separated in the gas-liquid separator 400 flows into the last channel of the first condenser 200, is finally cooled and subcooled while passing through the last channel, and then discharged to the outside through the outlet pipe 260 .

That is, the high-temperature gaseous heat exchange medium introduced from the outside through the inlet pipe 250 is cooled while passing through the first flow path of the first condenser 200, then flows along the flow paths of the second condenser 300, And the heat exchange medium in which the gas phase and the liquid phase are mixed passes through the gas-liquid separator, so that only the liquid heat exchange medium is separated and flows into the last channel of the first condenser 200, The heat exchange medium can be subcooled and discharged to the outside.

Here, the first condenser 200 and the second condenser 300 are arranged in a stacked manner in parallel to each other, and the first condenser 200 is arranged in the cooling air flowing direction And can be disposed forward. Thus, the cooling air having relatively low temperature in the cooling air and the first channel through which the relatively high-temperature heat exchange medium is introduced in the heat exchange medium can be firstly heat-exchanged, and the temperature difference between the cooling air and the heat exchange medium ) Can be maximized and the heat exchange efficiency can be improved. In addition, only the final liquid phase heat exchange medium, which is gas-liquid separated from the incoming cooling air having a relatively low temperature in the cooling air, is cooled while passing through the final flow path, and immediately before being discharged to the outside through the outlet pipe 260, It can be subcooled and the heat exchange efficiency can be improved.

As described above, in the two-row condenser of the present invention, the first condenser is disposed in two rows, the first condenser having the first channel in which the heat exchange medium is first introduced and the first channel in which the liquid heat exchange medium is finally cooled, The heat exchanging performance of the two-column condenser can be improved.

In addition, by optimizing the flow path of the heat exchange medium while constructing the condenser in two rows, the performance of the condenser can be improved even when the installation area of the condenser is narrowed or compared with the conventional one.

The first condenser 200 is formed to be divided into two separate flow paths so that the first flow path is formed by the first path P1 and the last flow path is formed by the fourth path P4, The condenser 300 is divided into two flow paths so that the second path P2 and the third path P3 are connected to each other so that the heat exchange medium flows through the first path P1, Passes through the third path P3 and the fourth path P4, and can be cooled.

That is, as shown in the drawing, the first condenser 200 may be formed by two baffles 211 and 221, which are completely divided into upper and lower sides and are divided into upper and lower flow paths with reference to the first partition line L1 . The inlet pipe 250 is formed on the upper side of the first-second header tank 220 partitioned by the baffle 221 and the lower portion of the second-second header tank 220 partitioned by the baffle 221 An outlet pipe 260 may be formed on the upper side and the lower side may be formed as a fourth path P4 which is the first path P1 and the lower path is the last path. The second condenser 300 is divided into the second-first header tank 310 by the baffle 311 and the second-second header tank 320 by the second partition line L2 And two flow paths are formed. The two flow paths may be connected to each other. At this time, the upper side of the second condenser 300 is formed as the second path P2 and the lower side is formed as the third path P3 so that the first path P1 of the first condenser 200 and the second path P2 The second path P2 of the condenser 300 may be connected to the first connection pipe 270 and the second path P2 and the third path P3 may be separately connected through the second- Can be connected directly without the external connector of. The first connection pipe 270 may be formed separately from the first connection pipe 270 of the first condenser 200 and the second connection pipe 310 of the second condenser 300, And the first connection pipe may be formed to be inserted into the header tanks. The second condenser 300 and the gas-liquid separator 400 may be connected to the second connection pipe 350 while the gas-liquid separator 400 and the first condenser 200 may be connected to the third connection pipe 280. have. Thus, the heat exchange medium introduced through the inlet pipe 250 is cooled while passing through the first pass P1, the second pass P2, the third pass P3 and the fourth pass P4, And may be discharged to the outside through the pipe 260.

Also, the first path P1 and the second path P2 may be disposed on the same side in the height direction.

That is, as shown in the drawing, the first path P1 is disposed on the upper side in the height direction in the first condenser 200 and the second path P2 is also disposed on the upper side in the height direction in the second condenser 300 Since the two flow paths are arranged on the same side in the height direction, the first connection pipe 270 connecting the first path P1 and the second path P2 can be formed as short as shown in the figure, The header tanks of the two condensers may be brought into contact with each other to be communicated with the through holes or the like so that the separate first connection pipe may be eliminated. Alternatively, the first path P1 and the second path P2 may be disposed on the lower side in the height direction. At this time, when the height of the second partition line L2 of the second condenser 300 is higher than the first partition line L1 partitioning the flow passages of the first condenser 200, The first path P1 is disposed and the fourth path P4 is disposed on the lower side and the third path P3 is disposed on the upper side in the second condenser 300 and the second path P2 is disposed on the lower side, So that the first path P1 and the second path P2 are connected to each other by the first connection pipe 270 and the adjacent portions of the first path P1 and the second path P2 in the height direction The length of the first connection pipe 270 may be shortened.

The inlet pipe 250 formed in the first path P1 and the outlet pipe 260 formed in the fourth path P4 may be disposed on the same side in the longitudinal direction.

That is, as shown in the drawing, the first and second passes P1 and P4 are disposed in the first condenser 200, and the inlet pipe 250 and the fourth pipe P4, which are connected to the first pass P1, P4 are disposed on the right side in the longitudinal direction in the same direction, the structure and connection of the inlet and the outlet through which the heat exchange medium is introduced and discharged can be easily and compactly formed.

A second connection pipe 350 connects the third path P3 and the gas-liquid separator 400. The first connection pipe 270 connects the first path P1 and the second path P2. Liquid separator 400 and the third connection pipe 280 connecting the gas-liquid separator 400 and the fourth pass P4 may be disposed on the same side in the longitudinal direction.

That is, as shown in the drawing, the inlet pipe 250 and the outlet pipe 260 are disposed on the right side in the longitudinal direction, and the first connection pipe 270, the gas-liquid separator 400, The second connection pipe 350 and the third connection pipe 280 are disposed so that the connection pipes can be easily disposed and the connection pipes can be formed in a short and simple shape.

As described above, the present invention is advantageous in that the condenser is formed in two rows, and the flow path of the heat exchange medium is optimized to simplify the configuration of the connection channel connecting the two rows.

In addition, the number of tube rows through which the heat exchange medium of the passes flows is smaller than the number of tube rows in the order of the first pass (P1), the second pass (P2) and the third pass (P3) P4 may be formed to be less than or equal to the tube number of the third path P3.

That is, the number of tube columns constituting each of the paths may be the first path P1> the second path P2, the third path P3, or the fourth path P4. At this time, the first tubes 230 of the first condenser 200 and the second tubes 330 of the second condenser 300 may be formed in the same manner. Depending on the number of tubes constituting each pass, The flow rate of the heat exchange medium passing through each pass can be varied. Thus, as described above, the heat exchange efficiency can be improved as the number of tube rows is formed.

And FIG. 4 is a conceptual view illustrating a cooling module including a two-row condenser of the present invention, and FIGS. 5 and 6 are an exploded perspective view and an assembled perspective view of a cooling module including the two-row condenser of the present invention.

As shown in the drawing, the cooling module 1000 of the present invention includes the radiator 100 including the two-row condenser described above and cooling the cooling water of the engine. The two-column condenser in which the first condenser (200) and the second condenser (300) are disposed in parallel to the front of the radiator (100) in the flow direction of the cooling air; An intercooler 500 disposed in parallel to the radiator 100 and the two-row condenser in the height direction; And a fan shroud 600 disposed in parallel to the rear of the radiator 100 and the intercooler 500 in the flow direction of the cooling air and having a cooling fan 610 for forcibly blowing the cooling air. . ≪ / RTI >

That is, as shown in the drawing, the fan shroud 600, the radiator 100, the first condenser 200 and the second condenser 300 constituting the two-row condenser may be stacked in parallel in the width direction, The intercooler 500 may be disposed below the radiator 100 and the two-column condenser in the height direction. At this time, the flow direction of the cooling air is the width direction, the cooling air can flow in the front direction from the front side, the front side can be forward in the cooling air flow direction, and the rear side can be the rear side in the cooling air flow direction. Thus, the fan shroud 600, the radiator 100, and the two-row condenser may be arranged from the rear to the front in the flow direction of the cooling air. In the two-row condenser, the first condenser 200 having the first path P1 as the first flow path and the fourth path P4 as the last flow path is arranged in front of the second condenser 300 in the cooling air flow direction The fan shroud 600, the radiator 100, the second condenser 300 and the first condenser 200 in this order from the rear in the flow direction of the cooling air. So that the first condenser 200 can be disposed at the foremost position in the cooling air flow direction. And the intercooler 500 may be disposed in front of the fan shroud 600 in the flow direction of the cooling air.

Thus, in the case where the cooling module 1000 is formed as an air dam type as described above, even if the installation space (height) of the condenser is reduced due to the intercooler 500 on the layout, a two-column condenser having two rows and an improved heat exchange efficiency is installed Therefore, the cooling module of the present invention can improve the performance of the engine by arranging the intercooler in front of the cooling air flow direction in the width direction of the fan shroud, and simultaneously improve the cooling performance by using the two- .

The radiator 100, the first condenser 200 and the second condenser 300 of the two-row condenser and the intercooler 500 are arranged in a manner corresponding to the width of the fan shroud 600 in the height direction and the longitudinal direction .

That is, the core portion including the tube and the pin, which are the portions where heat exchange occurs mainly in the radiator 100, the first condenser 200, the second condenser 300 and the intercooler 500, are disposed within the width of the fan shroud 600 So that the core portions do not deviate from the periphery of the fan shroud 600 when viewed in the width direction. Thus, by allowing the cooling air to flow through the fan shroud 600 through the core portions, the cooling efficiency of each heat exchanger can be improved.

The radiator 100, the first condenser 200 and the second condenser 300 of the two-row condenser and the intercooler 500 are formed so as to partially overlap the region where the cooling fan 610 is formed when viewed in the width direction .

That is, when viewed in the width direction, the intercooler 500 as well as the radiator 100 and the two-row condenser 500 are formed to partially overlap the core portion with the region where the cooling fan 610 is formed, Each of the heat exchangers can be cooled evenly when the cooling fan 610 is operated.

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.

1000: Cooling module
100: Radiator
200: first condenser
210: 1-1 header tank 211: baffle
220: 1st-2nd header tank 221: Baffle
230: first tube 240: first pin
250: inlet pipe 260: outlet pipe
270: first connector 280: third connector
300: second condenser
310: 2-1 header tank 311: baffle
320: Header tank 2-2
330: second tube 340: second pin
350: second connector
400: gas-liquid separator
500: intercooler
600: Fan shroud 610: Cooling fan
L1: first partition line L2: second partition line
P1: 1st pass P2: 2nd pass
P3: Third pass P4: Fourth pass

Claims (9)

A first condenser 200 in which the inside is divided to form a plurality of flow paths, a first flow path in which the heat exchange medium is introduced from the outside and a first flow path in which the heat exchange medium is finally cooled and then discharged to the outside;
A second condenser (300) connected to a first flow path of the first condenser (200), and a heat exchange medium flowing from the first flow path flows and is cooled along an internal divided flow path; And
A liquid heat exchanging medium, which is connected to the second condenser 300 and connected to the last channel of the first condenser 200 to separate the heat exchanging medium having passed through the second condenser 300, A gas-liquid separator (400) for allowing the gas to flow into the flow path; And,
The first condenser 200 and the second condenser 300 are stacked in parallel to each other in the width direction and the first condenser 200 is disposed in front of the second condenser 300 in the cooling air flow direction Two-row condenser.
The method according to claim 1,
The first condenser 200 is divided into two separate flow paths, the first flow path is formed by the first path P1, the last flow path is formed by the fourth path P4,
The second condenser 300 is divided into two flow paths, and the second path P2 and the third path P3 are connected to each other,
Wherein the heat exchange medium passes through the first pass (P1), the second pass (P2), the third pass (P3), and the fourth pass (P4) sequentially.
3. The method of claim 2,
Wherein the first path (P1) and the second path (P2) are arranged on the same side in the height direction.
3. The method of claim 2,
Wherein the inlet pipe (250) formed in the first pass (P1) and the outlet pipe (260) formed in the fourth pass (P4) are disposed on the same side in the longitudinal direction.
3. The method of claim 2,
A first connection pipe 270 connecting the first path P1 and the second path P2, a second connection pipe 350 connecting the third path P3 and the gas-liquid separator 400, Separator 400 and the third connection pipe 280 connecting the gas-liquid separator 400 and the fourth pass P4 are disposed on the same side in the longitudinal direction.
3. The method of claim 2,
The number of tube rows through which the heat exchange medium of the passes flows,
The number of tube rows is smaller in the order of the first path P1, the second path P2 and the third path P3 and the number of tubes of the fourth path P4 is smaller than the number of tubes of the third path P3 The number of the heat exchangers is less than or equal to the number of heat.
A cooling module comprising a two-row condenser according to any one of claims 1 to 6,
A radiator (100) for cooling the cooling water of the engine;
The two-column condenser in which the first condenser 200 and the second condenser 300 are disposed in parallel to the front of the radiator 100 in the flow direction of the cooling air;
An intercooler 500 disposed in parallel to the radiator 100 and the two-row condenser in the height direction; And
A fan shroud 600 disposed in parallel to the rear of the radiator 100 and the intercooler 500 in the flow direction of cooling air and having a cooling fan 610 for forcibly blowing the cooling air; And a cooling module.
8. The method of claim 7,
The radiator 100, the first condenser 200 and the second condenser 300 of the two-row condenser and the intercooler 500 are arranged to correspond to the widths of the fan shroud 600 formed in the height direction and the longitudinal direction thereof Features a cooling module.
8. The method of claim 7,
The radiator 100, the first condenser 200 and the second condenser 300 of the two-row condenser, and the intercooler 500 are formed so as to partially overlap the region where the cooling fan 610 is formed when viewed in the width direction Cooling module.

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