KR102210246B1 - Condenser and cooling module - Google Patents

Abstract

The condenser 100 according to the present invention comprises a first header 111, a first tank 112 coupled to the first header 111, and two or more hollows in the first tank 112 in a height direction. A first header tank 110 having a first hollow hole 113 formed therein; A second header tank 120 formed by a combination of the second header 121 and the second tank 122 and disposed in parallel with the first header tank 110 by a predetermined distance; A first inlet portion 131 formed in the second header tank 120 into which a first heat exchange medium is introduced and a first outlet portion 132 that is discharged; A plurality of first tubes 140 having both ends fixed to the first header tank 110 and the second header tank 120 to form a first heat exchange medium flow path; A first pin 150 interposed between the first tube 140; Gas-liquid in which a gaseous first heat exchange medium and a liquid first heat exchange medium are separated from one side of the first header tank 110, and a second hollow hole 161 corresponding to the first hollow hole 113 is formed in a height direction Separator 160; A first curved portion 171 corresponding to an outer surface of the first header tank 110 and a second curved portion corresponding to an outer surface of the gas-liquid separator 160 so that the gas-liquid separator 160 is eccentrically coupled in the vehicle longitudinal direction A connector 170 having an insertion hole 173 formed therein; And a connector 180 inserted into the insertion hole 173 of the connector 170, and both ends thereof are inserted into the first hollow hole 113 and the second hollow hole 161, respectively. .

Description

Condenser and cooling module {CONDENSER AND COOLING MODULE}

The present invention relates to a condenser and a cooling module, and in more detail, a gas-liquid separator is eccentrically coupled using a connector, so that the first header tank and the gas-liquid separator can be stably fixed, and the thickness between the cooling modules in the vehicle length direction is reduced to reduce size. It relates to possible condensers and cooling modules.

A heat exchanger is a device that absorbs heat from one side between two environments with a temperature difference and releases heat to the other.It is a cooling system when it absorbs heat from the room and releases it to the outside. In this case, it acts as a heating system. Basically, a heat exchanger consists of an evaporator that absorbs heat from the surroundings, a compressor that compresses the heat exchange medium, a condenser that discharges heat to the surroundings, and an expansion valve that expands the heat exchange medium.

In the cooling device, the heat exchange medium in a liquid state absorbs the amount of heat as much as the heat of vaporization in the surroundings and is vaporized, thereby actually causing a cooling action. The gaseous heat exchange medium flowing from the evaporator to the compressor is compressed at high temperature and high pressure in the compressor, and the heat of liquefaction is discharged to the surroundings while the compressed gaseous heat exchange medium is liquefied while passing through the condenser. The medium passes through the expansion valve again, enters a low-temperature and low-pressure compressed vapor state, then flows back into the evaporator and vaporizes to form a cycle.

As described above, in the condenser, a refrigerant in a gaseous state of high temperature and high pressure is introduced and condensed into a liquid state while releasing heat of liquefaction through heat exchange, and then discharged. The conventional condenser is shown in FIGS. 1 and 2.

The condensers shown in FIGS. 1 and 2 include: a first header tank 10 and a second header tank 20 spaced apart from each other by a predetermined distance and formed in parallel; An inlet pipe 40 and an outlet pipe 50 provided in the second header tank 20 to allow refrigerant to flow in or out; A baffle (30) provided in the first header tank (10) and the second header tank (20) to control the flow of the refrigerant; A plurality of tubes 60 fixed at both ends of the first header tank 10 and the second header tank 20 to form a refrigerant flow path; A plurality of fins (70) stacked between the tubes (60); And a gas-liquid separator 80 provided at one side of the first header tank 10 and separating gaseous refrigerant from liquid refrigerant, and subcooling by collecting only liquid refrigerant in the gas-liquid separator 80 It is structured to induce.

Looking at the internal flow of the condenser as shown in FIGS. 1 and 2, the gaseous refrigerant compressed at high temperature and high pressure by the compressor flows into the inlet pipe of the first header tank, and the second header by the baffle provided therein. It is moved to the tank. At this time, since condensation has already occurred inside the condenser, the gaseous phase and the liquid phase are mixed. As a rule, the gaseous refrigerant moves to the top and the liquid coolant to the bottom.

Refrigerant collected at the lower side of the gas-liquid separator through the upper and lower regions respectively along the flow path formed by the baffle collects mostly liquid refrigerant, and the enthalpy of the refrigerant is caused by supercooling as the liquid refrigerant passes through the subcooled region. It is possible to further lower the cooling efficiency can be improved.

Such a cooling module is provided on the front side of the vehicle, and it is difficult to secure sufficient space according to the trend of miniaturization of the vehicle, so it is necessary to reduce the thickness of the cooling module.

On the other hand, since the cooling module is provided in the cooling module mounting part of the carrier in front of the vehicle, it can be easily damaged even in the case of a light contact accident when a vehicle crashes, resulting in a problem that a repair cost is rapidly increased.

In particular, the Research Council for Automobile Repairs (RCAR) is an institution that calculates and studies the standards for durability and stability of each vehicle element, and each vehicle is based on the standards suggested by the World Vehicle Repair Technology Research Committee. Applicability is evaluated, and the result of this evaluation becomes a standard in calculating insurance premiums for insurance companies.

In other words, an increase in vehicle repair costs is a major cause of an increase in insurance premiums.

Therefore, it is necessary to maximize the distance between the cooling module and the bumper beam, but this also becomes a factor that hinders the miniaturization of the cooling module.

Korean Patent Publication No. 2013-0012986 (Name of invention: cooling module and its control method)

The present invention has been conceived to solve the above-described problems, and an object of the present invention is that the gas-liquid separator is eccentrically coupled using a connector to stably fix the first header tank and the gas-liquid separator, and It is to provide a condenser and cooling module that can be miniaturized by reducing the thickness between cooling modules.

In particular, an object of the present invention is a first reference line connecting the center of the first header tank and the center of the gas-liquid separator based on the cross-section of the area in which the connector is formed in the vehicle height direction, and parallel to the outer surface of the connector and the It is to provide a condenser and a cooling module capable of increasing the degree of eccentricity of the gas-liquid separator by forming a reference angle by a second reference line passing through the center of the first header tank.

The condenser according to the present invention comprises: a first header, a first tank coupled to the first header, and a first header tank having two or more first hollow holes hollow in the height direction in the first tank; A second header tank formed by a combination of the second header and the second tank, and disposed in parallel with the first header tank by a predetermined distance; A first inlet and a first outlet formed in the second header tank through which the first heat exchange medium is introduced; A plurality of first tubes having both ends fixed to the first header tank and the second header tank to form a first heat exchange medium flow path; A first pin interposed between the first tube; A gas-liquid separator separating the gaseous first heat exchange medium and the liquid first heat exchange medium at one side of the first header tank, and forming a second hollow hole corresponding to the first hollow hole in a height direction; A connector having a first curved portion corresponding to an outer surface of the first header tank and a second curved portion corresponding to an outer surface of the gas-liquid separator so that the gas-liquid separator is eccentrically coupled in a vehicle longitudinal direction, and an insertion hole formed therein; And a connection pipe inserted into the insertion hole of the connector, and both ends thereof are inserted into the first hollow hole and the second hollow hole, respectively.

In this case, the condenser has a first reference line connecting the center of the gas-liquid separator and the center of the first header tank, with the first reference line connecting the center of the gas-liquid separator and the center of the first header tank based on the cross section of the area where the connector is formed in the vehicle height direction, 1The second reference line passing through the center of the header tank forms the reference angle, and the first header tank and the gas-liquid separator can be stably fixed, and the thickness between the cooling modules in the longitudinal direction of the vehicle can be reduced to reduce the size, and the gas-liquid separator The degree of eccentricity can be increased.

In addition, the reference angle is set such that a third reference line connecting the outer surface of the gas-liquid separator and the first tank located on the outermost side opposite to the eccentric side of the gas-liquid separator in the vehicle longitudinal direction is parallel to the vehicle width direction.

In addition, the connector is characterized in that the length of the first outer surface of the side where the gas-liquid separator is eccentric in the vehicle length direction is smaller than the length of the second outer surface of the opposite side.

In addition, the condenser is characterized in that the first hollow hole and the second hollow hole are formed so that the outer surface of the connection pipe is positioned parallel to the outer surface of the connector, based on a cross-section of the region where the connector is formed.

On the other hand, the cooling module of the present invention comprises a condenser as described above; A radiator provided at the rear side of the condenser in the air flow direction; It characterized in that it comprises a fan and a shroud assembly provided on the rear side of the radiator in the air flow direction.

In this case, the radiator may include a third header tank formed by a combination of a third header and a third tank and spaced apart from each other by a predetermined distance and provided side by side; A second inlet and a second outlet formed in the third header tank through which the second heat exchange medium is introduced; A second tube having both ends fixed between the third header tank; And it characterized in that it comprises a second pin interposed between the second tube.

In addition, the cooling module is characterized in that the first header and the second header of the condenser are located outside the third header of the radiator in the vehicle width direction, and the gas-liquid separator is eccentric to the rear side in the vehicle longitudinal direction. .

In addition, in the cooling module, the first header tank and the second header tank of the condenser are located inside the third header of the radiator in the vehicle width direction, and the gas-liquid separator is eccentric to the front side in the vehicle length direction. To do.

Accordingly, in the condenser and cooling module of the present invention, the gas-liquid separator is eccentrically coupled using a connector, so that the first header tank and the gas-liquid separator can be stably fixed. have.

In particular, the condenser and the cooling module of the present invention have a first reference line connecting the center of the first header tank and the center of the gas-liquid separator, based on the cross section of the area where the connector is formed in the vehicle height direction, and the outer surface of the connector. The second reference line that is parallel and passes through the center of the first header tank forms a reference angle, thereby increasing the degree of eccentricity of the gas-liquid separator.

1 is a perspective view showing a conventional condenser.
Figure 2 is a flow chart of the refrigerant of the condenser shown in Figure 1;
3 and 4 are a perspective view and a top plan view of the cooling module according to the present invention.
Figure 5 is a partial exploded perspective view of the condenser according to the present invention.
6 is a partial cross-sectional view of a condenser according to the invention.
7 is a partial exploded cross-sectional view of the condenser according to the present invention.
8 is another top plan view of the cooling module according to the present invention.

Hereinafter, the condenser 100 and the cooling module 1000 having the above-described characteristics will be described in detail with reference to the accompanying drawings.

3 and 4 are perspective and top plan views of the cooling module 1000 according to the present invention, Figure 5 is a partial exploded perspective view of the condenser 100 according to the present invention, Figure 6 is the condenser 100 according to the present invention Fig. 7 is a partial exploded sectional view of the condenser 100 according to the present invention, and Fig. 8 is another top plan view of the cooling module 1000 according to the present invention.

First, the cooling module 1000 of the present invention is a configuration provided on the rear side of the bumper beam B at the front side of the vehicle in the longitudinal direction of the vehicle, and includes a condenser 100, a radiator 200, a fan and a shroud assembly 300 do.

The condenser 100 is a heat exchanger in which a first heat exchange medium flows to exchange heat with outside air, and the first heat exchange medium is a refrigerant. In more detail, the condenser 100 is configured to heat-exchange the high-pressure gaseous refrigerant sent from the compressor during the cooling cycle process with outside air to condense it into a high-temperature, high-pressure liquid, and send it to the expansion means, and constitute a cooling system. The detailed configuration of the condenser 100 will be described again below.

The radiator 200 is a heat exchanger in which a second heat exchange medium is heat-exchanged, and the second heat exchange medium is cooling water. The radiator 200 is configured to prevent the temperature of the cooling water from rising above a certain temperature. In this case, the coolant may be a coolant for cooling the engine, or may be a coolant for cooling electronic components for vehicles other than the engine. The radiator 200 is provided at the rear side of the condenser 100 in the air flow direction (from front to rear in the longitudinal direction of the vehicle). In this case, the radiator 200 includes a third header tank 210, a second inlet 221, a second outlet 222, a second tube 230, and a second fin 240.

The third header tank 210 is formed by a combination of the third header 211 and the third tank 212 in a configuration that is spaced apart by a predetermined distance and provided side by side. In this case, the third header 211 is a part protruding most in the vehicle longitudinal direction.

The second inlet portion 221 and the second outlet portion 222 are formed in the third header tank 210 to inflow a second heat exchange medium and discharge the heat exchange medium.

Both ends of the second tube 230 are fixed to the third header tank 210 to form a second heat exchange medium flow path, and a plurality of the second tubes 230 are provided with fins interposed therebetween.

The fan and shroud assembly 300 is provided on the rear side of the radiator 200 in the air flow direction to forcibly blow air.

On the other hand, in the condenser 100 of the present invention, the gas-liquid separator 160 is eccentrically coupled in the vehicle longitudinal direction, and the first header tank 110, the second header tank 120, the first inlet 131, and the second It includes 1 outlet 132, a first tube 140, a first pin 150, a gas-liquid separator 160, a connector 170, and a connector 180.

The first header tank 110 is formed by a combination of the first header 111 and the first tank 112, and a first hollow hole in which two or more predetermined areas are hollow in the height direction of the first tank 112 113 is formed. The first hollow hole 113 is a portion into which the connection pipe 180 is inserted for communication with the gas-liquid separator 160.

The second header tank 120 is formed by a combination of the second header 121 and the second tank 122, and is provided in parallel with the first header tank 110 at a predetermined distance apart.

The first inlet 131 and the first outlet 132 are formed in the second header tank 120 to inflow and discharge the first heat exchange medium.

The first tube 140 is fixed to both ends of the first header tank 110 and the second header tank 120 to form a first heat exchange medium flow path, and a plurality of first pins 150 are provided therebetween. ) Is interposed.

The gas-liquid separator 160 is connected to one side of the first header tank 110 to separate the gaseous first heat exchange medium and the liquid first heat exchange medium. In this case, the gas-liquid separator 160 has a second hollow hole 161 formed at a position corresponding to the first hollow hole 113 formed in the first tank in the height direction. Like the first hollow hole 113, the second hollow hole 161 is inserted into the connector 180. That is, the connection pipe 180 has two ends inserted into the first hollow hole 113 of the first tank 112 and the second hollow hole 161 of the gas-liquid separator 160 so that the two spaces (first header The tank 110 and the gas-liquid separator 160 are communicated.

The connector 170 is provided between the first header tank 110 and the gas-liquid separator 160 so that the gas-liquid separator 160 is eccentrically coupled in the vehicle longitudinal direction, and a connection pipe 180 penetrates therein. . At this time, the connector 170 corresponds to the first curved portion 171 corresponding to the outer surface of the first header tank 110 (precisely, the first tank 112) and the outer surface of the gas-liquid separator 160 An insertion hole in which the second curved portion 172 is formed and the connector 180 is inserted through the region in which the first curved portion 171 is formed and the second curved portion 172 is formed. 173) is hollow. That is, the connector 170 is a part that protects the connection pipe 180 and fixes the connection and the first tank 112 and the gas-liquid separator 160 at the same time.

At this time, the connector 170 is the center of the first header tank 110 (O2) and the center of the gas-liquid separator 160 (O1) based on the cross section of the region where the connector 170 is formed in the vehicle height direction. ) And a second reference line (L2) parallel to the outer surface of the connector 170 and passing through the center (O2) of the first header tank 110 (See Fig. 6) In more detail, the first tank 112 forms an outer surface of the first header tank 110 together with the first header 111, and the first header 111 ), and the portion coupled to the first header 111 is unsuitable for the connector 170 to be connected. Accordingly, when the connector 170 is simply formed to have an outer surface parallel to the first reference line (L1) connecting the center (O1) of the gas-liquid separator 160 and the center (O2) of the first header tank 110 , The degree of eccentricity of the gas-liquid separator 160 is bound to be limited, and in order to reduce the space between the gas-liquid separator 160 and the first header tank 110, the thickness of the connector 170 and the connection pipe 180 provided therein There is a problem that the diameter of the can only be reduced. In the condenser 100 of the present invention, in order to solve this problem, the connector 170 itself connects the center O2 of the first header tank 110 to the center O1 of the gas-liquid separator 160. It is formed to be inclined to have one reference line L1 and a reference angle α.

At this time, the reference angle α is a third connecting the outer surface of the gas-liquid separator 160 with the first tank 112 located at the outermost side opposite to the eccentric side of the gas-liquid separator 160 in the vehicle longitudinal direction. The reference line L3 may be set to be parallel to the vehicle width direction. That is, the condenser 100 and the cooling module 1000 of the present invention can minimize an increase in thickness due to the formation of the gas-liquid separator 160 in the condenser 100.

That is, in the condenser 100 of the present invention, the connector 170 itself is eccentrically coupled, and the connector 170 is the first outer surface length (D1) of the side where the gas-liquid separator 160 is eccentric in the vehicle length direction. Is smaller than the second outer surface length D2 of the opposite side. Through this, the condenser 100 of the present invention can maximize the eccentric angle of the gas-liquid separator 160 while minimizing the distance between the gas-liquid separator 160 and the first header tank 110, and the entire cooling module ( 1000) thickness (length in the longitudinal direction of the vehicle) can be reduced.

Meanwhile, in the cooling module 1000 of the present invention, the eccentric direction of the condenser 100 may be a front side or a rear side in the vehicle longitudinal direction, which is preferably determined according to the shape of the radiator 200 and the condenser 100. .

First, in the case where the first header 111 and the second header 121 are located outside the third header 211 of the radiator 200 in the vehicle width direction, the gas-liquid separator ( It is preferable that 160 is eccentric to the rear side in the vehicle longitudinal direction (see FIGS. 3 and 4). In this case, the overall width of the cooling module 1000 may be reduced and the distance between the bumper beams B may be maximized.

In addition, the condenser 100 is, when the first header tank 110 and the second header tank 120 are located inside the vehicle width direction than the third header 211 of the radiator 200, the condenser ( It is preferable that the gas-liquid separator 160 is eccentric to the front in the longitudinal direction of the vehicle so that the 100) and the radiator 200 can be placed in close contact with each other (see FIG. 8).

Accordingly, in the condenser 100 and the cooling module 1000 of the present invention, the gas-liquid separator 160 is eccentrically coupled using the connector 170 to stably fix the first header tank 110 and the gas-liquid separator 160 It can be, and there is an advantage of miniaturization by reducing the thickness between the cooling modules 1000 in the vehicle longitudinal direction. In particular, the condenser 100 and the cooling module 1000 according to the present invention include the center O2 of the first header tank 110 and the gas-liquid separator based on the cross section of the area in which the connector 170 is formed in the vehicle height direction. A first reference line (L1) connecting the center (O1) of 160, and a second reference line (L2) parallel to the outer surface of the connector 170 and passing through the center (O2) of the first header tank (110) By forming this reference angle α, there is an advantage in that the degree of eccentricity of the gas-liquid separator 160 can be increased.

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

1000: cooling module
100: condenser
110: first header tank 111: first header
112: first tank 113: first hollow hole
120: second header tank 121: second header
122: second tank
131: first entrance 132: first exit
140: first tube
150: first pin
160: gas-liquid separator 161: second hollow hole
170: connector 171: first curved portion
172: second curved portion
173: insertion hole
D1: 1st outer surface length
D2: 2nd outer surface length
180: connector
L1: first baseline L2: second baseline
L3: 3rd baseline
O1: center of gas-liquid separator O2: center of first header tank
200: radiator
210: 3rd header tank 211: 3rd header
212: 3rd tank
221: second entrance 222: second exit
230: second tube
240: 2nd pin
300: fan and shroud assembly

Claims (9)

A first header 111, a first tank 112 coupled to the first header 111, and a first hollow hole 113 that is hollow in the height direction of two or more in the first tank 112 is formed. A first header tank 110;
A second header tank 120 formed by a combination of the second header 121 and the second tank 122 and disposed in parallel with the first header tank 110 by a predetermined distance;
A first inlet portion 131 formed in the second header tank 120 into which a first heat exchange medium flows in and a first outlet portion 132 discharged;
A plurality of first tubes 140 having both ends fixed to the first header tank 110 and the second header tank 120 to form a first heat exchange medium flow path;
A first pin 150 interposed between the first tube 140;
Gas-liquid in which a gaseous first heat exchange medium and a liquid first heat exchange medium are separated from one side of the first header tank 110, and a second hollow hole 161 corresponding to the first hollow hole 113 is formed in a height direction Separator 160;
A first curved portion 171 corresponding to an outer surface of the first header tank 110 and a second curved portion corresponding to an outer surface of the gas-liquid separator 160 so that the gas-liquid separator 160 is eccentrically coupled in the vehicle longitudinal direction A connector 170 having an insertion hole 173 formed therein; And
And a connector 180 inserted into the insertion hole 173 of the connector 170, and both ends thereof are respectively inserted into the first hollow hole 113 and the second hollow hole 161,
The condenser 100 connects the center O1 of the gas-liquid separator 160 and the center O2 of the first header tank 110 based on the cross-section of the region where the connector 170 is formed in the vehicle height direction. One first reference line L1 and a second reference line L2 parallel to the outer surface of the connector 170 and passing through the center O2 of the first header tank 110 form a reference angle α,
The connector 170 is a condenser, characterized in that the first outer surface length (D1) of the side where the gas-liquid separator 160 is eccentric in the vehicle length direction is smaller than the second outer surface length (D2) of the opposite side.
delete The method of claim 1,
The reference angle α is a third reference line L3 connecting the outer surface of the gas-liquid separator 160 to the first tank 112 located at the outermost side opposite the gas-liquid separator 160 in the vehicle longitudinal direction. ) Is set to be parallel to the vehicle width direction.
delete The method of claim 1,
The condenser 100 includes the first hollow hole 113 so that the outer surface of the connector 180 is positioned parallel to the outer surface of the connector 170 based on the cross-section of the region where the connector 170 is formed, and The condenser, characterized in that the second hollow hole (161) is formed.
The condenser (100) according to any one of claims 1, 3 and 5;
A radiator 200 provided at the rear side of the condenser 100 in the air flow direction;
A cooling module comprising a fan and shroud assembly (300) provided at the rear side of the radiator (200) in the air flow direction.
The method of claim 6,
The radiator 200,
A third header tank 210 formed by a combination of the third header 211 and the third tank 212 and provided side by side with a predetermined distance apart;
A second inlet portion 221 through which a second heat exchange medium is introduced and a second outlet portion 222 formed in the third header tank 210;
A second tube 230 having both ends fixed between the third header tank 210; And
Cooling module, characterized in that it comprises a second fin (240) interposed between the second tube (230).
The method of claim 7,
The cooling module 1000,
The first header 111 and the second header 121 of the condenser 100 are positioned outside the third header 211 of the radiator 200 in the vehicle width direction,
The cooling module, characterized in that the gas-liquid separator 160 is eccentric to the rear side in the vehicle longitudinal direction.
The method of claim 7,
The cooling module 1000,
The first header tank 110 and the second header tank 120 of the condenser 100 are positioned inside the third header 211 of the radiator 200 in the vehicle width direction,
Cooling module, characterized in that the gas-liquid separator 160 is eccentric to the front side in the vehicle longitudinal direction.

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