KR20120111634A - Condenser - Google Patents

Abstract

PURPOSE: A condenser is provided to easily transfer liquid heat exchange media to an overcooling area of a core arranged on the top of a liquid receiver. CONSTITUTION: A condenser comprises upper and lower header tanks(110,120), first and second pipes(210,220), multiple tubes(300), pins(400), baffles(500), and a liquid receiver(600). The upper and lower header tanks are arranged in a line. The first and second pipes are formed on the upper header tank, and heat exchange media flow into the first and second pipes. Both ends of the tubes are fixed to the upper and lower tanks, and the upper and lower tanks form heat exchange medium paths. The pins are inserted between the tubes. The baffles are formed inside the upper and lower header tanks and control the flow of heat exchange media. The liquid receiver is installed under the lower header tank and separates gaseous heat exchange media from liquid heat exchange media.

Description

Condenser

The present invention relates to a condenser, and more particularly, in a downflow condenser having a receiver formed at a bottom thereof, a heat exchange medium discharged to a subcooled region to transfer a liquid heat exchange medium collected on a bottom surface of the receiver body to a core. By installing an insertion tube formed in the body of the receiver in the longitudinal direction so that the flow path of the flow path is formed in the longitudinal direction and the bottom surface in the height direction hollow hole, the heat exchange in the liquid state separated by gas-liquid by gravity A condenser that allows the medium to be easily transported to the subcooling zone of the core above the receiver.

A heat exchanger is a device that absorbs heat from one side and dissipates heat to the other between two environments with a difference in temperature. In this case it will act as a heating system. Basically, the heat exchanger is composed of an evaporator that absorbs heat from the surroundings, a compressor that compresses the refrigerant, a condenser that releases heat to the surroundings, and an expansion valve for expanding the refrigerant.

In the cooling device, the actual cooling action is caused by an evaporator in which the liquid refrigerant absorbs the amount of heat as vaporized heat from the surroundings and vaporizes. The gaseous refrigerant flowing from the evaporator to the compressor is compressed at high temperature and high pressure in the compressor, and liquefied heat is released to the surroundings in the process of liquefaction of the compressed gaseous heat exchange medium through the condenser, and the liquefied heat exchange medium After passing through the expansion valve again becomes a low-temperature and low-pressure wetted vapor state, it is introduced again into the evaporator to vaporize to form a cycle.

As described above, in the condenser 1, a refrigerant having a gaseous state of high temperature and high pressure flows in and is discharged after condensing into a liquid state while releasing liquefied heat by heat exchange.

The condenser 1 may be installed in a cross flow type as shown in FIG. 1 or a down flow type as shown in FIG. 2 according to a vehicle.

As shown in FIG. 1, in the cross flow type, a pair of header tanks 2 and 3 are spaced apart in the width direction, and a plurality of tubes 4 connecting the pair of header tanks 2 and 3 are also in the width direction. By the installation, the refrigerant has a flow flowing in the condenser 1 in the width direction.

As shown in FIG. 2, the downflow type has a pair of header tanks 2 and 3 spaced apart in the height direction, and a plurality of tubes 4 connecting the pair of header tanks 2 and 3 are also in the height direction. By the installation, the refrigerant has a flow flowing in the condenser 1 in the height direction.

In addition, by the baffles 5 provided in the pair of header tanks 2 and 3, the refrigerant introduced into the condenser 1 flows the plurality of tubes 4 in a zigzag, and thus the condenser The condensation area A1 and the subcooling area A2 in which the refrigerant passing through the condensation area A1 are cooled again are configured.

And a receiver 6 is installed on the refrigerant passage of the condenser 1, that is, the receiver 6 is connected to one side of any one of the pair of header tanks (2, 3), expansion, Supplying a complete liquid refrigerant to the valve (not shown), the inside is also filled with a desiccant (not shown) serves to absorb the moisture contained in the refrigerant.

In addition, the upper part of the receiver 6 installed vertically communicates with the condensation area A1 of the condenser 1, and the lower part communicates with the subcooling area A2 of the condenser 1, thereby condensing the condensation area A1. Liquid refrigerant in the refrigerant introduced into the receiver 6 through the through is located on the lower portion of the receiver 6 by gravity, while the gas phase refrigerant not yet liquefied is located on the upper portion of the receiver 6, Only the liquid refrigerant is supplied to the subcooling area A2 of the condenser.

On the other hand, in the defrosting process of melting the frost generated in the external heat exchanger, that is, the condenser, when the heat pump of the vehicle is generally operated, in the conventional crossflow fin / tube arrangement, the drainage of the melted water is poor, so the defrosting is well performed. There was a drawback that the frozen frost melted.

On the contrary, the downflow condenser is formed such that the melted frost flows downward like a general car evaporator, so that drainage can be improved and the defrost mode efficiency of the heat pump can be improved.

However, in the conventional down flow type condenser, due to the characteristics of the receiver which separates the liquid refrigerant that has already been condensed by gravity and the gaseous refrigerant which has not yet been condensed, the receiver is configured inside or outside the condenser in the direction of gravity like the cross flow type. In this case, the structure was complicated, which made it difficult to manufacture and manage.

Therefore, the situation is required to develop a receiver structure suitable for the downflow condenser to solve the above problems.

The present invention has been made in order to solve the above problems, an object of the present invention is to transfer the heat exchange medium in the liquid state collected on the bottom surface of the inside of the receiver body to the core in the down flow type condenser formed with a receiver at the bottom to the core In order to make the flow path of the heat exchange medium discharged to the subcooling region into a double tube form by inserting the insertion tube is formed in the body of the receiver in the longitudinal direction and the communication hole in which the bottom area is hollow in the height direction, The present invention relates to a condenser for allowing a liquid heat exchange medium separated by gravity to be easily transferred to a subcooled region of a core above the receiver.

The condenser of the present invention is spaced apart by a predetermined distance in the height direction, the upper header tank 110 and the lower header tank 120; A first pipe 210 and a second pipe 220 formed in the upper header tank 110 and into or out of a heat exchange medium ; A plurality of tubes 300 having both ends fixed to the upper header tank 110 and the lower header tank 120 to form a heat exchange medium flow path ; A plurality of fins 400 interposed between the tubes 300 ; A baffle 500 provided inside the upper header tank 110 and the lower header tank 120 to control a heat exchange medium flow ; And a cylindrical body 610 installed at a lower side of the lower header tank 120 to communicate with the connection part 700, separating the gas phase heat exchange medium and the liquid heat exchange medium, and formed in a width direction. A sealing cap 630 which seals the opening 611 formed at one end of the 610 and is provided inside the body 610 to filter foreign matters included in the heat exchange medium, and a sealing cap 630, and the body 610. A connection part 700 including a first connection part 710 into which a heat exchange medium is introduced, and a second connection part 720 from which the heat exchange medium is discharged from the body 610, and discharged into the second connection part 720. sap that passage of the heat exchanging medium is formed, including the insertion tube 800 that is a communication hole 810 side inserted in the longitudinal direction inside the body 610 and the bottom in the height direction of the predetermined area in which a hollow is formed to be a double tube type Group 600; Characterized in that it is formed to include.

In addition, in the receiver 600, the condensation area A1 is formed in the first connection part 710 such that the heat exchange medium introduced through the first connection part 710 is gas-liquid separated and accommodated in the body 610. It is installed on the side, the heat exchange medium of the liquid submerged on the bottom surface of the body 610 passes through the communication hole 810 through the filter unit 620, and then supercooled through the second connection portion 720 The filter part 620 is inserted into the insertion tube 800 so as to flow into the area A2, and the insertion tube 800, the filter part 620 and the second connection portion 720 are subcooled area A2. It is characterized in that it is installed on the side to be formed.

In addition, the insertion tube 800 is formed in a cylindrical shape corresponding to the outer circumferential surface of the filter portion 620 so that the filter portion 620 is inserted and fixed, the filter portion 620 of the body 610 toward the inside A protrusion 820 is formed in which a predetermined region of the inner circumferential surface of the insertion tube 800 protrudes inward so that one end thereof is fixedly supported, and both sides of the insertion tube 800 are in close contact with the inner circumferential surface of the body 610. It is characterized in that the close contact portion 830 is formed to protrude.

In addition, the receiver 600 includes the filter unit 620 and the first connection unit 710 in a condensation region such that the heat exchange medium introduced through the first connection unit 710 passes through the filter unit 620. A1) is installed on the side is formed, the liquid heat exchange medium sinks to the bottom surface of the body 610 flows into the insertion tube 800 and passes through the communication hole 810, the second connecting portion The insertion tube 800 and the second connection portion 720 are installed on the side where the subcooling area A2 is formed to flow to the subcooling area A2 through 720.

In addition, the condenser 10 is made of both the inlet and outlet through the first pipe 210 and the second pipe 220, the double pipe form by the insertion pipe 800 is the first connection portion 710 and Both ends of the insertion tube 800 inserted into the first connection portion 710 side and the insertion tube 800 inserted into the second connection portion 720 side are formed so that both sides of the second connection portion 720 are installed. It extends inwardly characterized in that it is formed in one piece.

In the condenser of the present invention, in order to transfer the liquid heat exchange medium collected in the bottom surface of the receiver body to the core, the flow path of the heat exchange medium discharged to the supercooling area is a double pipe type in the down flow type condenser having a receiver formed at the bottom thereof. By installing an insertion tube which is inserted into the body of the receiver in the longitudinal direction in the longitudinal direction and the bottom surface in the height direction hollow hole is formed, the heat exchange medium in the liquid state gas-separated by gravity is the receiver There is an advantage that can be easily transferred to the subcooling area of the core on the upper side of the.

In addition, the condenser according to the present invention forms a receiver at the bottom parallel to the pair of header tanks spaced apart in the height direction and at the same time allows the liquid heat exchange medium to flow smoothly to the subcooling region, thereby condenser structure Simplification has the advantage of ease of manufacture and management compared to conventional downflow condenser.

In addition, the condenser of the present invention is a downflow-type condenser with a smooth flow of refrigerant between the receiver and the core of the condenser, and has an advantage of improving the efficiency of the defrost mode during the heat pump operation due to the improved drainage of the melted water during the defrosting process.

1 is a front view showing a conventional cross flow condenser;
Figure 2 is a front view showing a conventional downflow condenser.
3 is a partial cross-sectional view showing a condenser according to the present invention.
4 is a partially exploded perspective view showing a condenser according to the present invention.
5 is a partial cross-sectional view showing another condenser according to the present invention.
6 is a perspective view showing the insertion tube of the condenser shown in FIG.
FIG. 7 is a side sectional view of the receiver of the condenser shown in FIG. 5; FIG.
8 is a perspective view showing another insertion tube of the condenser according to the present invention.
9 is a partially exploded perspective view showing another condenser according to the present invention.
10 is a flow chart showing the flow of the heat exchange medium during the operation of the heat pump in a partial cross-sectional view of the condenser of FIG.
FIG. 11 is a flow chart showing the flow of heat exchange medium during operation of the air conditioner in the partial cross-sectional view of FIG.

Hereinafter, the condenser of the present invention as described above will be described in detail with reference to the accompanying drawings.

Figure 3 is a partial cross-sectional view showing a condenser according to the invention, Figure 4 is a partially exploded perspective view showing a condenser according to the invention, Figure 5 is a partial cross-sectional view showing another condenser according to the invention, Figure 6 Figure 7 is a perspective view showing the insertion tube of the condenser shown in Figure 7 is a side cross-sectional view showing the receiver of the condenser shown in Figure 5, Figure 8 is a perspective view showing another insertion tube of another condenser in the present invention, Figure 9 is FIG. 10 is a partial exploded perspective view illustrating another condenser according to the present invention, and FIG. 10 is a flowchart illustrating a flow of a heat exchange medium during a heat pump operation in a partial cross-sectional view of FIG. 9, and FIG. 11 is a partial cross-sectional view of the condenser of FIG. 9. Is a flow chart showing the flow of heat exchange media during air conditioner operation.

The condenser 10 according to the present invention has a down flow type so as to have a flow in which the refrigerant flows in the height direction (longitudinal direction).

The condenser 10 is formed in the upper header tank 110 and the lower header tank 120 and side by side spaced apart a predetermined distance in the height direction, the first heat exchange medium is formed in the discharge header A plurality of tubes 300 having both ends fixed to the first pipe 210 and the second pipe 220, the upper header tank 110, and the lower header tank 120 to form a heat exchange medium flow path, and the tube 300. Interposed between the) is configured to include a heat radiation fin 400 to improve the heat exchange performance by widening the heat exchange area.

Inside the upper header tank 110 and the lower header tank 120, a baffle 500 is provided to control the heat exchange medium flow, and the heat exchange medium introduced into the condenser 10 by the baffle 500 has a plurality of heat exchange mediums. The tubes 300 are able to flow in a zigzag form.

In addition, the plurality of tubes 300 constitute a condensation region A1 and a subcooling region A2. That is, the gaseous heat exchange medium introduced into the condenser 10 cools while flowing the plurality of tubes 300. The area that is phase-changed into the liquid heat exchange medium is called the condensation area A1, and the area where the liquid refrigerant passing through the condensation area A1 is cooled again while flowing through the plurality of tubes 300 is called a supercooling area.

Meanwhile, when the condenser 10 changes the position or the number of the baffles 500 installed in the upper header tank 110 and the lower header tank 120, the flow path of the heat exchange medium flowing through the condensation area A1 is changed. You can also change the.

In addition, the upper header tank 110 and the lower header tank 120 may be configured in the form of a single pipe, respectively, a header (not shown) coupled to both ends of the plurality of tubes 300, and is coupled to the header It may also consist of a tank.

In addition, the condenser 10 is formed with a first pipe 210 and a second pipe 220 through which the heat exchange medium is introduced or discharged, the first pipe 210 and the second pipe 220. Are all formed in the upper header tank 110.

In this case, one of the first pipe 210 and the second pipe 220 in which the heat exchange medium is generally introduced is formed on the upper header tank 110 in communication with the condensation area A1, and the heat exchange medium is The other one discharged is formed on the upper header tank 110 in communication with the subcooling area A2.

The receiver 600 is installed parallel to the lower side of the lower header tank 120 spaced apart at a predetermined interval, the down flow type condenser 10 according to the present invention is arranged in the lower header tank 120 long in the width direction Therefore, the receiver 600 is also installed in the width direction.

The receiver 600 is installed on the lower side of the lower header tank 120 is communicated by the connecting portion 700, the gas phase heat exchange medium and the liquid heat exchange medium is separated, the cylindrical body 610 is formed long in the width direction (610) ).

At this time, both ends of the body 610 are opened in the width direction, one of which is sealed by a sealing cap 630, the sealing cap 630 is provided in the body 610 It includes a filter unit 620 for filtering foreign matter contained in the heat exchange medium. In addition, the opening 611 formed on the other side is sealed by a stopper 650.

In addition, a desiccant 640 is accommodated in the body 610, and the desiccant 640 absorbs and removes moisture contained in the heat exchange medium.

On the other hand, in the condenser 10 according to the present invention, the connecting portion 700 formed to communicate the lower header tank 120 and the body 610 is composed of a first connecting portion 710 and the second connecting portion 720. .

The first connector 710 is a passage through which a heat exchange medium flows into the receiver 600, and the second connector 720 is a passage through which the heat exchange medium is discharged from the receiver 600.

In particular, the receiver 600 of the condenser 10 according to the present invention is inserted in the longitudinal direction inside the body 610 so that the flow path of the heat exchange medium discharged to the second connecting portion 720 is a double pipe form, height It is formed including an insertion tube 800 is formed in the communication hole 810, the bottom surface of the predetermined area hollow.

As shown in FIG. 3, the receiver 600 condenses the first connector 710 such that the heat exchange medium introduced through the first connector 710 is gas-liquid separated and accommodated in the body 610. It is provided in the side in which area | region A1 is formed.

In addition, the receiver 600 after the liquid heat exchange medium that has sunk on the bottom surface of the body 610 passes through the communication hole 810 through the filter unit 620, the second connection portion 720 The filter part 620 is inserted into the insertion tube 800 to flow to the subcooling region A2, and the insertion tube 800, the filter portion 620 and the second connection portion 720 are subcooled region (2). It may be installed on the side where A2) is formed.

In this case, the insertion tube 800 may be formed in a cylindrical shape corresponding to the outer circumferential surface of the filter unit 620 so that the filter unit 620 is inserted and fixed, and the filter unit facing the inside of the body 610 ( 3, a protrusion 820 may be formed in which a predetermined region of the inner circumferential surface of the insertion tube 800 protrudes inwardly so that one end of the 620 is fixedly supported in FIG. 3.

In addition, contact portions 830 and 830 may be formed to protrude to the outside so that both ends of the insertion tube 800 are in close contact with the inner circumferential surface of the body 610.

Therefore, the receiver 600 is in close contact with the inner peripheral surface of the contact portion 830, 830 and the body 610 of the insertion tube 800, the gap does not occur, it is introduced through the first connecting portion 710 All of the heat exchange medium may be introduced into the insertion tube (800).

Then, all of the heat exchange medium passes through the filter unit 620 by the protrusion 820, passes through the communication hole 810 via the filter unit 620, the insertion tube 800 and the As shown in FIG. 7 along the space between the double pipes formed between the body 610 may be discharged to the subcooling area (A2) through the second connecting portion (720).

On the other hand, as shown in Figure 5, the receiver 600 is the filter unit 620 and the first so that the heat exchange medium flowing through the first connecting portion 710 passes through the filter unit 620. The connection part 710 may be installed at the side where the condensation area A1 is formed.

In addition, the receiver 600 is a heat exchange medium of the liquid state sank on the bottom surface of the body 610 flows into the insertion tube 800 and passes through the communication hole 810, the second connecting portion ( The insertion tube 800 and the second connection portion 720 may be installed on the side where the subcooling area A2 is formed to flow to the subcooling area A2 through 720.

In this case, as shown in FIG. 3, the insertion tube 800 may have a close contact portion 830 protruding outward so that both ends of the insertion tube 800 are in close contact with the inner circumferential surface of the body 610. have.

Therefore, the receiver 600 is in close contact with the inner circumferential surface of the insertion tube 800 and the inner peripheral surface of the body 610 is not generated, the gap is introduced through the first connecting portion 710 and the filter unit All of the heat exchange medium passed through 620 may be introduced into the insertion tube 800.

Then, the heat exchange medium passes through the communication hole 810 formed in the lower side of the insertion tube 800, and then along the space between the double tube formed between the insertion tube 800 and the body 610 as shown in Figure 7 As it rises, it may be discharged to the subcooling area A2 through the second connector 720.

At this time, the communication hole 810 formed in the insertion tube 800 may be formed by hollowing a predetermined area of the lower outer circumferential surface of the insertion tube 800, as shown in Figure 8, the communication hole 810 as shown in FIG. It may be formed to extend to one end of the insertion tube 800 so that a predetermined area of the outer circumferential surface of the end is opened.

In the insertion tube 800 illustrated in FIG. 8, when the receiver 600 is assembled, the side in which the communication hole 810 is formed faces the upper side even when the body 610 and the second connection portion 720 are assembled first. It can be inserted in the state to see so that the protruding portion of the second connection portion 720 is not caught, and then the communication hole 810 is rotated and assembled to be located on the floor.

In another embodiment, as shown in Figure 9, the condenser 10 is made of both the inlet and outlet through the first pipe 210 and the second pipe 220, the insertion pipe 800 Insertion tube 800 and the second connection portion 720 is inserted into the first connection portion 710 side so that the double tube form is formed on both the first connection portion 710 and the second connection portion 720 is installed side Both ends of the insertion tube 800 to be inserted into may extend in the inward direction to be integrally formed.

In this case, the condenser 10 is applied to a heat pump system that simultaneously performs cooling and heating by using one refrigerant, and the first pipe 210 and the refrigerant are moved in opposite directions in cooling and heating. In some cases, the second pipe 220 may enter or exit a heat exchange medium.

As shown in FIG. 11, during cooling, the heat exchange medium may be introduced through the first pipe 210, and the heat exchange medium may be discharged through the second pipe 220.

At this time, the condenser 10 flows zigzag along the condensation area A1 by the heat exchange medium through the first pipe 210 and then baffles 500, and then moves the first connection part 710 to the condenser 10. Through the receiver 600 is introduced.

Then, the heat exchange medium passes through the filter unit 620 and flows along the double tube, and passes through the communication hole 810 of the insertion tube 800 located on the second connecting portion 720 side, the insertion tube It is raised along the space between the double tube formed between the 800 and the body 610 is discharged to the subcooling area (A2) through the second connecting portion (720). The heat exchange medium supercooled through the subcooling area A2 is discharged through the second pipe 220.

As shown in FIG. 10, during heating, the heat exchange medium may be discharged through the first pipe 210, and the heat exchange medium may be introduced through the second pipe 220.

At this time, the condenser 10 enters the heat exchange medium through the second pipe 220 and then flows into the receiver 600 through the first connection part 710.

Then, the heat exchange medium passes through the filter unit 620 along the double pipe, and the heat exchange medium and oil in the gas state in which foreign matter is filtered out of the filter unit 620 pass through the communication hole 810 and the insertion pipe 800. ) And is raised along the space between the double tube formed between the body 610 is discharged through the second connecting portion 720, and finally discharged through the first pipe (210).

As shown in FIGS. 10 and 11, the insertion tube 800 is inserted into the insertion tube 800 inserted into the first connecting portion 710 and the insertion tube 800 inserted into the second connecting portion 720. Both ends of the e) are formed in one piece, extending inwardly, and the extended portion may be formed to be in close contact with the inner circumferential surface of the body 610, such as the close contact portion 830 of the insertion tube 800.

At this time, the receiver 600 may be accommodated by the desiccant 640 is inserted into the insertion tube (800).

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.

110: upper header tank 120: lower header tank
210: inlet pipe 220: outlet pipe
300 tube
400: pin
500: baffle
600: Receiver
610: body 611: opening
620: filter portion 630: sealing cap
640: Desiccant 650: stopper
700: connection
710: first connector 720: second connector
800 insertion tube
810: communication hole 820: protrusion
830: tight contact
A1: condensation zone A2: subcooling zone

Claims (5)

An upper header tank 110 and a lower header tank 120 spaced apart by a predetermined distance in a height direction ;
A first pipe 210 and a second pipe 220 formed in the upper header tank 110 and into or out of a heat exchange medium ;
A plurality of tubes 300 having both ends fixed to the upper header tank 110 and the lower header tank 120 to form a heat exchange medium flow path ;
A plurality of fins 400 interposed between the tubes 300 ;
A baffle 500 provided inside the upper header tank 110 and the lower header tank 120 to control a heat exchange medium flow ; And
A cylindrical body 610 installed below the lower header tank 120 and communicating with the connection part 700, separating the gas phase heat exchange medium and the liquid heat exchange medium, and formed in a width direction, and the body 610. A sealing cap 630 which seals the opening 611 formed at one end of the filter 610 and is provided inside the body 610 to filter foreign matters included in the heat exchange medium, and the body cap 610. The connection part 700 is composed of a first connection portion 710 into which the heat exchange medium is introduced and a second connection portion 720 through which the heat exchange medium is discharged from the body 610, and the heat exchange medium discharged to the second connection portion 720. A receiver formed into the body 610 so that the flow path of the flow path is inserted in the longitudinal direction and the insertion tube 800 is formed in the communication hole 810 hollowed out a predetermined area of the bottom surface in the height direction ( 600); Condenser characterized in that it is formed, including.
The method of claim 1,
The receiver 600 is
The first connector 710 is installed on the side where the condensation area A1 is formed so that the heat exchange medium introduced through the first connector 710 is gas-liquid separated and accommodated in the body 610.
After the liquid heat exchange medium that has settled on the bottom surface of the body 610 passes through the communication hole 810 through the filter part 620, flows to the subcooling area A2 through the second connection part 720. The filter unit 620 is inserted into the insertion tube 800 so that the insertion tube 800, the filter unit 620, and the second connection unit 720 are installed on the side where the subcooling region A2 is formed. A condenser, characterized in that.
The method of claim 2,
The insertion tube 800 is
The filter unit 620 is formed in a cylindrical shape corresponding to the outer peripheral surface of the filter unit 620 to be inserted and fixed,
A protrusion 820 is formed in which a predetermined region of the inner circumferential surface of the insertion tube 800 protrudes inward so that one end of the filter part 620 facing the inner side of the body 610 is fixedly supported.
Condenser characterized in that the contact portion (830) protruding outward so that both ends of the insertion tube 800 is in close contact with the inner peripheral surface of the body (610).
The method of claim 1,
The receiver 600 is
The filter part 620 and the first connection part 710 are installed on the side where the condensation area A1 is formed so that the heat exchange medium introduced through the first connection part 710 passes through the filter part 620. ,
After the liquid heat exchange medium that has sunk on the bottom surface of the body 610 flows into the insertion tube 800 and passes through the communication hole 810, the subcooling region A2 is formed through the second connection portion 720. Condenser, characterized in that the insertion pipe (800) and the second connecting portion (720) is installed on the side where the subcooling area (A2) is formed to flow to.
The method according to any one of claims 1 to 4,
The condenser 10
Through both the first pipe 210 and the second pipe 220 is made of both inlet and outlet,
Insertion tube 800 and the insertion tube 800 is inserted into the first connection portion 710 side so that the double tube form by the insertion tube 800 is formed on both sides of the first connection portion 710 and the second connection portion 720 is installed Both ends of the insertion tube (800) inserted into the second connection portion (720) side extends in the inward direction, characterized in that formed in one piece.

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