KR20130096819A - Cold reserving heat exchanger - Google Patents

Abstract

PURPOSE: A heat exchanger is provided to obtain independent space of a cold reserving material and a heat exchange medium by comprising refrigerant tubes of two rows and a cold reserving tube between the same. CONSTITUTION: A heat exchanger comprises a pair of header tanks, an inlet manifold (160), an outlet manifold (170), a plurality of refrigerant tubes (200), and a plurality of cold reserving tubes (300). The header tank forms a refrigerant header tank (110) in which a refrigerant flows in a first row and a third row, and a second row between the first and the second row is partitioned to form a cold reserving header tank (120) in which a cold reserving material is stored by a partition so that the header tank is formed in three rows. The inlet manifold and the outlet manifold are formed on the both ends of the header tank and are connected to the refrigerant header tank of the first row and the third row. Both ends of the refrigerant tube are connected to the refrigerant header tank of the first row and the third row formed to be separated at a predetermined interval so that the refrigerant flows. Both ends of the cold reserving tube are connected to the cold reserving header tank of the second row formed to be separated at a predetermined interval so that the cold reserving material is stored. [Reference numerals] (AA) Length; (BB) Height; (CC) Width

Description

Cold storage heat exchanger {Cold reserving heat exchanger}

The present invention relates to a cold storage heat exchanger, and more particularly, in an evaporator used in an air conditioner of a vehicle, a cold storage tube is provided between refrigerant tubes to discharge cold air stored in the cold storage tube when the air conditioner of the vehicle is stopped. The present invention relates to a heat storage heat exchanger capable of minimizing a sudden increase in temperature inside a vehicle, thereby improving cooling comfort of a user and minimizing energy and time consumed during re-cooling.

An air conditioning system is a device that absorbs heat inside a vehicle and releases heat to the outside of the vehicle between two environments with a temperature difference. Condenser, expansion valve for expanding the refrigerant.

In the cooling device, the actual cooling action is caused by the evaporator in which the liquid refrigerant absorbs the amount of heat as vaporization heat from the surroundings and vaporizes. The gaseous refrigerant flowing into the compressor from the evaporator is compressed to a high temperature and a high pressure in the compressor, and the refrigerant in the compressed gaseous state passes through the condenser and is liquefied, and the liquefied heat is discharged to the periphery. After passing through the expansion valve, it becomes a low-temperature and low-pressure wetted vapor state, and then flows into the evaporator again to be vaporized to form a cycle.

However, since the cooling device of the vehicle is based on the driving force of the engine, the cooling action does not occur while the vehicle is idle or parked for a short time. In the case where the temperature outside the vehicle is very high, if the air conditioner does not operate even in such a short time, the temperature inside the vehicle rises very quickly, and the air conditioner only starts when the vehicle starts to run again. Since the operation of the cool wind does not come out quickly, thereby the user's comfort is greatly reduced.

Recently, as the interest in the environment and energy in the automobile industry increases, researches for improving fuel economy have been conducted, and research and development for light weight, miniaturization and high functionalization have been steadily made to satisfy various consumer needs.

In particular, research and development on hybrid vehicles that use both engine power and electric energy at the same time is on the rise due to improved fuel economy and emissions regulations. Hybrid vehicles automatically stop the engine when the vehicle stops, In many cases, the idle stop / high system is adopted to allow the engine to be restarted by operating the transmission.

However, even in the case of the hybrid vehicle, since the air conditioner is operated by the engine, when the engine is stopped, the compressor is also stopped, and thus the temperature of the evaporator is rapidly increased, thereby degrading the user's comfort.

In addition, since the refrigerant inside the evaporator is easily vaporized even at room temperature, the refrigerant is vaporized for a short period of time when the compressor is not operated, and the engine is operated again, so even if the compressor and the evaporator are operated, the vaporized refrigerant must be compressed and liquefied. Not only does it take a long time, but there is a problem of increasing the overall energy requirement.

In order to solve the above problems, various forms of heat exchangers using a cold storage material for storing cold air have been proposed.

1 and 2 are views illustrating a heat exchanger in which a conventional coolant is stored.

As shown in FIG. 1, a heat exchanger in which a conventional coolant is stored is formed in a pair of tanks spaced apart from each other at a predetermined distance, and the tank includes a first tank 21 and a second tank 31. The first tank 21 is coupled to the first header 20 and the second tank 31 is coupled to the second header 30 to form independent flow paths.

In addition, both ends of the first header 20 and the second header 30 are fixed to each other to couple several refrigerant tubes 40 and the cold storage tube 50 to form a heat exchange medium flow path.

At this time, as shown in FIG. 2, the refrigerant tube 40 is configured in the cold storage tube 50 so that the heat exchange medium and the coolant flow path are independently formed.

Therefore, it is difficult to form an independent space of the cool storage material and the heat exchange medium, the structure is complicated, there is a problem that the production efficiency is lowered.

In addition, the conventional laminated plate type cold storage heat exchanger disclosed in Korean Laid-Open Patent Publication (10-2009-0108380) has three rows of tubes, refrigerant is injected into both sides, and a coolant is injected into the center. Since it is difficult to secure the amount of the coolant injected is small, there is a problem that it is difficult to obtain a proper cool storage performance.

In addition, the heat exchanger in which the conventional coolant is stored is likely to interfere with the flow of the heat exchange medium or to be mixed with each other, causing another problem.

KR 10-2009-0108380 A (2009.10.15.)

The present invention has been made in order to solve the above problems, the object of the present invention is to provide a coolant tube between the two rows of refrigerant tubes and between the coolant, and to ensure an independent space between the coolant and the heat exchange medium shaft The cold material is less likely to interfere with the flow of the heat exchange medium or mixed, and the structure is simple to provide a cold storage heat exchanger that can improve the production efficiency.

In the cold storage heat exchanger of the present invention for achieving the object as described above, the first row and the third row is a coolant header tank 110 through which a coolant flows, and the second row between them is a cool storage in which the coolant is stored. A pair of header tanks 100 which are partitioned by partition walls so that the header tank 120 is formed and formed in three rows and spaced apart by a predetermined distance; Is formed at both ends of the header tank 100 to communicate with the refrigerant header tanks 110 in the first and third rows, the inlet manifold 160 through which the refrigerant is introduced and the outlet manifold 170 through which the refrigerant is discharged. ); A plurality of refrigerant tubes 200 connected at both ends to the refrigerant header tanks 110 in the first and third rows formed to be spaced apart from each other by a predetermined distance; And a plurality of cold storage tubes 300 connected to both ends of the second cold storage header tank 120 formed to be spaced apart by a predetermined distance, and storing the cold storage material. And a control unit.

In addition, the refrigerant tube 200 and the cold storage tube 300 are formed as an integral tube 500, and a cold storage tube 300 is formed between the two rows of refrigerant tubes 200, and the integrated tube 500 is the header. Incision grooves 510 are formed at both ends to be inserted and coupled to the communication hole 140 formed in the tank 100.

In addition, the cold storage heat exchanger further includes a pump and a reservoir connected to the cold storage header tank 120, and the cold storage material is circulated along the cold storage header tank 120 and the cold storage tube 300.

And the cold storage heat exchanger of the present invention is a refrigerant header tank 110 is formed in two rows, the refrigerant flows, a pair of header tanks 100 are formed side by side spaced apart a certain distance; Formed at both ends of the header tank 100 to communicate with the refrigerant header tanks 110 in two rows, the inlet manifold 160 through which the refrigerant is introduced and the outlet manifold 170 through which the refrigerant is discharged; A plurality of refrigerant tubes 200 connected at both ends to the refrigerant header tanks 110 in two rows spaced apart from each other by a predetermined distance; And a cold storage tube 300 provided between the two rows of refrigerant header tanks 110 to store the coolant therein. And a control unit.

In addition, the two rows of refrigerant header tank 110 is characterized in that formed to be spaced apart from each other by a predetermined distance.

In addition, two rows of refrigerant header tanks 110 formed at an upper portion of the pair of header tanks 100 are larger than two rows of refrigerant header tanks 110 formed at a lower portion thereof, and thus, two rows of refrigerants formed at the lower portions thereof. The header tank 110 is characterized in that it is formed to be spaced apart a certain distance.

In addition, the coolant storage container 310 coupled to the lower side of the two-row refrigerant header tank 110 is formed in the lower portion is connected to the lower end of the cold storage tube 300 is made, the coolant storage container ( 310 is characterized in that the condensate discharge hole 311 penetrates up and down.

In addition, the opposite end of the header tank 100, the manifold (160, 170) is formed is characterized in that the end cap 150 is integrally coupled to the end.

In addition, the manifold (160, 170) or the end cap 150 is characterized in that the cold storage tube support 320 is coupled to the cold storage tube 300 is formed.

The present invention has been made to solve the above problems, the cold storage heat exchanger of the present invention is composed of two rows of refrigerant tubes and a cold storage tube therebetween, it is possible to secure an independent space of the cold storage material and the heat exchange medium The cool storage material is less likely to interfere with the flow of the heat exchange medium or mixed, and has a simple structure to improve production efficiency.

In addition, since there is no refrigerant communication path structure connecting the two rows of refrigerant tubes, the configuration of the refrigerant passage of the heat exchanger is easy.

In addition, since the refrigerant flow path is composed of two rows, the flow rate of the refrigerant passing through the header tank of each row decreases, thereby reducing the pressure drop of the refrigerant.

1 is a partial perspective view showing a conventional cold storage heat exchanger.
FIG. 2 is a sectional view taken along the line AA ′ of FIG. 1. FIG.
Figure 3 is an exploded perspective view showing a cold storage heat exchanger of the present invention.
4 is an assembled perspective view of FIG. 3.
5 is a cross-sectional view of the refrigerant tube and the cold storage tube of FIG.
6 is a sectional view showing an integrated tube and a header tank according to the present invention.
Figure 7 is a block diagram showing a circulation structure of the cool storage material according to the present invention.
8 to 10 are cross-sectional views showing another embodiment according to the present invention.

Hereinafter, the cold storage heat exchanger of the present invention having the configuration as described above will be described in detail with reference to the accompanying drawings.

3 and 4 are an exploded perspective view and an assembled perspective view showing the heat storage heat exchanger of the present invention.

As shown, in the cold storage heat exchanger 1000 of the present invention, the first and third rows are formed of the refrigerant header tank 110 through which the refrigerant flows, and the second row therebetween is the cold storage header in which the coolant is stored. A pair of header tanks 100 which are partitioned by partition walls so that the tank 120 is formed and formed in three rows and spaced apart by a predetermined distance; Is formed at both ends of the header tank 100 to communicate with the refrigerant header tanks 110 in the first and third rows, the inlet manifold 160 through which the refrigerant is introduced and the outlet manifold 170 through which the refrigerant is discharged. ); A plurality of refrigerant tubes 200 connected at both ends to the refrigerant header tanks 110 in the first and third rows formed to be spaced apart from each other by a predetermined distance; And a plurality of cold storage tubes 300 connected to both ends of the second cold storage header tank 120 formed to be spaced apart by a predetermined distance, and storing the cold storage material. It is made, including.

First, the pair of header tanks 100 are spaced apart by a predetermined distance and formed side by side up and down. In this case, each of the header tanks 100 has a coolant header tank 110 formed in two rows along the length direction, and a cool storage header tank 120 is formed between the coolant header tanks 110 in the two rows. That is, the heat storage header tank 120 is formed so that the heat storage material can be stored or flow in the column in the middle of the three rows.

Thus formed in three rows the header tank 100 is arranged up and down, the refrigerant tube 200 and the cold storage tube 300 is coupled thereto. At this time, the refrigerant tube 200 and the cold storage tube 300 is connected so that both ends are connected between the pair of header tanks 100 disposed in the upper and lower, the refrigerant tube 200 of the header tank 100 Both ends are connected to two rows of refrigerant header tanks 110 so that the heat exchange medium may flow. The cold storage tube 300 may be connected to both ends of the cold storage header tank 120 to allow the coolant to flow and store. It is configured to be.

That is, as shown in FIG. 6, the refrigerant tubes 200 are formed in two rows on both sides, and the heat storage tube 300 is formed in one row in the center, thereby forming three tubes.

The fin 400 is coupled to contact the refrigerant tube 200 and the cold storage tube 300, and is formed in a zigzag and corrugated plate to pass through the interior of the tubes 200 and 300. It serves to improve the heat exchange efficiency with.

In summary, the cold storage heat exchanger 1000 of the present invention has a form in which a cold storage unit of one layer is configured between two heat exchangers.

Here, a baffle 130 may be formed inside the refrigerant header tank 110 of the header tank 100 so as to control the flow of the heat exchange medium. In this case, the baffle 130 may be formed inside the refrigerant header tank 110, and various numbers may be formed at various positions to control the flow of the refrigerant.

In addition, the inlet manifold 160 into which the heat exchange medium is introduced and the outlet manifold 170 from which the heat exchange medium is discharged may be coupled to the header tank 100, and the inlet manifold 160 and the outlet manifold 170 may be combined. ) Is connected to both ends of the two-row refrigerant header tank 110 of the header tank 100 may be formed two flow paths through which the heat exchange medium can flow.

In addition, one side of the cold storage header tank 120 is formed with a cold storage material injection unit 151, it can be configured to inject the cold storage material into the cold storage header tank 120 and the cold storage tube (300). In this case, the cold storage material injection unit 151 forms a hole in the end cap 150 coupled to the ends of the header tanks 110 and 120 to communicate with the cold storage header tank 120, and after the cold storage material is injected, The cold storage material injection part 151 may be blocked with a plug or a blocking bolt to prevent leakage of the cold storage material.

As described above, the cold storage heat exchanger of the present invention has two heat exchange medium flow paths formed therebetween, and thus, the separate cold storage header tank 120 and the cold storage tube 300 are formed therebetween. Since it is possible to secure the coolant is less likely to interfere with the flow of the heat exchange medium or mixed, there is an advantage that the structure is simple and the production efficiency is improved.

In addition, since there is no refrigerant communication path structure connecting the two rows of refrigerant tubes, the structure of the refrigerant path is easy, and the refrigerant path is composed of two rows, so the flow rate of the heat exchange medium passing through the refrigerant header tank and the refrigerant tube in each row decreases. There is an advantage to reduce the pressure drop.

And the cold storage heat exchanger of the present invention, as shown in Figure 5 is formed with two refrigerant passages, the shape of the inlet manifold 160 and outlet manifold 170 so that two passages are formed in one manifold, 2 Different directions of the refrigerant flow flowing along the two refrigerant passages may be formed.

In addition, the refrigerant tube 200 and the cold storage tube 300 are formed as an integrated tube 500, and a cold storage tube 300 is formed between the two rows of the refrigerant tubes 200, and the integrated tube 500 is the header. Incision grooves 510 may be formed at both ends to be inserted and coupled to the communication hole 140 formed in the tank 100.

This is formed as an integral tube 500 so that the cold storage tube 300 is disposed between the two rows of refrigerant tubes 200 as shown in FIG. 7 and cutout grooves 510 are formed at both ends of the refrigerant header tank 110. It is formed so as to be inserted into each of the communication hole 140 and the communication hole 140 of the cold storage header tank 120, the integral tube 500 between the pair of header tank 100 is arranged up and down 1 Can be combined thermally.

Therefore, as compared with the two rows of refrigerant tube 200 and the first row of cold storage tube 300 to the header tank 100, when fabricated as an integral tube 500 can be assembled to the header tank 100 very easily.

At this time, the integral tube 500 may be manufactured by extrusion molding the refrigerant tube 200 and the cold storage tube 300 in one piece, the integral tube 500 is both ends of the pair of header tank (100). After the insertion is coupled through brazing may be coupled to prevent the leakage of the heat exchange medium and the coolant.

In addition, the refrigerant header tank 110 and the cold storage header tank 120 may be formed to be spaced apart from each other as shown in FIG. 8.

In addition, the cold storage heat exchanger 1000 formed as described above further includes a pump 600 and a reservoir 700 connected to the cold storage header tank 120, and the cold storage material is the cold storage header tank 120 and the cold storage. It can be configured to circulate along the tube 300.

This is provided with a pump 600 capable of circulating the cold storage material separately and the reservoir 700 for storing the cold storage material on the outside of the cold storage heat exchanger 1000, as shown in FIG. 9, one side of the one cold storage header tank 120 It is configured to be connected to the pump 600 to the pipe 900 and the reservoir 700 to the pipe 900 on one side of the other heat storage header tank 120. Thus, the coolant is circulated to the reservoir 700 through the reservoir 700, the pump 600, the coolant header tank 120, and the coolant tube 300, so that the amount of coolant increases and the engine is stopped. Even the indoor air of the vehicle can be cooled for a long time.

In this case, the pump 600 may be connected to the control unit 800 to control the circulation of the cool storage material through the control unit 800. That is, when the temperature inside the vehicle is maintained at an appropriate temperature, the pump 600 is operated to circulate the cold storage material to store cold air in a large amount of cold storage material stored in the reservoir 700, and to lower the temperature inside the vehicle. At this time, the operation of the pump 600 is stopped to prevent the coolant from being circulated, so that the coolant of the coolant tube 200 is not absorbed by the coolant, so that the temperature inside the vehicle can be lowered in a short time.

And the cold storage heat exchanger 1000 of the present invention is a refrigerant header tank 110 is formed in two rows, the refrigerant flows, a pair of header tank 100 is formed side by side spaced apart a certain distance; Formed at both ends of the header tank 100 to communicate with the refrigerant header tanks 110 in two rows, the inlet manifold 160 through which the refrigerant is introduced and the outlet manifold 170 through which the refrigerant is discharged; A plurality of refrigerant tubes 200 connected at both ends to the refrigerant header tanks 110 in two rows spaced apart from each other by a predetermined distance; And a cold storage tube 300 provided between the two rows of refrigerant header tanks 110 to store the coolant therein. . ≪ / RTI >

This configuration is similar to the above-described embodiment, but as shown in FIGS. 10 and 11, the cool storage header tank 120 is not formed in the header tank 100 but is formed of only two coolant header tanks 110. The refrigerant tube 200 is coupled to the refrigerant header tank 110 in two rows. In addition, the cold storage tube 300 is provided between the coolant tubes 200 in the two rows, and the coolant is stored in the cold storage tube 300. At this time, the cold storage tube 300 is configured to be coupled to both sides in contact with the refrigerant tube 200 of the two rows to absorb the cold air. That is, both ends of the refrigerant tube 200 are connected to the refrigerant header tank 110 to allow the heat exchange medium to flow therein, but the cold storage tube 300 is formed in a pack shape in which both ends are blocked to store the coolant therein. It is formed to be.

Thus, since the cold storage tube 300 in which the cold storage material is stored is formed in a pack shape, since the cold storage header tank 120 is formed in the header tank 100 and the cold storage tube 300 is not connected, the configuration is simple, and the cold storage tube There is an advantage of easy assembly and replacement of 300.

In this case, the two rows of refrigerant header tank 110 may be formed to be spaced apart from each other by a predetermined distance. The two rows of refrigerant header tanks 110 are formed separately, and are configured to be spaced apart by a predetermined distance in the width direction, and the two rows of refrigerant header tanks 110 are integrally end caps 150 or manifolds 160 and 170 at ends. It can be fixed and communicating by combining.

Thus, since the two rows of refrigerant header tanks 110 are configured to be spaced apart by a predetermined distance, the two-layer heat exchanger is manufactured to be assembled so that the pack-type storage cooling tube 300 is coupled between the refrigerant tubes 200, and the refrigerant header tank ( Combination of the end cap 150 or the manifolds 160 and 170 at both ends of the 110 may be manufactured as one cold storage heat exchanger. In addition, since the two rows of refrigerant header tank 110 is configured to be spaced apart by a predetermined distance, the two rows of refrigerant header tank condensed water generated on the surfaces of the refrigerant tube 200 and the cold storage tube 300 during heat exchange ( It can be discharged between 110) has the advantage of easy discharge of condensate.

In addition, two rows of refrigerant header tanks 110 formed at an upper portion of the pair of header tanks 100 are larger than two rows of refrigerant header tanks 110 formed at a lower portion thereof, and thus, two rows of refrigerants formed at the lower portions thereof. The header tank 110 may be formed to be spaced apart by a predetermined distance in the width direction.

Since the condensate generated as shown in FIG. 12 is discharged toward the refrigerant header tank 110 configured at the lower portion, the two rows of the refrigerant header tank 110 configured at the upper portion are formed integrally and are largely formed to store and flow therein. It is possible to increase the amount of heat exchange medium being. Therefore, it is possible to reduce the flow resistance of the heat exchange medium flowing through the inside of the refrigerant header tank (110). In addition, since the refrigerant header tank 110 is configured to be spaced apart from a predetermined distance, it is possible to replace and assemble the cold storage tube 300 formed in the form of a pack therebetween.

In addition, the coolant storage container 310 coupled to the lower side of the two-row refrigerant header tank 110 is formed in the lower portion is connected to the lower end of the cold storage tube 300 is made, the coolant storage container ( 310 may be formed with a condensate discharge hole 311 penetrating up and down. That is, as shown in FIG. 13, the storage material storage container 310 is formed in the longitudinal direction such that both sides are coupled to the lower side of the two rows of the refrigerant header tanks 110 formed in the lower portion, and the cooling tube 300 has a lower end thereof. Is connected to the storage coolant storage container 310, a plurality of discharge holes 311 are formed in the storage coolant storage container 310 to penetrate up and down to discharge the condensate generated. Thus, a large amount of the cold storage material can be stored in the cold storage material storage container 310 can store a lot of cold air. In addition, the coolant may be cooled by condensed water flowing around the coolant storage tank 310, and thus the coolant efficiency may be further improved.

In addition, the manifolds 160 and 170 or the end caps 150 may be provided with a cold storage tube support 320 coupled to the cold storage tube 300.

In this case, as shown in FIG. 14, the storage tube support part 320 is formed long or the lower header tank is coupled to both ends of the inlet manifold 160 and the outlet manifold 170 formed at both ends of the upper header tank 100. The cold storage tube support part 320 may be formed to have a long length so that both ends are coupled to a pair of integrated end caps 150 formed at both ends of the 100, and the cold storage tube support part 320 is the cold storage tube 300. It may be combined with and to serve to support the cold storage tube (300).

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: cold storage heat exchanger (of the present invention)
100: Header tank
110: refrigerant header tank 120: cold storage header tank
130: baffle 140: communication hole
150: end cap 151: coolant injection portion
160: inlet manifold
170: exit manifold
200: Refrigerant tube
300: cold storage tube
310: cold storage container 311: discharge hole
320: cold storage tube support
400: pin
500: integral tube 510: incision groove
600: Pump
700: Reservoir
800:
900: Piping

Claims (9)

The first row and the third row are partitioned by partitions so that the coolant header tank 110 through which the coolant flows is formed, and the second row therebetween is partitioned by partitions to form the cool storage header tank 120 in which the coolant is stored. A pair of header tanks 100 spaced apart from each other by a predetermined distance;
Is formed at both ends of the header tank 100 to communicate with the refrigerant header tanks 110 in the first and third rows, the inlet manifold 160 through which the refrigerant is introduced and the outlet manifold 170 through which the refrigerant is discharged. );
A plurality of refrigerant tubes 200 connected at both ends to the refrigerant header tanks 110 in the first and third rows formed to be spaced apart from each other by a predetermined distance; And
A plurality of cold storage tubes (300) having both ends connected to the second cold storage header tank (120) formed to be spaced apart at a predetermined distance, and storing the cold storage material; A cold storage heat exchanger comprising a.
The method of claim 1,
The coolant tube 200 and the cold storage tube 300 are formed as an integrated tube 500, and the coolant tube 300 is formed between the two rows of the coolant tubes 200.
The integrated tube 500 is a cold storage heat exchanger, characterized in that the incision grooves (510) are formed at both ends to be inserted and coupled to the communication hole 140 formed in the header tank (100).
3. The method according to claim 1 or 2,
The cold storage heat exchanger further includes a pump 600 and a reservoir 700 connected to the cold storage header tank 120, and the cold storage material is circulated along the cold storage header tank 120 and the cold storage tube 300. Cold storage heat exchanger.
The refrigerant header tank 110 is formed in two rows, and the refrigerant flows, and the pair of header tanks 100 are formed to be spaced apart by a predetermined distance from each other;
Formed at both ends of the header tank 100 to communicate with the refrigerant header tanks 110 in two rows, the inlet manifold 160 through which the refrigerant is introduced and the outlet manifold 170 through which the refrigerant is discharged;
A plurality of refrigerant tubes 200 connected at both ends to the refrigerant header tanks 110 in two rows spaced apart from each other by a predetermined distance; And
A refrigeration tube (300) provided between the two rows of refrigerant header tanks (110) to store the coolant; A cold storage heat exchanger comprising a.
5. The method of claim 4,
The two rows of refrigerant header tank 110 is a cold storage heat exchanger, characterized in that formed in the width direction spaced apart from each other.
5. The method of claim 4,
Two rows of refrigerant header tanks 110 formed at an upper portion of the pair of header tanks 100 are larger than two rows of refrigerant header tanks 110 formed at a lower portion of the pair of header tanks 100, and thus, two rows of refrigerant header tanks are formed at the lower portion of the pair of header tanks 100. Cold storage heat exchanger, characterized in that the 110 is formed to be spaced apart a certain distance in the width direction.
The method according to claim 6,
The heat storage material storage container 310 coupled to the lower side of the two-row refrigerant header tank 110 formed in the lower portion is connected to the lower end of the cold storage tube 300, the storage material storage container 310 The cold storage heat exchanger, characterized in that the condensate discharge hole 311 penetrates up and down.
5. The method of claim 4,
The manifold (160, 170) on the opposite side of the header tank (100) formed cold storage heat exchanger, characterized in that the integral end cap 150 is coupled to the end.
9. The method of claim 8,
The manifold (160, 170) or the end cap 150, the cold storage heat exchanger, characterized in that the cold storage tube support 320 is coupled to the cold storage tube (300) is formed.

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