KR19990001053A - Evaporator of cooling system - Google Patents

Abstract

The present invention discloses an improved rollbond evaporator of a cooling system.

In the related art, since the refrigerant flow path was sequentially configured in a zigzag form, there was a problem in that a temperature difference was large between the upper and lower portions of the product cavity and a separate accumulator was provided in the cooling system for filtration of liquid refrigerant.

In the present invention, the film is printed between two aluminum sheets in a predetermined shape, and the two sheets are bonded by hot rolling, and then a high pressure is blown into the film printing portion to expand and form a refrigerant flow path through which the refrigerant flows between the two sheets. In a roll bond evaporator of a cooling system installed to enclose a cavity of a product to be stored, refrigerant flows into one of the upper, lower, left, and right sides and alternately proceeds inwardly between the opposite sides, and then at approximately the middle of both sides. The refrigerant flow passage is configured to flow out, and the refrigerant flows into the lower side of the refrigerant flow passage to form a constant volume of liquid separation unit which flows through the upper side to minimize the temperature deviation between the upper and lower portions of the cavity and separate the cooling system. The use of accumulators was ruled out.

Description

Evaporator of cooling system

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cooling system, and more particularly, a roll used to vaporize a liquid refrigerant by heat exchange with air, which is employed in a food storage for properly aging and storing food such as a refrigerator or kimchi. It relates to a roll bond type evaporator.

As is well known, a cooling system is an air conditioner that performs a predetermined function by cooling or freezing ambient air by using a change in state of a refrigerant, and a schematic configuration thereof will be described with reference to FIG. 1.

In FIG. 1, the refrigerant gas compressed to a high pressure in a compressor (P) is liquefied by heat exchange with air while passing through a condenser (C), and after passing through a filter dryer (D), impurities, etc. Filtered The high temperature liquid refrigerant changes to low pressure through an expansion valve (V) and then cools the outside air by evaporation by heat exchange with the outside air while passing through the evaporator (E). The vaporized vapor refrigerant flows back into the compressor P and circulates in the aforementioned cycle.

As such, the cooling system performs its function by the heat of vaporization of the refrigerant, and the cooling performance is highly dependent on the heat exchange efficiency of the evaporator (E).

Fig. 2 schematically shows a conventional roll bond evaporator 1 for this purpose, which prints a film in a predetermined shape between two aluminum sheets 2 to hot rolling the two aluminum sheets 2. After adhering to each other, the refrigerant passage 3 is constituted by blowing high pressure into the film printing portion to expand.

However, such a conventional roll bond evaporator 1 has a structure in which the refrigerant flow passage 3 has a predetermined direction, for example, a zigzag form which sequentially progresses from the top to the bottom as shown in the figure. Cavity A large temperature difference occurs between the upper and lower parts. That is, when the refrigerant absorbs heat from the outside air and evaporates, the pressure increases, so that the evaporation efficiency gradually decreases as the refrigerant flows to the outlet side, thereby increasing the temperature difference between the upper and lower parts of the cavity. Accordingly, there is a problem that the food such as kimchi stored in the cavity is refrigerated unevenly and the taste varies depending on its location.

On the other hand, the refrigerant must be sufficiently condensed below the pressure set in the condenser C in order to surely evaporate in the evaporator 1, which is dependent on the temperature of the outside air. . In this case, the vapor refrigerant passing through the evaporator (1) is included in the evaporation poor liquid refrigerant to cause damage to the compressor (P) by the liquid compression, the conventional roll bond evaporator (1) is simply a refrigerant flow path (3) Since only the liquid refrigerant can not be filtered when the efficiency of the evaporator 1 is maximized, a separate accumulator (A) is provided immediately before the compressor P, as shown by the dotted line in FIG. 1 to filter the liquid refrigerant. As a result, the configuration of the cooling system was complicated and caused a cost increase. In addition, when the amount of refrigerant that contributes to cooling is reduced to prevent liquid refrigerant, the efficiency of the cooling system is reduced by the amount of refrigerant, which reduces the performance of the cooling system. As a result, the actual evaporation area that contributes to the refrigerant evaporates is relatively reduced. There was a problem that would result.

SUMMARY OF THE INVENTION An object of the present invention is to provide an evaporator of a cooling system capable of uniformly cooling a stored product on the entire cavity by reducing the temperature deviation generated between the opposite sides of the product in consideration of the above-described conventional problems.

Another object of the present invention is to provide an evaporator of a cooling system capable of reliably evaporating a liquid refrigerant regardless of the amount of refrigerant and its condensation pressure, thereby improving cooling characteristics and thus eliminating a separate accumulator in the cooling system.

It is another object of the present invention to reduce the temperature deviation generated between the opposite sides of the product as much as possible to cool the stored product evenly over the entire cavity, while evaporating the liquid refrigerant regardless of the condensation pressure of the refrigerant to separate the cooling system separately It is to provide an evaporator of the cooling system that can eliminate the accumulator of.

In order to achieve these objects, the evaporator of the cooling system according to the present invention prints a film in a predetermined shape between two aluminum sheets, bonds the two sheets by hot rolling, and expands the two sheets by blowing high pressure into the film printing portion. In the roll bond evaporator of a cooling system formed by forming a refrigerant flow path through which a refrigerant flows, and enclosing a cavity of a product in which food is stored, the refrigerant flows into one of the upper, lower, left, and right sides, and the inner side is opposed to the opposite side. Afterwards, the refrigerant flow passage is configured so as to flow out from the substantially middle portions of both sides.

According to one preferred feature of this invention, the volume of the refrigerant passage is configured to increase gradually as it proceeds to the outlet side.

In addition, the roll bond evaporator of the cooling system according to the present invention, after printing the film in a predetermined shape between the two aluminum sheets to bond the two sheets by hot rolling, by blowing a high pressure to the film printing portion to expand the refrigerant flow between the two sheets In a roll bond evaporator of a cooling system formed by forming a coolant flow path and enclosing a cavity of a product in which food is stored, the coolant flows into a lower portion of the coolant flow path and flows through the upper side. Characterized in that the liquid separation unit is configured integrally.

Accordingly, the present invention can reduce the temperature difference between the upper and lower parts of the product to a minimum, thereby allowing the stored food to be refrigerated uniformly and contributing to the cooling of all the refrigerant, thereby eliminating the need for a separate accumulator in the cooling system. It is very effective in improving system performance, reliability, and cost.

1 is a schematic view showing a general cooling system,

Figure 2 is a schematic exploded view of a conventional roll bond evaporator,

3 is a development view showing a roll bond evaporator according to the present invention,

4 is a partially enlarged plan view showing a coupling state thereof;

5 is a cross-sectional view taken along the line VV of FIG. 3;

6 is a cross-sectional view taken along the VI-VI line of FIG.

7 is a cross-sectional view taken along the line VII-VII of FIG. 3,

8 is a cross-sectional view taken along the line VII-VII of FIG. 3,

Figure 9 is a schematic cross-sectional view showing a food storage equipped with a roll bond evaporator of the present invention.

* Explanation of symbols for the main parts of the drawings *

11: roll bond evaporator

12: two aluminum sheets (of rollbond evaporator)

13 refrigerant flow path (of roll bond evaporator) 19 liquid separation unit (of roll bond evaporator)

20: food storage 21: (of food storage)

22: door 24: inner container

25: (cavity) cavity

Such specific features and other advantages of the present invention will become more apparent from the following description of the preferred embodiments with reference to the accompanying drawings.

3 to 9, the roll bond evaporator 11 of the cooling system according to the present invention prints a film (not shown) in a predetermined shape between two aluminum sheets 12 so that the two sheets 12 are hot rolled. After adhering to each other, the film printing portion is formed by blowing a high pressure to form a refrigerant passage 13 through which the refrigerant flows. The roll bond evaporator 11 is mainly used for a product having a storage cavity such as a small refrigerator or a show case. Hereinafter, the applicant's previously-applied food reservoir used for properly aging and storing food such as kimchi ( 20) will be described as an example.

As shown in FIG. 9, the food storage 20 includes a main body 21 having a food storage cavity therein and a door 22 that opens and closes the cavity 25. The main body 21 forms the outer container 23 so as to surround it outside of the inner container 24 constituting the cavity 25, and then fills the insulating material 26 therebetween. A condenser 28 is attached to the inner circumference of the outer container 23, and an evaporator 11 is attached to the outer circumference of the inner container 24, respectively, and driven by the compressor 27 to cool the cavity 25. The lower portion of the) is provided with a heater (29) for selectively heating the cavity 25 to properly heat and mature the food stored in the cavity 25, and then refrigerated.

Accordingly, the roll bond evaporator 11 of the present invention has a plurality of slots 12a formed at one end of the roll bond evaporator 11, and a plurality of fixing pieces 12b are lancing processed at the other end of the roll bond evaporator 11. It is formed to pass through each of the fixing piece (12b) to the corresponding slot (12a) and is installed to surround the outer periphery of the inner container 24 by banding (banding).

The refrigerant passage 13 is preferably formed to have a substantially elliptical cross section for easy heat transfer of the evaporator 11. That is, since the refrigerant passage 13 is advantageous in heat transfer, it is advantageous for heat transfer to contact the outer periphery of the inner container 24 constituting the cavity 25 to the largest possible area, as shown in FIGS. 6 to 8. It is configured to have an elliptical cross section to increase the area.

However, the roll bond evaporator 11 is connected to the condenser 28 and the compressor 27 through the conduit 30, and the refrigerant inlet 13a and the outlet 13b are conduits as shown in FIG. 5. It is formed to have a circular cross section for coupling with (30).

Meanwhile, the lower the pressure is, the better the evaporation of the refrigerant is, and thus, the refrigerant passage 13 of the roll bond evaporator 11 of the present invention is preferably configured to have a larger volume than the conduit 30 connecting to the condenser 28. . In this case, however, deformation of the bending portion 13d positioned at the corner portion of the inner container 24 is greatly generated, thereby inhibiting the smooth flow of the refrigerant. Accordingly, the bending portion 13d of the refrigerant passage 13 is preferably configured to be a semicircle of a circular type relatively smaller than the straight portion 13c corresponding to each surface of the cavity 25. Such a bending portion 13d also serves to induce good evaporation at each site by repeatedly dropping the pressure of the refrigerant raised by evaporation.

The refrigerant flow passage 13 is composed of a plurality of rows (14 to 18) are arranged side by side and connected in parallel with each other, after the refrigerant is introduced into either column (14 or 18) according to the characteristics of the present invention It is configured to flow alternately inwardly between these opposite rows 18 or 14 and out through the rows 16 located in the middle of both sides. That is, when the refrigerant passage 13 consists of five rows in the horizontal direction as shown in FIG. 3, the refrigerant flows into, for example, the first row 14 on the uppermost side and passes the second row 15 directly below. After the fifth row 18 on the lowermost side, it passes through the fourth row 17 of the upper portion and flows out through the third row 16, which is an intermediate row.

Accordingly, the roll bond evaporator 13 of the present invention hardly generates a temperature deviation between the upper and lower portions of the cavity 25, so that the food stored in the cavity 25 can be refrigerated uniformly on all of them. That is, when the refrigerant absorbs heat from the outside and evaporates, the pressure gradually increases, and the evaporation effect gradually decreases toward the outlet side of the refrigerant passage 13. In the conventional art, the refrigerant flows through each row 14 to 18 of the refrigerant passage 13. In the evaporator 11 of the present invention, the refrigerant flows alternately between the upper and lower portions of the cavity 25 opposite to the inflow side and the opposite side, because the temperature difference is generated between the upper and lower portions of the cavity 25 sequentially. Since the outflow in the middle of the temperature difference between the upper and lower parts of the cavity 25 is to be minimum.

In addition, since the temperature distribution of the cavity 25 is the highest on the door 22 side, a large evaporation effect is required, and thus, the roll bond evaporator 11 of the present invention is preferable, and the inflow side of the refrigerant passage 13 is the food storage 20. On the door 22 side. Accordingly, the most active refrigerant is evaporated at the opening side of the cavity 25 so that the temperature distribution is as uniform as possible on the whole.

On the other hand, in order for the refrigerant to evaporate uniformly at the inflow and outflow sides of the refrigerant flow path 13, the refrigerant pressure between the two must be uniform. In order to get to the outlet side, the increased pressure as the refrigerant evaporates should be relatively decreased. Accordingly, the refrigerant passage 13 is preferably configured to gradually increase in volume toward the outlet side thereof.

According to this configuration, the roll bond evaporator 11 according to the present invention not only ensures a uniform and uniform evaporation between the inflow and outflow sides of the refrigerant flow passage 13, but also has the highest temperature distribution on the door 22 side cavity ( The cooling of 25 is properly compensated so that the temperature deviation between the upper and lower portions of the cavity 25 can be kept to a minimum.

On the other hand, when the condensation pressure of the refrigerant is high, evaporation defects are caused, and liquid refrigerants that cannot be vaporized in the vapor refrigerant are included. This may cause damage to the compressor and may cause instability of the system. Accordingly, in the outlet side of the refrigerant passage 13 of the roll bond evaporator 11 of the present invention, the liquid separator 19 having the refrigerant passing through the refrigerant passage 13 is introduced into the lower side and is discharged to the upper side according to another feature of the present invention. It is formed integrally. The liquid separation unit 19 is configured together to have an appropriate volume in the formation of the refrigerant passage 13.

Accordingly, the refrigerant passing through the refrigerant passage 13 enters the compressor 27 via the liquid separation unit 19. At this time, the liquid refrigerant remains in the lower portion of the liquid separation unit 19, and only the vapor refrigerant is used. The liquid separation unit 19 passes through the compressor 27. In this way, the liquid refrigerant remaining in the liquid separation unit 19 is in a state where the pressure is further reduced, whereby continuous heat exchange with the cavity 25 is performed to completely evaporate.

Therefore, the roll bond evaporator 11 of the present invention allows liquid refrigerant to completely evaporate in the evaporator 11 so that the entire refrigerant can contribute to the cooling, thereby not only bringing a relative increase effect of the evaporation area but also greatly improving the cooling performance. do. This makes it possible to exclude the use of a separate accumulator (P in FIG. 1) as in the conventional cooling system.

As described above, according to the present invention, it is possible to reduce the temperature deviation between the upper and lower portions of the product cavity to a minimum, thereby uniformly refrigerating the stored food. In addition, since the entire refrigerant is completely evaporated in the evaporator to contribute to the cooling, the same amount of refrigerant can further improve the cooling performance compared to the conventional one, and a separate accumulator like the conventional one is unnecessary in the cooling system.

Therefore, the present invention can greatly improve the performance and reliability of the cooling system, as well as having a very excellent effect of reducing the cost.

Claims (5)

The film is printed in a predetermined shape between the two aluminum sheets, and the two sheets are bonded by hot rolling, and then the high pressure is blown into the film printing portion to expand and form a refrigerant flow path through which the refrigerant flows between the two sheets. In the roll bond evaporator of the cooling system installed to surround the product cavity, Cooling characterized in that the refrigerant flow path 13 is configured so that the coolant flows into one of the upper, lower, left and right and alternately proceeds inwardly between the opposite sides thereof, and then flows out from approximately the middle of both sides. Evaporator of the system. The method of claim 1, Evaporator of the cooling system, characterized in that the volume of the refrigerant passage 13 is configured to increase gradually as it proceeds to the outflow side. The method according to claim 1 or 2, The bending portion 13d of the refrigerant passage 13 corresponding to the corner portion of the cavity 25 has a cross-sectional area relatively smaller than that of the straight portion 13c corresponding to each surface of the cavity 25. Evaporator of the cooling system, characterized in that. The method of claim 1, Evaporator of the cooling system, characterized in that the inlet side of the refrigerant is located toward the door (22) of the product. The film is printed in a predetermined shape between the two aluminum sheets, and the two sheets are bonded by hot rolling, and then the high pressure is blown into the film printing portion to expand and form a refrigerant flow path through which the refrigerant flows between the two sheets. In the roll bond evaporator of the cooling system installed to surround the product cavity, Evaporator of the cooling system, characterized in that the refrigerant flows into the lower side of the refrigerant flow path (13) is integrally formed with a constant volume of liquid separation unit (19) flowing out through the upper side.