KR20130083600A - Cryocooler type freezer - Google Patents

Abstract

The present invention relates to a refrigerator of a single stage compression type having a double tube heat exchanger having a corrugated pipe located therein.
The single stage compression type refrigerator having the double tube heat exchanger of the present invention is a corrugated tube formed by spirally winding the inner tube located in the outer tube of the double tube heat exchanger so that bends are formed on the inner side and the outer side.
Therefore, the heat exchange efficiency in the double tube heat exchanger is very excellent, the energy efficiency is very excellent.

Description

Single stage compression freezer having double tube heat exchanger with corrugated pipe inside {CRYOCOOLER TYPE FREEZER}

The present invention relates to a cryocooler type refrigerator for cooling a refrigerant to a predetermined temperature by using one compressor.

There are various types of refrigerators, which are referred to as a two-stage compression method when two compressors are provided in the refrigerator, and a single-stage compression method when one compressor is used.

Korean Patent Application No. 10-2011-7012681 discloses a freezing structure of a single stage compression type.

The single stage compression type refrigerator is used to perform cryogenic freezing at a temperature of minus 150 ° C to 160 ° C using a mixed refrigerant in which various kinds of refrigerants having different evaporation temperatures are mixed.

Further, the gas compressed by the compressor passes through the oil separator, the oil is removed, the oil is passed through the water-cooled condenser, and the moisture is removed via the filter dryer.

In addition, the refrigerant passing through the filter dryer is cooled to a cryogenic state of minus 150 ° C to 160 ° C by being cooled while passing through a plurality of pipes through a double tube heat exchanger.

However, the conventional single stage compression type refrigerator has a problem of consuming a lot of energy to obtain a refrigerant for cooling in a cryogenic state of about minus 150 ℃ to 160 ℃.

Korean Patent Application No. 10-2011-7012681

The present invention is to solve the above problems, and more particularly, to provide a refrigeration unit of a single stage compression type with excellent energy efficiency.

In the present invention, by implementing the inner tube of the double tube heat exchanger for cooling the refrigerant in the single stage compression type refrigerator as a corrugated pipe to improve the heat exchange efficiency in the double tube heat exchanger to improve the energy efficiency.

The refrigerator of the present invention is a single-stage compression type refrigerator having a double tube heat exchanger, and the inner tube located in the outer tube of the double tube heat exchanger is a corrugated tube formed by spirally wound to form a bend on the inner side and the outer side. .

In the refrigerator of the present invention, since the inner tube of the double tube heat exchanger for cooling the refrigerant in the single stage compression type freezer is implemented as a corrugated pipe, the heat exchange efficiency in the double tube heat exchanger is very excellent and the energy efficiency is very excellent.

In addition, a plurality of double pipe heat exchangers are provided, a gas-liquid separator is located between any one of the double pipe heat exchangers and the other of the double pipe heat exchangers, and the refrigerant passing through the compressor and the condenser sequentially is either one of the double pipe heat exchangers. After passing through the gas, the liquid and gas are separated through the gas-liquid separator, and the liquid separated from the gas-liquid separator is sent to the double-tube heat exchanger to cool the double-pipe heat exchanger, and the liquid separated from the gas-liquid separator is separated from the gas-liquid separator. In case of cooling by way of another double tube heat exchanger which is cooled by, the energy efficiency is very excellent in the structure using the mixed refrigerant.

In addition, the double tube heat exchanger that is not cooled by the liquid separated from the gas-liquid separator is more energy efficient when a part of the refrigerant via the corresponding double tube heat exchanger is supplied to the corresponding double tube heat exchanger to be cooled. There is a characteristic.

1 is a schematic diagram for explaining a single stage compression type refrigerator having a double tube heat exchanger having a corrugated pipe of the present invention located therein;
2 is a schematic view for explaining the shape of the dual pipe type heat exchanger of the present invention

Hereinafter, the technical idea of the present invention will be described more specifically with reference to the accompanying drawings.

It is to be understood, however, that the appended drawings illustrate only typical embodiments of the present invention and are not to be considered as limiting the scope of the invention.

The present invention relates to a single stage compression refrigerator having a dual tube heat exchanger.

However, the present invention has an object to provide a single stage compression refrigerator excellent in energy efficiency.

To this end, in the present invention, the inner tube (10b) located in the outer tube (10a) of the double tube heat exchanger (10) in the refrigerator of the single stage compression type is a corrugated tube formed by spirally wound to form a bend on the inner and outer surfaces Be sure to

Of course, the outer pipe 10a and the inner pipe 10b of the double pipe type heat exchanger 10 are preferably made of a metal having excellent heat exchange efficiency, particularly a copper pipe or the like.

The corrugated tube formed by spirally winding the inner and outer sides to form a bend is used in various industrial fields.

Since the corrugated tube has a curvature formed on the inner side surface and the outer side surface, the heat exchange efficiency is improved due to the increase of the heat exchange area.

In the single-stage compressing refrigerator according to the present invention, the heat exchange efficiency of the dual-tubular type heat exchanger 10 is improved, leading to an improvement in energy efficiency.

The refrigerator of the present invention may be provided with a plurality of double tube heat exchangers as shown in FIG.

In addition, the gas-liquid separator may be positioned between one double tube heat exchanger and the other double tube heat exchanger.

In this case, the refrigerant passing through the compressor and the condenser sequentially may be separated into a liquid and a gas while passing through any one of the double tube heat exchangers and then through the gas-liquid separator.

In addition, the liquid separated from the gas-liquid separator is sent to the double tube heat exchanger to cool the double tube heat exchanger, and the liquid separated from the gas-liquid separator can be cooled while passing through another double tube heat exchanger which is cooled by the liquid separated from the gas-liquid separator. In this case the energy efficiency is even better.

Also, in the structure as described above, the double tube heat exchanger that is not cooled by the liquid separated in the gas-liquid separator as shown in FIG. 1 is passed through the corresponding double tube heat exchanger (double tube heat exchanger that is not cooled by the liquid separated in the gas-liquid separator). A portion of the refrigerant can be fed back to the corresponding double tube heat exchanger to allow for cooling to further improve energy efficiency.

In the attached refrigerator of FIG. 1, the double tube heat exchanger 10 includes a first double tube heat exchanger 11, a second double tube heat exchanger 12, a third double tube heat exchanger 13, a fourth double tube heat exchanger 14, It is divided into a fifth double tube heat exchanger (15).

In addition, a refrigerant flows through the inner tube (10b) of the first double tube heat exchanger (11) via the compressor (20) and the condenser (30), and separates the refrigerant into a liquid and a gas. The first gas-liquid separator 41 is supplied to the outer tube 10a of the second double tube heat exchanger 12 and the separated gas refrigerant is supplied to the inner tube 10b of the second double tube heat exchanger 12. .

The refrigerant passing through the inner tube 10b of the second double tube heat exchanger 12 is separated into a liquid refrigerant and a gas refrigerant, and the separated liquid refrigerant is transferred to the outer tube 10a of the third double tube heat exchanger 13. The gas refrigerant supplied and separated has a second gas-liquid separator 42 which supplies the inner tube 10b of the third double tube heat exchanger 13.

The refrigerant passing through the inner tube 10b of the third double tube heat exchanger 13 is separated into a liquid refrigerant and a gas refrigerant, and the separated liquid refrigerant is transferred to the outer tube 10a of the fourth double tube heat exchanger 14. The gas refrigerant supplied and separated has a third gas-liquid separator 43 for supplying the inner tube 10b of the fourth double tube heat exchanger 14.

The refrigerant passing through the inner tube 10b of the fourth double tube heat exchanger 14 passes through the inner tube 10b of the fifth double tube heat exchanger 15. Part of the refrigerant via the inner tube (10b) is supplied to the outer tube (10a) of the fifth double tube heat exchanger (15), and part of the fourth double tube type heat exchanger (14), the third double tube heat exchanger via the cooling zone. (13), the second double tube heat exchanger 12 and the first double tube heat exchanger 11 are supplied to the compressor 20.

The structure as shown in FIG. 1 is not only very excellent in energy efficiency but also very effective in cooling using a mixed refrigerant in which various refrigerants having different evaporation temperatures are mixed.

For example, the refrigerant liquefied in the first gas-liquid separator 41 is R-22, R-123, R-24, and the refrigerant liquefied in the second gas-liquid separator 42 is R-23, R-. 116, the refrigerant liquefied in the third gas-liquid separator (43) is R-14, R-23, R-116, and the liquefied refrigerant via the inner tube (10b) of the fifth double tube heat exchanger (15) By argon (Ar) it is possible to cool the space for cooling in a cryogenic state of about 150 ℃ to 160 ℃.

Reference numeral 50 denotes an expansion tank, reference numeral 60 denotes a oil separator for removing oil contained in the refrigerant, and reference numeral 70 denotes a filter dryer.

10. Double pipe heat exchanger
10a. Inner tube
10b. Outer tube
11. The first dual tube heat exchanger
12. The second dual tube heat exchanger
13. Third double tube heat exchanger
14. Fourth Duct Eutectic Exchanger
15. Fifth Double Tube Heat Exchanger
20. Compressor
30. Condenser
41. The first gas-liquid separator
42. Second gas-liquid separator
43. Third gas liquid separator
50. Expansion tank
60. Oil separator
70. Filter trailer

Claims (4)

In the single stage compression type refrigerator having a double tube heat exchanger,
The inner tube located in the outer tube of the double tube heat exchanger is a corrugated tube formed by spirally wound so that a bend is formed on the inner side and the outer side of the double tube heat exchanger. Freezer.
The method of claim 1,
The double pipe heat exchanger is provided with a plurality,
A gas-liquid separator is located between one double tube heat exchanger and the other double tube heat exchanger.
The refrigerant passing through the compressor and the condenser in sequence is separated through the gas-liquid separator and then separated into liquid and gas via any one of the double tube heat exchangers.
The liquid separated in the gas-liquid separator is sent to a double tube heat exchanger to cool the double tube heat exchanger, and the liquid separated in the gas-liquid separator is cooled while passing through another double tube heat exchanger which is cooled by the liquid separated in the gas-liquid separator. A refrigerator having a single stage compression type having a double tube heat exchanger having a corrugated pipe located therein.
The method of claim 2,
The double tube heat exchanger which is not cooled by the liquid separated in the gas-liquid separator is characterized in that a part of the refrigerant via the corresponding double tube heat exchanger is supplied to the corresponding double tube heat exchanger to cool the corrugated pipe. A single stage compressor having a double tube heat exchanger located therein.
The method of claim 1,
The double pipe heat exchanger is divided into a first double pipe heat exchanger, a second double pipe heat exchanger, a third double pipe heat exchanger, a fourth double pipe heat exchanger, and a fifth double pipe heat exchanger.
The refrigerant flows through the inner tube of the first double tube heat exchanger via the compressor and the condenser, separates the refrigerant into liquid and gas, and supplies the separated liquid refrigerant to the outer tube of the second double tube heat exchanger and separates the gas. The refrigerant is the first gas-liquid separator for supplying the inner tube of the second double tube heat exchanger;
The refrigerant passing through the inner tube of the second double tube heat exchanger is separated into a liquid refrigerant and a gas refrigerant, and the separated liquid refrigerant is supplied to the outer tube of the third double tube heat exchanger, and the separated gas refrigerant is supplied to the third double tube heat exchanger. A second gas-liquid separator supplied to the inner tube;
The refrigerant passing through the inner tube of the third double tube heat exchanger is separated into a liquid refrigerant and a gas refrigerant, and the separated liquid refrigerant is supplied to an outer tube of the fourth double tube heat exchanger, and the separated gas refrigerant is supplied to the fourth double tube heat exchanger. A third gas-liquid separator supplied to the inner tube;
The refrigerant passing through the inner tube of the fourth double tube heat exchanger is configured to pass through the inner tube of the fifth double tube heat exchanger, and a part of the refrigerant passing through the inner tube of the fifth double tube heat exchanger is external to the fifth double tube heat exchanger. Corrugated pipe, characterized in that to be supplied to the compressor after passing through the fourth cooling pipe, the third double pipe heat exchanger, the third double pipe heat exchanger, the second double pipe heat exchanger, the first double pipe heat exchanger via the cooling zone. A single stage compression type refrigerator having a double tube heat exchanger located therein.

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