KR20160104930A - Industrial-station air chiller and its cooling method - Google Patents

Abstract

The present invention relates to an industrial freezer using a gaseous refrigerant. The industrial freezer using a gaseous refrigerant comprises: a gaseous refrigerant regulator (42) to receive gas used as a secondary refrigerant to adjust an amount of the supplied secondary refrigerant; a first unidirectional check valve (44) to open to move the supplied gaseous refrigerant in one direction; a pressure gauge (45) to check a pressure of the supplied secondary refrigerant; a secondary refrigerant supply tube (48) to supply the supplied secondary refrigerant to a heat exchanger (52); a pump motor (46) for circulation to circulate the supplied gaseous refrigerant; a refrigerant supplying flexible hose (51) to supply the secondary refrigerant provided through the secondary refrigerant supply tube (48) to the heat exchanger (52); the heat exchanger (52) connected to an end of the refrigerant supplying flexible hose (51) and formed in a coil shape; a return tube (56) installed to discharge a refrigerant used in a chamber (30); and a second unidirectional check valve (54) which is installed in the return tube (56), and opens to move the used gaseous refrigerant in one direction.

Description

Technical Field [0001] The present invention relates to an industrial refrigerator and a refrigeration method using gas refrigerant,

BACKGROUND OF THE INVENTION 1. Field of the Invention [0002] The present invention relates to a refrigerator for cooling and providing a refrigerant, and more particularly, to an industrial refrigerator using a gas refrigerant that is cooled by charging a liquid into a conventional refrigerator in which a liquid refrigerant is introduced and cooled.

The configuration of a conventional refrigerant cooling apparatus will be described with reference to Figs. 1 and 2. Fig.

FIG. 1 is a block diagram showing a configuration and a principle of a general refrigerator, and FIG. 2 is a block diagram showing a configuration of a conventional refrigerator using liquid refrigerant.

As shown in Fig. 1, a conventional general refrigerator has a structure of a two-way freezer 10 having two compressors.

The structure of the conventional two-way freezer 10 includes first and second compressors 1 and 2 for cooling the refrigerant, and each of the compressors 1 and 2 supplies and replenishes the oil to the inner cylinder. The oil separator 3 connected to the second compressor 2 is connected to a condenser / condenser 4 which receives the cooling gas from the second compressor 2 to cool the oil separator 3, 1 compressor 1 discharges a refrigerant having a heat quantity to the heat exchanger 5 and supplies the refrigerant from the condenser 7 for cooling the heat to the blower fan 7a The refrigerant is supplied to the condenser 11 via the solenoid valve 9, cooled together with the refrigerant gas, and then supplied to the condenser 11 via the additional solenoid valve 9a. Reference numeral 6 denotes an expansion tank storing a cooling gas, and reference numeral 8 denotes a bypass valve for discharging and exchanging used gas.

Next, the configuration and operation of a refrigerator using a liquid refrigerant used conventionally will be described with reference to FIG. In FIG. 2, components of the refrigerator composed of 1 to 11 are the same, and the same reference numerals are given thereto, and a separate explanation will be omitted.

As shown in Fig. 2, there is used a refrigerator in which a liquid refrigerant is cooled by using a configuration of a basic two-way refrigerating machine. Such a liquid refrigerant freezer is constituted by adding a liquid coolant cooling portion 20 to the basic refrigerator structure shown in Fig.

The liquid coolant cooling unit 20 includes a conventional condenser 22, a liquid coolant reservoir 24 for storing liquid coolant, and a pumping motor 26 for circulating the cooled gas. In addition, the liquid coolant cooling unit 20 and the chamber are connected through a refrigerant supply / discharge hose (Inlet / Outlet Hose) 28.

The chamber 30 includes a chamber 30 for lowering the temperature by using a refrigerant connected to a pair of flexible hoses 32 connected to and connected to the refrigerant supply / discharge hose 28 do.

With this configuration, the cooled and condensed liquid refrigerant gas is introduced into the chamber mounted in the chamber 30 and cooled.

However, the inventors of the present invention have found that the following problems are continuously generated when a refrigerator using liquid refrigerant is used as described above.

First, the temperature of the chamber should be maintained at a low temperature by flowing the cooled refrigerant into the chamber 30. However, the characteristics of the liquid refrigerant used conventionally are such that the density (density) and viscosity (viscosity) are increased at a low temperature and the operation is not smooth due to the increased viscosity, thereby degrading the accuracy in operation.

Secondly, the cooled liquid refrigerant creates a gap in each hose portion connected at a low temperature, and there is a problem that much leakage occurs at the connection portion of the hose.

Third, when the liquid refrigerant leaking out through the gap formed at the hose connection portion evaporates, not only the harmful air pollution occurs in the human body but also the expensive liquid refrigerant must be continuously replenished to use it.

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a refrigerator using gas refrigerant by providing a refrigerant gas at a constant temperature and viscosity at all times.

In addition, the present invention provides a refrigerator using gas refrigerant that eliminates leakage of liquid refrigerant, prevents air contamination due to leakage, and eliminates unnecessary manufacturing cost by not using expensive liquid refrigerant. It is for that purpose.

It is another object of the present invention to provide an industrial refrigerator using gas refrigerant by thoroughly eliminating hardening of a hose caused by leakage of a liquid refrigerant and failure factors of other equipments.

The construction of an industrial refrigerator using gas refrigerant according to an embodiment of the present invention is as follows.

According to the configuration of the refrigerator using the gas refrigerant according to the present invention, the following effects can be obtained.

First, by providing the refrigerant gas to maintain a constant temperature and viscosity at all times, the operating accuracy can be maintained at a constant high quality.

In addition, according to the structure of the present invention, leakage of liquid refrigerant can be removed, air contamination can be prevented, and unnecessary waste of manufacturing cost can be eliminated by not using expensive liquid refrigerant .

In addition, the hardening of the hose caused by the leakage of the liquid refrigerant and the failure factors of other equipments are thoroughly removed, so that the downtime of the equipment can be minimized and the productivity can be improved.

1 is a block diagram showing a general refrigerator,
2 is a block diagram showing a configuration of a conventional refrigerator using liquid refrigerant,
3 is a block diagram illustrating a configuration of a refrigerator using a gas refrigerant according to a preferred embodiment of the present invention.

The present invention as described above is a refrigerator for cooling a chamber provided with a refrigerator having a normal cooling function, comprising: a gas refrigerant regulator for receiving a gas used as a secondary refrigerant and adjusting an amount of a secondary refrigerant supplied; (42); A first unidirectional check valve (44) provided at a rear end of the gas refrigerant regulator (42) for opening the supplied gas refrigerant so as to proceed in one direction; A pressure gauge 45 installed at a rear end of the unidirectional check valve 44 for checking the pressure of the supplied secondary refrigerant; A secondary refrigerant supply tube 48 provided at the rear end of the pressure gauge 45 for supplying the supplied secondary refrigerant to the heat exchanger 52; A circulation pump motor 46 installed in the secondary refrigerant supply tube 48 for circulating the supplied gas refrigerant; A flexible hose 51 for supplying refrigerant to the heat exchanger 52 to supply the secondary refrigerant provided through the secondary refrigerant supply tube 48; A heat exchanger 52 connected to the end of the flexible hose 51 for supplying refrigerant and formed in a coil shape to enhance the cooling function by increasing the refrigerant supply path and providing the cooled refrigerant to the chamber 34, ; A return tube 56 installed to discharge the refrigerant used in the chamber 30; And a second unidirectional check valve (54) installed in the return tube (56) and opening the used gas refrigerant to proceed in one direction.

At this time, it is preferable that the secondary refrigerant supply tube or the flexible hose for supplying the refrigerant or the return tube is made of a silicone material having elasticity.

In addition, it is preferable to insert a bellows stainless hose having a good curvature in the inside of the flexible hose for supplying refrigerant to prevent damage by the refrigerant.

It is preferable that the flexible hose for supplying the refrigerant has a configuration in which a certain length of the end portion is wound in the form of a coil to expand the length of the refrigerant.

It is preferable that the gas refrigerant passing through the first unidirectional check valve and the gas refrigerant passing through the second unidirectional check valve are combined and returned to the pressure gauge side.

The return tube may further include an air control valve 58 for discharging the gas used in the chamber partially to the outside to smooth the circulation.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

3 is a block diagram illustrating the configuration of a refrigerator using a gas refrigerant according to a preferred embodiment of the present invention.

In FIG. 3, the same reference numerals are assigned to the parts commonly used in FIGS. 1 and 2, and a detailed description of the operation is omitted.

In the present invention, a gas cooling unit (60) is provided to cool the chamber (30). The gas cooling unit 60 is supplied with the refrigerant cooled first from the binary refrigerator 10 described above. This means that refrigerant primarily cooled by the flexible heat exchanger 52 shown in Fig. 3 is introduced from the solenoid valve 9a shown in Fig.

A gas refrigerant supply unit 60 for secondary cooling using a gas is provided in the following configuration. A gas refrigerant regulator 42 for regulating the amount of the secondary refrigerant supplied from the gas supply device 41 is installed at the rear end of the gas supply device 41 for generating and supplying the gas used as the secondary refrigerant And a unidirectional check valve 44 is provided at the rear end of the gas refrigerant regulator 42 to advance the introduced gas refrigerant.

A pressure gauge 45 for checking the pressure of the secondary refrigerant is provided at the rear end of the unidirectional check valve 44 to check the pressure state of the gas to be introduced and to supply the secondary refrigerant to the heat exchanger 52 And a pump motor 46 for circulation is provided in the tube 48 so as to circulate the gas refrigerant. At this time, it is preferable to use a shielded silicone hose as the material of the tube 48. Since the silicone hose has good elasticity and curvature characteristics, it can be prevented from damage due to external force.

Next, the secondary refrigerant supplied through the tube 48 is supplied to the heat exchanger 52 through the primary cooled cooling portion provided from the solenoid valve 9a of Fig. 1 described above.

The heat exchanger 52 is connected to the silicone hose 51 through a flexible hose 51a through which a tubular hose 51a of a stainless material is inserted. That is, the end of the tube 48 described above is communicated with the silicone hose 51 of the same material to double-inject the refrigerant, and a hose 51a of a bellows type of a cushion material having anti- . Particularly, a part of the end portion of the slow hose 51a (about 20) is wound so as to be wound in the form of a coil, and the combined refrigerant flows to the central portion. So that the heat exchange of the heat exchanger is performed. In the present invention, it is also referred to as a flexible heat exchanger (52) including the thus manufactured slow hose (51a). The cooling effect can be further enhanced through the flexible heat exchanger 52, and a fluid material can be employed to improve the operability.

Next, heat exchange is performed at a low temperature while passing through the heat exchanger 52, and the cooled refrigerant is transmitted to the chamber 30 to be cooled.

When the gas provided from the chamber 30 is used and the temperature is raised to a predetermined temperature, the gas (air) whose temperature has risen through the return tube 56 connected to the rear end proceeds, The directional check valve 54 is connected and returned to the gas feeder 41 side.

Next, the introduced air and the return-treated air provided respectively from the above-mentioned unidirectional check valve 44 and the unidirectional check valve 54 described later are merged with each other, and the above-mentioned circulating pump motor 46 is advanced Thereby processing the new process.

At this time, most of the air used in the chamber 30 flows to the inlet side through the return tube 56, but a part of air (approximately 5 to 20%) flows through the air control valve 58 . This is to facilitate the flow of the air to be used as a whole, and is designed to discharge only a small amount of air and reuse most of the air, thereby performing the function of cooling at a low cost.

With this configuration, it becomes possible to implement a refrigerator using gas refrigerant according to the configuration of the present invention.

As a result, the liquid refrigerant is not used, but only the gas is used to cool the liquid refrigerant. Therefore, various effects provided by the object of the present invention can be obtained.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be construed as limited to the particular embodiments set forth herein. Various changes and modifications may be made by those skilled in the art.

10: 2 source refrigerator 20: liquid coolant cooling unit
30: chamber
42: gas refrigerant regulator 44, 54: first and second one way check valve
45: pressure gauge 46: pump motor
48: Secondary refrigerant supply tube 51: Flexible hose for supplying refrigerant
51a: Suse hose 52: Heat exchanger
56: return tube 58: air regulating valve
60: gas cooling unit

Claims (6)

1. A freezer for cooling a chamber with a freezer having a normal cooling function,
A gas refrigerant regulator 42 for receiving the gas used as the secondary refrigerant and regulating the amount of the secondary refrigerant supplied;
A first unidirectional check valve (44) provided at a rear end of the gas refrigerant regulator (42) for opening the supplied gas refrigerant so as to proceed in one direction;
A pressure gauge 45 installed at a rear end of the unidirectional check valve 44 for checking the pressure of the supplied secondary refrigerant;
A secondary refrigerant supply tube 48 provided at the rear end of the pressure gauge 45 for supplying the supplied secondary refrigerant to the heat exchanger 52;
A circulation pump motor 46 installed in the secondary refrigerant supply tube 48 for circulating the supplied gas refrigerant;
A flexible hose 51 for supplying refrigerant to the heat exchanger 52 to supply the secondary refrigerant provided through the secondary refrigerant supply tube 48;
A heat exchanger 52 connected to an end of the flexible hose 51 for supplying the refrigerant and formed in a coil shape to enhance the cooling function by increasing the supply path of the refrigerant and providing the cooled refrigerant to the chamber 30; ;
A return tube 56 installed to discharge the refrigerant used in the chamber 30; And a second unidirectional check valve (54) installed in the return tube (56) for opening the used gas refrigerant to advance in one direction. The method according to claim 1,
Wherein the secondary refrigerant supply tube or the flexible hose or the return tube for supplying the refrigerant is made of a silicone material having elasticity. The method according to claim 1,
Wherein a hose made of stainless steel is inserted into the flexible hose for supplying refrigerant so as to prevent the refrigerant from being damaged by the refrigerant. 4. The method according to any one of claims 1 to 3,
Wherein the refrigerant supply flexible hose is configured to wind a certain length of its end portion in a coil shape to expand the length of the refrigerant passage. The method according to claim 1,
Wherein the gas refrigerant passing through the first unidirectional check valve and the gaseous refrigerant passing through the second unidirectional check valve are joined together and returned to the pressure gauge side. The method according to claim 1,
Wherein the return tube is further provided with an air regulating valve (58) for partially discharging the used gas to the outside.

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