KR101854254B1 - Duality Refrigerating System having Hot gas defrosting - Google Patents

Abstract

The present invention provides a dual refrigeration system having a hot gas defrosting means, which has a defrosting type with high defrosting and energy saving efficiencies. According to one embodiment of the present invention, the dual refrigeration system comprises: a high temperature refrigeration cycle interconnecting a first compressor, a first condenser, a first liquid receiver, a first expansion valve, and a first evaporator by a first refrigerant pipe to circulate a first refrigerant while compressing, condensing, expanding, and evaporating the first refrigerant at a relatively high temperature; a low temperature refrigeration cycle interconnecting a second compressor, a second condenser, a second liquid receiver, a second expansion valve, and a second evaporator by a second refrigerant pipe to circulate a second refrigerant while compressing, condensing, expanding, and evaporating the second refrigerant at a relatively low temperature; and a middle heat exchanger transferring heat generated from the second condenser by the low temperature refrigeration cycle to the first evaporator of a high temperature refrigeration cycle apparatus to induce evaporation of the refrigerant so as to perform heat exchange between the first and second refrigerants.

Description

[0001] The present invention relates to a dual-refrigerating system having hot gas defrosting means,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a refrigeration system using a dual refrigeration cycle, and a dual refrigeration system capable of defrosting without requiring a separate electric heater.

A refrigerator is a device that takes heat from one side and transfers it to the other side to reduce the temperature of the other side. Such a refrigerator can generally be configured to include a compressor, a condenser, a receiver, an expansion valve and an evaporator.

The compressor compresses the low-temperature and low-pressure gas refrigerant supplied from the evaporator to high-temperature and high-pressure and delivers the gas refrigerant to the high-temperature and high-pressure refrigerant. And the liquid receiver temporarily stores the liquid refrigerant condensed at a high temperature and a high pressure in the condenser. The expansion valve rapidly expands the high-temperature and high-pressure liquid refrigerant supplied from the receiver to transfer the low-temperature low-pressure refrigerant to the evaporator. The evaporator controls the low-temperature and low-pressure refrigerant supplied from the expansion valve, Exchanges heat with the heat exchange medium to evaporate heat to generate low-temperature and low-pressure gaseous refrigerant, which is then transferred to the compressor.

However, since the refrigerator is performed by one refrigeration cycle, there is a limitation in cooling the temperature of one side of the refrigerator to an ultra-low temperature, for example, minus 50 or less. In order to solve such a problem, in recent years, a dual refrigeration cycle system has been mainly used.

The two-way refrigeration cycle system refers to a device capable of cooling to a cryogenic temperature in the low-temperature-side refrigeration cycle by interconnecting the low-temperature-side refrigeration cycle and the high-temperature-side refrigeration cycle for heat exchange.

Generally, the two-way refrigeration cycle system includes a first refrigeration cycle device for circulating a first refrigerant such as R-22 to perform the high temperature side refrigeration cycle, and a second refrigeration cycle device for circulating the refrigerant such as R- And a condenser in the second refrigeration cycle apparatus is disposed adjacent to the evaporator in the first refrigeration cycle apparatus to perform heat exchange. That is, the heat generated in the condenser in the second refrigeration cycle apparatus is transferred to the evaporator in the first refrigeration cycle apparatus to induce the evaporation of the refrigerant, thereby improving the heat transfer efficiency. Thus, in the freezer of the second refrigeration cycle apparatus The internal temperature can be cooled to a very low temperature.

In order to recover the function of the evaporator, the two-way refrigeration system is operated by periodically operating an electric heater provided at one side of the evaporator, thereby reducing the energy efficiency due to the operation of the electric heater. As a result of frequent failure of the electric heater, It has a problem that it runs unstably.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a two-way refrigeration system having a defrosting method with high defrost efficiency and high energy consumption rate.

The present invention provides a dual refrigeration system capable of preventing damage due to a rise in refrigerant pressure due to malfunction of a valve in a defrost mode.

The problems to be solved by the present invention are not limited to the above-mentioned problems, and the problems not mentioned can be clearly understood by those skilled in the art from the description and the accompanying drawings will be.

According to one aspect of the present invention, in order to cause the first refrigerant to be compressed, condensed, expanded, and evaporated while being circulated at a relatively high temperature, a first compressor, a first condenser, a first receiver, a first expansion valve, A high temperature refrigeration cycle wherein the refrigerant is connected to the first refrigerant pipe by a first refrigerant pipe; A second condenser, a second condenser, a second expansion device, and a second expansion device for causing the second refrigerant circulating in the high-temperature refrigeration cycle to be circulated while being compressed, condensed, expanded and evaporated at a relatively low temperature A valve, and a second evaporator are connected to each other by a second refrigerant pipe; And a heat exchanger for connecting the high temperature refrigeration cycle and the low temperature refrigeration cycle, wherein heat generated in the second condenser in the low temperature refrigeration cycle is transferred to the first evaporator in the high temperature refrigeration cycle apparatus to induce evaporation of the refrigerant, An intermediate heat exchanger in which heat exchange is performed between the first refrigerant and the second refrigerant; Wherein the low temperature refrigeration cycle includes a third expansion valve installed on a connection pipe connecting the intermediate heat exchanger and the second condenser such that the second condenser functions as an evaporator in a defrosting mode of the second evaporator; A defrost valve unit for supplying a second refrigerant of high temperature and high pressure provided from the second compressor to the second evaporator for defrosting the second evaporator; A first bypass pipe for bypassing the refrigerant discharged from the second evaporator to flow through the second refrigerant pipe without passing through the second expansion valve when the second evaporator is in operation; A second bypass pipe for bypassing refrigerant flowing through the first bypass pipe to the second refrigerant pipe through the intermediate heat exchanger to flow into the second receiver when the second evaporator is in operation; And a second refrigerant pipe extending from the second refrigerant pipe between the branch point to which the second bypass pipe is connected and the second refrigerant pipe so that the refrigerant from the second receiver flows to the third expansion valve when the second evaporator is in operation, And a third bypass pipe connected to the second refrigerant pipe between the connecting pipe and the intermediate heat exchanger.

Also, the low temperature refrigeration cycle may further include a first three-way valve installed at a branch point to which the third bypass pipe is connected to change a refrigerant flow direction according to a normal mode or a defrost mode.

The first three-way valve may include a first port to which the second refrigerant pipe connected to the second receiver is connected, a second port to which the second refrigerant pipe connected to the second evaporator is connected, And a third port to which the third bypass pipe is connected. In the normal mode, the first port and the second port are opened. In the defrosting mode of the second evaporator, the first port and the third port are opened .

Also, the low-temperature refrigeration cycle is provided on the second refrigerant pipe between the branch points where the intermediate heat exchanger and the third bypass pipe are connected to each other, and the second 3 Directional valve.

The second three-way valve may include a first port to which the second refrigerant pipe connected to the second condenser side is connected, a second port to which the second refrigerant pipe connected to the intermediate heat exchanger side is connected, And a third port to which a branch line branched from the second refrigerant pipe connected to the second condenser is connected. In the normal mode, the first port and the second port are opened, and the defrost mode of the second evaporator The first port and the third port may be opened.

According to an embodiment of the present invention, defrosting efficiency and energy consumption efficiency can be improved by the hot gas defrosting method.

According to one embodiment of the present invention, by applying two three-way valves for changing the flow direction of the refrigerant in the defrost mode, the refrigerant flows in the defrost flow direction during normal operation of the three-way valve, So that it is possible to prevent damage due to an increase in pressure in the piping.

The effects of the present invention are not limited to the above-mentioned effects, and the effects not mentioned can be clearly understood by those skilled in the art from the present specification and attached drawings.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a configuration diagram illustrating a dual refrigeration system according to an embodiment of the present invention; FIG.
FIG. 2 is a view showing the refrigerant flow of the first three-way valve in the defrost mode. FIG.
3 is a view showing the refrigerant flow of the second three-way valve in the defrost mode.

Other advantages and features of the present invention and methods of achieving them will be apparent by referring to the embodiments described hereinafter in detail with reference to the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, and the present invention is only defined by the scope of the claims. Although not defined, all terms (including technical or scientific terms) used herein have the same meaning as commonly accepted by the generic art in the prior art to which this invention belongs. A general description of known configurations may be omitted so as not to obscure the gist of the present invention. In the drawings of the present invention, the same reference numerals are used as many as possible for the same or corresponding configurations. To facilitate understanding of the present invention, some configurations in the figures may be shown somewhat exaggerated or reduced.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. The singular expressions include plural expressions unless the context clearly dictates otherwise. In the present application, the terms "comprises", "having", or "having" are intended to specify the presence of stated features, integers, steps, operations, components, Steps, operations, elements, parts, or combinations thereof, whether or not explicitly described or implied by the accompanying claims.

Hereinafter, an example of the present invention will be described in detail with reference to FIG.

The two-way refrigeration cycle of the present invention is applied to a cryogenic cooler having a temperature of -50 ° C or lower. By implementing two refrigeration cycles for each refrigerant cycle, the condenser of the low temperature refrigeration cycle is cooled by the evaporator of the high temperature refrigeration cycle, Cryogenic cooling can be realized.

Referring to FIG. 1, the dual refrigeration system 1000 of the present invention may include a high temperature refrigeration cycle 100, a low temperature refrigeration cycle 200, and an intermediate heat exchanger 9.

The high temperature refrigeration cycle 100 can provide a refrigeration cycle in which the first refrigerant compresses, condenses, expands, and evaporates while maintaining a relatively high temperature state. For example, the high temperature refrigeration cycle 100 includes a first compressor 1, a first condenser 2, a first receiver 3, a first expansion means 8, a first evaporator 9-1, And each component may be connected to be circulated by the first refrigerant pipe 110. [ It is needless to say that the first refrigerant pipe 110 may be provided with a structure commonly used in a refrigerant cycle such as a filter dryer and a valve for removing moisture and foreign matter from the refrigerant.

The cryogenic refrigeration cycle 200 can provide a refrigeration cycle in which the first and second refrigerants circulating in the high temperature refrigeration cycle 100 are circulated while being compressed, condensed, expanded and evaporated to a relatively low temperature. For example, in the low temperature refrigeration cycle 200, the second compressor 12, the second condenser 15, the second receiver 27, the second expansion valve 32, and the second evaporator 35 are connected to the second May be connected to each other by a refrigerant pipe (210). The second evaporator 35 may include a drain plate 34.

The second refrigerant pipe 210 includes a first pipe 211 connecting the second compressor 12 and the second condenser 15, a second pipe 211 connecting the second condenser 15 and the intermediate heat exchanger 9, A third pipe 213 connecting the intermediate heat exchanger 9 and the second fluid receiver 27 and a fourth pipe connecting the second fluid receiver 27 and the second expansion valve 32 214), and a fifth pipe (215) connecting the second evaporator (35) and the second compressor (12).

For reference, the second refrigerant pipe 210 may be provided with a structure commonly used in a refrigerant cycle such as a filter dryer, a valve, etc. for removing moisture and foreign matter from the refrigerant.

The first refrigerant applied to the high temperature refrigeration cycle 100 and the second refrigerant applied to the low temperature refrigeration cycle 200 have different boiling points from each other. For example, the first refrigerant applied to the high temperature refrigeration cycle 100 And the second refrigerant applied to the low temperature refrigeration cycle 200 may be a cryogenic refrigerant such as R13, R23, and R503 having low boiling points.

The intermediate heat exchanger 9 connects the high temperature refrigeration cycle 100 and the low temperature refrigeration cycle 200 and the heat generated in the second condenser 15 in the low temperature refrigeration cycle 200 is transferred to the high temperature refrigeration cycle 100 And is then transferred to the first evaporator 9-1 of the first evaporator 9-1 to induce evaporation of the refrigerant, thereby performing heat exchange between the first refrigerant and the second refrigerant. The intermediate heat exchanger 9 includes a first evaporator 9-1 of the hot refrigeration cycle 100 and a secondary condenser 9-2 of the low temperature refrigeration cycle 200. [ That is, the second refrigerant in the low-temperature refrigeration cycle 200 is firstly condensed in the second condenser 15, then supplied to the intermediate heat exchanger 9 and condensed again in the second condenser 9-2, Temperature and pressure.

The low temperature refrigerant cycle 200 may include a defrost system for defrosting the second evaporator and the drain plate to restore the function of the second evaporator.

The defrosting valve unit 13, the third expansion valve 19, the first bypass pipe 221, and the second bypass pipe 223 for switching the flow of the refrigerant in the normal direction or the reverse direction, A second bypass pipe 222, a third bypass pipe 223, a first three-way valve 28, and a second three-way valve 24.

The defrost valve unit 13 switches the refrigerant discharged from the second compressor 12 to circulate to the second condenser 15 in the cooling mode and circulates the refrigerant to the second evaporator 35 in the defrosting mode It is a role to convert. In this embodiment, the defrost valve unit 13 may be a four-way valve. The first pipe 211 and the fifth main pipe 215 are connected to the four-way valve 13. That is, the four-way valve 13 is connected to D- > A and C- > B in the cooling mode and D- > C and A- > B in the defrost mode. For reference, in the defrost mode, the second condenser 15 is used as an evaporator, and the second evaporator 35 can be used as a condenser.

The third expansion valve 19 is connected to the second pipe 212 for connecting the intermediate heat exchanger 9 and the second condenser 15 so that the second condenser 15 serves as an evaporator in the defrosting mode of the second evaporator 35 (Not shown). A check valve 22 is installed in the second pipe 212 so that the refrigerant flows to the connection pipe 225 in the defrosting mode of the second evaporator. The third expansion valve may include a capillary expansion valve.

The first bypass pipe 221 is connected to the fourth pipe 214 of the second refrigerant pipe without passing the second expansion valve 32 through the second evaporator 25 when the second evaporator 35 discharges refrigerant It is a pipe which bypasses to flow. A check valve 33 may be installed in the first bypass pipe 221.

The second bypass pipe 222 is connected to the second bypass pipe 221 through the first bypass pipe 221 and the second bypass pipe 222. The second bypass pipe 222 is connected to the second bypass pipe 221, It is a pipe to bypass. The second bypass pipe 222 is connected to the fourth pipe 214 and the second pipe 212. P1 is a branch point of the second bypass pipe connected to the fourth pipe 214 and P2 is a branch point of the second bypass pipe connected to the second pipe. A check valve 41 may be installed in the second bypass pipe 222.

The third bypass pipe 223 is a pipe that bypasses the refrigerant flowing from the second receiver (27) to the third expansion valve (19) when the second evaporator (35) is defrosted. The third bypass pipe is branched from the fourth pipe 214 between the point P1 where the second bypass pipe 222 is connected and the second fluid receiver 27 and connected to the connection pipe 225 and the intermediate heat exchanger 9, To the second piping 212 between the first piping 212 and the second piping 212.

For reference, the line with valves 48 and 49 is a hot gas bypass line for pressure compensation during winter or pressure drop (refrigerant).

FIG. 2 is a view showing the refrigerant flow of the first three-way valve in the defrost mode. FIG.

1 and 2, the first three-way valve 28 is provided at a branch point to which the third bypass pipe 223 is connected, and functions to change the direction of the refrigerant flow in accordance with the normal mode or the defrost mode . The first three-way valve 28 includes a first port 28-1 connected to a fourth pipe 214 connected to the second receiver 27 side and a second port 28-2 connected to the second evaporator 35 A second port 28-2 to which the fourth pipe 214 is connected, and a third port 28-3 to which the third bypass pipe 223 is connected. In the normal mode, the first port 28-1 and the second port 28-2 are opened. In the defrosting mode of the second evaporator, the first port 28-1 and the third port 28-3 are opened do.

3 is a view showing the refrigerant flow of the second three-way valve in the defrost mode.

1 and 3, the second three-way valve 24 is located between a point P3 where the intermediate heat exchanger 9 and the third bypass pipe 223 are connected, more specifically, Is installed on the second pipe between the point P 2 where the pipe 222 is connected and the point P 3 where the third bypass pipe 223 is connected. The second three-way valve (24) blocks the refrigerant from flowing in the direction of the intermediate heat exchanger in the defrost mode. The second three-way valve 24 includes a first port 24-1 to which a second pipe connected to the second condenser 15 is connected, a second pipe 212 to be connected to the intermediate heat exchanger 9, And a third port 24-3 to which the branch line 226 branched from the second pipe 212 connected to the second condenser 15 side is connected can do. In the normal mode, the first port 24-1 and the second port 24-2 are opened. In the defrosting mode of the second evaporator, the first port 24-1 and the third port 24-3 are opened do.

In the low temperature refrigerant cycle 200 of the two-way refrigerant system 1000, the refrigerant flow in the defrosting mode flows from the second compressor 12 to the defrost valve portion 13 (D-> C) to the fifth piping 215 to the drain plate 34) (heating agent phase) - second evaporator 35 (heating agent phase) - first bypass pipe 221 - fourth pipe 214 - second bypass pipe 222 - intercooler 9 - The second bypass line 223, the third expansion valve 19, the second bypass line 223, the third bypass line 223, the third bypass valve 223, A condenser 15, a first pipe 211, a defrost valve 13 (AB), a liquid separator (40), and a second compressor (12).

That is, in the defrosting mode, refrigerant (approximately 130 ° C) of high temperature and high pressure, which is leaned in the second compressor 12, passes through the check valve 38 and the filter 39 (bidirectional filter) And the second evaporator. The defrosted vaporized refrigerant passes through the check valve 33, passes through the second bypass pipe 222, and is liquefied in the intermediate cooler. The liquefied refrigerant is temporarily stored in the receiver 27, and the stored liquefied refrigerant flows from the first three-way valve 28 to the third bypass line and is evaporated in the second condenser through the third expansion valve. The evaporated refrigerant further includes a gas compressed in the second compressor by the gas separated from the liquid separator 40 through the defrost valve 13.

As described above, according to the present invention, by applying two three-way valves for changing the flow direction of the refrigerant in the defrost mode, the refrigerant flows in the defrost flow direction during normal operation of the three-way valve, So that it is possible to prevent damage due to the pressure rise in the piping.

The foregoing detailed description is illustrative of the present invention. In addition, the foregoing is intended to illustrate and explain the preferred embodiments of the present invention, and the present invention may be used in various other combinations, modifications, and environments. That is, it is possible to make changes or modifications within the scope of the concept of the invention disclosed in this specification, within the scope of the disclosure, and / or within the skill and knowledge of the art. The above-described embodiments illustrate the best mode for carrying out the technical idea of the present invention, and various modifications required for specific application fields and uses of the present invention are also possible. Accordingly, the detailed description of the invention is not intended to limit the invention to the disclosed embodiments. It is also to be understood that the appended claims are intended to cover such other embodiments.

100: high temperature refrigerant cycle 200: low temperature refrigerant cycle
300: intermediate heat exchanger

Claims (5)

The first compressor, the first condenser, the first condenser, the first expansion valve, and the first evaporator are connected to each other by a first refrigerant pipe in order to circulate the first refrigerant while being compressed, condensed, expanded and evaporated at a relatively high temperature Linked high temperature refrigeration cycle;
A second condenser, a second condenser, a second expansion device, and a second expansion device for causing the second refrigerant circulating in the high-temperature refrigeration cycle to be circulated while being compressed, condensed, expanded and evaporated at a relatively low temperature A valve, and a second evaporator are connected to each other by a second refrigerant pipe; And
Wherein the heat generated by the second condenser in the low temperature refrigeration cycle is transferred to the first evaporator in the high temperature refrigeration cycle apparatus to induce evaporation of the refrigerant, 1 < / RTI >refrigerant; and an intermediate heat exchanger for performing heat exchange between the first refrigerant and the second refrigerant;
The low temperature refrigeration cycle
A third expansion valve installed on a connection pipe connecting the intermediate heat exchanger and the second condenser such that the second condenser serves as an evaporator in a defrost mode of the second evaporator;
A defrost valve unit for supplying a second refrigerant of high temperature and high pressure provided from the second compressor to the second evaporator for defrosting the second evaporator;
A first bypass pipe for bypassing the refrigerant discharged from the second evaporator to flow through the second refrigerant pipe without passing through the second expansion valve when the second evaporator is in operation;
A second bypass pipe for bypassing refrigerant flowing through the first bypass pipe to the second refrigerant pipe through the intermediate heat exchanger to flow into the second receiver when the second evaporator is in operation; And
Is branched from the second refrigerant pipe between the branch point to which the second bypass pipe is connected and the second refrigerant pipe so that the refrigerant from the second receiver flows to the third expansion valve when the second evaporator is in operation And a third bypass pipe connected to the second refrigerant pipe between the connecting pipe and the intermediate heat exchanger. The method according to claim 1,
The low temperature refrigeration cycle
Further comprising a first three-way valve installed at a branch point to which the third bypass pipe is connected to change the refrigerant flow direction according to a normal mode or a defrost mode. 3. The method of claim 2,
The first three-way valve
A second port to which the second refrigerant pipe connected to the second evaporator side is connected, and a second port to which the third bypass pipe is connected, the third port connected to the second refrigerant pipe, Port,
In the normal mode, the first port and the second port are opened,
And the first port and the third port are opened in the defrost mode of the second evaporator. 3. The method of claim 2,
The low temperature refrigeration cycle
Further comprising a second three-way valve provided on the second refrigerant pipe between the branch points where the intermediate heat exchanger and the third bypass pipe are connected to block the flow of refrigerant in the direction of the intermediate heat exchanger in the defrosting mode, Refrigeration system. 5. The method of claim 4,
The second three-way valve
A first port connected to the second refrigerant pipe connected to the second condenser, a second port connected to the second refrigerant pipe connected to the intermediate heat exchanger, and a second port connected to the second condenser, And a third port to which a branch line branched from the refrigerant pipe is connected,
In the normal mode, the first port and the second port are opened,
And the first port and the third port are opened in the defrost mode of the second evaporator.

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