KR101347074B1 - Non-noise condensing device using waste heat of a compressor and Refrigerator using the condensing device - Google Patents

Abstract

The present invention relates to a silent condenser using waste heat of a compressor capable of condensing a refrigerant without using a fan motor for a condenser and eliminating noise generated by the fan motor for the condenser and widening a storage space of the refrigerator, .
To this end, the present invention provides a refrigeration cycle system comprising: a main condensing tube that is condensed while a first refrigerant in a high-temperature, high-pressure gaseous state discharged from a compressor is moved and heat-exchanged with the first refrigerant to accelerate condensation of the first refrigerant, And a condensation promoting unit in which a second refrigerant having an independent circulation path is circulated, wherein the condensation promoting unit is connected to a refrigerant circulation pipe through which the second refrigerant circulates while changing state, A second refrigerant circulation pipe for circulating the second refrigerant in a liquid state in a gas state and a second refrigerant circulating in the liquid state, And a refrigerator using the waste heat condensing device.

Description

TECHNICAL FIELD [0001] The present invention relates to a non-noise condensing apparatus using waste heat of a compressor and a refrigerator using the same,

The present invention relates to a condenser and a refrigerator using the condenser. More particularly, the present invention relates to a condenser and a refrigerator using the condenser, and more particularly, to a condenser that can minimize noise by condensing a refrigerant without using a fan motor for a condenser, A condenser and a refrigerator using the condenser.

The refrigerator is a household appliance that allows the contents to be stored at low temperature in an internal storage space which is shielded by a door. The refrigerator can cool the inside of the storage space by using cool air generated through heat exchange with the refrigerant circulating in the refrigeration cycle, so that the contents stored in the storage space can be stored optimally.

Generally, food is stored in the storage space, but recently, a cosmetic refrigerator having a storage space for storing only cosmetics has been developed and used. Some organic cosmetics sold in recent years are likely to deteriorate easily. Therefore, consumers are advised to store in cosmetics exclusive refrigerator rather than at room temperature.

A general refrigerator in which foods are stored and a cosmetic refrigerator in which cosmetics are stored all have the same refrigeration cycle. That is, the refrigerant circulates along the pipe, such as a compression process, a condensation process, an expansion process, and a vaporization process.

The conventional refrigerator includes a compressor, a condenser, a capillary, and an evaporator for implementing the refrigeration cycle. The compressor and the condenser are typically disposed in the machine room of the refrigerator.

The structure of the machine room of the conventional refrigerator will be described with reference to FIG.

A compressor (4) for compressing the refrigerant, a condenser (6) for condensing the refrigerant, and a fan motor (8) for condenser for cooling the refrigerant are disposed in the machine room (2).

The condenser 6 is formed in the shape of a quadrangular cylinder with the condenser tube being rolled, and the fan motor 8 for condenser blows outside air to the surface of the condenser 6. As a result, the refrigerant in the condenser is phase-changed from the gas state to the liquid state through heat exchange with the outside air.

At this time, driving noise of the refrigerator occurs due to driving of the fan motor 8 for the condenser. In addition, due to the laminated structure of the condenser 6 and the presence of the fan motor 8 for the condenser, the machine room 2 can not but have a volume larger than a certain volume.

As a result, the conventional refrigerator has a disadvantage that the operation noise is large and the storage space of the contents due to the increase of the volume of the machine room is small.

Korean Patent Publication No. 10-2008-0071967 (title: refrigerator)

SUMMARY OF THE INVENTION It is an object of the present invention to provide a silent condenser using waste heat of a compressor capable of condensing a refrigerant without using a fan motor for a condenser and a refrigerator using the silent condenser.

Another object of the present invention is to provide a refrigerator using waste heat of a compressor which can expand the volume of a storage space in which contents are stored by minimizing a space in which a condenser is installed.

In order to solve the above-described problems, the present invention provides a refrigerant compressor comprising: a main condensing tube that is condensed while a first refrigerant in a high-temperature and high-pressure gaseous state discharged from a compressor is moved; And a condensation promoting unit in which a second refrigerant having a circulation path independent of the first refrigerant is circulated, wherein the condensation promoting unit includes a refrigerant circulation pipe circulating through the second refrigerant while changing state, The refrigerant circulation pipe being connected to one side of the refrigerant circulation pipe to provide a place where at least a part of the second refrigerant is changed from a liquid state to a gaseous state and at least a part of the second refrigerant is heat- Provided is a silent condenser using waste heat of a compressor including a radiating fin for changing from a gaseous state to a liquid state.

The storage container may include a first storage container installed at one side of the refrigerant circulation pipe based on the radiating fin, and a second storage container installed at the other side of the refrigerant circulation pipe.

Wherein the refrigerant circulation pipe comprises a second refrigerant circulation pipe provided with the radiating fins, a first refrigerant circulation pipe arranged between the second refrigerant circulation pipe and the first storage vessel, and a second refrigerant circulation pipe arranged between the second refrigerant circulation pipe and the second storage A third refrigerant circulation tube disposed between the first and second storage vessels, and a fourth refrigerant circulation tube disposed between the first storage vessel and the second storage vessel.

The third refrigerant circulation pipe may be provided with a U-shaped anti-circulation trap for preventing the second refrigerant in the liquid state condensed in the second refrigerant circulation pipe from flowing backward.

The first refrigerant circulation pipe may surround the outer surface of the compressor at least once.

Wherein the main condensing tube is wound on an outer surface of the first storage vessel and directly disposed on the outer surface of the second storage vessel, the first condensation tube being disposed in an inner space of the first storage vessel, A second condensation pipe disposed in the inner space of the second storage vessel, and a connection condensation pipe connecting the first condensation pipe and the second condensation pipe.

A first recess may be formed on an outer surface of the first storage vessel to correspond to an outer shape of the first condensation tube.

According to another aspect of the present invention, there is provided a nonaqueous-pressure condensing apparatus, comprising: the above-mentioned silent condenser; a capillary tube through which the first refrigerant condensed by the condensing device is expanded; and a second refrigerant passing through the capillary tube, An evaporator for evaporating the refrigerant, and a compressor through which the first refrigerant passed through the evaporator flows and is compressed, using the waste heat of the compressor.

The silent condenser using the waste heat of the compressor according to the present invention and the refrigerator using the silent condenser have the following effects.

First, there is an advantage that the operation noise of the refrigerator can be minimized by condensing the first refrigerant by using the condensation promoting unit without using the fan motor for the condenser.

Second, since the fan motor for the condenser is not used and the main condensing tube through which the first refrigerant is moved does not need to have a laminated structure, the volume of the machine room is reduced and the volume of the storage space of the refrigerator, There is an advantage to increase.

Third, the condensation efficiency of the first refrigerant is increased by using the waste heat of the compressor to smoothly circulate the second refrigerant in the condensation promoting unit, thereby increasing the thermal efficiency of the refrigerator.

Fourth, there is no need for a separate circulation device in the operation of the condensation promoting unit, and there is an advantage that the operation cost of the refrigerator is reduced because there is no need to install the fan motor for the condenser.

1 is a perspective view showing the interior of a conventional refrigerator machine room.
2 is a perspective view showing the inside of a machine room of a refrigerator provided with a silencer and condenser according to the present invention;
3 is a view schematically showing a refrigeration cycle of a refrigerator including a first embodiment of a silent condenser according to the present invention.
4 is a view schematically showing a refrigeration cycle of a refrigerator provided with a second embodiment of a silent condenser according to the present invention.
5 is a view showing a third embodiment of a silent condenser according to the present invention.
6 is a view showing a fourth embodiment of a silent condenser according to the present invention.
7 is a view showing another embodiment of the first storage container provided in the silent condenser according to the present invention.

A noise-free condensing apparatus using waste heat of a compressor according to the present invention and a refrigerator using the same will be described with reference to the accompanying drawings.

2 and 3, a first embodiment of a silent condenser according to the present invention and a refrigerator including the silent condenser will be described.

The refrigerator includes a case (1) forming an outer shape, a silent condenser disposed in the case, a capillary tube (30) in which the first refrigerant condensed by the silent condenser is expanded, a capillary tube An evaporator 20 in which the first refrigerant evaporates from a liquid state to a gaseous state, and the compressor 10 through which the first refrigerant passes through the evaporator 20 and is compressed.

A machine room (2) in which the compressor (10) is installed is formed at the lower end of the rear surface of the case (1). Here, all of the divided spaces except the machine room 2 can be used as a storage space of the refrigerator. Therefore, the smaller the volume of the machine room 2, the larger the storage space of the refrigerator.

A suction pipe 15 is provided between the compressor 10 and the evaporator 20 and a dryer 40 is provided between the silencer condenser and the capillary 30. Here, the dryer 40 serves to filter foreign substances contained in the first refrigerant passed through the silent condenser.

The evaporator includes an evaporation pipe 21 which is laminated while forming a plurality of rows in a meandering shape and a heat radiation member 23 installed on the surface of the evaporation pipe 21 for heat exchange between the first refrigerant and outside air do.

The first refrigerant is compressed to a high-temperature and high-pressure state by the compressor (10) and is moved to the silencer. The first refrigerant is changed from a gas state to a liquid state while passing through the silencer condenser, and the foreign matter is filtered while passing through the dryer (40).

Next, the first refrigerant expands while passing through the capillary tube 30, and is changed from the liquid state to the gaseous state via the evaporator 20. At this time, due to the phase change of the first refrigerant, the air in the periphery of the evaporator cools and cold air is generated, and the cool air cools the storage space of the refrigerator.

Next, the first refrigerant flows into the compressor (10) and is compressed again into a high-temperature, high-pressure gas state.

Wherein the silencer (50) comprises a main condensing pipe (50) condensed while the first refrigerant in a high-temperature and high-pressure gaseous state discharged from the compressor (10) is moved and a second condenser And a condensation promoting unit (60) for circulating a second refrigerant having a circulation path independent of the first refrigerant.

The main condensing pipe 50 includes a first condensing pipe 51 directly connected to the compressor 10 and a second condensing pipe 53 corresponding to the second storage container 63 of the condensation promoting unit. , And a connection condensing pipe (55) connecting the first condensing pipe (51) and the second condensing pipe (53).

The condensation promoting unit 60 is connected to the refrigerant circulation pipe 65 through which the second refrigerant circulates while changing state and at least a part of the second refrigerant is connected to one side of the refrigerant circulation pipe 65, (67) which is provided on the refrigerant circulation pipe (65) and at least a part of the second refrigerant is heat-exchanged with external air to change from a gaseous state to a liquid state, ).

The storage vessel includes a first storage vessel 61 installed at one side of the refrigerant circulation pipe 65 on the basis of the radiating fins 67 and a second storage vessel 61 installed at the other side of the refrigerant circulation pipe 65 63). Of course, the present invention is not limited to the above-described embodiment, and the storage container may be constituted by one storage container.

The first condenser tube 51 is wound around the outer surface of the first storage vessel 61 and the second condenser tube 53 is wound around the outer surface of the second storage vessel 63.

Here, the second refrigerant in the first storage vessel (61) and the first refrigerant in the first condensing tube (51) undergo heat exchange with each other, and the second refrigerant in the second storage vessel (63) The first refrigerant of the condensing tube 53 exchanges heat with each other.

Specifically, at least a part of the second refrigerant is changed from the liquid state to the gaseous state in the first storage container 61, and the first refrigerant is cooled. In addition, the second refrigerant is heated in the second storage vessel (63), and the first refrigerant is at least partially changed from the gas state to the liquid state in the second condensing tube (53).

The vaporization of the second refrigerant is more actively generated in the first storage vessel 61 than in the second storage vessel 63, And is more actively generated in the second condensing pipe (53).

The refrigerant circulation pipe 65 includes a second refrigerant circulation pipe 65b provided with the radiating fins 67 and a second refrigerant circulation pipe 65b disposed between the second refrigerant circulation pipe 65b and the first storage container 61, A third refrigerant circulation pipe 65c disposed between the second refrigerant circulation pipe 65b and the second storage container 63 and a third refrigerant circulation pipe 65c disposed between the first storage container 61 and the second storage container 63, And a fourth refrigerant circulation pipe (65d) disposed between the two storage containers (63).

In the second refrigerant circulation pipe (65b), the second refrigerant is changed from a gas state to a liquid state through heat exchange with outside air.

The third refrigerant circulation pipe (65c) is provided with a U-shaped reverse circulation preventing trap (69) for preventing the second refrigerant in the liquid state condensed in the second refrigerant circulation pipe (65b) from flowing backward.

The first refrigerant circulation pipe 65a, the second refrigerant circulation pipe 65b, the third refrigerant circulation pipe 65c and the fourth refrigerant circulation pipe 65d are arranged in the inner space of the machine room 2 And is provided on the rear wall of the case 1 of the refrigerator.

The first storage container 61 and the second storage container 63 are installed in a container installation part 70 disposed at the bottom of the machine room 2. The container installation part 70 includes a first installation groove 71 corresponding to the bottom of the first storage container 61 and a second installation groove 73 corresponding to the bottom of the second storage container 63, And a third installation groove 75 corresponding to a part of the fourth refrigerant circulation pipe 65d.

Therefore, in the conventional machine room, a compressor, a condensing structure of a condensing tube that is rolled in a square cylindrical shape, and a fan motor for a condenser for cooling the condensing tube are installed in the machine room 2, Since the compressor 10, the first storage container 61 and the second storage container 63 are provided only in the machine room 2, the machine room 2 can be used in a narrow volume. As a result, the refrigerator according to the present embodiment has an advantage that the storage space of the refrigerator is widened.

The process of circulating the second refrigerant will be described below.

First, the second refrigerant is vaporized through heat exchange with the first refrigerant in the first storage vessel (61). Thereafter, the refrigerant is moved along the first refrigerant circulation pipe (65a) and moved to the second refrigerant circulation pipe (65b).

Next, the second refrigerant moves along the second refrigerant circulation pipe (65b), and is changed from the gas state to the liquid state through heat exchange with the outside air.

Next, the second refrigerant flows along the third refrigerant circulation pipe 65c to the second storage vessel 63, and performs heat exchange with the first refrigerant in the second storage vessel 63 . At this time, the first refrigerant changes from a gaseous state to a liquid state.

Next, the second refrigerant is transferred from the second storage vessel (63) to the first storage vessel (61).

Here, R-124a may be used as the second refrigerant.

The second refrigerant is circulated through the first storage container 61, the first refrigerant circulation pipe 65a, the second refrigerant circulation pipe 65b, the third refrigerant circulation pipe 65c, 63) and the fourth refrigerant circulation pipe (65d) while having a circulation path independent of the first refrigerant and promoting the condensation of the first refrigerant.

Therefore, the first refrigerant can be efficiently condensed and the noise generated by the use of the fan motor for the condenser can be removed even if the fan motor for condenser for condensing the first refrigerant is not provided.

At this time, the second refrigerant circulates through the condensation promoting unit due to a natural circulation system, that is, a natural convection phenomenon and gravity of self-load. Specifically, in the first refrigerant circulation pipe (65a), the second refrigerant in a gaseous state is moved to the second refrigerant circulation pipe (65b) due to natural convection, and the second refrigerant circulation pipe (65b) The third refrigerant circulation pipe 65c and the fourth refrigerant circulation pipe 65d are sequentially moved by their own loads.

Referring to FIG. 4, a refrigeration cycle of a refrigerator including a second embodiment of the silent condenser according to the present invention will be described.

The silent condenser and the refrigeration cycle according to the present embodiment have a structure similar to that of the first embodiment described above. Therefore, detailed description of the same components as those of the above-described first embodiment will be omitted.

However, in the first refrigerant circulation pipe 65a according to the present embodiment, a compressor winding portion 65aa is formed which surrounds the outer surface of the compressor at least once, unlike the above-described embodiment.

The second refrigerant in the gaseous state existing in the first refrigerant circulation pipe 65a is heated to a higher temperature so that the movement of the second refrigerant can be prevented It can be smoothly performed.

As a result, the circulation of the second refrigerant can be smoothly performed by using the waste heat of the compressor.

Referring to Fig. 5, a third embodiment of a silent condenser according to the present invention will be described.

The silent condenser according to the present embodiment includes a main condensing tube and a condensation promoting unit for promoting the condensation of the first refrigerant of the main condensing tube.

The condensation promoting unit includes a refrigerant circulation pipe 650 through which the second refrigerant undergoes a state change, a heat radiation fin 670 provided on the refrigerant circulation pipe 650, A first storage vessel 610 installed at one side of the refrigerant circulation pipe 650 and a second storage vessel 630 installed at the other side of the refrigerant circulation pipe 650.

The main condensing tube includes a first condensing tube 510 at least partially disposed on the inner space of the first storage vessel 610 and a second condensing tube 510 disposed at least partially on the inner space of the second storage vessel 630 A second condensing pipe 530 and a connection condensing pipe 550 connecting the first condensing pipe 510 and the second condensing pipe 530 to each other.

The first storage vessel 610 is formed with a first inlet 615 through which the first condensing tube 510 flows and a first outlet 617 through which the first condensing tube 510 is discharged. The first storage container 610 is formed with a first refrigerant inlet 613 through which the second refrigerant flows and a first refrigerant outlet 611 through which the second refrigerant is discharged.

Similarly, the second storage container 630 is formed with a second inlet 635 through which the second condensation tube 530 flows and a second outlet 637 through which the second condensation tube 530 is discharged have. The second storage container 630 is formed with a second refrigerant inlet 631 through which the second refrigerant flows and a second refrigerant outlet 633 through which the second refrigerant is discharged.

As a result, the first refrigerant undergoes heat exchange with the second refrigerant in the inner space of the first storage container 610 and the second storage container 630, and more efficient heat exchange occurs.

Referring to Fig. 6, a fourth embodiment of the silent condenser according to the present invention will be described.

The silencerless condensing apparatus according to this embodiment has a structure similar to that of the third embodiment described above. Hereinafter, detailed description of the same components as those of the third embodiment will be omitted.

However, in the silent condenser according to the present embodiment, an auxiliary radiation member 800 for cooling the first refrigerant flowing on the connection condensation pipe 550 is further installed.

The auxiliary radiating member 800 may be provided in a plate shape through which the connection condensing pipe 550 passes.

The auxiliary radiating member 800 is formed with a condensing tube inlet 810 through which the connecting condensing tube 550 flows and a condensing tube outlet 820 through which the connecting condensing tube 550 is discharged.

As a result, the first refrigerant of the connection condensing pipe 550 is cooled while passing through the auxiliary heat-radiating member 800, thereby increasing the efficiency of condensing the first refrigerant, thereby increasing the thermal efficiency of the refrigerator.

Referring to FIG. 7, another embodiment of the first storage container provided in the silent condenser according to the present invention will be described.

In the outer surface of the first storage container 6100 according to this embodiment, a first depression groove 6130 corresponding to the outer shape of the first condensation pipe 51 is formed. The first storage container 6100 is formed with a coolant inlet port 6110 through which the second coolant flows and a coolant outlet port 6130 through which the second coolant is discharged.

The first condensing tube 51 is wound on the outer surface of the first storage vessel 6100 while corresponding to the first depressed groove 6130 so that the first refrigerant of the first condensing tube 51 and the first refrigerant of the first condensing tube 51 The heat exchange of the second refrigerant in the storage container 6100 is more efficiently performed. Of course, the second storage container may have the same structure as the first storage container 6100.

As a result, the efficiency of condensing of the first refrigerant is increased, thereby increasing the thermal efficiency of the refrigerator.

As described above, the present invention is not limited to the above-described specific preferred embodiments, and various changes and modifications may be made by those skilled in the art without departing from the scope of the present invention as claimed in the claims. And such variations are within the scope of the present invention.

1: Case 2: Machine room
10: compressor 20: evaporator
30: capillary tube 40: dryer
50: main condensing pipe 51: first condensing pipe
53: second condensing pipe 53: connecting condensing pipe
60: condensation promoting unit 61: first storage container
63: second storage container 65: refrigerant circulation pipe
67: Heat sink pin 69: U-shaped anti-reverse trap
70: container mounting part 800: auxiliary heat radiation member

Claims (8)

A main condensing tube which is condensed while the first refrigerant in the high-temperature high-pressure gaseous state discharged from the compressor moves; And,
And a condensation promoting unit for promoting the condensation of the first refrigerant while exchanging heat with the first refrigerant and circulating the second refrigerant having a circulation path independent of the first refrigerant,
The condensation promoting unit may include a refrigerant circulation pipe through which the second refrigerant is circulated while changing state, and a place connected to one side of the refrigerant circulation pipe to provide a place where at least a part of the second refrigerant is changed from a liquid state to a gaseous state And a radiating fin installed on the refrigerant circulation tube and adapted to heat exchange at least a part of the second refrigerant with external air to change from a gaseous state to a liquid state,
Wherein the storage container includes a first storage container installed on one side of the refrigerant circulation pipe based on the radiating fin and a second storage container provided on the other side of the refrigerant circulation pipe,
Wherein the refrigerant circulation pipe comprises a second refrigerant circulation pipe provided with the radiating fins, a first refrigerant circulation pipe arranged between the second refrigerant circulation pipe and the first storage vessel, and a second refrigerant circulation pipe arranged between the second refrigerant circulation pipe and the second storage A third refrigerant circulation tube disposed between the first and second storage vessels, and a fourth refrigerant circulation tube disposed between the first storage vessel and the second storage vessel,
Wherein the first storage container and the second storage container are installed in a container mounting portion disposed at the bottom of the machine room, wherein the container mounting portion includes a first installation groove corresponding to a bottom surface of the first storage container, A second installation groove corresponding to a bottom surface of the storage container and a third installation groove corresponding to a part of the fourth refrigerant circulation tube are formed,
In the first refrigerant circulation pipe, the second refrigerant in a gaseous state is moved to the second refrigerant circulation pipe due to natural convection, and the second refrigerant circulation pipe, the third refrigerant circulation pipe, In the pipe, it is moved sequentially by its own load,
Wherein the main condensing tube is connected to the compressor and is wound on the outer surface of the first storage container or disposed in the inner space of the first storage container, Or a second condensing tube disposed in the inner space of the second storage vessel and a connection condensing tube connecting the first condensing tube and the second condensing tube,
Wherein the connection condensing pipe is provided with an auxiliary heat radiation member through which the connection condensation pipe passes to cool the first refrigerant. delete delete The method according to claim 1,
Wherein the third refrigerant circulation pipe is provided with a U-shaped reverse-circulation-preventing trap for preventing the second refrigerant in the liquid state condensed in the second refrigerant circulation tube from flowing backward. Condenser. The method according to claim 1,
Wherein the first refrigerant circulation pipe surrounds the outer surface of the compressor at least one time. delete 6. The method of claim 5,
Wherein a first depressed groove is formed on an outer surface of the first storage container so as to correspond to an outer shape of the first condensation pipe. A silencer condenser according to any one of claims 1, 4, 5, and 7;
A capillary tube in which the first refrigerant condensed by the silencer condenser is expanded;
An evaporator in which the first refrigerant passed through the capillary is evaporated from a liquid state to a gaseous state; And,
Wherein the first refrigerant passed through the evaporator is introduced and compressed.

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