KR101172914B1 - Arrangement structure of duplex evaporator for refrigerator - Google Patents

Abstract

The present invention relates to a double evaporator mounting structure for a refrigerator, comprising: a first-first refrigerant pipe connected to a valve of the refrigerator, the first-first refrigerant pipe connected to a valve of the refrigerator by a valve, The second refrigerant pipe connected to the end of the 1-2 refrigerant pipe extending to the -1 refrigerant pipe is installed to cool the upper storage chamber, and as the 1-2 refrigerant tube is installed to cool the central storage chamber, the first The upper storage compartment and the central storage compartment are uniformly cooled by the refrigerant supplied at the same cooling efficiency to the first refrigerant tube and the 1-2 refrigerant tube at the same time, and the second refrigerant tube and the accumulator are installed close to each other in the upper storage chamber. And to be installed at a similar height to prevent the refrigerant from remaining inside the second refrigerant pipe.

Refrigerator, double evaporator, residual refrigerant

Description

Double evaporator installation structure for refrigerator {ARRANGEMENT STRUCTURE OF DUPLEX EVAPORATOR FOR REFRIGERATOR}

1 is a configuration diagram of a refrigerant pipe arrangement of a general refrigerator dual evaporator.

2 is a configuration diagram of the refrigerant pipe arrangement of the refrigerator dual evaporator according to the present invention.

<Description of Major Symbols in Drawing>

10-Refrigerator 11-Upper Storage Room

12-Central Storage Room 13-Lower Storage Room

20-Valve 21-Euro 1

22-2nd Euro 30-1st-1 Refrigerant Pipe

31-1-2 refrigerant tube 32-2nd refrigerant tube

33-3rd refrigerant pipe 41-1st evaporator

42-2nd Evaporator 43-3rd Evaporator

The present invention relates to a refrigerant pipe of a refrigerator, and more particularly, to a structure for installing a dual evaporator for a refrigerator to change the structure of the double evaporator installed in the storage compartment of the refrigerator to prevent the refrigerant from remaining when the refrigerant flow path is changed. will be.

In general, a refrigerator generally uses a principle of a refrigeration cycle that absorbs ambient heat as the compressed and cooled refrigerant expands to lower the ambient temperature at which the refrigerant expands and evaporates. The refrigerator is equipped with a compressor, a condenser, an evaporator and an accumulator.

In addition, the refrigerator is provided with a plurality of box-shaped storage compartment with its front open to accommodate food, and the front opening of the storage compartment is opened / closed by a door having one end coupled to the front opening via a hinge. It is usually formed to be.

In addition, in order to cool the air in each of the storage chambers, the refrigerant is evaporated in each of the storage chambers.

In recent years, there has been a development of a refrigerator in which the evaporator is doubled so that either one of the two evaporators is operated and the other one is stopped, or both of the two evaporators are operated.

In addition, there was a refrigerator in which three storage compartments of the refrigerator are arranged in a direction perpendicular to the ground, and an evaporator arrangement of the refrigerator having the three storage compartments is shown in FIG. 1.

The refrigerator 10 includes an upper storage chamber 11, a central storage chamber 12, and a lower storage chamber 13, and the upper storage chamber 11 is positioned at the top of the refrigerator 10. The storage chamber 12 is located at the center of the upper storage chamber 11 and the lower storage chamber 13 to be described later, and the lower storage chamber 13 is located at the bottom of the refrigerator 10 and at the bottom of the central storage chamber 12. Is located.

In addition, the refrigerator 10 includes a compressor, a condenser, an evaporator, an accumulator 23, and a valve 20.

The compressor is a device for compressing a low-temperature low-pressure gas refrigerant to form a high-temperature high-pressure gas refrigerant, it is generally installed in the lower rear of the refrigerator (10).

The condenser is a device for forming a gas refrigerant of high temperature and high pressure compressed by the compressor into a liquid refrigerant of room temperature and high pressure, and is generally installed below the refrigerator 10.

The evaporator is formed of a tube formed so that the refrigerant cooled to room temperature in the condenser is expanded through a capillary tube to change into a low temperature low pressure liquid refrigerant, and the low temperature low pressure liquid refrigerant is evaporated to take away the ambient air temperature.

In addition, the evaporator is generally installed on the rear wall of the storage chamber, and it is generally formed to be bent in a plate shape in a plurality of parts according to the shape of the rear wall of the evaporator.

In addition, the evaporator includes a first evaporator 410, a second evaporator 420, and a third evaporator 43 to be installed in each of the upper storage chamber 11, the central storage chamber 12, and the lower storage chamber 13. It is composed.

The first evaporator 410 is formed in the first flow passage 21 to be described later, is installed on the rear wall of the upper storage chamber 11 is installed to cool the interior of the upper storage chamber (11).

The second evaporator 420 is formed in the first passage 21 to be described later, and is installed on the rear wall of the central storage chamber 12 so as to cool the inside of the central storage chamber 12.

The third evaporator 43 is formed in the second flow passage 22 to be described later, and is installed on the rear wall of the lower storage chamber 13 so as to cool the inside of the lower storage chamber 13.

In addition, as shown in FIG. 1, the first evaporator 410 has a first refrigerant pipe 310 constituting the first flow passage 21 extending upward from a lower portion of the upper storage chamber 11. It is formed to be bent to form a plate in a plurality of parts.

In addition, the second evaporator 420 extends from the end of the first refrigerant pipe 310 to the central storage chamber 12 so that the second refrigerant pipe 320 forming the first flow passage 21 is the central storage chamber. It extends downward from the upper part of (12), and is bent to form a plate shape in many parts.

In addition, the second refrigerant pipe 320 of the second evaporator 420 is connected to an accumulator whose end is described later.

The third evaporator 43 has a third refrigerant pipe 33 constituting the second flow passage 22 is formed on the rear wall of the lower storage chamber 13 extends downward from the upper portion thereof in a plate shape in a plurality of parts. It is bent to form a.

In addition, an end of the third refrigerant pipe 33 of the third evaporator 43 is connected to the accumulator 23.

The valve 20 is installed between the condenser and the evaporators, and includes a first passage 21 composed of the first evaporator 410 and a second evaporator 420, and a second composed of the third evaporator 43. It is configured to selectively flow the refrigerant in the flow path (22).

The accumulator 23 passes the low-temperature low-pressure gas refrigerant evaporated in the evaporators to the compressor, and the ends of the second refrigerant pipe 320 and the third refrigerant pipe 33 are integrated to filter the liquid refrigerant. Are connected to each other, and are often installed on an upper portion of the refrigerator 10.

Accordingly, when the refrigerator 10 is operated, the compressor and the condenser are operated to move the refrigerant compressed and cooled at room temperature in the directions of the evaporators, and the refrigerant moved to the evaporators is installed between the condenser and the evaporators. Selective opening / closing of the valve 20 allows the first passage 21 in which the first evaporator 410 and the second evaporator 420 are formed, or the second passage 22 in which the third evaporator 43 is formed. Is moved to.

When the valve 20 is opened to the first flow passage 21, the refrigerant moved from the condenser moves to the first flow passage 21 through the valve 20 and moves to the first flow passage 21. The refrigerant is evaporated while moving from the lower portion of the rear wall of the upper storage chamber 11 to the upper side along the first refrigerant pipe 310 of the first evaporator 410 to reduce the air temperature of the upper storage chamber 11, The refrigerant passing through the first refrigerant pipe 310 is moved to the second refrigerant pipe 320 to which the first refrigerant pipe 310 is connected.

The refrigerant moved to the second refrigerant pipe 320 reduces the temperature of the central storage chamber 12 while evaporating inside the second refrigerant pipe 320, and the refrigerant passing through the second refrigerant pipe 320 is An end of the second refrigerant pipe 320 is circulated to the compressor again through an accumulator connected to the end of the second refrigerant pipe 320.

When the valve 20 opens the second passage 22, the refrigerant moves along the third refrigerant pipe 33 constituting the second passage 22 to cool the internal air of the lower storage chamber 13. The end of the third refrigerant pipe 33 is circulated to the compressor through the accumulator 23 connected.

However, in the conventional evaporator arrangement structure as described above, the refrigerant passing through the first refrigerant pipe 310 of the upper storage chamber 11 is moved to the second refrigerant pipe 320 of the central storage chamber 12. When the temperature of the upper storage compartment 11 is relatively high, such as initial operation of the refrigerator 10, as the heat exchange is completed in the upper storage compartment 11 and the refrigerant which is no longer evaporated is moved to the second refrigerant pipe 320. As the refrigerant passes through the second refrigerant pipe 320 without performing evaporation and heat exchange, the time for reducing the temperature of the central storage chamber 12 to a desired temperature is increased.

In addition, after the refrigerant is moved to the first flow passage 21, the first flow passage 21 is closed after the evaporation is performed in the first evaporator 410 and the second evaporator 420, and the second flow passage 22 is closed. When the refrigerant is moved to the third evaporator 43, the refrigerant moving to the first flow passage 21 is blocked, and the first refrigerant pipe 310 and the second refrigerant pipe 320 are opened. Since the moving refrigerant is blocked, the suction force of the compressor for pressurizing the refrigerant remaining in the first refrigerant pipe 310 and the second refrigerant pipe 320 is abolished.

As the suction force for sucking the refrigerant remaining in the first refrigerant pipe 310 and the second refrigerant pipe 320 is abolished, the refrigerant remaining in the first refrigerant pipe 310 is inertia of the refrigerant and the first It is moved to the second refrigerant pipe 320 while being sucked by the suction force remaining before blocking the flow path (21).

However, the refrigerant moved to the second refrigerant pipe 320 and the remaining refrigerant remain in the second refrigerant pipe 320 while the suction force is abolished, and a part thereof is moved through the accumulator 23.

In particular, as shown in FIG. 1, the refrigerant remaining in the upper portion of the second refrigerant pipe 320 and the accumulator in the refrigerant remaining portion R below the second refrigerant pipe 320 of the second evaporator 420. Refrigerants that did not rise to 23 remain stacked.

In this way, the refrigerant remaining in the second refrigerant pipe 320 reduces the temperature of the central storage chamber 12 that should not be operated while evaporating inside the second refrigerant pipe 320, thereby preventing the normal control operation of the refrigerator 10. The refrigerant evaporated from the second refrigerant pipe 320 flows into the accumulator 23 to overload the accumulator 23.

When the inside of the closed second refrigerant pipe 320 is pressurized and the valve 20 is operated again to open the first flow passage 21, the first flow passage 21 is opened at the same time. The refrigerant remaining in the second refrigerant pipe 320 evaporates at a time to overload the accumulator 23 as well as causing abnormal operation of the entire cooling circuit such as the compressor and the condenser.

The present invention has been invented to solve the above problems, it is an object of the present invention to provide a refrigerated double evaporator installation structure to maintain the correct operation of the cooling circuit by removing the refrigerant remaining in the refrigerator evaporator.

Another object of the present invention is to provide a dual evaporator installation structure for a refrigerator in which a flow path through which a refrigerant of a refrigerator flows is equally arranged in each storage compartment to achieve an equal degree of cooling of each storage compartment.

The dual evaporator installation structure for a refrigerator according to the present invention for achieving the above object is provided with an upper storage compartment, a central storage compartment and a lower storage compartment in the refrigerator, and the evaporators of the first channel are installed in the upper storage compartment and the central storage compartment. The evaporator of the second flow path is installed in the lower storage chamber, and the first evaporator installed in the upper storage chamber includes the first-first refrigerant pipe adjacent to the valve and the first-second refrigerant pipe in which the first-first refrigerant pipe extends. Comprising a second refrigerant pipe connected to the end, the second evaporator installed in the central storage compartment is characterized in that composed of the 1-2 refrigerant pipe.

Another feature of the invention is characterized in that the end of the second refrigerant pipe is connected to the accumulator installed on the refrigerator.

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

In addition, while the same reference numerals are denoted in the same parts as in Fig. 1 showing the conventional structure, detailed description thereof will be omitted.

2 shows that the evaporators of the refrigerator 10 according to the present invention are arranged.

According to the present invention, a refrigerant pipe through which refrigerant passes first is arranged in two storage compartments, and a refrigerant pipe connected to an accumulator 23 installed above the refrigerator 10 is installed in the direction of the accumulator. .

In the present embodiment, the refrigerator 10 includes three storage compartments, an upper storage compartment 11, a central storage compartment 12, and a lower storage compartment 13.

In addition, the first evaporator 41, the second evaporator 42 and the third evaporator 43 are respectively installed on the rear wall of each storage compartment to lower the air temperature of each storage compartment.

In addition, the refrigerator 10 of the present exemplary embodiment is configured to form a valve 20 at a point between the evaporators and the condenser so as to select and supply a refrigerant moving from the condenser.

Accordingly, two flow paths are formed from the valve 20 to the accumulator installed at the upper portion of the refrigerator 10, and these two flow paths are opened / closed by the valve 20, or open / closed at the same time. do.

The two flow passages are composed of a first flow passage 21 and a second flow passage 22, and the first flow passage 21 includes a first evaporator 41 and a second evaporator 42. The second flow passage 22 consists of a third evaporator 43.

The first evaporator 41 and the second evaporator 42 is composed of a 1-1 refrigerant tube 30, 1-2 refrigerant tube 31 and the second refrigerant tube 32, the first 1- 1, the refrigerant pipe 30, as shown in Figure 2, is connected to the upper portion of the rear wall of the upper storage chamber 11 in the valve 20, a plurality of parts in the downward direction from the upper of the upper storage chamber (11) Is formed to be bent to form a plate.

At this time, the first-first refrigerant pipe 30 is formed in a plate shape that is bent in a plurality of parts from the upper portion to the center of the upper storage chamber 11 to about half the size of the rear wall of the upper storage chamber 11. It is arranged to form part of the first evaporator 41.

Here, the refrigerant tubes are composed of a conventional tube that is compressed in the compressor and the condenser of the refrigerator 10 and the refrigerant cooled at room temperature flows and evaporates therein.

The first-second refrigerant pipe 31 is formed at an end of the first-first refrigerant pipe 30, and is formed at the center of the upper storage chamber 11 in which the first-first refrigerant pipe 30 is installed. It extends to the lower portion of the central storage chamber 12, is formed extending in the upper portion from the lower portion of the central storage chamber 12 is bent in a plurality of parts to form a plate shape is installed on the rear wall of the central storage chamber (12).

In addition, the 1-2 refrigerant tube 31 may be installed so as to reach the upper portion from the center of the central storage chamber 12, the lower portion of the central storage chamber 12 to the third refrigerant tube 33 to be described later Of course, the third evaporator 43 may be extended to be installed to cool the lower portion of the central storage chamber 12.

The second refrigerant pipe 32 is formed extending from the end of the 1-2 refrigerant pipe 31 to the lower portion of the upper storage chamber 11, the plate shape on the lower rear wall of the upper storage chamber (11) It is bent and installed in multiple parts to achieve.

In addition, one end of the second refrigerant pipe 32 is connected to the 1-2 second refrigerant pipe 31, and an end thereof is connected to the accumulator 23 installed at the upper portion of the refrigerator 10.

At this time, since the installation position of the second refrigerant pipe 32 is the upper storage chamber 11 located above the refrigerator 10, the end of the second refrigerant pipe 32 and the accumulator 23 are almost similar. The height is reached, which leads to a small rise / fall connection.

The second flow passage 22 is composed of a third evaporator 43, the third evaporator 43 is composed of a third refrigerant pipe (33).

The third evaporator 43 is installed on the rear wall of the lower storage chamber 13 positioned below the refrigerator 10 and includes the third refrigerant pipe 33.

The third refrigerant pipe 33 is composed of a pipe from the valve 20 to the accumulator 23, is connected to the upper portion of the lower storage chamber 13 from the valve 20, the lower storage chamber ( 13 is formed to extend in a downward direction and bend in a plurality of portions to form a plate shape corresponding to the rear wall of the lower storage chamber 13.

In the present embodiment, the first-first refrigerant pipe 30, the first-second refrigerant pipe 31, the second refrigerant pipe 32 and the third refrigerant pipe 33 in the upper or lower portion of each storage compartment It is to be formed to extend in the opposite direction, but each of the refrigerant pipe is connected to the opposite side of the first storage compartment can be formed to extend to the upper or lower to the opposite of course.

Accordingly, the first evaporator 41 installed in the upper storage chamber 11 of the refrigerator 10 is connected to the first-first refrigerant pipe 30 and the first-first refrigerant pipe 30 connected to the valve 20. A second evaporator (42) connected to the end of the extended 1-2 refrigerant pipe (31), and the second evaporator (42) installed in the central storage chamber (12) is the 1-2 refrigerant pipe ( 31), the third evaporator 43 of the lower reservoir 13 is composed of a third refrigerant pipe (33) connected to the valve (20).

Next, the operation of the dual evaporator for a refrigerator of the present invention configured as described above will be described.

The compressor and the condenser are operated in accordance with the operation of the refrigerator 10, and the refrigerant compressed in the compressor and the condenser and cooled to room temperature is supplied to the valve 20 installed between the condenser and the evaporators installed in the respective storage compartments of the refrigerator 10. Is moved.

The refrigerant moved to the valve 20 is moved to the first flow passage 21 and / or the second flow passage 22 to which the valve 20 is connected by selective opening of the valve 20.

Here, when the second flow passage 22 is opened, the refrigerant moved from the condenser is moved to the third refrigerant pipe 33 of the second flow passage 22, and the third refrigerant pipe 33 is As the third evaporator 43 is installed in the lower storage chamber 13 of the refrigerator 10, the refrigerant is evaporated in the third refrigerant pipe 33 to cool the inside of the lower storage chamber 13.

The refrigerant evaporated inside the third refrigerant pipe 33 is moved to the accumulator 23 to which the third refrigerant pipe 33 is connected and circulated to the compressor.

When the first flow passage 21 is opened in the valve 20, the refrigerant moved in the condenser is moved to the first-first refrigerant pipe 30 connected to the valve 20 through the valve 20. .

Here, since the first-first refrigerant pipe 30 is installed as a part of the first storage evaporator 41 of the upper storage chamber 11 of the refrigerator 10, the upper portion of the first evaporator 41 of the upper storage chamber 11 is provided. In the refrigerant is evaporated to operate to cool the upper portion of the upper storage chamber (11).

The refrigerant passing through the first-first refrigerant pipe 30 is moved to the first-second refrigerant pipe 31 connected to the first-first refrigerant pipe 30, and the first-second refrigerant pipe 31 As the second evaporator 42 of the central storage chamber 12 is formed, the refrigerant moved to the 1-2 refrigerant tube 31 is moved while cooling the air in the central storage chamber 12.

In this case, the refrigerant moved to the first-second refrigerant pipe 31 is a refrigerant passing through the first-first refrigerant pipe 30 formed in only a part of the upper storage chamber 11 and having a relatively short length. The central storage chamber 12 is cooled with a cooling efficiency almost the same as that of the refrigerant moved to the -1 refrigerant pipe 30.

The refrigerant passing through the 1-2 refrigerant tube 31 is moved to the second refrigerant tube 32 to which the 1-2 refrigerant tube 31 is connected.

Here, the second refrigerant pipe 32 is installed as a part of the first evaporator 41 in the lower portion of the upper storage chamber 11 in which the first-first refrigerant pipe 30 is installed, the upper storage chamber ( 11 is moved to the bottom of the evaporation to cool the lower portion of the upper reservoir (11).

Accordingly, the valve 20 opens the first flow passage 21 and cools the upper portion of the upper storage chamber 11 while the refrigerant moves to the first-first refrigerant pipe 30. A second refrigerant pipe 32 connected to the 1-2 refrigerant pipe 31 connected to the 1-2 refrigerant pipe 31 to cool the central storage chamber 12 and connected to the 1-2 refrigerant pipe 31. While moving to) to cool the lower portion of the upper storage chamber (11).

In addition, the refrigerant moved to the end of the second refrigerant pipe 32 is moved to the accumulator 23 to which the second refrigerant pipe 32 is connected and circulated to the compressor.

In this case, the second refrigerant pipe 32 is located in the upper storage chamber 11 located above the refrigerator 10, and the accumulator 23 is also located above the refrigerator 10, so that the second refrigerant pipe Since the distance between the 32 and the accumulator 23 is shortened and is installed at a similar height, the refrigerant moved to the end of the second refrigerant pipe 32 moves in a relatively short distance while making a small increase / decrease of the accumulator. It is moved to 23.

In addition, as the accumulator 23 continuously vaporizes the liquid refrigerant and inhales the gas refrigerant in the compressor, the refrigerant contained in the second refrigerant pipe 32 is continuously vaporized and sucked into the compressor to move to the second refrigerant. There is no refrigerant remaining inside the tube 32.

In addition, when the second passage 22 is opened after the closing of the first passage 21, the suction force of the compressor with respect to the first passage 21 is abolished, but due to the continuous vaporization of the accumulator, The refrigerant contained in the second refrigerant pipe 32 is all moved to the accumulator 23 and is moved to the compressor. Since the height of the second refrigerant pipe 32 is similar to the accumulator 23, the second refrigerant pipe 32 is used. The refrigerant inside is easily moved to the accumulator 23 and removed.

Accordingly, the coolant is moved to the first-first refrigerant pipe 30 and the first-second refrigerant pipe 31 at the same time, and the upper storage chamber 11 and the central storage chamber in which the first passage 21 is formed are formed in the refrigerator 10. 12 is simultaneously cooled, and the refrigerant moved to the first-first refrigerant pipe 30 and the first-second refrigerant pipe 31 is cooled by almost the same cooling efficiency, and the second refrigerant pipe 32 As the accumulator 23 is installed in close proximity to the accumulator 23, the refrigerant contained in the second refrigerant pipe 32 is moved to the compressor due to the action of the accumulator 23, and the refrigerant is transferred to the second refrigerant pipe 32. Is easily moved to the accumulator 23 and removed.

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

As described above, according to the present invention, the refrigerant is prevented from remaining in the evaporator of the refrigerator and the remaining refrigerant is removed, thereby preventing the refrigerator control malfunction or damage to the accumulator and the compressor due to the remaining refrigerant. It is effective to prevent.

Another effect of the present invention, while cooling the respective storage compartments of the refrigerator at about the same time, there is an effect of further improving the quality of the respective storage compartment by cooling with a uniform cooling efficiency.

Claims (2)

1 for the refrigerator selectively opening / closing by the valve the first flow path installed to move the refrigerant to the upper storage compartment in the upper part of the refrigerator and the central storage compartment in the center, and the second flow path installed to move the refrigerant to the lower storage compartment in the lower part of the refrigerator. In the middle evaporator installation structure, A first-first refrigerant pipe formed to move the refrigerant from the valve to the upper storage chamber, and installed on the upper storage chamber; A 1-2 refrigerant tube connected to an end of the 1-1 refrigerant tube and formed to move the refrigerant, and installed in the central storage chamber; The second refrigerant pipe is connected to the end of the 1-2 refrigerant pipe is formed to move the refrigerant, and the accumulator is connected to the end of the second refrigerant pipe and installed below the upper storage chamber. The refrigerant evaporator installation structure of the refrigerator, characterized in that the refrigerant is moved in the order of the 1-1 refrigerant pipe, the 1-2 refrigerant pipe, the second refrigerant pipe, the accumulator in accordance with the opening of the valve. The method of claim 1, And the second refrigerant pipe and the accumulator are installed in close proximity to each other in the upper storage compartment.

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