KR101328762B1 - Wine cellar - Google Patents

Abstract

The present invention relates to a wine cellar structure.

By the wine cellar structure according to the present invention, there is an effect that the shortage of the refrigerant flowing into the compressor when the switch from the hakan operation to the upper column operation is eliminated.

Wine Cellar, Insulation, Evaporator

Description

Wine cellar

1 is a perspective view showing the appearance of a wine cellar according to the spirit of the present invention.

2 is a view showing a cooling system of the wine cellar according to the spirit of the present invention.

3 is a block diagram specifically showing the cooling system.

4 is a cross-sectional view taken along the line II ′ of FIG. 1, illustrating a structure for minimizing reverse heat exchange.

<Description of the symbols for the main parts of the drawings>

1: wine cellar 2: out case

3: door 4: window

5: inner case 6: upper barrier

7: lower barrier 8: upper column

9: middle cell 30: heat exchange blocking member

The present invention relates to a wine cellar structure.

In general, the environment where the wine is well ventilated, the temperature / humidity change is small, and a quiet place without vibration is preferable. Such an environment includes a basement warehouse, an oyster, and a basement layer. However, since such a natural environment is very difficult to find, a wine cellar has been introduced as a cold storage device for artificially creating such an environment.

On the other hand, in order to obtain an optimal flavor by the wine cellar, it is important to implement a suitable temperature environment, especially among the above-mentioned conditions such as temperature, humidity, ventilation, etc., in order to store wine, an appropriate temperature is approximately It is 10-18 degreeC, and when it is white wine, it is known that it is about 4-10 degreeC.

In recent years, the wine cellar that has been supplied to consumers is divided into upper compartments, middle compartments, and lower compartments, and an evaporator is disposed on the back of each compartment so that each compartment is maintained at a different temperature.

In particular, a plurality of evaporators respectively provided on the back of the upper compartment, the middle compartment and the lower compartment are connected in series, and a large number of direct-cooled wine cellars provided with a three-way valve are provided on the outlet side of the condenser. In detail, in the case of the hakan in which the internal temperature is kept at the lowest state, the refrigerant flows to the hakan side evaporator by switching the three-way valve so that the hakan is cooled to the set temperature. Then, when the internal temperature falls to the set temperature, the three-way valve is switched again so that the refrigerant flows toward the upper compartment and the middle compartment side evaporator. Then, the refrigerant passing through the condenser passes through the expansion member and then flows in the order of the upper compartment, the middle compartment and the lower compartment.

Here, the evaporators are embedded in the case constituting the wine cell body, the case is interposed with a heat insulating material for preventing the leakage of cold air.

On the other hand, during the operation of the hakan, the evaporation temperature of the hakan evaporator is lowered to minus 36 degrees, and the temperature of the heat insulating material is also lowered to about the same temperature. In this state, the refrigerant passing through the upper compartment and the middle compartment evaporator does not absorb heat from the lower compartment evaporator but is deprived to the heat insulating material when the operation is switched to the upper compartment and the middle compartment operation. Then, the amount of refrigerant vaporized is reduced, and as a result, the amount of refrigerant in the gas phase flowing into the compressor is reduced.

In addition, when the amount of refrigerant supplied to the compressor is reduced, the refrigerant is already dried out in the upper column evaporator, and the temperature of the middle column evaporator is abnormally high. Therefore, there is a disadvantage in that heat exchange with cold in the middle compartment cannot be performed smoothly. In other words, the internal temperature of the middle compartment rises above the appropriate temperature, thereby reducing the refrigeration efficiency.

In addition, the cooling time inside the wine cell is increased due to the lack of refrigerant, and furthermore, the compressor is not turned off and is immediately switched to the hakan operation, thereby causing a problem of deteriorating the life of the compressor.

The present invention has been proposed in order to solve the above technical problem, an object of the present invention is to provide a refrigerant circulation system of the wine cell to eliminate the refrigerant shortage phenomenon when switching from the hakan operation to the upper column operation.

Wine cellar according to the present invention for achieving the object as described above, the outer case, the inner case coupled to the inner side of the outer case and the insulating material interposed between the outer case and the inner case, the upper compartment and the middle compartment A main body in which a storage space divided into a hakan is formed; An upper compartment evaporator, a middle compartment evaporator, and a hakan evaporator disposed between the inner case and the heat insulating material, and connected in series with the upper compartment, the middle compartment, and the lower compartment to cool the corresponding space; A triangular valve provided at an outlet of the condenser, for branching the flow paths of the refrigerant into two to selectively supply the refrigerant to the upper column evaporator and the lower column evaporator, respectively; A first expansion device provided on a flow path between the three sides and the upper evaporator to phase change the refrigerant supplied to the upper evaporator; A second expansion device provided on the flow path between the three sides and the hakan evaporator to phase change the refrigerant supplied to the hakan evaporator; And a heat exchange blocking member disposed behind the Hakan evaporator having the lowest temperature and preventing heat exchange between the heat insulating material and the evaporator, wherein the heat exchange blocking member is a fluid-packed pack having a lower specific heat than the heat insulating material. It is formed in a shape, characterized in that formed in a shape that wraps all the remaining surfaces except the front of the evaporator.
By the above configuration, there is an effect that the refrigerant shortage phenomenon is removed when switching from the hakan operation to the upper column operation.

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Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention will be described in detail. However, the spirit of the present invention is not limited to the embodiments in which the present invention is presented, and those skilled in the art who understand the spirit of the present invention can easily make other embodiments by adding, changing, deleting, and adding components within the scope of the same idea. It may be proposed, but this will also fall within the scope of the present invention.

1 is a perspective view showing the appearance of a wine cellar according to the spirit of the present invention.

Referring to FIG. 1, the wine cellar 1 according to the present invention includes an outer case 2 forming an outer shape, an inner case 5 coupled to an inner side of the outer case 2, and the outer case 2. Insulation material 21 (see FIG. 4) interposed between the inner case 5 to block heat transfer to the outside, and an inner space of the inner case 5 includes the upper compartment 8, the lower compartment 10, and the middle compartment ( 9) the upper barrier 6 and the lower barrier 7 to be distinguished from each other, and the front part of the inner case 5 is selectively shielded so that the door 3 to maintain the appropriate temperature of the interior space is included. . The door 3 is further provided with a transparent window 4 that allows the user to easily see the interior of the wine cell 1.

In another aspect, it is described that the main body of the wine cell is formed by the outer case 2 and the inner case 5, and the main body of the wine cell is opened by the door 3.

On the other hand, the interior of the wine cellar, as described above, divided into the upper compartment (8), the middle compartment (9) and the lower compartment (10), each of the receiving space may be stored in a different type of wine. For example, the upper compartment 8, which is formed with a relatively high temperature, may store utensils such as red wine and wine glasses that are stored at a relatively high temperature, and the middle compartment 9 may store red wine, and a relatively low temperature lower hakan ( 10) white wine can be stored at a relatively low temperature. As such, the internal space of the wine cellar is partitioned by temperature because it is good for the wine to ripen and different storage temperature according to the type of wine, it is possible to increase the taste of consumers. In addition, since the temperature can be efficiently maintained according to the storage location of the wine, the energy consumption efficiency can also be increased.

2 is a view showing a cooling system of the wine cellar according to the spirit of the present invention, Figure 3 is a block diagram showing the cooling system in detail.

2 and 3, the rear of the wine cellar 1 according to the invention is provided with a machine room 20 in which the elements constituting the cooling system are accommodated.

In detail, the machine room 20 accommodates a compressor 11 for compressing a refrigerant to high temperature and high pressure. The cooling system includes a condenser 12 through which the high temperature and high pressure refrigerant compressed by the compressor 11 is condensed, and a three-way side 80 provided at an outlet side of the condenser 12 to control a flow direction of the refrigerant. And a refrigerant passing through the first expansion device 13 and the second expansion device 14 and the first expansion device 13 provided at a branch branched from the three sides 80, and the upper compartment ( The upper column evaporator 15 which heat-exchanges with the cold of 8), the middle column evaporator 15 which is connected to the outlet side of the upper column evaporator 15, and heat-exchanges with the cold of the said middle cell 9, and the said 2nd expansion apparatus 14 Refrigerant passing through the) flows, and consists of a Hakan evaporator (17) that exchanges heat with the cold of the Hakan (10). At least the upper column evaporator 15, the middle column evaporator 16, and the lower column evaporator 17 are wrapped in the heat insulating material 21 to block heat transfer to the outside air, and the upper column 8, the middle column 9, and The coolant and the refrigerant are exchanged through the inner wall of the hakan 10.

More specifically, the upper column evaporator 8, the middle column evaporator 9 and the lower column evaporator 10 are connected in series. The outlet of the second expansion device 14 is connected to the inlet side of the hakan evaporator 10.

In the wine cell cooling system according to the above-described configuration, a hakan cooling mode for cooling the lower column 10 and an upper column cooling mode for cooling the upper compartment 8 and the middle compartment 9 are selectively performed.

In detail, when the Hakan cooling mode is set, the three-way 80 is switched so that the second expansion device 14 and the condenser 12 communicate with each other. Accordingly, the refrigerant passing through the condenser 12 is changed into a two-phase refrigerant having a low temperature and low pressure while passing through the second expansion device 14. In addition, the refrigerant flowing into the hakan evaporator 17 allows the hakan 10 to be cooled to a predetermined temperature while exchanging heat with the cold of the hakan 10. At this time, the temperature of the refrigerant flowing inside the Hakan evaporator 17 is about minus 36 degrees.

On the other hand, when switched to the upper compartment cooling mode, the three-way side 80 is switched so that the condenser 12 and the first expansion device 13 communicate. Therefore, the refrigerant passing through the condenser 12 is converted into a low-temperature, low-pressure two-phase refrigerant while passing through the first expansion device 13. In addition, the expanded refrigerant is introduced into the upper column evaporator 15 to cool the upper column 8 first, and then flows into the middle column evaporator 16 to cool the secondary cell 9 secondly. The refrigerant passing through the middle column evaporator 16 flows into the lower bay evaporator 17.

Here, the refrigerant flowing into the hakan evaporator 17 is in a state where the temperature is increased while passing through the upper column evaporator 15 and the middle column evaporator 16. In addition, the temperature of the inner wall of the hakan 10 and the heat insulating material surrounding the hakan evaporator 17 is higher than that of the refrigerant passing through the bikan evaporator 16. Therefore, the refrigerant flowing into the hakan evaporator 17 after passing through the middle column evaporator 16 is deprived of heat from the refrigerant of the hakan 10. That is, reverse heat exchange occurs.

The present invention is characterized by providing a means for minimizing such reverse heat exchange. Hereinafter, a structure for minimizing such reverse heat exchange will be described in more detail with reference to the accompanying drawings.

FIG. 4 is a cross-sectional view taken along line II ′ of FIG. 1, illustrating a structure for minimizing reverse heat exchange.

Referring to FIG. 4, the wine cellar 1 according to the present invention is provided with a heat exchange blocking member 30 filled with a low specific heat fluid around the Hakan evaporator 17.

In detail, the hakan evaporator 17 is provided inside the rear wall of the hakan 10. That is, it is surrounded by the heat insulating material 21 interposed between the outer case 2 and the inner case 5. In addition, the front surface of the hakan evaporator 17 is in close contact with the rear surface of the inner case 5 constituting the hakan 10, the rear surface is surrounded by the heat exchange blocking member 30.

Here, the temperature of the Hakan evaporator 17 and the temperature of the heat insulating material 21 is maintained almost the same, the temperature of the heat insulating material 21 is characterized in that it does not rise in a short time. Therefore, in the case of the conventional wine cell structure, the refrigerant flowing into the Hakan evaporator 17 may not absorb heat from the cold air of the Hakan 10, but may be deprived of heat to the heat insulator 21. As a result, the temperature of the refrigerant is lowered so that the amount of gaseous refrigerant is reduced. In addition, since only the reduced gaseous refrigerant flows into the compressor 11, the refrigerant flow rate decreases as a whole, and thus a refrigerant shortage may occur.

In more detail, the heat exchange blocking member 30 may be formed in a pack shape filled with a low specific heat gas. Here, the type of the gas is not limited and a gas having a low heat capacity is sufficient so that heat absorption and release can be performed quickly. In addition, the heat exchange blocking member 30 may be formed to surround all surfaces except the front surface of the hakan evaporator 17. That is, it may be made along the shape of the Hakan evaporator 17.

According to the structure as described above, the fluid inside the heat exchange blocking member cooled by the refrigerant flowing inside the Hakan evaporator 17 in the Hakan cooling mode is heat in a short time from the refrigerant passing through the middle column evaporator 16 in the Upper Khan cooling mode. Absorbs and the temperature rises. This is because the fluid inside the heat exchange blocking member absorbs and releases a small amount of heat since the heat capacity is small.

In detail, heat dissipation of the refrigerant flowing into the hakan evaporator 17 through the middle column evaporator 16 is minimized while the upper column operation mode is performed. As a result, the amount of gaseous refrigerant flowing into the compressor 11 is increased, so that the refrigerant shortage does not occur in the upper column operation mode. Furthermore, the shortage of the coolant does not occur, so that the temperature of the coolant rapidly rises at the outlet of the upper column evaporator 15. As a result, the time taken for the cold air of the said intermediate | middle 9 to fall to a preset temperature is shortened.

In addition, the time taken for the upper compartment 8 and the middle compartment 9 to cool to a set temperature is shortened. As a result, it is possible to switch to the hakan cooling mode after the driving of the compressor 11 is stopped. By stopping the driving of the compressor 11 temporarily during the cycle switching process as described above, an overload operation of the compressor 11 is prevented, and an additional effect of extending the life of the compressor 11 can be obtained.

By the wine cellar structure according to the present invention having the above configuration, there is an effect that the shortage of the refrigerant flowing into the compressor when switching from the hakan operation to the upper column operation is eliminated.

Furthermore, by eliminating the shortage of refrigerant, the temperature of the middle compartment is maintained at the set temperature at the time of switching to the upper compartment operation, thereby improving the cooling efficiency. In addition, when the refrigerant shortage phenomenon is eliminated when switching to the upper column operation, excessive operation of the compressor is prevented, thereby increasing the compressor life.

Claims (10)

A main body including an outer case, an inner case coupled to the inner side of the outer case, and a heat insulating material interposed between the outer case and the inner case, and having a storage space partitioned into an upper compartment and a lower compartment; An upper compartment evaporator, a middle compartment evaporator, and a hakan evaporator disposed between the inner case and the heat insulating material, and connected in series with the upper compartment, the middle compartment, and the lower compartment to cool the corresponding space; A triangular valve provided at an outlet of the condenser, for branching the flow paths of the refrigerant into two to selectively supply the refrigerant to the upper column evaporator and the lower column evaporator, respectively; A first expansion device provided on a flow path between the three sides and the upper evaporator to phase change the refrigerant supplied to the upper evaporator; A second expansion device provided on the flow path between the three sides and the hakan evaporator to phase change the refrigerant supplied to the hakan evaporator; And  It is disposed behind the Hakan evaporator having the lowest temperature, and includes a heat exchange blocking member for preventing heat exchange between the heat insulating material and the evaporator. The heat exchange blocking member is formed in a pack shape filled with a fluid having a lower specific heat than the heat insulating material, characterized in that the wine cell, characterized in that it is formed in a shape surrounding all of the remaining surface except the front surface of the evaporator. delete delete delete delete delete delete delete delete delete

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