KR20130044819A - Wine cooling device - Google Patents

Abstract

PURPOSE: A wine cooling apparatus is provided to prevent freezing of cooling water, and to reduce a space for installation. CONSTITUTION: A wine cooling apparatus comprises: a cooling chamber, one or more first pipes, one or more second pipes, a coolant pipe, a coolant cooling module, and an oak barrel(70). The first pipe is placed to contact the air in the cooling chamber and cools wine by heat exchange with the air. The second pipe cools the wine by heat exchange with cooling water. The coolant pipe cools the cooling water nearly at freezing point by a coolant. The coolant cooling module comprises a compressor which cools the coolant, a condenser, and a cooling fan. The oak barrel has the cooling chamber and the coolant cooling module therein.

Description

Wine chiller {WINE COOLING DEVICE}

The present invention relates to a wine chiller, and more particularly, to a wine chiller capable of supplying different kinds of wines to consumers at an optimized temperature by using an air-cooled and water-cooled chilling method together.

In general, if you want to cool the wine, such as beer or wine is to cool the wine in the refrigerator in the state, in recent years is a way of cooling the liquid wine, not the wine in the container while passing through the cooling system is used.

Such a cooling system is generally composed of a container of insulation, cooling water filled in the inside, and a cooling tube disposed through the inside from the outside of the container, the wine passing through the cooling tube passes through the portion filled with the cooling water endothermic process Can be cooled to a desired temperature.

Figure 1 is a side sectional view showing a cooling system according to the prior art. The wine introduced into the vessel 1 flows from the top to the bottom along the cooling tube 2 and undergoes a cooling process through a heat exchange process with the cooling water 3.

The cooling pipe 2 extends to the outside of the container 1 with an inlet disposed at the top and an outlet disposed at the bottom. In addition, in order to improve the heat exchange performance, the cooling pipe 2 is spiraled from the top of the container 1 to the bottom.

In addition, the lower portion of the front portion of the container 1 is formed with a discharge port 4 to be drawn out to be discharged in a cooled state in a cup or another container. The valve 5 is generally provided for opening and closing to the outlet 4.

By the way, in the case of having such a structure, there is a problem that only one type of wine can be cooled to only one predetermined temperature by one cooling device.

In addition, it is practically difficult to control the set temperature freely, and according to the limitation of the container size, the required cooling effect may not be obtained or more power is consumed than necessary.

On the other hand, when the wine is to be cooled to the temperature near the freezing point of water, the temperature of the cooling water is too low, there is also a problem that the cooling water occurs.

Accordingly, the present invention has been made to solve the above problems, and an object of the present invention is to provide a wine cooling apparatus that can use a combination of air-cooled and water-cooled to cool different types of wines to optimized temperatures.

In addition, the object of the present invention is to provide a wine chiller having a simpler structure and high cooling efficiency while maintaining maintainability.

In addition, an object of the present invention is to provide a wine cooling apparatus having a structure in which the cooling water does not freeze even when supercooled.

It is also an object of the present invention to provide a wine chiller having an improved structure to supply wines of different types and temperatures at the same time.

Wine cooling apparatus according to the present invention is a cooling chamber in which the cooling water is stored at a predetermined level; At least one first pipe disposed to be in contact with the air inside the cooling chamber, wherein the wine flowing along the inside is cooled by heat exchange with the air; At least one second pipe disposed to be submerged in the cooling water, the wine flowing along the inside of the cooling pipe being cooled by heat exchange with the cooling water; A refrigerant pipe disposed to be submerged in the cooling water, and the refrigerant flowing along the inside of the refrigerant pipe cools the cooling water to a temperature near an ice point; A refrigerant cooling module comprising a compressor, a condenser, and a cooling fan for cooling the refrigerant; And an oak barrel in which the cooling chamber and the refrigerant cooling module are disposed in an inner space.

According to a preferred embodiment of the present invention, the first pipe, the second pipe and the refrigerant pipe is formed in a coil shape, the second pipe is preferably disposed inside the refrigerant pipe.

In addition, a plurality of the first and second pipes may be installed and configured to supply several kinds of wines at one time.

In addition, one end of the first and second pipe is formed with a wine supply port connected to the wine supply module, the other end is preferably connected to the valve for supplying the cooled wine.

In this case, the wine supply ports of the first and second pipes are connected to different types of wine supply modules, wherein the wine supply module includes a vacuum flask having a wine bag therein and a wine supply can of a gas injection type. It is preferable to provide one.

The valve is provided outside the oak barrel, it is preferable to control the flow rate of the wine supplied to the user from the first pipe and the second pipe.

In addition, the cooling chamber is disposed in the cooling chamber, and prevents the freezing of the cooling water further comprises; wherein the freezing prevention means may be provided as an injection device for sucking and spraying the cooling water.

On the other hand, the temperature of the wine to be cooled is preferably determined by the number of turns of the first pipe, the second pipe and the refrigerant pipe.

According to the present invention as described above, it is possible to simultaneously supply wines of various oils to consumers at different temperatures.

In addition, since the consumer installs a valve to be supplied with wine in the oak barrel, it can give the impression that the wine is directly supplied from the oak barrel.

In addition, even if the coolant is supercooled, freezing of the coolant can be prevented.

In addition, since both the wine supply and the cooling device is installed inside the oak barrel, the installation space can be reduced compared to the existing product.

1 is a side cross-sectional view showing a wine cooling apparatus according to the prior art.
Figure 2 is a side sectional view showing a wine cooling apparatus according to the present invention.
Figure 3 is a side cross-sectional view showing a state combined with the refrigerant cooling device according to the present invention.
Figure 4 is a perspective view of the oak barrel installed valves.
5 is a perspective view of the valve removed from the oak barrel of FIG.
6 is a view illustrating a state in which the oak barrel cover is removed for maintenance.
7 is a view showing a state in which the wine supply module is connected to the oak barrel.
8 and 9 are views each showing a wine supply module connected to the wine cooling apparatus according to the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail the wine cooling apparatus according to a preferred embodiment of the present invention.

Figure 2 is a side cross-sectional view showing a cooling unit of the wine cooling apparatus according to the present invention. Cooling water 50 is stored in the lower part of the case. In order to cool the cooling water 50, a refrigerant pipe 40 is disposed below the cooling chamber 10 in a coil shape. More preferably, the coolant pipe 40 is disposed to form a coil in proximity to the inner wall of the lower portion of the cooling chamber 10.

In addition, the inlet and outlet of the refrigerant pipe 40 are respectively connected to the compressor 61 and the condenser 62 which are drawn out of the cooling chamber 10 and disposed outside. Therefore, the refrigerant circulating in the refrigerant pipe 40 absorbs heat from the cooling water 50 in the cooling chamber 10, receives energy from the outside, undergoes a heat exchange process, and then returns to the inside of the cooling chamber 10 again. .

The cooling water 50 is made of a material that is slowly released by preserving long-term cold air in a low temperature state, water may be used, or a separate liquid cooling material may be used.

Apart from the refrigerant circulating in the refrigerant pipe 40, the cooling water 50 does not play a role of a refrigerant that absorbs heat again by heat exchange from the outside thereof. Therefore, the cooling water 50 is preferably selected as a material having a property of absorbing the surrounding hot or cold air well for a long time.

On the other hand, the cooling chamber 10 preferably maintains the cold temperature of the air cooled by the cooling water 50 and the cooling water 50 by using a separate insulating member to minimize heat transfer with the outside air. . As the heat insulating material is disposed in the case, heat transfer between the inside and the outside of the case may be minimized, thereby minimizing the problem of loss of cooling efficiency. The heat insulating material may be glass fiber, polystyrene foam or urethane foam, and the like, and the glass fiber may be attached to an extremely thin glass fiber by resin bonding, and there may be a difference in heat insulating effect depending on the thickness of the fiber, and thus may be appropriately selected. In addition, the polystyrene foam is a polysaturated polystyrene resin, which is easy to handle and easy to form. In addition, urethane foam is a foam produced by the reaction of isocyanate and polyol, and has excellent thermal insulation properties. do.

The cooling chamber 10 formed of the heat insulating material may include a cooling chamber body 12 having an upper side and a space part therein, and a cover 11 closing the open opening. When the cooling chamber 10 is configured as described above, the maintenance of the cooling water 50 may be more easily performed by mounting and detaching the cover 11.

According to the concept of the present invention, the method of cooling wine while circulating is used in combination of air-cooled and water-cooled. Accordingly, the first chamber 20 passing through the cooling water 50 is disposed in the lower space of the cooling chamber body 12, and the cooling chamber body 12 adjacent to the cooling cover 11 in which the cooling water 50 is not received is disposed. The second pipe 30 passing through is disposed in the upper space.

2 and 3 illustrate a state in which the first and second pipes 20 and 30 are installed one by one, but the present invention is not limited thereto, and the first and second pipes 20 and 30 operate in an air-cooled manner. A plurality of second pipes 30 may be provided, respectively, and may be configured to supply wines of multiple ends at the same time. For example, two pairs of first pipes 20 and two pairs of second pipes 30 may be provided to simultaneously supply two kinds of white wine and two kinds of red wine.

In the case of the first pipe 20, it is preferable that the refrigerant pipe 40 is formed in a coil shape. It is possible to adjust the degree of heat exchange in the coolant 50 in accordance with the number of times the first pipe 20 is wound, which is the temperature of the wine discharged from the second pipe in accordance with the number of turns of the first pipe 20 Means that you can adjust

The end of the pipe is drawn out so that the first pipe 20 can communicate with the outside of the case. Preferably the second inlet 23 and the second outlet 21 are arranged in the cooling chamber body 12, more preferably the second outlet 21 is so that the user can easily put the wine in the container It is located in front of the case.

On the end side of the second outlet 21, a second valve 22 is arranged to control the flow. Therefore, the user can operate the operation portion of the second valve 22 having a cock or lever shape to contain the cooled wine discharged from the second outlet 21 in the drinking container.

On the other hand, the second pipe 30 is additionally disposed on the upper portion of the cooling chamber body 12 so that the wine can be cooled by air cooling. Like the first pipe 20, the second pipe 30 is formed in a coil shape to increase heat exchange efficiency. However, unlike the first pipe 20, the second pipe 30 is disposed in air, which is a space above the cooling chamber body 12. There is a difference in that. The air in the upper space is cooled by the coolant 50 to be in a cooler state than the air outside the cooling chamber 10.

According to this arrangement, since the first pipe 20 is capable of direct heat exchange through the endothermic action of the cooling water 50, it is possible to discharge wine at a temperature lower than room temperature, and the second pipe 30 is relatively Since the efficiency of heat transfer is disposed in the air, it is possible to discharge the wine at a temperature relatively higher than the first pipe (20). Therefore, it should be noted that the two wines can be discharged at different temperatures by cooling by using the air-cooled and water-cooled methods as described above.

The first pipe 20 also includes a first inlet 23 and a first outlet 21 which are drawn out of the cooling chamber 10 to allow inflow and outflow of wine to and from the outside. Preferably, the first outlet 21 is disposed in front of the cooling chamber 10. Of course, the first outlet 21 may be formed adjacent to the second outlet 31.

Meanwhile, in FIG. 2, the second pipe 30 is coupled to the upper portion of the cooling chamber body 12, but the second pipe 30 may be coupled to the cover 11. Therefore, when the cover 11 is separated, the first pipe 20 may be separated together, thereby improving the maintainability. Therefore, the cover 11 is coupled to the air-cooled second pipe 30 is disposed, the cooling chamber body 12 is the concept that the water-cooled first pipe 20 and the refrigerant pipe 40 is coupled to the arrangement is presented. do.

As such, relatively high temperature cooling is possible in the upper space of the cooling chamber body 12 adjacent to the cover 11, and relatively low temperature cooling is possible in the lower space of the cooling chamber body 12.

In addition, a first valve 22 is disposed at the side of the first outlet 21 to control the flow of wine. When the user wants to discharge the wine cooled to a relatively high temperature, the first valve 22 is opened to open the first valve 22. 1 can be discharged through the outlet 21.

On the other hand, the refrigerant pipe 40 is preferably extended through the rear or side of the refrigerant chamber 10 to be connected to the compressor, the condenser and the evaporator which is an external heat exchange device. In addition, the first inlet 23 and the second inlet 33 may be formed to be pulled in from the rear or front of the cooling chamber body 12, as shown in Figure 3, the height with the outlet 21, 31 according to the selection Of course, it can be adjusted appropriately.

With the above structure, an example of cooling different wines to different temperatures will be described below. White wine flows on the first pipe 20 side which is water-cooled, and red wine flows on the second pipe 30 side which is air-cooled. White wine is about 5 ~ 10 ℃, red wine is preferably drink in the range of 15 ℃ ~ 20 ℃. Therefore, the white wine is cooled in the water pipe-type first pipe 20 capable of cooling to a relatively low temperature, and the red wine is cooled in the second pipe 30 capable of cooling to a relatively high temperature. The red wine and the white wine are just examples of wines cooled to different temperatures along the first pipe 20 and the second pipe 30, and various beverages such as juice or beer besides the wine flow according to a desired temperature. Of course you can.

On the other hand, as the cooling chamber 10 is made of a heat insulating material, the temperature of the first pipe 20 side can be further lowered, and the cooling temperature required by the air cooling method is about 5 ° C to 10 ° C than the cooling temperature of the water cooling method. High is required.

As described above, adjustment of the temperature to be cooled may be set according to the number of turns of the first pipe 20 and the second pipe 30. In addition, it is to be understood that the temperature of the wine to be cooled is the temperature of the wine discharged from the outlets 21 and 31, not the temperature inside the respective cooling pipes 20 and 30. Therefore, when the temperature of the cooling water 50 stored in the cooling chamber body 12 is around 0 ° C, the wine discharged from the second outlet 21 may exhibit a temperature of about 5 ° C to 10 ° C.

As described above, when the temperature of the cooling water 50 is set at a temperature of 0 ° C. or less, the cooling water may form ice crystals or completely freeze, which may make it difficult to control cooling of the wine. Therefore, it is preferable to provide an icing preventing device 51 so that the cooling water 50 does not icing.

The anti-icing device 51 is disposed at the lower center of the cooling chamber body 12 has a high efficiency. The icing preventing device 51 may be made of a screw that rotates by a motor to flow the coolant, or to prevent overcooling by heating the electric heater. More preferably, the freezing prevention device 51 is composed of an injection device for sucking and spraying the cooling water 50. Therefore, when the icing preventing device 51 is disposed in the cooling chamber body 12 as described above, icing of the cooling water 50 can be prevented, thereby reducing the cooling efficiency.

On the other hand, Figure 3 is a side cross-sectional view showing a wine cooling apparatus according to the present invention. In the refrigerant cooling module 60 of FIG. 3, it should be noted that all of the paths flowing out of the cooling chamber 10 of the pipe through which the wine and the refrigerant flow are disposed above the cooling chamber 10.

Therefore, it is preferable that an opening is formed in the front upper portion of the lower case 12 so that the outlets 21 and 31 and the inlets 23 and 33 can be drawn out. The inlet and the outlet are drawn out adjacent to the opening, and the first inlet 23 and the second inlet 33 extend downward to communicate with the bottom of the oak barrel 70. In addition, the first outlet 21 and the second outlet 31 are exposed to the user through the front portion of the oak barrel (70).

As described above, when the inlets 23 and 33 are disposed in front, the arrangement of the wine cooling device becomes easy, and as the inlets 23 and 33 are disposed below, the amount of wine discharged by the discharge pressure is properly controlled. You can do it.

In addition, the second pipe 30 may be formed to be coupled to the cover 11. Therefore, when the cover 11 is separated from the lower case 12, it should be noted that since the second pipe 30 and the cover 11 are separated together, ease of maintenance is provided. According to this concept, it is preferable that the outlet 31 of the second pipe 30 and the outlet 21 of the first pipe form a coupling portion with the valve 22, 32 side that is coupled to the oak barrel 70. That is, when the connection portion of the valve side and the outlet is formed in the space between the cooling chamber 10 and the oak barrel 70, there is an advantage that the ease of maintenance is improved.

Accordingly, according to the concept that the outlets 21 and 31 of the first and second pipes are detachable from the valves 22 and 32, the ends of the pipes 20 and 30 may be connected to the valves. It is preferred to engage in such a way as to be indented with the inlets of 22) (32).

In addition, in the embodiment of Figure 3 the piping of the refrigerant is formed to extend from the rear upper portion of the cooling chamber 10 to the external cooling and compression device. Therefore, both the inlet and outlet of the refrigerant pipe and the pipe are located at the top of the cooling chamber 10 and provide reliability and ease of maintenance for the refrigerant accommodation of the cooling chamber 10.

On the other hand, the first pipe 20 immersed in the cooling water 50 may be made of one strand as shown in the drawing, but two pipes may be made together, in some cases, the first pipe 20 and the second pipe 30 All may consist of two or more piping. According to this concept, the type of wine which can be cooled by the number of pipes may be increased.

Oak barrel 70 is designed to inspire and enhance the aesthetics of the consumer, it may be configured using natural wood, it is also possible to use a synthetic wood such as oak-like resin injection molding or MDF.

The oak barrel 70 may be disposed in the cooling chamber 10 and the refrigerant cooling module 60 therein. Although not shown, the oak barrel 70 may be disposed in an inner space up to a wine supply module W1 or W2 which will be described later. have. A pair of first through holes 71 and 72 are disposed on the front surface of the oak barrel 70 forming the overall appearance such that the wine outlets 21 and 31 can be controlled through the valves 22 and 32. The bottom surface is formed with second through holes 122 and 123 through which the first and second inlets 23 and 33 of the first and second pipes 20 and 30 are exposed.

In addition, the oak barrel 70 is composed of a cover member 75 that is open to the side, as shown in Figure 6, to remove a part of the exterior so that the cooling chamber 10 installed therein is exposed to enable maintenance Can be configured. Of course, although not shown, it is also possible to configure the upper disc portion to access the cover 11 by opening.

On the other hand, according to a preferred embodiment of the present invention, as shown in Figure 3, the refrigerant cooling module 60 is provided in the rear of the cooling chamber 10, it is accommodated inside the oak barrel (70). That is, the refrigerant is discharged from the refrigerant pipe 40, compressed by the compressor 61, cooled through the condenser 62 and the expansion valve, and cooled again to the refrigerant pipe 40, the liquid refrigerant is counted to the cooling chamber 10 The endothermic process is repeated inside. Heat generated in this process is discharged to the outside through the fan (63).

However, the cooling device of the refrigerant may use a thermoelectric element instead of using the relationship between the volume and temperature of the fluid such as the compressor and the condenser as described above. The Peltier element is used as the thermoelectric element, and the Peltier element means an element that absorbs heat on one side and generates heat on the other side in accordance with a current flowing by connecting end portions of different metals.

On the other hand, preferably the wine cooling apparatus according to the present invention further comprises a controller (64). The controller 64 controls the cooling process of the coolant so as to maintain the temperature of the set wine.

Therefore, it is more preferable that a temperature sensor is provided inside the cooling chamber 10 for proper control of the controller 64. According to the concept of the present invention, a method of cooling wine by using a combination of air cooling and water cooling is proposed, so that the temperature sensor is disposed on the cover 11 and the cooling chamber body 12, respectively.

The temperature signal detected by the temperature sensor is input to the controller 64, and when the temperature signal is higher than the set temperature, the compressor and a cooling device such as a condenser or a thermoelectric element are operated to cool the refrigerant and lower than the set temperature. In this case, the cooling operation will be stopped.

The temperature of the wine respectively cooled in the air cooling and water cooling methods in the cooling chamber 10 is affected by the temperature of the refrigerant flowing through the refrigerant pipe 40. However, according to the concept of the present invention, the temperature of the wine discharged through the outlets 21 and 31 is accurately controlled by the number of turns of the first pipe 20, the second pipe 30 and the refrigerant pipe 40 Can be. That is, the more the number of windings, the longer the area and the residence time for the heat exchange, so that the temperature of the wine can be further lowered, so that the number of windings of the pipes (20, 30) and the refrigerant pipe (40) appropriately adjusted The temperature of the refrigerant can be precisely adjusted.

On the other hand, the wine is cooled in a water-cooled manner according to the degree of being spaced apart from the refrigerant pipe 40 of the cylindrical first pipe 20 is spirally wound and disposed inside the refrigerant pipe 40 having a substantially cylindrical shape. The temperature can be controlled.

4 to 7 are diagrams schematically showing an example of the configuration of the wine cooling device configured as described above. As shown, in order to supply wine into the cooling chamber 10 of the wine chiller, the first and second inlets 23 and 33 are exposed to the bottom surface of the oak barrel 70 and therein. It is connected to each of the wine supply module (W1) (W2) for receiving wine.

At this time, the wine supply module (W1) may be provided as a vacuum flask having a wine bag in the portion, as shown in Figure 7, as shown in Figure 8 is provided with any one of the gas supply type wine supply can It is preferable.

When the wine supply module W1 is provided as a vacuum flask having a wine bag, the air is injected into the vacuum flask, and the injected air presses the wine bag at atmospheric pressure to squeeze the wine into the cooling chamber 10. When supplying the wine to the inside and the gas injection type cans are finished, such as a weekly supply from the draft beer house, the gas inside the can is injected into the can by the pressure of the gas to the wine inside the can the cooling chamber (10) ) Can be supplied internally. Of these two, the vacuum flask type is hygienic and suitable for wine supply.

By using the air-cooled and water-cooled together by the wine cooling device according to the present invention configured as described above there is an advantage that can be cooled to a temperature optimized for the type of wine can be cooled according to the temperature of each wine.

In addition, since the set temperature can be controlled appropriately according to the type of wine, there is an advantage to prevent the waste of excessive power, it is possible to cool the wine efficiently without the cooling water even at a temperature close to 0 ℃.

In the foregoing, the present invention has been described in detail based on the embodiments and the accompanying drawings. However, the scope of the present invention is not limited by the above embodiments and drawings, and the scope of the present invention will be limited only by the contents described in the claims below.

10 ... case 11 ... cover
12.Cooling chamber 20 ... First pipe
21 ... 1st outlet 22 ... 1st valve
23 ... 1st inlet 30 ... 2nd pipe
31 ... 2nd outlet 32 ... 2nd valve
33.2nd inlet 40 ... refrigerant tube
50 ... Coolant 51 ... Ice freeze protection
61.Compressor 62 ... Condenser
63.Fan 64 ... Controller
70 ... oak

Claims (9)

A cooling chamber in which cooling water is stored at a predetermined level;
At least one first pipe disposed to be in contact with the air inside the cooling chamber, wherein the wine flowing along the inside is cooled by heat exchange with the air;
At least one second pipe disposed to be submerged in the cooling water, the wine flowing along the inside of the cooling pipe being cooled by heat exchange with the cooling water;
A refrigerant pipe disposed to be submerged in the cooling water, and the refrigerant flowing along the inside of the refrigerant pipe cools the cooling water to a temperature near an ice point;
A refrigerant cooling module comprising a compressor, a condenser, and a cooling fan for cooling the refrigerant; And
Wine cooling device comprising a; oak barrel in which the cooling chamber and the refrigerant cooling module is disposed in the inner space.
The method of claim 1,
The first pipe, the second pipe and the refrigerant pipe is formed in a coil shape, the second pipe is a wine cooling apparatus disposed inside the refrigerant pipe.
The method of claim 1,
One end of the first and second pipe is formed with a wine supply port is connected to the wine supply module, the other end is connected to the valve for supplying the cooled wine wine cooling device.
The method of claim 3, wherein
The wine supply port of the first and the second pipe, the wine cooling apparatus connected to the different types of wine supply module.
The method of claim 4, wherein the wine supply module,
A wine cooler provided with either a vacuum flask having a wine bag inside or a wine supply can of a gas injection type.
The method of claim 1, wherein the valve,
The wine cooling apparatus installed on the outside of the oak barrel to control the flow rate of the wine supplied to the user from the first pipe and the second pipe.
The method of claim 1,
It is disposed inside the cooling chamber, and further comprising: a freezing prevention means for preventing the freezing of the cooling water,
The freezing preventing means is a wine cooling device which is a spray device for sucking and spraying the cooling water.
The method of claim 1,
The temperature of the wine to be cooled is determined by the number of turns of the first pipe, the second pipe and the refrigerant pipe winding wine chiller.
The method of claim 1,
The plurality of first and second pipes are installed, the wine cooling device is configured to supply a variety of wines at a time.

Images