KR100872236B1 - Apparatus for supercooling - Google Patents

Abstract

A supercooling device is provided to supply water in the supercooled state like slush by using a water case storing water in the supercooled state not to be frozen completely. A water case(1300) is positioned in a refrigerating chamber, which supplies chilled air, to store supercooled water. A water supply port(1400) is positioned at a lower part of the water case and connected to an external water supply source. A supercooled water outlet(1350) is located at a position higher than the water supply port. A water supply valve(1410) is positioned between the external water supply source and the water supply port.

Description

Subcooler {APPARATUS FOR SUPERCOOLING}

The present invention relates to a subcooling device. More specifically, the present invention relates to a supercooling apparatus in which water is stored in a supercooled state in a bucket provided in a subcooling apparatus, and a user can take water in a supercooled state.

Subcooling means a phenomenon that no change occurs even when the melt or solid is cooled to below the phase transition temperature at equilibrium. Each substance has a stable state corresponding to the temperature at that time, so that the temperature can be gradually changed so that members of the substance can keep up with the temperature change while maintaining the stable state at each temperature. However, if the temperature suddenly changes, the member cannot afford to change to the stable state according to each temperature, so that the state remains stable at the starting point temperature, or a portion thereof changes to the state at the end point temperature.

For example, if water is gradually cooled, it will not temporarily solidify even if it reaches a temperature of 0 ° C or lower. However, when the object is in the supercooled state, it becomes a kind of metastable state, and the unstable equilibrium state is broken even by a slight stimulus, and it is easy to move to a more stable state. That is, when a small piece of material is added to the supercooled liquid or the liquid is suddenly shaken, the liquid starts to solidify immediately and the temperature of the liquid rises to the freezing point, thereby maintaining a stable equilibrium at that temperature.

BACKGROUND ART Conventionally, an electrostatic field atmosphere is created in a refrigerator, and thawing of meat and fish in the refrigerator is performed at a negative temperature. In addition to meat and fish, freshness of fruits is maintained.

This technique uses a supercooling phenomenon, which refers to a phenomenon in which the melt or solid does not change even when the melt or solid is cooled to below the phase transition temperature at equilibrium.

Such a technique includes the electrostatic field treatment method, the electrostatic field treatment device, and electrodes used in them.

1 is a view showing an embodiment of a thawing and freshness holding device according to the prior art, wherein the cold storage 1 is constituted by a heat insulator 2 and an outer wall 5, and the internal temperature control mechanism (not shown). Is installed. The metal shelf 7 installed in the interior of the storehouse has a two-stage structure, and on each stage, objects for thawing or freshness maintenance and ripening of vegetables, meat and fish are mounted. The metal shelf 7 is insulated from the bottom of the furnace by the insulator 9. The high voltage generator 3 can generate direct current and alternating voltage up to 0 to 5000 V, and the inside of the heat insulating material 2 is covered with an insulating plate 2a such as vinyl chloride. The high voltage cable 4 for outputting the voltage of the high voltage generator 3 is connected to the metal shelf 7 through the outer wall 5 and the heat insulator 2.

When the door 6 provided on the front side of the cold storage 1 is opened, the safety switch 13 (refer FIG. 2) which is not shown in figure is turned off, and the output of the high voltage generator 3 is interrupted | blocked.

2 is a circuit diagram showing the circuit configuration of the high voltage generator 3. AC 100V is supplied to the primary side of the voltage regulating transformer 15. Reference numeral 11 denotes a power supply lamp, and reference numeral 19 denotes a lamp indicating an operating state. The relay 14 operates when the above-mentioned door 6 is closed and the safety switch 13 is turned on. This state is indicated by the relay operation lamp 12. The relay contact ( 14a, 14b, and 14c are closed, and an AC 100V power source is applied to the primary side of the voltage regulating transformer 15.

The applied voltage is adjusted by the adjusting knob 15a on the secondary side of the voltage adjusting transformer 15, and the adjusted voltage value is displayed on the voltmeter. The adjusting knob 15a is connected to the primary side of the secondary boosting transformer 17 of the voltage adjusting transformer 15. In this boosting transformer 17, the boosting voltage is boosted at a ratio of 1:50, for example. When a voltage of 60V is applied, it is stepped up to 3000V.

_One end O ₁ of the secondary side output of the boosting transformer 17 is connected to the metal shelf 7 insulated from the cold storage via the high voltage cable 4, and the other end O _{2 of the} output is earthed. Moreover, since the outer wall 5 is earthed, even if the user of the cold storage 1 contacts the outer wall of the cold storage, there is no electric shock. In addition, if the metal shelf 7 is exposed in the furnace in FIG. 1, since the metal shelf 7 needs to be kept insulated in the furnace, it is necessary to separate it from the walls of the furnace (the air insulates). . In addition, when the object 8 protrudes from the metal shelf 7 and contacts the inner wall, current flows to the ground through the high wall. Therefore, when the insulating plate 2a is attached to the inner wall, the drop of applied voltage is prevented. In addition, even if the metal shelf 7 is covered with vinyl chloride or the like without exposing the inside of the furnace, the entire interior of the furnace becomes an electric field atmosphere.

In the prior art, since an electric field or a magnetic field is applied to an object to be cooled and stored so that the object enters a supercooled state, a complicated device for generating an electric field or a magnetic field for storage in the supercooled state of the object is provided. High power consumption is required for the generation of such electric or magnetic fields. In addition, such a device for generating an electric field or a magnetic field is additionally provided with a device (for example, an electric field or magnetic field shielding structure, a blocking device, etc.) for the safety of the user when the electric field or the magnetic field is generated, when the electric field or magnetic field is generated due to the high power. Should be.

An object of the present invention is to provide a subcooling device having a bucket for storing water in a subcooled state.

In addition, an object of the present invention is to provide a subcooling device having a subcooling water dispenser that can take the subcooling water from the outside of the door of the subcooling device.

In addition, an object of the present invention is to provide a subcooling device that can provide a subcooled water in which a phase is converted into a slush state when a user takes water through a dispenser.

The present invention provides a cooling chamber provided with cold air, a water reservoir for storing subcooled water, a water reservoir located at a lower portion of the water tank, connected to an external water source, a subcooled water outlet located above the water supply port, and an external water supply. It provides a supercooling device comprising a water supply valve located between the source and the water inlet.

In another aspect, the present invention further includes a water intake button for controlling the opening and closing of the water supply valve, and provides a subcooling device characterized in that the supercooled water flows out to the subcooled water outlet by opening the water supply valve.

In addition, as another aspect of the present invention, the intake passage located outside the cooling chamber, connecting the intake port and the subcooled water outlet and the intake port for intake of the subcooled water, and located in an environment of a temperature higher than the ice crystal generation temperature It provides a supercooling device, characterized in that it further comprises.

In another aspect of the present invention, the water intake passage provides a subcooling apparatus comprising an approximately V-shaped section including an upwardly facing portion, a downwardly facing portion, and a connecting portion.

In another aspect, the present invention provides a subcooling apparatus, characterized in that the subcooled water outlet is located at the top of the bucket.

In another aspect of the present invention, the cooling chamber is partitioned into a freezer compartment and a refrigerating compartment, and the water tank provides a supercooling device, characterized in that located in the freezer compartment.

In addition, the present invention is located in the interior of the freezer compartment door, a water tank for storing water at a sub-zero temperature, a water supply passage connected to the bottom of the bucket, one end is connected to the upper portion of the bucket, the other end is a water intake passage exposed outside the door and water supply It provides a supercooling device comprising a water supply valve installed on the flow path.

In another aspect of the present invention, there is provided a subcooling device, characterized in that the intake passage is located over different temperature ranges.

In another aspect of the present invention, there is provided a subcooling device, characterized in that the intake passage has a shape bent so that water remains to a predetermined position.

In another aspect of the present invention, there is provided a supercooling apparatus, wherein a position where water remains in the intake passage has a temperature environment higher than a temperature of the maximum ice crystal generation zone.

The supercooling apparatus according to the present invention includes a bucket for storing water in a supercooled state, and a user may use the water in a slush state by taking the supercooled water.

In addition, the supercooling apparatus according to the present invention can prevent the water from being frozen because the portion where the surface of the water where the ice crystals are formed is located in the temperature region of the image.

In addition, in the subcooling device according to the present invention, one end of the intake flow path of the subcooling water, that is, the intake port exists outside the subcooling device, so that the user can easily take the subcooling water from the subcooling device.

In addition, the supercooling apparatus according to the present invention can prevent the supercooling water remaining in the water intake passage from freezing because the water intake passage is located over the temperature range of the image and the sub-zero temperature region.

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

3 is a view showing a process in which ice tuberculosis is generated in the liquid being cooled. As shown in FIG. 3, the container C containing the liquid L in the cooling space S is cooled.

It is assumed that the cooling temperature of the cooling space S is cooled, for example, from room temperature to 0 degrees (phase transition temperature of water) or below the phase transition temperature of the liquid L. As this cooling proceeds, for example, below water (-1 to -5 degrees) or below the maximum ice crystal formation zone of water where ice crystals are produced at maximum at about -1 degrees to -5 degrees for water. It is intended to maintain the supercooled state of water or liquid (L) even at a cooling temperature below the maximum ice crystal generation zone.

Evaporation takes place from the liquid L during this cooling, so that the water vapor W1 flows into the gas (or space) Lg in the vessel C. When the container C is closed by the lid Ck, the gas Cg may be in a supersaturated state due to the vaporized water vapor W1. However, in the present specification, the container (C) may optionally include a lid (Ck), if included, the cold air of the cooling space directly flows in, or the surface of the liquid (L) or the temperature of the gas (Lg) on the surface The cooling by the cold air can be prevented to some extent.

As the cooling temperature reaches or passes the temperature of the maximum ice crystal generation zone of the liquid L, it is formed as freeze tuberculosis F2 on the inner wall of the container or freeze tuberculosis F1 in the gas Lg. Alternatively, condensation takes place at a portion where the surface Ls of the liquid L and the inner wall of the container C (which substantially coincide with the cooling temperature of the cooling space S) are formed and the condensed liquid L is iced. It can be formed as freezing tuberculosis (F3).

For example, when the frozen tuberculosis F1 in the gas Lg descends and penetrates into the liquid L through the surface Ls of the liquid L, the supercooled state of the liquid L is released and the liquid ( A freezing phenomenon is caused in L), and the supercooling of the liquid L is released.

Alternatively, when the frozen tuberculosis F3 comes into contact with the surface Ls of the liquid L, the supercooled state of the liquid L is released, thereby causing a freezing phenomenon in the liquid L. FIG.

As described above, looking at the process of formation of freezing tubers F1 to F3, when the liquid L is stored below the temperature of the maximum ice crystal generation zone of the liquid L, it is evaporated from the liquid L, and the liquid Release of the supercooled state of the liquid L due to freezing of water vapor on the surface Ls of (L) and freezing at the inner wall of the container C near the surface Ls of the liquid L. Is caused.

4 is a view showing a process for preventing the formation of ice tuberculosis applied to the supercooling apparatus according to the present invention.

4 shows the temperature on the surface Ls of the gas Lg or the liquid L so as to prevent freezing of the water vapor W1 in the gas Lg, ie, to maintain the water vapor W1 state continuously. More preferably, the phase transition temperature of the liquid L is higher than or equal to the temperature of the maximum ice crystal generation zone of L). In addition, the temperature of the surface Ls of the liquid L is set to the temperature of the maximum ice crystal generation zone of the liquid L so that the surface Ls of the liquid L does not freeze even if it contacts the inner wall of the container C. More preferably, the phase transition temperature of the liquid L is equal to or higher than that.

As a result, the liquid L in the container C is maintained in the supercooled state at or below the phase transition temperature or below the maximum ice crystal generation temperature of the liquid L.

5 is a supercooled state graph of water according to FIG. 4. The graphs of FIG. 5 are temperature graphs measured with the principle according to FIG. 4 applied when liquid L is water.

As shown in FIG. 5, line I is a cooling temperature curve of the cooling space S, line II is a temperature curve of gas Lg (air) on the water surface in the container C, and line III is a container ( C) The temperature of the outer surface, the temperature of the outer surface of the container (C) is substantially the same as the temperature of the water inside the container (C).

As shown, when the cooling temperature is maintained at about -13 to -14 degrees (see line I), the temperature of the gas Lg on the water surface in the vessel C is about 4 higher than the temperature of the maximum ice crystal generation zone of the water. When maintained at -6 degrees, the supercooled state in which the liquid state is maintained stably is maintained for a long time while the temperature of the water in the vessel C is maintained at about -11 degrees, which is below the temperature of the maximum ice crystal generation zone of the water.

6 is a view showing a supercooling apparatus according to an embodiment of the present invention. The supercooling apparatus 1000 includes a casing 1200 constituting an external appearance and includes a cooling chamber 1100 maintained at a sub-zero temperature in the casing 1200. The casing 1200 includes a main body 1210 and a door 1220, and the casing 1200 includes a foamed layer formed of a heat insulating material to insulate the cooling chamber 1100 from the outside. The door 1220 is provided with a bucket 1300 for storing the subcooled water. The bucket 1300 is formed to be exposed to the cold air of the cooling chamber 1100. Thus, the water stored in the bucket 1300 is stored at sub-zero temperatures.

In addition, the lower portion of the bucket 1300 is connected to the water supply flow path 1400 for introducing water into the bucket from the external water supply source, the valve 1410 for controlling the inflow of water is installed in the water supply flow passage 1400. A water intake passage 1330 is connected to an upper portion of the bucket 1300 so that the supercooled water stored in the bucket can be withdrawn from the outside of the door 1220. The intake passage 1330 is connected to the intake port 1350 through the door 1220. The water supply passage 1400 is connected to the lower portion, the water intake passage 1330 is connected to the upper portion, and the inside of the bucket 1300 is filled with water without an air layer. In addition, in order not to generate an air layer, the discharge of water from the bucket 1300 is such that the water flows into the bucket 1300 through the opening of the valve 1410 and pushes the water inside the bucket 1300, thereby causing the water intake path 1330 to be removed. Water is discharged through the intake port 1350 located outside the door 1220 through the. Therefore, since the air layer is not formed inside the water tank, ice crystals are not generated, the water inside the water tank 1300 may be stored in a supercooled state.

 Around the intake port 1350, there is also a lever 1360 that allows the user to control the discharge of the supercooled water. The lever 1360 and the valve 1410 are designed to be mechanically or electronically interlocked so that when the user pushes the lever 1360 to take in the supercooled water, the valve 1410 is opened to drain the water inside the bucket 1300. To be pushed. Since the position of the valve 1410 and the lever 1360 is difficult to be mechanically interlocked, it is difficult to design the position of the valve 1410 and the lever 1360 close, or electronically interlocked through a control unit (not shown) It is desirable to design as possible.

FIG. 7 is a diagram illustrating an example of a subcooled water dispenser included in a subcooling device according to an embodiment of the present invention. As described above, the bucket 1300 is exposed to the cold air of the subcooling chamber 1100 (shown in FIG. 6). The water supply passage 1400 is connected to the water tank 1300, and the water supply passage 1400 is provided with a valve 1410 for controlling inflow of water. One end of the water supply passage 1400 is connected to the water supply source, and the other end is connected to the water tank 1300. Preferably, the other end of the water supply passage 1400 is connected to the lower portion of the water tank 1300 or inserted into the water tank 1300 and positioned below the water tank 1300.

In addition, the upper portion of the bucket 1300 is connected to the intake passage 1330 for discharging the supercooled water to the outside, and the other end of the intake passage 1330 is connected to the intake port 1350 located outside the subcooling apparatus 1000. In the vicinity of the intake port 1350, a member that allows a user to select whether to take the supercooled water is installed, and a lever 1360 is generally used. The user opens the intake flow path 1330 by pressing the lever 1360 against the cup 1360, and the supercooled water is discharged into the cup, and the supercooled water is converted into a slush state by a free fall. The opening of the water intake passage 1330 is preferably performed simultaneously with the opening of the water supply passage 1400. This is because the supercooled water is pushed out by the inflow of water through the opening of the water supply passage 1400 to remove the air layer, which is an environment in which ice crystals are generated in the bucket 1300, and the water is discharged through the intake passage 1330.

The water intake passage 1330 is connected to the outside of the subcooling device through the heat insulating material of the door 1220. The exterior of the door 1220, that is, the exterior of the subcooling apparatus is room temperature, and the subcooling chamber 1100 in which the water tank 1300 is located is below freezing. Therefore, the temperature of the heat insulator has a linear temperature distribution such that the outer surface side of the door 1220 has a room temperature and the inner surface side of the door 1220 has a temperature below zero. Therefore, the water intake passage 1330 is located over the temperature range of room temperature from the sub-zero temperature. At this time, the shape and length of the water intake flow path 1330 are selected so that the surface of the water remaining in the water intake flow path 1330 is located at a temperature region higher than the temperature of the maximum ice crystal generation zone, thereby freezing the water remaining in the water intake flow path 1330. You can prevent it. Since the water intake passage 1330 has a curved shape at a predetermined height relative to the bucket 1300, water may always remain in the curved portion. In addition, the temperature of the environment of the curved portion can be set by having the curved portion positioned at a predetermined depth from the outer surface of the door 1220. Accordingly, the water remaining in the water intake passage 1330 may be in a predetermined temperature range, and the surface of the remaining water may remain at a temperature higher than the maximum ice crystal generation zone, more preferably at the temperature of the image. Therefore, since ice crystals are not generated on the surface of the water remaining in the water intake passage 1330, the water remaining in the water intake passage 1330 may not be frozen. In addition, since the water in the intake passage 1330 is not frozen, the water stored in the bucket 1300 may also be stored in a supercooled state without being frozen. Therefore, the subcooling apparatus provided in the present invention stores the water stored in the bucket 1300 and the water intake passage 1330 in a supercooled state, and can be used in a slush state when the user desires it.

1 is a view showing an embodiment of a thawing and freshness holding device according to the prior art;

2 is a circuit diagram showing a circuit configuration of the high voltage generator 3;

3 is a view showing a process of generating ice tuberculosis in the liquid being cooled,

4 is a view showing a process for preventing the formation of ice tuberculosis applied to the supercooling apparatus according to the present invention,

5 is a supercooled state graph of water according to FIG. 4,

6 is a view showing a supercooling apparatus according to an embodiment of the present invention,

7 is a diagram illustrating an example of a subcooling water dispenser provided in a subcooling device according to an embodiment of the present invention.

Claims (10)

A cooling chamber provided with cold air; A bucket for storing subcooled water located inside the cooling chamber; A water inlet located at the bottom of the water tank and connected to an external water source; A subcooled water outlet located above the water supply port; And And a water supply valve positioned between the external water supply source and the water supply port. The method of claim 1, And a water intake button for controlling opening and closing of the water supply valve. Subcooling apparatus, characterized in that the subcooled water flows out to the subcooled water outlet by opening the water supply valve. The method of claim 1, Located on the outside of the cooling chamber, the inlet for intake of supercooled water; And a water intake passage connecting the subcooled water outlet and the intake port and positioned in an environment of a temperature higher than the ice crystal generation temperature. The method of claim 3, The intake flow passage is characterized in that the subcooling device comprises a substantially fin-shaped section consisting of a portion facing upwards and a portion facing downwards. The method of claim 1, The subcooling water outlet is located in the upper portion of the water tank. The method of claim 1, The cooling chamber is divided into a freezer compartment and a refrigerating compartment, The water tank is supercooling apparatus, characterized in that located in the freezer compartment. Located in the interior of the freezer door, the water reservoir for storing the water at a sub-zero temperature; A water supply passage connected to the lower portion of the bucket; One end is connected to the upper portion of the bucket, the other end is the water intake passage exposed out of the door; And And a water supply valve installed on the water supply passage. The method of claim 7, wherein Intake flow passages are characterized in that located over different temperature ranges. The method of claim 7, wherein The water intake passage has a shape bent so that water remains to a predetermined position. The method of claim 9, The location where water remains in the water intake passage has a temperature environment higher than the temperature of the maximum ice crystal generation zone.

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