KR100886987B1 - Apparatus for supercooling - Google Patents

Abstract

The present invention has a bucket for receiving cold air, the water can be stored at a low temperature, having an end connected to the bottom of the bucket, located in the water supply passage and the water supply for supplying water to the bucket, and applying an electric field to the bucket Provided is a supercooling device comprising a pair of electrodes. With this arrangement, the water stored in the bucket can maintain the liquid state without causing a phase transition, i.e., without freezing, even below the phase transition temperature. In addition, since the water supply passage is connected to the lower portion of the bucket, it is possible to prevent the supercooled water from being frozen due to the impact of the drop of water supplied to the bucket.

Dispenser, Supercooling, Freezing, Electrodes, Refrigerator, Euro, Bucket

Description

Subcooler {APPARATUS FOR SUPERCOOLING}

1 is a view showing an example of a refrigerator equipped with a conventional dispenser,

2 is a view showing a bucket, a water supply passage and an electrode provided in the supercooling apparatus according to an embodiment of the present invention;

3 is a view showing a supercooling apparatus according to an embodiment of the present invention.

Subcooling means that the liquid does not transition even below the phase transition temperature to a solid and maintains a high temperature phase, that is, a liquid state. In the natural state, for example, the supercooled water drop (supercooled water drop) is an example, even in the conventional refrigerator, the water or the drink does not freeze by chance in the case of the supercooled state. Meanwhile, as the principle of subcooling is applied to a refrigerator, there are a freezing method disclosed in Japanese Patent Laid-Open Publication No. S59-151834 and a freezing method disclosed in Japanese Patent Laid-Open Publication No. 2001-086967 and a refrigerator. A technique of applying a magnetic field to maintain a food in a supercooled state below a phase transition temperature is disclosed. In addition, the electrostatic field treatment method disclosed in WO / 98/41115 discloses various types of electrode structures that can be used for supercooling and thawing food.

1 is a view illustrating an example of a refrigerator equipped with a conventional dispenser, and the refrigerator 10 includes a freezing chamber 11 and a refrigerating chamber 12. An ice maker 13 is provided in the freezer compartment 11, and a dispenser 15 is provided in the freezer compartment door 14. A flow path 16 for supplying water to the ice maker 13 and the dispenser 15 is formed, the flow path 16 is connected to an external water supply source (not shown), and the flow path 16 has a first valve 17. The filter 18 and the second valve 19 are located. The first valve 17 controls the water supply from the external water supply to the refrigerator 10, the filter 18 filters the water, and the second valve 19 opens a flow path 16a for supplying water. It includes, and the water in the flow path (16a) is cooled through the heat exchange with the freezing chamber 11 and flows out through the outlet (16b) of the flow path (16a) or the outlet (15a) of the dispenser (15).

However, the conventional refrigerator dispenser prevents the freezing of water by using a heater, and when the water is frozen, it is released by using a heater, and thus there is a problem in that the refrigerator has an adverse effect of raising the temperature of the water in order to lower the temperature.

Accordingly, there has been developed a supercooling device that prevents freezing of water by applying an energy field such as an electric field to a bucket for storing water instead of a heater. However, in the conventional supercooling apparatus, as external water flows into the bucket, there is a concern that the supercooling of the supercooled water stored in the bucket may be released by the drop of water and the inflow of hot water having a relatively high phase transition temperature.

An object of the present invention is to provide a subcooling device having a dispenser capable of withdrawing subcooled water from the outside.

In addition, an object of the present invention is to provide a subcooling device having a water reservoir for storing the supercooled water and a water supply passage for introducing water into the water bucket.

In addition, an object of the present invention is to provide a subcooling device that can prevent the subcooling of the subcooled water by the water flowing through the water supply passage.

The present invention has a bucket for receiving cold air, the water can be stored at a low temperature, having an end connected to the bottom of the bucket, located in the water supply passage and the water supply for supplying water to the bucket, and applying an electric field to the bucket It provides a supercooling device comprising an electric field generating unit. With this arrangement, the water stored in the bucket can maintain the liquid state without causing a phase transition, i.e., without freezing, even below the phase transition temperature. In addition, since the water supply passage is connected to the lower portion of the bucket, it is possible to prevent the supercooled water from being frozen due to the impact of the drop of water supplied to the bucket.

In still another aspect of the present invention, there is provided a supercooling apparatus, wherein the water supply passage has a gentle inclination. Through such a configuration, it is possible to prevent the rapid inflow of water into the bucket.

In still another aspect of the present invention, there is provided a supercooling apparatus, wherein the water supply flow passage is formed in a spiral shape. Through this configuration, water can be smoothly introduced without canceling the supercooled state of the subcooled water.

In addition, as another aspect of the present invention, the water supply passage provides a supercooling device, characterized in that the bypass around the water tank so as to exchange heat with the water tank. Through this configuration, since water having a relatively higher temperature than the supercooled water introduced from the outside is introduced into the water tank after the temperature is lowered through heat exchange, the temperature of the supercooled water stored inside the water tank is prevented from being released from the supercooled state. can do.

In addition, as another aspect of the present invention, the water supply passage provides a supercooling device, characterized in that the upstream of the portion connected to the lower portion of the water tank performs heat exchange while contacting the water tank. Through this configuration, it is possible to heat exchange with the bucket before the water supplied from the outside is introduced into the bucket.

In another aspect of the present invention, the water supply passage provides a supercooling device, characterized in that formed by a tube connecting the water tank with the outside.

In addition, as another aspect of the present invention, the electric field generating unit provides an subcooling device comprising an electrode located outside the water supply passage, and a power supply unit for applying a high voltage to the electrode. Through such a configuration, it is possible to apply a high-voltage alternating current power to the electrodes, thereby preventing an electric field from being formed between the electrodes and freezing the water supply flow path located between the electrodes.

In still another aspect of the present invention, the water supply passage provides a supercooling device, wherein the other end is at least at a position higher than the top of the bucket. Through such a configuration, even when a very small amount of water escapes from the bucket, water can be easily supplied from the outside.

In another aspect of the present invention, the water supply passage provides a supercooling device, characterized in that one end connected to the bottom of the bucket is connected at least below the center of the bucket. Through this configuration, it is possible to reduce the drop between the supercooled water stored in the bucket and one end of the water supply passage.

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

2 is a view showing a bucket, a water supply flow path and an electrode provided in the subcooling device according to an embodiment of the present invention, Figure 3 is a view showing a supercooling device according to an embodiment of the present invention. The supercooling apparatus 100 includes a cooling chamber 101 and a door 102 that opens and closes the cooling chamber 101. The door 102 is filled with a heat insulator 103, a flow path 104 is formed in the door 102, the flow path 104 is connected to an external water source, and the flow of water on the flow path 104 is prevented. A high pressure AC voltage is applied to the valve 105 for controlling the water, the water tank 106 containing water, the electrode 107 for applying an electric field to lower the phase transition temperature of the water stored in the water tank 106, and the electrode 107. A power supply unit (not shown) to be applied, a temperature sensor 108 for sensing the temperature of the water tank and an outlet 104a through which water is provided are provided. Opening of the outlet 104a is achieved by the user pressing the actuating lever 109.

A power supply unit (not shown) for applying a high voltage AC voltage is connected to the electrode 107, and a power supply unit (not shown) applies a high voltage AC voltage to the electrode 107, and is located between the electrodes 107. An electric field is formed in the bucket 106 to supply energy to the bucket 106 so that the water does not freeze.

The flow path 104 may be divided into a water supply flow path 104a and a water extraction flow path 104b, and the water supply flow path 104a is a flow path for supplying water from the external water supply source to the bucket 106, and a water extraction flow path 104b. ) Is a flow path for taking out water from the bucket 106 to the outside of the subcooling apparatus 100. One end of the water supply passage 104a is connected to the water tank 106, the other end is connected to an external water supply source, and a valve 105 is positioned between the external water supply source and the other end. One end of the water supply passage 104a is located below the water tank 106. In the bucket 106, the phase transition is prevented by the electric field applied by the electrode 107, so that the uncooled subcooled water is stored. By the way, when the water level of the supercooled water in the bucket 106 is lowered, when water is supplied from the external water supply to the bucket 106 through the water supply passage 104a, one end of the water supply passage 104a is If it is located above the water level, the water will impact the supercooled water by the drop. The supercooled water does not have high freezing stability and can be easily frozen by such an impact. Therefore, one end of the water supply passage 104a is connected to the lower portion of the bucket 106 so that the water supplied to the bucket 106 does not impact the supercooled water by dropping and freeze the supercooled water.

In addition, the water supply passage 104a and the water extraction passage 104b may be formed by hoses and pipes of various materials. At this time, the water supply passage 104a is in contact with the outer surface of the bucket 106, it is preferable that one end is connected to the lower portion of the bucket 106 to surround the bucket 106 in a spiral. The water flowing through the water supply passage 104a is almost equal to the temperature of the water of the external water supply source and generally has a water temperature higher than the phase transition temperature of the water. If the water supplied to the bucket 106 is introduced into the bucket 106 while maintaining a high water temperature, there is a fear that the water temperature of the supercooled water stored below the phase transition temperature rises and the supercooled state is terminated. Therefore, before the water is introduced into the bucket 106 from the external water supply source to be sufficiently subjected to heat exchange. Here, when one end of the water supply flow path (104a) is connected to the lower portion of the bucket 106, there is an advantage that the time for heat exchange with the cold circulating through the bucket 106 and the cooling chamber 101 is long.

At this time, the electrode 107 is positioned outside the water supply passage 104a so that an electric field may be applied to the water supply passage 104a. Through this configuration, the electric field applied by the electrode 107 affects the water supply passage 104a and a part of the water extraction passage 104b, so that not only the water stored in the bucket 106 but also the water supply passage 104a And freezing of water passing through the water extraction flow path 104b.

The water extraction flow path 104b is located above the water tank 106. A part of the water extraction flow path 104b may be configured to extend into the bucket 106. The water level of the supercooled water should be adjusted so that the supercooled water stored in the water tank 106 can be smoothly drawn out through the water outlet passage 104b, and the level of the supercooled water is controlled by opening and closing the valve 105.

The supercooling apparatus according to the present invention can directly take out the supercooled water from the outside of the subcooling apparatus without opening the door of the subcooling apparatus.

In addition, the supercooling apparatus according to the present invention is connected to the lower portion of the bucket having a gentle inclination of the water supply passage for introducing the water into the bucket for storing the subcooled water, the water flowing into the bucket impacts the supercooled water to cause freezing Can be prevented.

In addition, the supercooling apparatus according to the present invention, since the water supplied from the external water source to the bucket for storing the subcooled water is introduced into the bucket in a low temperature state through a heat exchange sufficiently, the water temperature of the supercooled water stored in the bucket It can be prevented by canceling the supercooling state by increasing the.

In addition, the supercooling apparatus according to the present invention may apply an electric field to the water supply flow path and the water extraction flow path located around the water tank to prevent the freezing of water existing on the flow path or the flow path located around the water tank. .

Claims (9)

A bucket for receiving cold air and storing water at a low temperature; A water supply passage having an end portion connected to the lower portion of the bucket and supplying water to the bucket; A water extraction flow path for extracting water from the bucket to the outside; And Located in the vicinity of the bucket, the electric field generating unit for applying an electric field to the bucket; subcooling apparatus comprising a. The method of claim 1, The water supply flow passage is installed obliquely around the water tank. The method of claim 1, The water supply flow passage is made of a spiral, characterized in that the supercooling device. The method of claim 1, The water supply flow passage bypasses the water tank so that heat exchange with the water tank is possible. The method of claim 1, The water supply flow path is a supercooling apparatus characterized by performing heat exchange while the upstream portion of the portion connected to the lower portion of the bucket is in contact with the bucket. The method of claim 1 The water supply flow passage is formed by a tube connecting the outside and the water tank. The method of claim 1, The electric field generating unit includes an electrode unit located outside the water supply passage, and a power supply unit applying a high voltage to the electrode unit. The method of claim 1, The water supply flow passage is a subcooling device, characterized in that the other end is at least a position higher than the top of the water tank. The method of claim 1, The water supply flow passage, the end portion connected to the lower portion of the bucket is connected to the lower portion than the center of the bucket at least.

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