KR101008281B1 - Refrigerator for thawing - Google Patents

Abstract

The present invention relates to a thawing refrigerator using a cooling tank. The thawing refrigerator of the present invention includes a cooling tank for containing a fluid. The evaporator cools the fluid contained in the cooling tank. The cooled fluid circulates around the thawing chamber so that the temperature inside the thawing chamber is at a temperature suitable for thawing. Alternatively, a pipe in which one end is in contact with the fluid contained in the cooling tank may be installed in the thawing chamber to transfer the cool air of the fluid into the thawing chamber.

According to the present invention, since the fluid contained in the cooling tank is cooled and circulated around the thawing chamber, condensation does not occur inside the thawing chamber. In addition, there is no temperature deviation according to the position inside the thawing chamber. Therefore, it is possible to thaw without damaging the food to be thawed.

Refrigerator, thawing, indirect cooling, cooling tank, heat pipe, fluid

Description

Thawing Refrigerator {Refrigerator for thawing}

The present invention relates to a thawing refrigerator, and more particularly, to a thawing refrigerator that cools a fluid contained in a cooling tank, and delivers the cold air of the fluid to a thawing chamber.

Typically refrigerators are used for cold storage of food. A typical refrigerator includes a refrigerator compartment for storing food at a low temperature of an image, and a freezer compartment for freezing food at a sub-zero temperature. Food stored frozen in the freezer is frozen, so when taken out and cooked immediately, only the outside of the food is cooked and not inside. Therefore, frozen foods are usually thawed before cooking.

Conventionally, the frozen food was left at room temperature to thaw the frozen food. However, when the frozen food is left at room temperature, water is formed around the food and the food may be easily damaged. As another method, there is a method of heating and thawing frozen food using a cooking utensil such as a microwave oven. However, this method ripens the surface of the food during the heating process. Especially in the case of fish or meat, thawing will change the taste of the food.

To solve this problem, various types of thawing refrigerators have been developed. The conventional thawing refrigerator has been thawed by installing a fan in the thawing chamber and injecting warm air into the thawing chamber. However, when warm air circulates inside the thawing chamber, there is a problem that food to be thawed dries. Another type of thawing refrigerator was installed along the wall of the thawing chamber so that the temperature inside the thawing chamber was a suitable temperature for thawing. However, this type of direct cooling causes condensation inside the thawing chamber, and due to the temperature difference between the evaporator and other parts inside the thawing chamber, it is difficult for the sensor to detect the correct temperature inside the thawing chamber, so that thawing is properly performed. There is a problem that is not.

The problem to be solved by the present invention is to provide a refrigerator for thawing the condensation phenomenon does not occur while thawing the food at a low temperature of the image so that food is not damaged.

In addition, the temperature inside the thawing chamber is kept constant, it is to provide a refrigerator for thawing does not occur in the temperature difference according to the position inside the thawing chamber.

The thawing refrigerator according to the embodiment of the present invention includes a thawing chamber, a cooling tank, an evaporator, and a pipe. The cooling tank is located on at least one side of the thawing chamber. The fluid is contained in the cooling tank. The evaporator is located inside the cooling tank. The evaporator absorbs the heat of the fluid contained in the cooling tank as the refrigerant passes. Thus, the temperature of the fluid contained in the cooling tank is lowered. The pipe is located inside the thawing chamber. One end of the pipe is in contact with the fluid contained in the cooling tank. The cool air of the fluid is transferred to the inside of the thawing chamber through the pipe.

A thawing refrigerator according to another embodiment of the present invention includes a thawing room, a door, a cooling tank, and an evaporator. The door is located on one side of the thawing chamber. The cooling tank is partially in contact with the door. The cooling tank is located on at least one side of the thawing chamber. The evaporator is located inside the cooling tank. The evaporator absorbs the heat of the fluid contained in the cooling tank as the refrigerant passes. The door is provided with protrusions in contact with the cooling tank. The fluid contained in the cooling tank can enter and exit the door through the protrusion. The interior of the thawing chamber may further include a pipe for transferring the cold air of the fluid contained in the cooling tank into the thawing chamber. In the present embodiment, the cooling tank may have a cover elastically supported at a portion in contact with a portion of the door. The cover may be opened by the protrusion when the door is closed and by elasticity when the door is opened.

In the present invention, the pipe located inside the thawing chamber may be a heat pipe. Alternatively, a hole through which fluid may move may be formed at one end of the pipe. This hole allows fluid contained in the cooling tank to move inside the pipe.

In the present invention, the cooling tank may further include a fan. The fan circulates the fluid in the cooling tank. In another embodiment, the cooling tank may further include a guide portion. The guide part is located inside the cooling tank, and when the guide part is installed, the circulation of the fluid in the cooling tank is smooth. In another embodiment, the cooling tank may further comprise a valve. Valves are used to inject fluid into or out of a cooling tank. An insulation portion may be formed outside the cooling tank to prevent cold air from being released to the outside of the cooling tank.

The present invention uses a method of circulating the fluid contained in the cooling tank to circulate outside the thawing chamber, so that condensation does not occur inside the thawing chamber.

In addition, since the cool air of the fluid contained in the cooling tank is transferred to the thawing chamber by using a pipe, the temperature inside the thawing chamber can be maintained at a low temperature of the image, and the temperature difference does not occur in the thawing chamber. Therefore, it is possible to thaw at low temperatures so that food is not damaged during the thawing process.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Note that, in the drawings, the same components are denoted by the same reference symbols as possible. In addition, detailed descriptions of well-known functions and configurations that may blur the gist of the present invention will be omitted. For the same reason, in the accompanying drawings, some components are exaggerated, omitted or schematically illustrated.

1 is a view showing the principle of the thawing refrigerator according to an embodiment of the present invention.

As shown in FIG. 1, the thawing refrigerator 100 according to the embodiment of the present invention includes a compressor 110, a condenser 120, an evaporator 130, a cooling tank 140, a thawing chamber 150, and a pipe. And 160. The compressor 110 compresses and circulates the refrigerant in a gaseous state using a motor 111 at a high pressure. As the refrigerant, a material having a large latent heat and easily evaporated and compressed, such as ammonia or freon gas, may be used. The refrigerant compressed by the compressor 110 flows into the condenser 120. In the condenser 120, the heat of the refrigerant is released to the outside of the thawing refrigerator 100, and the refrigerant is liquefied.

The refrigerant liquefied in the condenser 120 is introduced into the evaporator 130 through the capillary tube. The evaporator 130 is located inside the cooling tank 140. The interior of the cooling tank 140 is filled with a fluid such as air or oil. The oil used in the present invention is hygienic, and oil having a low viscosity is preferable. The refrigerant absorbs heat of the fluid contained in the cooling tank 140 while passing through the evaporator 130. As a result, the refrigerant rises in temperature to vaporize, and the temperature of the fluid contained in the cooling tank 140 is lowered. After that, the refrigerant flows back into the compressor 110.

The pipe 160 protruding into the thawing chamber 150 has one end in contact with the fluid contained in the cooling tank 140. Therefore, when the temperature of the fluid contained in the cooling tank 140 is lowered, the temperature of the pipe 160 is also lowered. When the temperature of the pipe 160 is lowered, the internal temperature of the thawing chamber 150 is also lowered. In this embodiment, the sensor 151 senses the internal temperature of the thawing chamber 150, and may control the compressor 110 to maintain the internal temperature of the thawing chamber 150 at a temperature suitable for thawing. In another embodiment, the sensor 151 may sense the temperature of the fluid contained in the cooling tank 140 to control the compressor 110 so that the internal temperature of the thawing chamber 150 is maintained at a temperature suitable for thawing.

In general, considering that the temperature of the food frozen in the freezer is -20 ℃ ~ -10 ℃, if the internal temperature of the thawing chamber 150 is an image, the frozen food may be thawed. However, when the internal temperature of the thawing chamber 150 is maintained in a high state, food may deteriorate while thawing. An appropriate internal temperature of the thawing chamber 150 for allowing food to thaw without spoiling is about 1 ° C.

2 is a view showing the structure of a thawing refrigerator according to an embodiment of the present invention.

As shown in FIG. 2, the thawing refrigerator 200 includes an evaporator 230, a cooling tank 240, a thawing chamber 250, a pipe 260, a heat insulating part 270, a door 280, and a cooling part. The case 290 may be included. The cooling unit case 290 may accommodate a compressor, a condenser, and the like for cooling. In the present embodiment, the cooling unit case 290 is located below the thawing chamber 250, but is not limited thereto. The door 280 is located at one side of the thawing chamber 250. Through the door 280, food may be put into or taken out of the thawing chamber 250.

The cooling tank 240 is located at the side of the thawing chamber 250. In other embodiments, the cooling tank 240 may be located across several sides of the thawing chamber 250. The interior of the cooling tank 240 is filled with a fluid. The fluid can be air or oil. The fluid circulates inside the cooling tank 240. In addition, the fluid circulating in the cooling tank 240 exchanges heat with the inside of the thawing chamber. The fan 241 may be installed to smoothly circulate the fluid in the cooling tank 240. The position of the fan 241 may be anywhere where fluid circulation is smooth. In addition, the guide part 242 may be installed in the cooling tank 240 to facilitate the circulation of the fluid. The guide part 242 may be installed in various places in various places according to the movement path of the fluid. Cooling tank 240 may have a valve 243 that can drain or inject fluid. The valve 243 may be provided in plurality, if necessary. Valve 243 may be used to clean or repair cooling tank 240.

The evaporator 230 is located inside the cooling tank 240, and both ends thereof are connected to the cooling unit case 290. As the refrigerant passes through the evaporator 230, the temperature of the fluid contained in the cooling tank 240 is lowered.

The pipe 260 is located inside the thawing chamber 250, and one end of the pipe 260 contacts the fluid contained in the cooling tank 240. In order to bring the pipe 260 into contact with the fluid contained in the cooling tank 240, a hole or a groove is drilled in the side surface of the cooling tank 240 in contact with the thawing chamber 250, and then the pipe 260 is inserted into the hole or the groove. The packing method can be used. Since the pipe 260 is in contact with the fluid contained in the cooling tank 240, the pipe 260 delivers the cool air of the fluid to the thawing chamber 250. The material of the pipe 260 may be made of a material that transfers heat (cold air) well. The interior of the pipe 260 is filled with a fluid such as air or freon. The pipe 260 may be installed to have a predetermined slope to allow the fluid to circulate well in the pipe 260. When the pipe 260 has a predetermined inclination, a shelf 261 may be installed to stably place an object (for example, food) to be thawed. Shelf 261 may be installed on top of pipe 260.

In other embodiments, pipe 260 may be a heat pipe. A heat pipe is a pipe that efficiently conducts heat (cold air), and attaches a core material such as glass fiber or reticulated copper wire to the inside of an aluminum, steel, or copper pipe. It is a pipe without air after filling. In the case of using the heat pipe, the cool air of the fluid contained in the cooling tank 240 may be efficiently transferred to the thawing chamber 250.

The outside of the cooling tank 240 may be surrounded by a heat insulating part 270. The heat insulation part 270 prevents the cold air of the cooling tank 240 from being discharged to the outside. Therefore, by installing the heat insulator 270 may increase the energy efficiency of the thawing refrigerator 200.

3 is a view showing the structure of a thawing refrigerator according to another embodiment of the present invention.

As shown in FIG. 3, the pipe 360 of the thawing refrigerator 300 has a hole formed at one end thereof in contact with the cooling tank 340. This hole allows fluid contained in the cooling tank 340 to move into the pipe 360. In another embodiment, the pipe guide part may be installed inside the pipe 360 to allow the fluid contained in the cooling tank 340 to circulate well inside the pipe 360. Since the fluid contained in the cooling tank 340 cools the thawing chamber 350 while circulating inside the pipe 360, the cooling efficiency of the thawing refrigerator 300 is increased.

4 is a view illustrating a structure of a thawing refrigerator according to still another embodiment of the present invention, and FIG. 5 is an enlarged view of a portion A of FIG. 4 and illustrates a principle of a cover of the thawing refrigerator.

As shown in FIG. 4, the thawing refrigerator 400 includes an evaporator 430, a cooling tank 440, a thawing chamber 450, a heat insulating part 470, a door 480, and a cooling part case 490. Include. The cooling unit case 490 may accommodate a compressor, a condenser, and the like for cooling. In this embodiment, the door 480 is positioned on the front side of the thawing chamber 450, and the cooling tank 440 is positioned on the rear side and the upper surface thereof, but is not limited thereto.

The door 480 has a circulation portion 481 and a door insulation 482. The fluid contained in the cooling tank 440 may move through the circulation portion 481. The door insulator 482 surrounds the outside of the circulation part 481 so that the circulation part 481 is insulated. The door 480 has a protrusion 483 formed at a portion in contact with the cooling tank 440. The protrusion 483 is an inlet for fluid to enter and exit the circulation portion 481.

The cooling tank 440 is provided with a cover 444 at a portion in contact with the door 480. The lid 444 is elastically supported by the spring 445 or the like. A protrusion 483 formed in the door 480 can be opened by pushing the cover 444. The process of opening and closing the cover 444 will be described with reference to FIG. 5.

When the door 480 is open, as shown in FIG. 5A, the lid 444 is elastically supported by the spring 445 to block the cooling tank 440. When the door 480 is closed, as shown in FIG. 5B, the protrusion 483 formed in the door 480 pushes the cover 444. Since only one end of the cover 444 is fixed to the cooling tank 440, the cover 444 is opened to rotate about the fixed end. Accordingly, the fluid contained in the cooling tank 440 may flow into the circulation portion 481 of the door 480. When the door 480 is opened again, the cover 444 is closed again by the elasticity of the spring 445, and the fluid contained in the cooling tank 440 does not flow out. In the present embodiment, the cover 444 is described as being elastically supported by the spring 445, but may be supported by an elastic member other than the spring.

The fluid contained in the cooling tank 440 is cooled as it passes by the evaporator 430. In the present embodiment, the fluid contained in the cooling tank 440 may be air or oil. However, the oil may be air because the cover 444 may open to the outside when the cover 444 is opened. The fan 441 moves the cooled fluid to the upper portion of the thawing chamber 450. The cooled fluid flows through the upper portion of the thawing chamber 450 and enters the circulation portion 481 of the door 480 through the protrusion 483. The fluid introduced into the circulation portion 481 of the door 480 turns around the inside of the circulation portion 481 and then exits the protrusion 483, and flows into the cooling tank 440. The fluid contained in the cooling tank 440 circulates around the thawing chamber 450 in this manner while maintaining the internal temperature of the thawing chamber 450 at a temperature suitable for thawing. A shelf 461 is installed inside the thawing chamber 450 to stably place an object (for example, food) to be thawed.

6 is a view showing the structure of a thawing refrigerator according to another embodiment of the present invention.

As illustrated in FIG. 6, the thawing refrigerator 500 may include a pipe 560 in the thawing chamber 550. Pipe 560 has one end in contact with the fluid contained in cooling tank 540. Accordingly, the pipe 560 delivers the cool air of the fluid contained in the cooling tank 540 to the inside of the thawing chamber 550. The pipe 560 may be installed to have a predetermined slope to allow the fluid to circulate well inside the pipe 560. When the pipe 560 has a predetermined slope, a shelf 561 may be installed to stably place an object (for example, food) to be thawed. In other embodiments, pipe 560 may be a heat pipe. In another embodiment, as shown in FIG. 3, a hole may be formed in one end of the pipe 560 in contact with the cooling tank 540. This hole allows fluid contained in the cooling tank 540 to move into the pipe 560. In this case, a pipe guide part may be installed in the pipe 560 to smoothly circulate the fluid.

7 is a view showing the structure of a thawing refrigerator according to another embodiment of the present invention.

As illustrated in FIG. 7, the thawing refrigerator 600 is surrounded by a cooling tank 640 on the rear, upper and lower surfaces of the thawing chamber 650. The door 680 is located in front of the thawing chamber 650. The cooling tank 640 includes a first cover 644 at a portion in contact with the upper portion of the door 680, and a second cover 646 at a portion in contact with the lower portion of the door 680. The first cover 644 and the second cover 646 are elastically supported by a spring or the like. The heat insulation 670 surrounds the outside of the cooling tank 640.

The door 680 has a circulation portion 681 and a door insulation portion 682. The fluid contained in the cooling tank 640 may move through the circulation portion 681. The door heat insulation part 682 surrounds the outside of the circulation part 681 and prevents the cold air of the circulation part 681 from being discharged to the outside. The door 680 has a first protrusion 683 formed at an upper portion thereof in contact with the cooling tank 640, and a second protrusion 684 formed at a lower portion thereof in contact with the cooling tank 640. Fluid flows into the circulation portion 681 through the first protrusion 683, and fluid flows from the circulation portion 681 through the second protrusion 684. In another embodiment, the fluid may flow into the circulation portion 681 through the second protrusion 684, and the fluid may flow out of the circulation portion 681 through the first protrusion 683. The principle that the first protrusion 683 opens and closes the first cover 644 and the principle that the second protrusion 684 opens and closes the second cover 646 are the same as those described with reference to FIG. 5.

The fluid contained in the cooling tank 640 is cooled as it passes by the evaporator 630. The fan 641 moves the cooled fluid to the top of the thawing chamber 650. The cooled fluid flows through the upper portion of the thawing chamber 650 and enters the circulation portion 681 of the door 680 through the first protrusion 683. Fluid introduced into the circulation portion 681 passes through the circulation portion 681 and exits to the second protrusion 684. The fluid exiting the second protrusion 684 flows back into the cooling tank 640. The fluid contained in the cooling tank 640 circulates around the thawing chamber 650 in this manner while maintaining the internal temperature of the thawing chamber 650 at a temperature suitable for thawing. The shelf 661 may be installed inside the thawing chamber 650 to stably place an object (for example, food) to be thawed.

In the present embodiment, only the shelf 661 is provided inside the thawing chamber 650, but in another embodiment, a pipe may be installed inside the thawing chamber 650. The pipe installed inside the thawing chamber 650 may be a heat pipe. In addition, as shown in FIG. 3, a hole may be formed in one end of the pipe in contact with the cooling tank 640. This hole allows fluid contained in the cooling tank 540 to move inside the pipe. At this time, the pipe guide portion may be installed inside the pipe to facilitate the circulation of the fluid.

In the above embodiments, the entire refrigerator is used for thawing, but in another embodiment, the refrigerator may be implemented as a thawing compartment in a part of the inside of the refrigerator.

It should be noted that the embodiments of the present invention disclosed in the present specification and drawings are only illustrative of the present invention in order to facilitate description of the present invention and to facilitate understanding of the present invention and are not intended to limit the scope of the present invention. It will be apparent to those skilled in the art that other modifications based on the technical idea of the present invention can be carried out in addition to the embodiments disclosed herein.

1 is a view showing the principle of the thawing refrigerator according to an embodiment of the present invention.

2 is a view showing the internal structure of the thawing refrigerator according to an embodiment of the present invention.

3 is a view showing the structure of a thawing refrigerator according to another embodiment of the present invention.

4 is a view illustrating a structure of a thawing refrigerator according to still another embodiment of the present invention, and FIG. 5 is an enlarged view of a portion A of FIG. 4 and illustrates a principle of a cover of the thawing refrigerator.

6 is a view showing the structure of a thawing refrigerator according to another embodiment of the present invention.

7 is a view showing the structure of a thawing refrigerator according to another embodiment of the present invention.

Claims (10)

delete Thawing Room, A plurality of shelves in which the object to be thawed is placed at intervals installed in the thawing chamber in the vertical direction; Located in at least one side of the thawing chamber, the cooling tank for receiving the fluid, Located in the cooling tank, the evaporator for absorbing the heat of the fluid contained in the cooling tank while the refrigerant passes, A protrusion is formed at a portion in contact with the cooling tank, and the fluid accommodated in the cooling tank enters and exits, and opens and closes the thawing chamber. A plurality of pipes installed inside the thawing chamber and supporting the shelf Including, The cooling tank has a cover that is elastically supported in a portion in contact with a portion of the door, the lid is opened by the protrusion when the door is closed, when the door is opened the refrigerator for thawing. delete delete In claim 2, The pipe is a thaw refrigerator. In claim 2, One end of the pipe in contact with the cooling tank is formed with a hole in which the fluid of the cooling tank is introduced, the fluid introduced into the pipe through the hole is a thawing refrigerator heat exchange with the inside of the thawing chamber. In claim 2, The cooling tank further comprises a fan for circulating the fluid. In claim 2, The cooling tank further comprises a guide unit therein. In claim 2, The cooling tank further comprises a valve for discharging or injecting fluid. In claim 2, The thawing refrigerator further comprises a heat insulating part surrounding the outside of the cooling tank.

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