KR100753441B1 - Refrigerating System - Google Patents

Abstract

The present invention relates to a refrigeration system, and more particularly to a refrigeration system having a plurality of evaporation unit using a thermosiphon (Thermosyphon) for controlling the temperature of the convertible box independently adjustable temperature. An object of the present invention is to keep fresh food and the like stored while maintaining the temperature and high humidity of the temperature in the convertible box. To this end, the cooling system of the present invention uses a convertible box capable of independent temperature control, a plurality of evaporators using a thermosiphon installed to control the temperature of the convertible box, and are connected in series with the plurality of evaporators and using cold air. And a liquefier for liquefying the circulating refrigerant inside the thermosiphon, and a control unit for controlling the amount of circulating refrigerant flowing through the evaporator.

Description

Cooling System

1 is a schematic diagram of a conventional cooling system.

2 is a schematic representation of a portion of a cooling system according to the present invention.

3 is a view schematically showing a refrigerant cycle of the convertible box according to the present invention.

4 is a view showing that the refrigerant is controlled by the heater.

5 is a control flowchart of the cooling operation of the convertible box of the present invention.

Figure 6 is a control flow chart of the thawing operation of the convertible box of the present invention.

* Description of symbols on the main parts of the drawings *

110: damper 200: convertible box

230: liquefier 240: first evaporator

260: first heater 250: second evaporator

270: second heater 280: temperature sensor

The present invention relates to a refrigeration system, and more particularly to a refrigeration system having a plurality of evaporation unit using a thermosiphon (Thermosyphon) for controlling the temperature of the convertible box independently adjustable temperature.

In general, the refrigerator lowers the temperature in the refrigerator or maintains the food at a constant temperature through a refrigerant cycle including a compressor 190, a condenser (not shown), an expansion valve (not shown), and an evaporator (120, 150). Refers to a system for storing or deicing water. Such refrigerators are often provided with a convertible box 100 capable of precise temperature control and temperature control independently of the interior 180 for a specific purpose.

Referring to FIG. 1, the convertible box 100 conventionally controls temperature using a separate evaporator 150, a fan 140, and an adjusting unit 160 that controls cold air introduced into the convertible box 100. Temperature was controlled using the cold air of the freezer using the damper 110 and the adjusting unit 160 provided in the middle of the flow path 170 connected to the freezer. The cold air control of the inter-cooling occurs severely due to temperature deviation in the refrigerator according to the on / off of the fan 140 or the damper 110, and there is a problem in that the stored food is dried by moisture evaporation due to cooling.

In addition, since the refrigerant cycle of the refrigerator is used to control the temperature of the convertible box 100, the refrigerant cycle affects the refrigerant cycle, which makes it difficult to stably operate the refrigerant cycle.

The present invention is to solve the above-mentioned problems, an object of the present invention is to maintain the temperature and temperature of the convertible box in the variable temperature control of the convertible box of the cooling system, to keep the food and the like kept fresh and kept fresh To provide a cooling system that can be.

In addition, to control the temperature of the convertible box to a variable and constant temperature while minimizing the impact on the refrigerant cycle.

The cooling system of the present invention for achieving the above object is a convertible box capable of independent temperature control, a plurality of evaporation unit using a thermosiphon installed for temperature control of the convertible box, and the plurality of evaporation unit in series A liquefier connected to and liquefied the circulating refrigerant inside the thermosiphon using cold air, and a controller for controlling the amount of circulating refrigerant flowing through the evaporator, wherein the plurality of evaporators are liquefied in the liquefier. The liquid crystal refrigerant is connected to the liquid crystal through a descending portion and a rising portion in which the vapor phase refrigerant evaporated in the plurality of evaporation portions rises.

In addition, the plurality of evaporation unit is characterized in that arranged in the upper and lower portion of the convertible box.

In addition, a first heater for controlling the flow of the refrigerant moving to the first and second evaporation portion is provided in the lower portion between the first evaporation portion and the liquefier located in the upper portion do.

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The apparatus may further include a temperature sensor in the convertible box, and the controller may turn on / off the first heater by using the detected temperature of the temperature sensor.

In addition, a second heater for thawing the convertible box is provided in the second evaporation unit located at the lower portion.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings.

2 is a schematic view showing a part of a cooling system according to the present invention. The evaporator 210 located at the rear of the cooling system that expands the refrigerant compressed by the compressor (not shown) and supplies the cold air therein and the fan 220 that circulates the cold cold air through the cold air flow path and the inside of the cold place. A return passage 290 is provided in which cold air returns to the evaporator. In addition, the first and second using the convertible box 200 and the thermosiphons provided in the upper and lower portions of the convertible box 200 for temperature control, etc., which are provided in the interior and are capable of independent temperature control. The cold air that is passed through the evaporator 240 and 250 and the refrigerant flowing through the first and second evaporator 240 and 250 to the refrigerant that is in a gas state through heat exchange with the convertible box 200 is provided through the cold air flow path. Liquefier 230 is supplied to convert to a liquid refrigerant. The second heater 270 and the convertible provided to defrost and defrost the first heater 260 and the convertible box 200 provided to control the flow of the refrigerant flowing through the first and second evaporators 240 and 250. It includes a temperature sensor 280 for detecting the temperature of the box 200 and a control unit (not shown) for controlling the first and second heaters, etc. (corresponding to a microcomputer or the like usually included to control the cooling system). . The evaporation unit using a thermosiphon may be further installed as necessary, and the installation position is not limited to the upper and lower portions, but it is preferable to position each of the upper and lower portions to minimize the temperature deviation in the convertible box 200. In addition, although the convertible box 200 is located at the bottom of the refrigerator in FIG. 2, the convertible box 200 may be insulated and positioned at the center of the refrigerating compartment.

Referring to Figure 3 illustrates the operation of the cooling system of the present invention by such a configuration, the gaseous refrigerant introduced in the liquid crystal 230 by heat exchange between the cold air supplied by the evaporator 210 and the fan 220 Converted to liquid refrigerant. The liquid refrigerant thus converted is moved through the lower portion 310 to the lower first and second evaporation portions 240 and 250 by the potential energy due to gravity. The liquid refrigerant moved in the a direction is converted into gaseous refrigerant through heat exchange with the upper portion of the convertible box 200 in the first evaporation unit 240, and moves in the c direction to move through the riser 320 due to the density difference. The liquid refrigerant flowing into the 230 and moving in the b direction becomes a gaseous refrigerant after heat exchange with the lower portion of the convertible box 200, and then flows into the liquidifier 230 through the rising part 320 in the d direction. The circulation of the refrigerant is caused by the difference in the potential energy due to the gravity difference, and thus is not forced convection by the fan, thereby reducing the water vaporization in the convertible box 200. In addition, the portion moving to the lower portion 310 to move the liquid refrigerant and the rising portion 320 to the evaporated gaseous refrigerant is separated, it is easy to control the flow of the refrigerant through the heater.

The flow of the coolant should be adjusted to maintain the temperature in the convertible box 200 set by the user. For this adjustment, the coolant flow is lowered to the lower portion 310 between the first evaporator 240 and the liquid crystal 230. One heater 260 is provided. 4 is a view illustrating a process of controlling the refrigerant by the first heater. When the temperature detected by the temperature sensor 280 provided in the convertible box 200 is lower than the temperature set by the user, the first heater 260 is turned on by the controller (not shown) of the cooling system. Therefore, the refrigerant moving downward by the gravity difference in the liquid crystal 230 is converted into a gaseous refrigerant by heat supplied by the first heater. The refrigerant in the gaseous state is less dense than the liquid refrigerant and has a force to rise, and the liquid refrigerant has a force to descend by the gravity difference. As more heat is supplied from the heater, the ascending force of the gaseous refrigerant increases, which is in equilibrium with the descending force caused by the gravity difference of the liquid refrigerant. As a result, the amount of the liquid refrigerant moving to the first and second evaporators 240 and 250 is controlled. Therefore, the temperature of the convertible box 200 is changed by on / off of the first heater and maintained at a predetermined temperature. In addition, as the first heater operates, the frost partially formed on the pipe melts, thereby increasing the humidity of the convertible box 200.

In addition, the second heater 270 provided in the second evaporator 250 is provided for the thawing function in the convertible box 200. When the thawing is selected by the user, the flow of the refrigerant is controlled by the first heater 260. As a result, further cooling stops and the second heater provided in the lower portion of the convertible box 200 is operated to perform thawing over time according to the selected thawing process. Here, the second heater is preferably installed or insulated at a position not affecting refrigeration or freezing in other stores. In FIG. 2, the defrosting function of the convertible box 200 is performed without affecting the refrigeration of other parts in the refrigerator by being located under the convertible box 200. However, the second evaporator may also act as a buffer against heat transfer.

5 is a control flowchart of the cooling operation of the convertible box of the present invention. When the temperature of the convertible box 200 is set by the user (step S500), the circulating refrigerant is liquefied in the liquid crystal 230 through the supplied cold air and the first and second evaporators 240 and 250 are caused by the gravity difference. The furnace liquid refrigerant moves through the lowering part 310 to exchange heat with the air in the convertible box 200. (S510) The temperature of the convertible box 200 is detected by the temperature sensor 280 to control the control unit of the cooling system. In operation S520, the first heater 260 is operated to maintain the set temperature when the detection temperature is lower than the set temperature by the user (step S520). When the first heater is operated, the convertible box ( The temperature of 200 is increased, and this is detected using the temperature sensor 280. When the detected temperature is higher than the set temperature, the first heater is turned off (step S540) and the thermosiphon is operated.

6 is a control flowchart of the thawing operation of the convertible box of the present invention. When the thermosiphon is operating to control the temperature of the convertible box 200 (step S600), when a signal for instructing the thawing function is input by the user (step S610), the fan 220 is stopped to supply more cold air. This is because the supply of cold air is not necessary because the heat is supplied to the convertible box 200 for thawing. In addition, the supply of cold air to the first and second evaporators is stopped by operating the first heater (step S630). Then, the second heater is operated for thawing in the convertible box 200 (step S640). The control unit (not shown) of the cooling system checks whether the defrosting time has elapsed according to the thawing course set by (step S650), and the thawing is stopped. That is, the first and second heaters are turned off and the fan 220 is operated again to supply cold air. (Step S660) When the first heater is turned off, the liquid refrigerant converted by the liquid crystal 230 through the supplied cold air. Moves to the first and second evaporators 240 and 250 to cool the convertible box 200 (step S670). Then, a control operation for maintaining a set temperature of the set convertible box 200 is performed. (Step S680)

As described above in detail, the present invention can control the temperature of the convertible box to minimize the temperature deviation of the convertible box through a plurality of increasing parts using a thermosiphon and maintain the humidity in the convertible box at high humidity.

In addition, it is possible to easily adjust the amount of the refrigerant flowing through the evaporator using a plurality of heaters and to perform the thawing function while minimizing the influence on other parts of the cooling system.

In addition, since the temperature of the convertible box can be adjusted independently of the refrigeration cycle of the cooling system, it is possible to stably operate the refrigeration cycle of the cooling system.

Claims (6)

Convertible box with independent temperature control, And a plurality of evaporation unit using a thermosiphon is installed for temperature control of the convertible box, A liquefier connected in series with the plurality of evaporators and liquefying a circulating refrigerant in the thermosiphon using cold air; A control unit for controlling the amount of the circulating refrigerant flowing through the evaporator; The plurality of evaporation unit, the cooling system is connected to the liquid crystal through a lower portion of the liquid refrigerant liquefied in the liquefier (falling) descends and the rising portion of the vapor phase refrigerant evaporated in the plurality of evaporation unit is raised. The method of claim 1, The plurality of evaporators comprises a first evaporator and a second evaporator; And the first evaporator and the second evaporator are disposed above and below the convertible box, respectively. delete The method of claim 2, A first heater is provided at the lowering portion between the liquidifier and the first evaporator; The first heater is for controlling the flow of the refrigerant moving to the first and second evaporator through the lower portion. The method of claim 4, wherein And a temperature sensor inside the convertible box, and wherein the controller turns on / off the first heater by using the detected temperature of the temperature sensor. The method of claim 2, Cooling system, characterized in that the second heater for thawing the convertible box is provided in the second evaporator located in the lower portion of the convertible box.

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