KR100321493B1 - Control method for operation of kimch'i store house - Google Patents

Abstract

The present invention relates to an operation control method of a kimchi storage, and the refrigerant is not circulated when the condition that the refrigerant is not circulated even during the circulation of the refrigerant while the refrigerant is being circulated only in some of the plurality of stores. If the temperature in the furnace rises close to the refrigerant circulation temperature, the refrigerant is immediately circulated to the furnace where the temperature rises close to the refrigerant circulation temperature without stopping the compressor, so that the temperature in the furnace is maintained for the minimum rest time during which the operation of the compressor is stopped. It is to prevent the rise above the set temperature.

Description

Operation Control Method of Kimchi Storage {CONTROL METHOD FOR OPERATION OF KIMCH'I STORE HOUSE}

The present invention relates to a method for controlling the operation of a kimchi storage, and more particularly, to an operation control method for a kimchi storage that can prevent the temperature in the refrigerator from rising above the set temperature during the minimum rest time during which the compressor is stopped. It is about.

In general, in order to store frozen foods, refrigerated foods, and fermented foods (for example, kimchi) at a temperature suitable for storing them, a refrigerator having a freezing compartment and a refrigerating compartment may be used. Mainly used.

However, when the refrigerated food and the fermented food are stored together in the refrigerator, the odor is generated in the refrigerating chamber due to the smell of the fermented food. As the number of refrigerated foods and fermented foods to be refrigerated can increase, there is a need to store relatively bulky fermented foods (kimchi) in separate storage.

In addition, kimchi can be properly seasoned by burying it in the ground and ripening it at the proper temperature conditions.However, due to the limitations of the residential environment such as apartments and townhouses, it is difficult to keep it in the ground. It is difficult.

Recently, in order to solve the above problems, research on kimchi storage that can store kimchi in a separate storage space, rather than a refrigerator, has been variously studied in various technical fields related thereto. As shown in FIG.

As shown in FIG. 1, the appearance of the kimchi storage as described above is a plurality of insides of the kimchi, that is, the kimchi is refrigerated, that is, the inside of the left storehouse (左 庫內) 11 and the inside of the storehouse (右 庫內; 12) Is a pair of doors provided with a hinge at the upper portion of the main body 10 and the upper portion of the main body 10 so as to open and close the main body 10 formed therein and the inside of the upper left 11 and the upper right 12. It consists of an inner door 21 and an in-go door 22.

On both sides of the main body 10, the handle 30 is installed so that the user can easily pull the main body 10 when moving the kimchi storage, and the main body (on the bottom surface of the main body 10) 10) is provided with a horizontal adjustment leg 40 for adjusting the horizontal, the bottom portion of the bottom surface of the main body 10 is attached to the wheel 50 that is rotated when moving the kimchi storage.

On a predetermined portion of the upper surface of the left in-door door 21 and the right in-door door 22, a pair of key input units, i.e., a left in-high key input unit 61, can be freely selected and input according to a user's preference. And an in-house key input unit 62 are provided.

As shown in FIG. 2, the refrigerant cycle for circulating the refrigerant into each of the kimchi reservoirs includes a compressor 70, a condenser 71, a solenoid valve 72 in a left height, and a solenoid valve 73 in a right height. ), The left upper capillary tube 74, the right upper capillary tube 75, the left upper chamber evaporator 76, and the right upper chamber evaporator 77.

2, the compressor 70 compresses and discharges the refrigerant gas at high temperature and high pressure, and the condenser 71 condenses the refrigerant compressed at high temperature and high pressure through the compressor 70 into a liquid refrigerant at high pressure and room temperature.

The left in-sole solenoid valve 72 and the right in-sole solenoid valve 73 selectively supply the liquid refrigerant condensed in the condenser 71 to the in-left capillary tube 74 and the right-side capillary tube 75, respectively. The inner capillary tube 74 and the in-house capillary tube 75 depressurize the liquid refrigerant condensed in the condenser 71 to low pressure, respectively.

The upper left upper evaporator 76 is installed at a predetermined portion of the upper left 11 to vaporize the refrigerant decompressed in the upper left capillary 74 to heat-exchange the air in the upper left 11 with cold air. The evaporator 77 is installed at a predetermined portion of the in-vehicle 12 to vaporize the refrigerant depressurized in the in-vehicle capillary tube 75 to heat-exchange the air in the in-vehicle 12 with cold air.

The operation process of the kimchi storage configured as described above is as follows.

In the initial state, when the user operates the left in-stock key input unit 61 to select 'cold storage mode', the in-left solenoid valve 72 is opened by the control unit, not shown, and power is supplied to the compressor 70. The compressor 70 is driven.

The refrigerant gas is compressed to high temperature and high pressure through the compressor 70 driven by the control unit, and is supplied to the condenser 71. The high temperature and high pressure refrigerant gas supplied from the compressor 70 is condensed at high pressure and room temperature. After condensed with the liquid refrigerant, it is supplied to the in-left capillary tube 74 through the left in-sole solenoid valve 72.

The high-pressure room temperature liquid refrigerant supplied from the condenser 71 through the in-stock left solenoid valve 72 is decompressed to a low pressure through the in-stock left capillary 74, and then supplied to the in-stock left evaporator 76, and the in-stock left capillary tube. The low pressure liquid refrigerant supplied from 74 to the left inbox evaporator 76 is vaporized inside the left inbox evaporator 76.

When the low-pressure liquid refrigerant is evaporated inside the left-stored evaporator 76, heat exchange is performed by latent latent heat of evaporation, thereby cooling the internal air in the left-storey 11, thereby storing the kimchi in the left-storey 11 refrigerated.

At this time, the temperature in the upper left 11 is sensed by the left upper temperature sensor, which is not shown, and a temperature signal corresponding to the temperature in the upper left height is input from the left upper temperature sensor to the controller, and the control unit receives the temperature from the left upper temperature sensor. If the temperature in the left height 11 determined by determining the temperature in the left height 11 by the temperature signal is less than or equal to the preset refrigerant circulation stop temperature (see 'Tmin' in FIG. 3 (a)), the left height solenoid valve ( 72 is closed to stop the supply of the coolant to the left upper evaporator 76 (see FIG. 3 (b)), and the temperature in the left upper 11 is set at a predetermined refrigerant circulation temperature (' If it is higher than the Tmax ', the internal left high solenoid valve 72 is opened to supply a refrigerant to the internal high evaporator 76 (see FIG. Keep at storage temperature.

In addition, the driving process of the right height 12 is also the same as the driving process of the left height 11 described above.

On the other hand, as can be seen with reference to Figure 3, when at least one of the left in-sole solenoid valve 72 and the right in-sole solenoid valve 73 is open (OPEN), the compressor 70 continues to be driven (Fig. 3 (E) of), when the left inner solenoid valve 72 and the right inner solenoid valve 73 are closed, the driving of the compressor 70 is stopped.

However, in the conventional kimchi storage as described above, as can be seen with reference to FIG. 3, once the compressor is stopped, the compressor is not restarted for a predetermined minimum idle time T ₀ to prevent frequent on / off. Since the compressor does not operate even if the internal temperature of one of the left and right warehouses becomes greater than or equal to the refrigerant circulation temperature Tmax during the mandatory stop time T0, the internal temperature of the refrigerator is raised and stored therein. There was a problem that the kimchi was over ripened.

Accordingly, the present invention has been made to solve the above-mentioned problems of the prior art, and the compressor is driven when at least one of the plurality of chambers circulates the refrigerant, even if it is a condition to stop the driving of the compressor. By operating the refrigerant to the evaporator with the circulation point of the refrigerant without stopping, the operation control method of the Kimchi reservoir can be prevented that the temperature inside the refrigerator rises above the set temperature during the minimum rest time of the compressor and prevents the kimchi from being over-matured. The purpose is to provide.

1 is a perspective view schematically showing the appearance of a typical kimchi storage,

Figure 2 is a schematic diagram showing a refrigerant cycle of the kimchi storage shown in Figure 1,

3 (a) to (e) is a schematic diagram for explaining the operation of the conventional kimchi storage,

4 is a schematic block diagram of hardware for carrying out the present invention;

Figure 5 is a flow chart for explaining the operation control method of kimchi storage in accordance with a preferred embodiment of the present invention,

Figure 6 (a) to (e) is a schematic diagram for explaining the operation of the kimchi storage in accordance with the present invention.

<Explanation of symbols for the main parts of the drawings>

70: compressor 72, 73: solenoid valve

100, 110: key input unit 120, 130: temperature detection unit

140: control unit 150: compressor driving unit

160: solenoid valve drive unit

The operation control method of the kimchi storage according to the present invention for achieving the above object, the refrigerant from the compressor is circulated simultaneously or selectively to a plurality of evaporators in accordance with the temperature and operating conditions in each chamber, but the refrigerant for all the plurality of evaporators In the operation control method of the kimchi storage which stops the operation of the compressor at a time when it is not circulated, the temperature in at least one of the plurality of stores is set in advance even when the condition is that the refrigerant is not circulated for all of the plurality of evaporators. When the temperature rises toward the refrigerant circulation temperature, the refrigerant is circulated to the evaporator in the furnace that is raised to the refrigerant circulation temperature without stopping the operation of the compressor.

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

FIG. 4 is a schematic block diagram of hardware for carrying out the present invention. As can be seen from the same drawing, the hardware for carrying out the present invention includes a left inner height key input unit 100 and a right inner height key input unit 110. And the left high temperature sensor 120, the right high temperature sensor 130, the control unit 140, the compressor driver 150, the compressor 70, the solenoid valve driver 160 and the left high solenoid valve 72 and Consists of an in-sole solenoid valve 73, the basic configuration of the hardware for carrying out the present invention is the same as in Figures 1 and 2, the same reference numerals are assigned to the same components and the duplicated description will be omitted.

In FIG. 4, the left in-stock key input unit 100 includes a plurality of selection buttons for selecting and inputting an operation mode (for example, a refrigerated storage mode and a ripening mode) of the in-stock 11. When the button is operated, a key signal corresponding to the operated selection button is input to the controller 140.

The in-house key input unit 110 includes a plurality of selection buttons for selecting and inputting an operation mode (for example, a refrigerated storage mode and a maturing mode) of the in-house 12, and when the user operates the select button. The key signal corresponding to the operated selection button is input to the controller 140.

The temperature in the left height sensor 120 senses the temperature of the inside of the left height 11 and inputs a temperature signal corresponding to the detected temperature to the control unit 140, the temperature inside the right height sensor 130 is in the height Detects the temperature of 12 and inputs a temperature signal corresponding to the detected temperature to the controller 140.

The control unit 140 according to the operation mode of the in-left 11 or in-high 12 selected by the user through the left in-high driving mode selection unit 100 or the right in-high driving mode selection unit 110. 70) and the left insole high solenoid valve 72 or the right insole solenoid valve 73 are selectively driven to drive the inside of the left height 11 or the inside of the right height 12.

The compressor driving unit 150 applies power to the compressor 70 according to a control signal from the controller 140 to drive the compressor 70, and the compressor 70 compresses the refrigerant gas at a high temperature and high pressure to condenser 71. To be discharged.

The solenoid valve driving unit 160 selectively opens and closes the left inner solenoid valve 72 or the right inner solenoid valve 73 according to a control signal from the control unit 140.

An operation example of the present invention through the hardware configured as described above will be described in detail with reference to FIGS. 4 to 6.

First, when power is applied to each part of the kimchi storage from a predetermined power supply source (for example, a commercial AC power supply), the control unit 140 is initialized, and the initialized control unit 140 is the left height key input unit 100 and the right height. Switched to the standby mode for receiving a key signal from the inner key input unit 110, the temperature in the upper left 11 and the inner right 12 from the temperature sensor 120 and the inside temperature inside the high temperature sensor 130 The temperature signals corresponding to the respective signals are output to the controller 140 (S1).

In this case, when the user operates the selection buttons provided in the left in-height key input unit 100 and the right in-height key input part 110 to set the operation mode of the left-height 11 and the in-height 12 to the refrigerated storage mode. The key signal corresponding to the selection button selected by the user is input to the controller 140 from the left height key input unit 100 and the right height key input unit 110.

The control unit 140 selects the operation mode of the in-left 11 and in-high 12 selected by the user by the key signals input from the in-left height key input unit 100 and the in-high height key input unit 110. If it is determined whether or not (S10), and the determination result that the operation mode of the left 11 and the right 12 selected by the user is not the 'cold storage mode' other operation mode selected by the user (for example, ripening mode ).

If, as a result of the determination in the step (S10), if the operation mode of the user in the left height 11 and the right height 12 selected by the user in the 'cold storage mode', the control unit 140 is in the left height solenoid valve 72 and in the right height. The valve opening signal for opening the solenoid valve 73 is output to the solenoid valve driver 160, and then a compressor driving signal for driving the compressor 70 is output to the compressor driver 150 after a predetermined time elapses ( S20).

Power is supplied from the solenoid valve driving unit 160 to the left in-sole solenoid valve 72 and the in-go solenoid valve 73 by the valve opening signal from the control unit 140, so that the in-sole solenoid valve 72 and the in-sole solenoid The valve 73 is opened, and after a predetermined time, power is applied from the compressor driver 150 to the compressor 70 by the compressor drive signal from the controller 140 to drive the compressor 70.

The refrigerant gas is compressed to a high temperature and high pressure through the driven compressor (70) and supplied to the condenser (71), and the high temperature and high pressure refrigerant gas supplied from the compressor (70) is condensed into a liquid refrigerant at high pressure and room temperature in the condenser (71). Then, it is supplied to the in-left capillary tube 74 and the in-vehicle capillary tube 75 through the left in-sole high solenoid valve 72 and the in-high solenoid valve 73.

The high-pressure room temperature liquid refrigerant supplied from the condenser 71 through the in-stock left solenoid valve 72 is decompressed to a low pressure through the in-stock left capillary 74, and then supplied to the in-stock left evaporator 76, and the in-stock left capillary tube. The low pressure liquid refrigerant supplied from 74 to the left internal evaporator 76 is vaporized inside the left internal evaporator 76.

When the liquid refrigerant is evaporated in the evaporator 76 inside the left storage, heat exchange is performed by latent heat of evaporation, thereby cooling the internal air in the left storage 11, so that the kimchi in the storage inside 11 is refrigerated.

In addition, the high-pressure room temperature liquid refrigerant supplied from the condenser 71 through the in-house solenoid valve 73 is reduced to low pressure through the in-house capillary tube 75, and then supplied to the in-house evaporator 77, and The low-pressure liquid refrigerant supplied from the inner capillary tube 75 to the intra-evaporator 77 is vaporized inside the intra-evaporator 77.

When the liquid refrigerant is vaporized in the interior of the evaporator 77, the heat exchange is performed by latent heat of evaporation, thereby cooling the internal air of the in-vegetation 12, so that the kimchi in the in-vehicle 12 is refrigerated.

Subsequently, the controller 140 detects the temperature of the left height 11 and the right height 12 by a temperature signal applied from the left height temperature detecting part 120 and the right height temperature detecting part 130. The refrigerant is circulated selectively in the interior 11 and the interior 12 by opening and closing the interior left solenoid valve 72 and the interior right solenoid valve 73 according to the temperatures of the interior 11 and the interior 12 of the warehouse. (S30).

That is, if the temperature in the upper left 11 is greater than or equal to the refrigerant circulation temperature Tmax, the left upper left solenoid valve 72 is opened to circulate the refrigerant from the compressor 70 to the lower left evaporator 76, When the temperature of 11) is lower than the refrigerant circulation stop temperature Tmin, the left inner solenoid valve 72 is closed to stop the refrigerant circulation of the left upper internal evaporator 76.

In addition, if the temperature of the in-house 12 is greater than or equal to the refrigerant circulation temperature Tmax, the in-house solenoid valve 73 is opened to circulate the refrigerant from the compressor 70 to the in-house evaporator 77, If the temperature at 12 is less than or equal to the refrigerant circulation stop temperature Tmin, the in-sole solenoid valve 73 is closed to stop the refrigerant circulation of the in-evaporator evaporator 77.

Here, while performing the step (S30), the control unit 140 of the left height 11 and the right height 12 by the temperature signals from the left high temperature inside the temperature sensor 120 and the right inside temperature detection unit 130. The temperature in the chamber where the circulation of the refrigerant is stopped is periodically checked and stored in a predetermined storage means (for example, a buffer memory built into the controller) (S40).

On the other hand, if the refrigerant is not circulated in the upper left 11 and the upper 12, the driving of the compressor 70 is stopped. Therefore, the control unit 140 controls the lower left 11 and the upper 12. By continuously checking the operation status, it is determined whether the refrigerant is not circulated in both the left height 11 and the right height 12, that is, the driving stop condition of the compressor 70 (S50). If the drive stop condition is not satisfied, the flow returns to step S20 to continuously drive the compressor 70.

If the condition at the step S50 determines that the refrigerant is not circulated in both the left height 11 and the right height 12, that is, the driving stop condition of the compressor 70 is satisfied, the controller 140 determines the above. The present temperature Tc in the store checked in step S40 is compared with the set temperature Ts (S60).

For example, in step S50, the coolant is not circulated in both the left height 11 and the right height 12, that is, the driving stop condition of the compressor 70 is satisfied. If the coolant has been circulated and the coolant has not been circulated in the rain chamber 12, the temperature of the rain chamber 12 is periodically checked in step S40, and the current temperature of the rain chamber 12 is checked in step S60. (Tc) and the set temperature (Ts) are compared.

Then, the control unit 140 determines whether the present temperature Tc in the chamber that has been checked in step S40 is greater than or equal to the set temperature Ts based on the comparison result in step S60 (S70). If the present temperature Tc in the chamber checked in step S40 is less than the set temperature Ts, the temperature in the chamber checked in step S40 does not approach the refrigerant circulation temperature Tmax. It is judged that it is not, and it progresses to the following step S110 which stops driving of the compressor 70.

If the present temperature Tc in the chamber checked in step S40 is greater than or equal to the set temperature Ts, as a result of the determination in step S70, the temperature in the chamber periodically checked in step S40. The slope ΔT is calculated (S80).

Here, the temperature gradient ΔT is calculated as a variation of the internal temperature per unit time as shown in Equation 1 below.

ΔT = ΣT / t

In Equation (1), 'ΣT' is the fluctuation range of the internal temperature, and 't' is the time.

Then, the controller 140 compares the temperature gradient ΔT calculated in the step S80 with a predetermined set temperature gradient ΔTs (for example, about 0.5 ° C./minute) (S90), and compares the result. It is determined whether the temperature gradient ΔT calculated in step S80 is equal to or larger than the set temperature gradient ΔTs (S100).

As a result of the determination in step S100, if the temperature gradient ΔT calculated in the step S80 is equal to or larger than the set temperature gradient ΔTs, the controller 140 checks that the temperature is checked in step S40. Assuming that the temperature inside is rising near the refrigerant circulation temperature Tmax, a control signal for opening the solenoid valve in the chamber whose temperature is checked in step S40 is output (S105), and the step ( Returning to S20, the compressor 70 is continuously driven.

If the temperature gradient ΔT calculated in the step S80 is less than the set temperature gradient ΔTs as a result of the determination in the step S100, the controller 140 checks the temperature in the step S40. It is assumed that the temperature in the existing refrigerator is not approaching the refrigerant circulation temperature Tmax or is falling, and at the same time, the compressor driving stop signal for stopping the driving of the compressor 70 is output to the compressor driving unit 150 (S110). In operation S120, the idle time of the compressor 70 is counted.

For reference, when the internal temperature is lowering from the refrigerant circulation temperature (Tmax), the temperature gradient (ΔT) always has a negative value (for example, -6 ° C / min), so that the set temperature gradient (ΔTs) is always used. Is lower than).

The supply of power applied from the compressor driving unit 150 to the compressor 70 is stopped by the compressor driving stop signal from the control unit 140, and the driving of the compressor 70 is stopped.

Subsequently, the controller 140 senses the temperature of each in-vehicle, that is, in the left-height 11 and the right-height 12 by the temperature signals input from the left-inside temperature sensor 120 and the right-side temperature sensor 130. Then, it is determined whether the detected temperature in the left height 11 or the right height 12 reaches the refrigerant circulation temperature Tmax, that is, satisfies the driving conditions of the compressor 70 (S130). If the driving condition of 70 is not satisfied, the flow returns to step S110 to continue the driving of the compressor 70.

If, at the step S130, the temperature of at least one of the left height 11 or the right height 12 reaches the refrigerant circulation temperature Tmax, that is, the driving condition of the compressor 70 is satisfied. The controller 140 determines whether the idle time of the compressor 140 counted to the present is greater than or _equal to the minimum idle time t ₀ (for example, about 1 minute) (S140), and as a result of the determination, the compressor ( If the idle time of 140 is less than the minimum pause time t ₀ , the flow returns to the step S110 via step S150 to be described later, and the driving of the compressor 70 is continuously stopped.

If the idle time of the compressor 140 counted to the present is greater than or equal to the minimum pause time t ₀ as a result of the determination in step S140, the controller 140 returns to the step S20 and the compressor 70. Drive.

On the other hand, step (S150) indicates that the operation of the kimchi storage is stopped when the supply of power to the kimchi storage is stopped while operating the inside of the left high 11 and the inside of the high 12 as described above.

One specific example according to the operation process of the present invention described above is as shown in (a) to (e) of Figure 6, as can be seen with reference to the same figure, the in-sole solenoid valve 73 is closed (CLOSE) In the open state solenoid valve 72 is opened to circulate the refrigerant through the left high evaporator 76 while the temperature in the left high 11 is below the coolant circulation stop temperature Tmin. When the valve 73 is also closed (ie, the condition to stop the operation of the compressor 70), the temperature in the inboard height 12 becomes the point 'P1', in the inward height at this point 'P1' ( If the temperature of 12) is greater than or equal to the set temperature Ts and the temperature gradient ΔT is greater than or equal to the set temperature gradient ΔTs, the solenoid valve 73 in the wogo is opened immediately without stopping the operation of the compressor 70 ( OPEN) to circulate the refrigerant into the in-evaporator 77.

That is, according to the present invention, the refrigerant is not circulated when the condition that the refrigerant is circulated is not circulated while the refrigerant is circulated only in one of the left and the right heights. If the temperature in the refrigerator rises near the refrigerant circulation temperature, the refrigerant is immediately circulated to the furnace where the temperature rises close to the refrigerant circulation temperature without stopping the compressor, so that the temperature in the refrigerator is set during the minimum pause time when the operation of the compressor is stopped. It is to prevent the rise above the temperature.

On the other hand, in the embodiment of the present invention has been described by taking only the case of operating all the plurality of refrigerators in the refrigerated storage mode as an example, the present invention is not limited to this operation of the plurality of refrigerators according to the ripening operation mode or the cold storage mode and the ripening operation It will be readily apparent to those skilled in the art that the present invention can be readily applied in any situation in which the refrigerant is circulated into a plurality of refrigerators such as selective operation in a mode.

As described above, according to the present invention, even when a condition is not caused to circulate the refrigerant in all of the plurality of refrigerators, the operation of the compressor is not stopped when the temperature in at least one of the plurality of refrigerators is raised to the refrigerant circulation temperature. By circulating the refrigerant into the high rise near the refrigerant circulation temperature, the circulation of the refrigerant is stopped during the minimum rest time of the compressor, thereby preventing the temperature in the high rises above the set temperature.

Claims (8)

According to the operation control method of Kimchi storage, the refrigerant from the compressor is circulated simultaneously or selectively to the plurality of evaporators according to the temperature and the operating conditions in each chamber, and the operation of the compressor is stopped when the refrigerant is not circulated for all the plurality of evaporators. In Even when the refrigerant is not circulated for all of the plurality of evaporators, if the temperature in at least one of the plurality of refrigerators rises toward the predetermined refrigerant circulation temperature, the refrigerant circulation temperature is not stopped. Operation control method of the kimchi storage, characterized in that the refrigerant is circulated to the evaporator in the high rise near. The method of claim 1, wherein whether the temperature in the refrigerator rises close to the refrigerant circulation temperature is determined by a comparison result of comparing the temperature gradient and the predetermined set temperature gradient of the interior of the refrigerator. Operation control method. The method of claim 2, wherein the temperature gradient is a variation of the temperature in the refrigerator per unit time. 4. The kimchi according to claim 2 or 3, wherein whether or not the temperature in the refrigerator rises close to the refrigerant circulation temperature is determined by further considering a comparison result between the present temperature in the refrigerator and a predetermined set temperature. Operation control method of storage. In the operation control method of the kimchi storage in which the refrigerant from the compressor is circulated simultaneously or selectively to a plurality of evaporators in accordance with the temperature and operating conditions in each chamber, A temperature change check step for periodically detecting and storing the internal temperature of the evaporator at which the refrigerant is not circulated when selectively circulating the refrigerant with the plurality of evaporators; A discrimination step of determining whether or not the temperature in the chamber, in which the temperature change is checked, rises close to a predetermined refrigerant circulation temperature when it is a condition not to circulate the refrigerant to all of the plurality of evaporators; And the step of circulating the refrigerant to the evaporator in the furnace determined that the temperature rises close to the refrigerant circulation temperature in the determination step and continuously driving the compressor. The operation control method of the kimchi storage system according to claim 5, wherein the operation of the compressor is stopped if there is no high temperature in the plurality of high temperatures close to the refrigerant circulation temperature. 7. The method according to claim 5 or 6, wherein, in the determination step, whether or not the temperature in the refrigerator rises close to the refrigerant circulation temperature is compared with a comparison result of comparing the present temperature in the refrigerator with a predetermined set temperature and the temperature gradient in the refrigerator. And a method of controlling the kimchi storage, characterized in that it is discriminated by a comparison result comparing a predetermined set temperature gradient. 8. The method of claim 7, wherein the temperature gradient is a fluctuation range of the internal temperature per unit time.