KR100484971B1 - Method for controlling of kimchi storage - Google Patents

Abstract

The present invention relates to an operation control method of a kimchi storage, and in particular, in a kimchi storage having a plurality of independently controlled storage rooms, by adjusting the storage temperature bandwidth of each storage room in the storage mode to synchronize the temperature change time of each storage room. By equalizing the driving time of the compressor, it is possible to reduce the operating time of the compressor which was operated independently for independent control, thereby reducing the noise generated by the compressor operation as well as reducing the power consumption.

Description

Operation Control Method of Kimchi Storage {Method for controlling of kimchi storage}

The present invention relates to an operation control method of a kimchi storage, and more particularly, the operation time of the compressor is equalized by synchronizing the temperature change time of each storage room in the storage mode, thereby reducing the operating time of the compressor to reduce noise caused by the operation of the compressor. The present invention relates to a method for controlling operation of kimchi storage to reduce generation and power consumption.

In general, in order to refrigerated frozen foods and refrigerated foods and fermented foods (for example, kimchi, etc.) should be stored at a suitable temperature to store them, and this function is mainly performed by a refrigerator equipped with a freezer and a refrigerator compartment. Was used.

However, when the refrigerated food and the fermented food are stored together in the freezer of the refrigerator, not only the odor is generated in the refrigerating chamber due to the smell of the fermented food, but also the other odor is exuded in the refrigerated food, so the inherent aroma of the refrigerated 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.

Recently, in order to solve the above-mentioned difficulties, 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.

As shown in FIG. 1, a first storage chamber 11 and a second storage chamber 12, that is, a plurality of storage chambers 11 and 12 and a machine chamber 13 are formed in the kimchi storage body 10. The first storage chamber evaporator 76 and the second storage chamber evaporator 77 which generate cold air by using latent heat of evaporation when the refrigerant is evaporated on each wall of the first storage chamber 11 and the second storage chamber 12, and each storage chamber. The first storage chamber temperature sensor 80 and the second storage chamber temperature sensor 81 for detecting the temperature of the first chamber, and the first storage chamber heater 78 and the second storage chamber heater 79 for generating heat are provided.

In the inside of the machine room 13, a compressor 70 for compressing a refrigerant gas at high temperature and high pressure, and a condenser 71 for condensing the refrigerant compressed at high temperature and high pressure through the compressor 70 to a liquid refrigerant at high pressure and room temperature. Then, the liquid refrigerant condensed in the condenser 71 is supplied through the first storage solenoid valve 72 and the second storage solenoid valve 73 to be decompressed to low pressure, and then the first storage chamber evaporator 76 described above. And a first storage chamber capillary tube 74 and a second storage chamber capillary tube 75 supplied to the second storage chamber evaporator 77, and cold air to the condenser 71 and the compressor 70 to blow the condenser 71 and the compressor ( A cooling fan motor 82 for cooling 70 is provided.

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

First, the user stores kimchi in the first storage room 11 and the second storage room 12, and then operates the first storage room key input unit (not shown) and the second storage room key input unit (not shown) to control the first kimchi. When the operation modes (mature mode and storage mode, etc.) of the storage chamber 11 and the second storage chamber 12 are selected, key signals corresponding to the operation mode selected by the user are provided in the first storage chamber key input unit and the second storage chamber key input unit. The control unit is inputted to a control unit, not shown, from which the control unit determines the respective storage room operation modes selected by the user according to the entered key signals and operates the kimchi storage according to the determined operation mode.

However, since the storage mode driving conditions (temperature and time, etc.) for driving each storage chamber are different when driving the storage mode of the kimchi storage having a plurality of storage chambers using the operation control method of the conventional kimchi storage chamber as described above. Since the compressor for compressing the refrigerant gas at high temperature and high pressure to drive is continuously driven for maintaining a different time and temperature, there is a problem in that power consumption increases due to a long time driving of the compressor.

In addition, there is a problem that the noise is severely generated when the compressor is driven by the long time or frequent compressor drive.

The present invention has been made to solve such a conventional problem, and in the kimchi storage having a plurality of independent controlled storage room, the temperature change time of each storage room by adjusting the storage temperature bandwidth of each storage room in the storage room when driving the storage mode It is an object of the present invention to provide an operation control method of a kimchi storage system to reduce the operation time of a compressor operated independently for independent control by synchronizing the same operation time of the compressor.

The present invention for achieving the above object is a kimchi storage having a plurality of storage chambers, the step of comparing the storage mode of the operation state of the kimchi storage; In the storage mode, measuring a temperature change time t1 of the reference storage compartment and a temperature change time t2 of another storage compartment; Comparing the temperature change time t1 of the reference storage room and the temperature change time t2 of the other storage room measured above; Resetting an operating temperature band of another storage compartment when the difference between the temperature change time t1 of the reference storage compartment and the temperature change time t2 of the other storage compartment is greater than 2 minutes before the preset time width Δt. Wow; If the difference between the temperature change time t1 of the reference storage compartment and the temperature change time t2 of the other storage compartment is less than 2 minutes, the operating temperature band of the other storage compartment is determined as the operating temperature of the reference storage compartment. And returning to the band.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings. In addition, this embodiment is not intended to limit the scope of the present invention, but is presented by way of example only.

Figure 2 is a schematic block diagram showing the operation control method of the kimchi storage according to the present invention.

As shown in FIG. 2, the kimchi storage room according to the present invention is different from the first storage room key input unit 100, that is, the reference storage room, that is, the second storage room key input unit 110 and the first storage room temperature sensing unit 200. The second storage compartment temperature sensing unit 210, the control unit 500, the compressor driving unit 300, the compressor 310, the solenoid valve driving unit 400, the first storage compartment solenoid valve 410, and the second storage compartment solenoid valve 420. The kimchi reservoir to which the operation control method of the kimchi reservoir according to the present invention is applied is the same as the kimchi reservoir shown in FIG. 1, and the same reference numerals will be given to the same constituent members, and redundant description thereof will be omitted.

In FIG. 2, the first storage compartment key input unit 100 and the second storage compartment key input unit 110 select and input an operation mode (eg, a cold storage mode and a aging mode) of the first storage compartment and the second storage compartment. In order to provide a plurality of selection buttons, and when the user operates the selection button, the controller 500 inputs a key signal corresponding to the operated selection button.

The first storage compartment temperature sensing unit 200 senses a temperature of the first storage compartment and inputs a temperature signal corresponding to the detected temperature to the controller 500, and the second storage compartment temperature sensing unit 210 is configured to have a second temperature. The temperature of the storage compartment is sensed and a temperature signal corresponding to the sensed temperature is input to the controller 500.

The control unit 500 according to the operation mode of the first storage compartment or the second storage compartment selected by the user through the first storage compartment key input unit 100 or the second storage compartment key input unit 110, the first storage compartment solenoid. The valve 410 or the second storage solenoid valve 420 is selectively driven to operate the first storage chamber or the second storage chamber.

The compressor driver 300 drives the compressor 310 by applying power to the compressor 310 according to a control signal from the controller 500, and the compressor compresses the refrigerant gas at high temperature and high pressure and discharges the refrigerant gas to the condenser.

The solenoid valve driver 400 opens and closes the first storage solenoid valve 410 or the second storage solenoid valve 420 according to a control signal from the controller 500.

An embodiment of the present invention through the kimchi storage configured as described above will be described in detail with reference to FIGS. 2 to 5.

First, when the user operates the selection buttons provided in the first storage compartment key input unit and the second storage compartment key input unit to set the operation modes of the first storage compartment and the second storage compartment to the storage mode, the first storage compartment key input unit and the second storage compartment A key signal corresponding to the selection button selected by the user from the key input unit is input to the controller.

The controller determines whether the operation mode of the first storage room and the second storage room selected by the user is the 'storage mode' based on the key signals input from the first storage room key input unit and the second storage room key input unit (S10). If the operation modes of the first storage room and the second storage room selected by the user are not the 'storage mode', another operation mode selected by the user (eg, a ripening mode) is performed (S20).

If the operation mode of the first storage chamber and the second storage chamber selected by the user is the 'storage mode' in the step S10, the controller may control the temperature signal applied from the first storage chamber temperature detector and the second storage chamber temperature detector. Detecting the temperatures of the first storage compartment and the second storage compartment and selectively opening / closing the first storage compartment solenoid valve and the second storage compartment solenoid valve according to the detected temperatures of the first storage compartment and the second storage compartment,

The temperature change time t1 of the first storage compartment and the temperature change time t2 of the second storage compartment are measured in a state in which the first storage solenoid valve and the second storage solenoid valve are selectively opened and closed (S30).

That is, when the temperature of the first storage chamber is equal to or higher than the preset temperature Tmax (for example, about 1 ° C.), the first storage chamber solenoid valve is opened to circulate the refrigerant to the first storage chamber evaporator, and the first storage chamber If the temperature of the first storage compartment is less than the predetermined temperature (Tmin; for example, about -1 ℃), the first storage compartment solenoid valve is closed so that the refrigerant circulation of the first storage compartment is closed, at this time, the storage of the first storage compartment The temperature is controlled at a temperature between Tmax and Tmin.

In addition, when the temperature of the second storage compartment is greater than or equal to the temperature Tmax of the first storage compartment, the second storage compartment solenoid valve is opened to circulate the refrigerant to the second storage compartment evaporator, and the first storage compartment whose temperature of the second storage compartment is the reference storage compartment. When the temperature is less than Tmin, the second storage compartment solenoid valve is closed to stop the refrigerant circulation of the second storage compartment evaporator.

At the same time, the control unit drives the compressor according to the open / closed state of the first storage solenoid valve and the second storage solenoid valve, and at this time, the difference between the temperature change time t1 of the first storage compartment and the temperature change time t2 of the second storage compartment. It is determined whether the value is smaller than 2 minutes, which is a predetermined time width Δt (S40). Here, the time width Δt is set as a reference value for comparing with the temperature change time of the storage room and stored in the memory built in the controller.

As a result of the determination in step S40, when the difference between the temperature change time t1 of the first storage chamber and the temperature change time t2 of the second storage chamber is smaller than the preset time width Δt 2 minutes, FIG. 4. As shown in the graph, the operating temperature band of the second storage chamber is returned between the operating temperature bands Tmax and Tmin of the first storage chamber, which is the reference storage chamber, that is, the reference set value, so that the first storage chamber and the second storage chamber correspond to the operating temperature bands. By driving the same drive time of the compressor (S60).

 However, if the difference between the temperature change time t1 of the first storage compartment and the temperature change time t2 of the second storage compartment is greater than 2 minutes, the determination result at step S40 is greater than the preset time width Δt. As shown in the graph of FIG. 5, the operating temperature band of the second storage compartment is defined as T'max (for example, about 0.5 ° C.) based on the range of the operating temperature bands Tmax and Tmin of the first storage compartment which is the reference storage compartment. It drives by resetting to the range of T'min (for example, about -0.5 degreeC).

At this time, the operating temperature bands of the second storage room are T'max (for example, about 0.5 ° C.) and T'min (for example, based on the range of the operating temperature bands Tmax and Tmin of the first storage room, which is the reference storage room). , -0.5 ° C.), the width of the temperature change time t2 of the second storage compartment decreases as shown in the graph shown in FIG. 5 so that the temperature change time t1 and the second storage compartment temperature of the first storage compartment are reduced. In the portion where the temperature change time t2 of the storage chamber is synchronized, the driving time of the compressor is equally driven (S50).

As described above, the present invention reduces the operating time of compressors operated independently for independent control by synchronizing the operating time of the compressor by synchronizing the temperature change time by adjusting the storage temperature bandwidth of each storage chamber in the storage mode in the storage mode. In addition to reducing the noise generated by the compressor operation, there is an effect that can reduce the power consumption.

1 is a cross-sectional view of a typical plurality of kimchi storage.

Figure 2 is a schematic block diagram showing for explaining the operation control method of the kimchi storage in accordance with the present invention.

Figure 3 is a flow chart illustrating the operation control method of the kimchi storage in accordance with the present invention.

4 and 5 are graphs shown for explaining the operation control method of the kimchi storage in accordance with the present invention.

  -Explanation of symbols for the main parts of the drawing-

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

Claims (1)

In the kimchi storage having a plurality of storage rooms, Judging whether or not the kimchi storage mode is in a storage mode; In the storage mode, measuring a temperature change time t1 of the reference storage compartment and a temperature change time t2 of another storage compartment; Comparing the temperature change time t1 of the reference storage room and the temperature change time t2 of the other storage room measured above; Resetting an operating temperature band of another storage compartment when the difference between the temperature change time t1 of the reference storage compartment and the temperature change time t2 of the other storage compartment is greater than 2 minutes before the preset time width Δt. Wow; If the difference between the temperature change time t1 of the reference storage compartment and the temperature change time t2 of the other storage compartment is less than 2 minutes, the operating temperature band of the other storage compartment is determined as the operating temperature of the reference storage compartment. Returning to the band; Operation control method of the kimchi storage, characterized in that consisting of.