KR100269465B1 - Mithod for controlling operation of kimch'i store house - Google Patents

Abstract

The present invention relates to a drive control method of a kimchi storage, and checks the compressor operation rate while turning the compressor on and off according to the temperature detection value of the high temperature sensor. By selectively shortening and adjusting the compressor operation rate, the compressor operation rate is lowered or increased depending on the ambient temperature of the kimchi storage, so that the kimchi stored in the interior can be prevented from being over mature and overcooled.

Description

Driving Control Method of Kimchi Storage

The present invention relates to a kimchi storage, and more particularly, to a drive control method of the kimchi storage to prevent the compressor drive rate is lowered or increased according to the ambient temperature of the kimchi storage to prevent overheating and overcooling of the kimchi stored in the interior. .

In general, in order to store frozen and refrigerated foods or fermented foods (for example, kimchi, etc.), each of them should be stored at a temperature suitable for storing them. A refrigerator having a freezer and a refrigerating chamber is mainly used to perform this function. Used.

On the other hand, when the refrigerated food and the fermented food is stored together in the refrigerator compartment of the refrigerator, the odor generated by the fermentation of the fermented food not only generates odors in the refrigerating chamber, but also odor is exhausted in other refrigerated foods inherent in the refrigerated food There is a need to store bulky fermented foods (kimchi) in a separate reservoir due to the increase in refrigerated foods and fermented foods stored in the refrigerator compartment.

In addition, kimchi should be buried in the ground for proper ripening, and the kimchi should be stored in it to be ripe and taste properly. However, it is difficult to keep it in a residential area.

Recently, researches on kimchi storage that can store kimchi in a separate storage space, rather than a refrigerator, to solve the above-mentioned difficulties have been variously researched in various technical fields, such kimchi storage is generally 1 and As shown in FIG.

Conventional kimchi storage can be seen in reference to Figure 1, the kimchi storage room to be described later is rotated in one direction on the upper surface of the main body 10 formed therein the door 20 to open and close the kimchi storage room Is hinged.

In addition, at both side predetermined portions of the main body 10, a handle 30 is provided to allow a user to grip the main body 10 when the main body 10 moves.

In addition, the bottom surface front portion of the main body 10 is provided with a horizontal adjusting leg 40 for adjusting the horizontality of the main body 10, the bottom surface rear portion of the main body 10 the main body 10 Wheel 50 is installed to be rotated when the movement of the).

In addition, a predetermined portion of the upper surface of the door 20 is provided with a key input unit 60 for setting an operation mode of the kimchi storage and adjusting the temperature of the kimchi storage room according to a user's preference, and the door 20 At the front of the door), the door handle 70 is installed so that the user can easily grip the door 20 when opening and closing the door 20.

Here, the inside of the main body 10, as shown in Figure 2, the kimchi storage chamber 80, and the machine room 90 is installed, the compressor 91 and the control box 92, etc. are stored Kimchi storage container Each partition is formed by a partition wall 11 made of a heat insulating material, and an evaporator 81 is inserted into the outer partition wall 11 of the kimchi storage chamber 80 to generate cold air by using latent evaporation generated when the refrigerant is vaporized. It is installed.

Here, a control unit for controlling the driving of the compressor 91 is built in the control box 92.

In addition, the bottom partition 11 of the point where the inlet refrigerant pipe 81a of the evaporator 81 is installed, the temperature sensor 100 is indirectly detect the internal temperature of the kimchi storage chamber 80, the metal pipe 101 It is installed by inserting it.

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

In the initial state, when the user selects the "cold storage mode" through the key input unit 60, the compressor 91 is driven by the control unit in the control box 92, the refrigerant by the drive of the compressor 91 Is circulated to supply the refrigerant to the evaporator 81, the refrigerant supplied to the evaporator 81 vaporizes while the coolant is generated, the kimchi stored in the kimchi storage chamber 80 by the cold is stored refrigerated.

At this time, the ambient temperature of the evaporator 81 is detected through the temperature sensor 100, a temperature signal corresponding to the detected ambient temperature of the evaporator 81 is applied to the control unit, the control unit is a temperature sensor 100 The ambient temperature of the evaporator 81 is sensed through the temperature signal applied from).

Then, the controller maintains the driving state of the compressor 91 when the detected ambient temperature of the evaporator 81 is equal to or greater than a predetermined "compressor operating temperature" while the ambient temperature of the detected evaporator 81 is increased. When the temperature is equal to or lower than the preset "compressor stop temperature", the drive of the compressor 91 is stopped.

That is, the compressor 91 is driven by indirectly detecting the internal temperature of the kimchi storage chamber 80 through the ambient temperature of the evaporator 81 detected by the temperature sensor 100.

3 (a) to 3 (c) are diagrams for explaining a conventional compressor operating state, and FIG. 3 (a) shows the compressor 91 when the ambient temperature of the kimchi storage room is room temperature. Figure 3 (b) shows the operating state of the compressor 91 when the ambient temperature of the kimchi storage is a low temperature, Figure 3 (c) shows the ambient temperature of the kimchi storage is high temperature In this case, the operating state of the compressor 91 is illustrated.

However, according to the conventional kimchi storage as described above, since the temperature sensor is installed on the evaporator side in the partition forming the kimchi storage chamber, the temperature sensing value of the temperature sensor is affected by the ambient temperature of the kimchi storage, As can be seen from (b) of 3, when the ambient temperature of the kimchi storage becomes low, the rise time of the temperature sensing value of the temperature sensor becomes longer, which leads to a longer idle time of the compressor, resulting in a lower compressor operation rate. There was a problem that the kimchi stored in the storage room is over mature.

In addition, as can be seen with reference to (c) of Figure 3, when the ambient temperature of the kimchi storage is a high temperature, the temperature sensing value fall time of the temperature sensor according to the operation of the compressor is longer than when the room temperature, which is because of the compressor There was a problem that the operation time of the long kimchi stored in the kimchi storage room is overcooled.

Accordingly, the present invention has been made to solve the problems of the prior art as described above, by checking the compressor drive rate, by selectively reducing the drive time and idle time of the compressor according to the check result to adjust the compressor drive rate, The purpose of the present invention is to provide a driving control method of the kimchi storage, which can prevent overheating and overcooling of the kimchi stored in the refrigerator by decreasing or increasing the compressor driving rate according to the ambient temperature of the kimchi storage.

The drive control method of the kimchi storage according to the present invention for achieving the above object, the compressor operation step of turning on / off the compressor in accordance with the temperature detection value of the temperature sensor, and the compressor for calculating the compressor drive ratio in the compressor operation step The drive rate calculation step and the idle time reduction step of driving the compressor by forcibly shortening the idle time of the compressor when the calculated compressor drive rate is less than the lower limit set drive rate, and the calculated compressor drive rate is the upper limit set drive rate. If it is higher, it is characterized by consisting of a drive time shortening step for forcibly shortening the drive time of the compressor to drive the compressor.

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

Figure 2 is a vertical cross-sectional view of the kimchi storage cut on the basis of AA 'line,

3 (a) to (c) is a view for explaining a conventional compressor operating state,

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

5 (a) and (b) are views for explaining the operating state of the compressor according to a preferred embodiment of the present invention,

Figure 6 is a flow chart for explaining the drive control method of the kimchi storage in accordance with a preferred embodiment of the present invention,

FIG. 7 is a flowchart for describing a detailed operation of the idle time reduction step shown in FIG. 6;

FIG. 8 is a flowchart for explaining a detailed operation process of the driving time reduction step shown in FIG. 6;

<Description of the code | symbol about the principal part of drawing>

60: key input unit 80: kimchi storage room

81: evaporator 91: compressor

100: temperature sensor 200: control unit

300: compressor drive unit

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

4 is a schematic block diagram of hardware for carrying out the present invention. The hardware for carrying out the present invention includes a key input unit 60, a temperature sensor 100, a control unit 200, and a compressor driving unit. 300 and the compressor 91, the basic configuration of the hardware shown in the same drawing is the same as the kimchi storage shown in Figs. 1 and 2, the same parts are given the same reference numerals and duplicate description It will be omitted.

In FIG. 4, when the user selects the "cold storage mode" through the key input unit 60, the controller 200 drives the compressor 91 according to the temperature signal input from the temperature sensor 100. Output the signal.

In addition, the compressor driver 300 drives the compressor 91 by applying power in response to a drive signal from the controller 200.

Meanwhile, FIGS. 5A and 5B are diagrams for describing an operating state of a compressor according to a preferred embodiment of the present invention, and FIG. 5A shows a compressor driving rate P having a lower limit setting driving rate. In the case of less than PL, the idle time of the compressor 91 is forcibly shortened to within the idle limit time ts _{L. In} FIG. 5B, the compressor drive rate P is the upper limit setting drive. When the ratio PH is higher than the ratio PH, the driving time of the compressor 91 is forcibly shortened to within the driving limit time td _L.

The operation of the present invention through the hardware configured as described above will be described in detail with reference to FIGS. 4 to 8.

First, when power is applied from the outside, the control unit 200 is initialized (S10).

At this time, when the user selects an operation mode (for example, a cold storage mode and a maturing mode) through the key input unit 60, a key signal corresponding to the operation mode selected by the user from the key input unit 60 is controlled by the control unit ( 200).

At the same time, a temperature signal corresponding to the ambient temperature of the evaporator 81 is input from the temperature sensor 100 to the controller 200.

Here, the controller 200 determines whether the user selects the "cold storage mode" through the key signal from the key input unit 60 (S20), and if the operation mode selected by the user is not the "cold storage mode", the control is performed. End the operation.

If it is determined in step S20 that the user selects the "cold storage mode", the controller 200 detects and senses the ambient temperature of the evaporator 81 through the temperature signal from the temperature sensor 100. According to the ambient temperature of the evaporator 81, the compressor 91 is turned on / off (S30), the details of which are as follows.

In step S30, the control unit 200 detects the ambient temperature of the evaporator 81 through the temperature signal from the temperature sensor 100, and the detected ambient temperature of the evaporator 81 is a predetermined "compressor operating temperature. Is higher than or equal to, the drive signal for driving the compressor 91 is applied to the compressor driving unit 300.

Power is supplied from the predetermined power supply means to the compressor 91 through the compressor driving unit 300 by the drive signal applied from the control unit 200, and the refrigerant cycle is driven by driving the compressor 91 to which power is applied. Through the refrigerant is circulated.

Refrigerant circulated by the compressor (91) flows into the evaporator (81) and vaporizes, and by evaporation of the refrigerant, cool air by latent heat of evaporation is generated from the evaporator (81), and the cold air from the evaporator (81) Kimchi stored in the kimchi storage room 80 is refrigerated.

On the other hand, if the ambient temperature of the evaporator 81 is less than the predetermined "compressor stop temperature", the control unit 200 applies a driving stop signal for stopping the driving of the compressor 91 to the compressor driving unit 300.

Power supplied from the predetermined power supply means to the compressor 91 through the compressor driving unit 300 is cut off by the driving stop signal from the control unit 200, and the driving of the compressor 91 is stopped by cutting off the power. do.

Here, the control unit 200 averages and calculates the compressor drive ratio P for a predetermined period (for example, about two cycles) (S40).

For reference, the compressor drive ratio P is a compressor drive cycle (“ON” cycle) of the compressor drive cycle (“ON / OFF” cycle; T [sec]) as shown in Equation 1 below: Td [sec ]) Ratio.

Subsequently, the control unit 200 sets the compressor driving rate P calculated in the step S40 to a predetermined lower limit setting drive rate (preferably, about 7%; PL) and an upper limit setting drive rate (preferably, About 30%; compared with PH) (S50), if the compressor drive ratio P falls within the range which is equal to or less than the lower limit set drive ratio PL and less than or equal to the upper limit set drive ratio PH, the step S40 is performed. As described above, the operation state of turning on / off the compressor 91 is maintained according to the temperature detection value of the temperature sensor 100 (S60).

If the compressor driving ratio P is less than the lower limit set driving ratio PL as a result of the comparison in the step S50, the controller 200 forcibly shortens the idle time of the compressor 91 to perform the operation. (S100), a detailed operation thereof is as shown in FIG.

In FIG. 7, first, the control unit 200 calculates the compressor drive cycle Td and the compressor drive cycle T checked in step S40, so that the compressor drive ratio P is the lower limit set drive ratio PL. The idle time limit ts _L is calculated to be within the range of not less than and equal to or less than the upper limit setting drive ratio PH (S101).

Then, the controller 200 detects the ambient temperature of the evaporator 81 through the temperature signal from the temperature sensor 100 (S102), and detects the ambient temperature and the "compressor operating temperature" of the detected evaporator 81. In comparison (S103), if the ambient temperature of the evaporator 81 is less than the "compressor operating temperature" as a result of the comparison, the process returns to the step S102 of detecting the ambient temperature of the evaporator 81.

If the ambient temperature of the evaporator 81 is equal to or greater than the "compressor operating temperature" as a result of the comparison in step S103, the control unit 200 sends a drive signal for driving the compressor 91 to the compressor driving unit 300. It is applied (S104).

Thus, power is supplied from the predetermined power supply means to the compressor 91 through the compressor driver 300 by the drive signal applied from the control unit 200, and the refrigerant is driven by driving the compressor 91 to which power is applied. The refrigerant is circulated through the cycle.

Refrigerant circulated by the compressor (91) flows into the evaporator (81) and vaporizes, and by evaporation of the refrigerant, cool air by latent heat of evaporation is generated from the evaporator (81), and the cold air from the evaporator (81) Kimchi stored in the kimchi storage room 80 is refrigerated.

Then, the control unit 200 detects the ambient temperature of the current evaporator 81 through the temperature signal from the temperature sensor 100 (S105), the ambient temperature of the detected evaporator 81 and the "compressor stop temperature" (S106), if the ambient temperature of the evaporator 81 is higher than the "compressor stop temperature" as a result of the comparison, the process returns to the step S104 to continue the driving state of the compressor 91.

If the ambient temperature of the evaporator 81 is equal to or lower than the "compressor stop temperature" as a result of the comparison in step S106, the control unit 200 outputs a driving stop signal for stopping the driving of the compressor 91. In step S107).

As a result, the power supplied from the predetermined power supply means to the compressor 91 through the compressor driving unit 300 is cut off by the driving stop signal from the control unit 200, and the compressor 91 is driven by cutting off the power. Is stopped.

At the same time, the control unit 200 counts the idle time of the compressor 91 from the time when the driving of the compressor 91 of the step S107 is stopped (S108), and calculates the idle time counted up to the present time (S101). It compares with the time limit (ts _L ) calculated in (S109).

If the time counted as a result of the comparison in step S109 is greater than or equal to the limit stop time tSL, the controller 200 resets the pause time counted up to the present time (S110), and returns to the step S104. Drive 91.

If the time counted as a result of the comparison in step S109 is less than the limit stop time tSL, the controller 200 determines the current ambient temperature of the evaporator 81 through a temperature signal from the temperature sensor 100. By detecting (S111), the ambient temperature of the detected evaporator 81 is compared with the "compressor operating temperature" (S112).

When the ambient temperature of the evaporator 81 is equal to or greater than the "compressor operating temperature" as a result of the comparison in step S112, the controller 200 resets the idle time counted up to the present time (S110), and then proceeds to step S104. The compressor 91 is returned.

If the ambient temperature of the evaporator 81 is less than the "compressor operating temperature" as a result of the comparison in the step S112, the control unit 200 causes the operation mode to be "cold storage" by the key signal from the key input unit 60. Mode "to determine other operation mode (for example, aging mode) is changed (S113). If the operation mode is not changed as a result of the determination, the process returns to the step S107 and the compressor 91 is driven. Keep stopped.

If, in step S113, the user operates the selection button of the key input unit 60 to change the operation mode from the "cold storage mode" to another operation mode (for example, ripening mode), the corresponding key A signal is input from the key input unit 60 to the control unit 200, and the control unit 200 ends the control operation.

On the other hand, if the result of the comparison in the step (S50) the compressor drive rate (P) is less than the upper limit set drive rate (PH), the control unit 200 forcibly shortens the drive time of the compressor 91 to perform the operation (S200), a detailed operation thereof is as shown in FIG.

In Fig. 8, first, the control unit 200 calculates the compressor drive cycle Td and the compressor drive cycle T, which are checked in step S40, so that the compressor drive ratio P is the lower limit set drive ratio PL. The driving time limit td _L is calculated to be within the range that is equal to or greater than and equal to or less than the upper limit set driving ratio PH (S201).

Then, the control unit 200 detects the ambient temperature of the evaporator 81 through the temperature signal from the temperature sensor 100 (S202), and the detected ambient temperature of the evaporator 81 and the "compressor operating temperature" and In comparison (S203), if the ambient temperature of the evaporator 81 is less than the "compressor operating temperature" as a result of the comparison, the process returns to the step S202 of detecting the ambient temperature of the evaporator 81.

If the ambient temperature of the evaporator 81 is equal to or greater than the "compressor operating temperature" as a result of the comparison in the step S203, the control unit 200 sends a drive signal for driving the compressor 91 to the compressor driving unit 300. It is applied (S204).

Thus, power is supplied from the predetermined power supply means to the compressor 91 through the compressor driver 300 by the drive signal applied from the control unit 200, and the refrigerant is driven by driving the compressor 91 to which power is applied. The refrigerant is circulated through the cycle.

Refrigerant circulated by the compressor (91) flows into the evaporator (81) and vaporizes, and by evaporation of the refrigerant, cool air by latent heat of evaporation is generated from the evaporator (81), and the cold air from the evaporator (81) Kimchi stored in the kimchi storage room 80 is refrigerated.

At the same time, the control unit 200 counts the driving time of the compressor 91 from the time when the compressor 91 of the step S204 is driven (S205), and calculates the driving time of the compressor 91 counted up to now. compared to the driving limit time (td _L) calculated in (S201) and (S206), the comparison result if the driving time of the compressor (91) than the driving limit time (td _L) step for stopping the compressor 91 Proceed to S209.

If the driving time of the compressor 91 is less than the driving limit time td _L as a result of the comparison in the step S206, the controller 200 may present the current evaporator 81 through the temperature signal from the temperature sensor 100. Detects the ambient temperature of (S207).

Then, the control unit 200 compares the ambient temperature of the evaporator 81 detected in step S207 with the "compressor stop temperature" (S208), and the comparison result shows that the ambient temperature of the evaporator 81 is "compressor stop temperature." If higher, the flow returns to the step S204 to continue the driving state of the compressor 91.

If the ambient temperature of the evaporator 81 is less than the "compressor stop temperature" as a result of the comparison in the step S208, the compressor 200 outputs a driving stop signal for stopping the driving of the compressor 91 by the controller 200. ) And the driving time of the compressor 91 counted up to now is reset (S209).

As a result, the power supplied from the predetermined power supply means to the compressor 91 through the compressor driving unit 300 is cut off by the driving stop signal from the control unit 200, and the compressor 91 is driven by cutting off the power. Is stopped.

Then, the controller 200 detects the ambient temperature of the current evaporator 81 through the temperature signal from the temperature sensor 100 (S210), and detects the ambient temperature and the "compressor operating temperature" of the detected evaporator 81. When the ambient temperature of the evaporator 81 is equal to or greater than the "compressor operating temperature", the process returns to the step S204 and the compressor 81 is driven.

If the ambient temperature of the evaporator 81 is less than the "compressor operating temperature" as a result of the comparison in the step S211, the operation mode is "refrigerated storage" by the control unit 200 by the key signal from the key input unit 60. Mode "to determine other operation mode (for example, aging mode), and if it is determined that the operation mode is not changed (S212), the process returns to the step (S209) and the drive of the compressor 91 Keep stopped.

If the user changes the operation mode from the "cold storage mode" to another operation mode (for example, ripening mode) by operating the selection button of the key input unit 60 in step S212, the corresponding key. A signal is input from the key input unit 60 to the control unit 200, and the control unit 200 ends the control operation.

That is, according to the prior art, when the outside temperature, that is, the ambient temperature of the kimchi storage, is low, the temperature sensing value of the high temperature sensor is increased from the compressor stop temperature to the compressor operating temperature, thereby increasing the compressor downtime. Compressor operation rate is lowered, and the kimchi stored in the refrigerator is over-maturated. In addition, when the ambient temperature is high, the temperature detection value falls from the "compressor operating temperature" to the "compressor stop temperature". While the time was longer and the compressor running rate increased, the kimchi was supercooled,

As can be seen with reference to Fig. 5, the present invention is to check the compressor running rate, and if the checked compressor running rate is less than the lower limit setting drive rate, the compressor rest time is shortened to within the rest limiting time ts _L. If the drive rate is increased and the compressor drive rate exceeds the upper limit, then the drive time is shortened to within the drive limit time (td _L ), thereby lowering the compressor drive rate. The increased kimchi is to prevent over-maturation and overcooling.

On the other hand, in the embodiment of the present invention has been described by taking only the case of indirectly detecting the temperature in the kimchi storage room, that is, the interior of the evaporator through the ambient temperature, the skilled in the art through the temperature sensor installed in the present invention It can be easily seen that it can be easily applied even if the temperature in the refrigerator is directly detected.

Therefore, according to the present invention, the compressor drive rate is checked and the compressor drive rate is adjusted by selectively shortening the drive time and idle time of the compressor according to the checked compressor drive rate, thereby adjusting the compressor drive rate according to the ambient temperature of the kimchi reservoir. As the rate is lowered or higher, there is an effect that can prevent the kimchi stored in the overheating and overcooling.

Claims (5)

In the drive control method of the kimchi storage, A compressor operation step of turning on / off the compressor according to the temperature detection value of the temperature detection sensor, A compressor drive ratio calculation step of calculating a compressor drive ratio in the compressor operation step; If the calculated compressor drive ratio is less than the lower limit set drive ratio, the idle time shortening step of forcibly shortening the idle time of the compressor to operate the compressor; And a drive time reduction step for driving the compressor by forcibly shortening the drive time of the compressor when the calculated compressor drive ratio is higher than the upper limit set drive ratio. The method of claim 1, wherein the compressor drive rate, Kimchi storage drive control method, characterized in that the percentage of the compressor drive cycle divided by the compressor drive cycle. The method of claim 1, wherein the compressor drive rate calculation step, A drive control method for a kimchi storage, characterized in that the average of the compressor drive rate during a plurality of operation cycles. The method of claim 1, wherein the pause time shortening step, Calculating a rest time limit for correcting a compressor drive rate within a range above the lower limit set drive rate and below the upper limit set drive rate; And counting the idle time of the compressor to drive the compressor forcibly when the idle time elapses. The method of claim 1 or 4, wherein the driving time shortening step, Calculating a drive time limit for correcting a compressor drive rate within a range above the lower limit set drive rate and below the upper limit set drive rate; The driving control method of the kimchi storage, characterized in that the step of counting the drive time of the compressor and forcibly stopping the compressor when the drive time limit elapses.