KR19980023164A - Freezer temperature control method - Google Patents

Abstract

The present invention proposes a refrigerator control technology that can maximize the refrigeration control efficiency of the refrigerator.

A feature of the present invention is to determine the driving cycle of the compressor based on the temperature information on the current cooling conditions by the defrost sensor and the refrigeration sensor and the door opening and closing information by the door switch, and then through the fan motor driving circuit and the compressor driving circuit. In a cooling control system including a microcomputer for controlling the input of the driving voltage to the fan motor and the compressor, respectively, performing a normal operation mode for cooling the freezer of the refrigerator, cumulative operating time information of the refrigerator, a defrost sensor, a freezing sensor And determining a driving cycle of the compressor based on the refrigerator control information sensed by the door switch, and simultaneously driving the compressor and the cooling fan through the compressor driving circuit and the cooling fan driving circuit. If the condition is off, only the driving voltage applied to the compressor at that time is controlled. From that time in the cooling control method comprising the step of controlling the drive voltage is turned off with the cooling fan after a certain time.

Therefore, the present invention can obtain the effect of maximizing the internal temperature control efficiency of the refrigerator.

Description

Freezer temperature control method

The present invention relates to the control of the freezer compartment temperature of the refrigerator, and more particularly, to a freezer compartment temperature control method for maximizing the internal temperature cooling efficiency by efficiently using the remaining cold air in the cooling compartment where the cooler is installed during the cooling cycle of the freezer compartment.

The refrigeration cycle in a typical refrigerator is as follows.

First, the high temperature refrigerant compressed by the compressor is cooled by passing through the hot pipe, the thick plate pipe, and the wire condenser pipe through the auxiliary heat dissipation pipe connected to the compressor, and then supplied to the dryer.

In addition, the refrigerant passing through the dryer is connected to the heat exchanger in the cooler via a capillary tube.

The recovery pipe is connected to the compressor such that the refrigerant passing through the heat exchanger is recovered through the accumulator to the compressor again.

The refrigeration cycle in such a refrigerator will be described in detail as follows.

First, the compressor compresses a refrigerant, such as a freon gas, at high temperature and high pressure, and sends it out to the auxiliary heat dissipation pipe.

The auxiliary heat dissipation pipe is disposed in an evaporation vessel for defrost water storage installed at the bottom of the refrigerator.

The auxiliary heat dissipation pipe evaporates the defrost water collected into the evaporation vessel by the high temperature (70 ° C. to 80 ° C.) refrigerant flowing therein.

At this time, a dual effect is obtained in which the high temperature refrigerant is somewhat cooled.

The refrigerant passing through the auxiliary heat dissipation pipe passes through the hot pipe.

The hot pipe is installed to pass through the front part inside the cabinet of the door side of the refrigerator, and the function of the hot pipe is to remove dew condensation caused by the difference between the internal temperature and the external temperature when exchanging the outside air of the refrigerator due to the door opening.

After that, the refrigerant is further cooled through the thick plate pipe and the wire condenser pipe to be liquefied, and then passes through the dryer.

The refrigerant cooled from the high temperature while passing through the wire condenser pipe is generated according to the temperature difference between the internal and external air in the pipe through which the refrigerant flows, and is included in the liquid phase refrigerant. This leads to a significant decrease in cooling efficiency.

As a countermeasure against this phenomenon, a dryer is installed at the rear end of the wire condenser pipe to remove moisture components contained in the liquid refrigerant.

The low temperature and high pressure refrigerant from which moisture is removed while passing through the dryer is supplied to a capillary tube (capillary tube).

In this capillary, the pressure of the refrigerant is rapidly adiabaticly expanded from high pressure to low pressure to make the refrigerant low temperature low pressure to produce a temperature drop of about -30 ° C.

The low temperature low pressure liquid refrigerant passing through the capillary is rapidly vaporized in the cooler to take the ambient temperature to create a freezer cold air.

The accumulator separates the liquid refrigerant that is not sufficiently vaporized in the cooler to supply only the pure gaseous refrigerant to the compressor.

By such a refrigeration cycle, the temperature of the cooler is lowered to a very low temperature. The cold air produced in the cooler is mainly fed into the freezer by a freezer fan (hereinafter referred to as a F fan), and a part of the cooler fan (hereinafter R). The pan is weak).

Accordingly, the room temperature of the freezer compartment is cooled to about minus 25 degrees, and the room temperature of the freezer compartment is cooled to a temperature between minus 1 and 2 degrees and plus 4 and 5 degrees.

The cooling in the high temperature is based on the signal of the refrigerating (R) sensor that detects various function key input signals and the temperature of the refrigerating chamber, and the signal of the refrigeration (F) sensor that senses the temperature of the freezing chamber, and the cooling mounted on the cooler. (D) The temperature detection signal of the sensor is input in accordance with the program of the system control microcomputer.

As the freezer compartment cooling of a conventional refrigerator is referred to in part of FIG. 3, the internal temperature of the freezer compartment is moved up and down based on a set temperature value.

When the internal temperature of the freezer compartment increases, the driving voltage is input to the compressor at the upper limit of the temperature rise of the internal temperature distribution characteristic curve, and at the same time, the driving voltage is also applied to the cooling fan motor.

Accordingly, the internal temperature of the freezer compartment is lowered toward the lower temperature limit by driving the compressor and the fan motor.

When the temperature inside the high temperature reaches the lower limit of the temperature drop, the driving voltage supplied to the compressor is cut off, and at the same time, the driving voltage is cut off to the cooling fan motor.

However, the conventional cooling control method has an efficient cooling control effect by turning off the fan motor which is linked to the compressor driving on / off control signal even though the atmosphere sufficiently cooled by the heat exchange in the cooler remains in the cooling chamber. There is a problem that can not be obtained.

An object of the present invention is to provide a freezer compartment temperature control method that can maximize the freezer compartment temperature control efficiency by a simple control program change in the freezer compartment control of the refrigerator.

A feature of the present invention is to determine the drive cycle of the compressor based on the temperature information on the current cooling conditions by the defrost sensor and the refrigeration sensor and the door open and close information by the door switch, and then through the fan motor drive circuit and the compressor drive circuit. In a cooling control system including a microcomputer for controlling the input of the driving voltage to the fan motor and the compressor, respectively, performing a normal operation mode for cooling the freezer of the refrigerator, cumulative operating time information of the refrigerator, a defrost sensor, a freezing sensor And determining the driving cycle of the compressor based on the refrigerator control information sensed by the door switch, and simultaneously driving the compressor and the cooling fan through the compressor driving circuit and the cooling fan driving circuit. If the condition is off, only the driving voltage applied to the compressor at that time From that time in the cooling control method comprising the step of controlling the drive voltage is turned off with the cooling fan after a certain time.

1 is a block diagram of a refrigerator control system for implementing the present invention.

2 is a flow chart for explaining the present invention.

Figure 3 is a fan motor control output waveform diagram according to the present invention.

＊＊ Explanation of symbols on main parts of drawing ＊＊

10: microcomputer 11: refrigeration sensor

12: Refrigeration sensor temperature detection circuit 13: Defrost sensor

14: Defrost sensor temperature detection circuit 15: Fan motor drive circuit

16: fan motor 17: compressor drive circuit

18: compressor

Hereinafter, the present invention will be described with reference to the accompanying drawings.

1 is a hardware configuration diagram of a cooling control system of a refrigerator for implementing the present invention.

As referred to herein, the temperature detection signal from the defrost sensor 13 installed in the cooler to read the defrost temperature condition of the cooler is converted into a voltage component for the microcomputer input in the defrost sensor temperature sensing circuit 14. The connection is provided to the microcomputer 10 side.

In addition, the temperature detection signal from the freezing sensor 11 installed in the refrigerating chamber to read the temperature condition of the refrigerating chamber is converted into a voltage component for the input of the microcomputer in the freezing sensor temperature sensing circuit 12, and thus the micom 10 side. Connect to provide.

The fan motor control signal output from the microcomputer 10 is connected to the fan motor driving circuit 15 so that the driving voltage supplied to the fan motor 16 is switched by the fan motor driving circuit 15. do.

The compressor control signal output from the microcomputer 10 is connected to the compressor driving circuit 17 so that the driving voltage supplied to the compressor 18 is switched by the compressor driving circuit 17.

The control process of the present invention will be described with reference to FIG. 2 based on the hardware configuration for refrigerator cooling control configured as described above.

First, the refrigerator performs a normal operation mode for cooling control in the refrigerator according to a user temperature setting program.

In the normal operation mode, the accumulated information of the driving time of the refrigerator, which is accumulated in the microcomputer of the control system, is the injection force data, and the temperature for the current cooling condition by the defrost sensor 13 and the freezing sensor 11 is included. The driving cycle of the compressor is determined by adding information and door opening and closing information by the door switch 19.

After the compressor driving point is determined according to the driving cycle of the compressor, the microcomputer 10 inputs a driving voltage to the compressor 18 through the compressor driving circuit 17.

At the same time, the microcomputer 10 inputs the fan motor driving voltage to the fan motor 16 through the fan motor driver 17.

Therefore, since the cold air of the cooling chamber heat-exchanged in the freezer is forced into the freezing chamber by the cooling fan, the internal temperature of the freezer drops rapidly toward the lower temperature set value.

Then, as shown in FIG. 3, when the internal temperature reaches the lower limit of the cooling temperature, the microcomputer 10 controls the compressor driving circuit 17 to turn off the driving voltage supplied to the compressor 18.

However, the microcomputer does not simultaneously send control signals for turning off the fan fan 16 to the fan motor driving circuit.

That is, when the microcomputer is turned off after starting the compressor by the time width W1 of FIG. 3, which is a value determined by the program in advance, after the continuous drive control of the cooling fan further by the time width W2 from the off point of the compressor. It is off-controlled.

Therefore, since the cold air remaining in the cooling chamber by the time width W2 is further introduced into the freezing chamber, the temperature of the freezing chamber can be further lowered.

As described above, the present invention enables the internal temperature of the freezer compartment to be significantly lowered than the conventional case without additional power consumption through simple modification of the existing refrigerator control program.

Therefore, the present invention can bring the maximum power utilization efficiency of the refrigerator, this / T will have a unique effect.

Claims (1)

The driving period of the compressor is determined based on the accumulated accumulated time information of the refrigerator, temperature information on current cooling conditions by the defrost sensor 13 and the freezing sensor 11, and door opening and closing information by the door switch 19. In the cooling control system including a microcomputer 10 for controlling the input of the driving voltage to the fan motor 16 and the compressor 18 through the fan motor driving circuit 15 and the compressor driving circuit 17, respectively, Performing a normal operation mode for cooling the freezer compartment of the refrigerator; After determining the driving period of the compressor based on the accumulated operating time information of the refrigerator and the refrigerator control information detected by the defrost sensor 13, the freezing sensor 11, and the door switch 19, the compressor driving circuit 17 and the cooling fan are determined. Simultaneously driving the compressor 18 and the cooling fan 16 through the drive circuit 15; And if the compressor is in the driving off condition, controlling only the driving voltage applied to the compressor at that time, and controlling the driving voltage input to the cooling fan after a certain time has elapsed. Freezer temperature control method.