KR19980018135U - Cold room overcooling device - Google Patents

Abstract

The present invention proposes a technology for preventing overcooling in a refrigerator in which an air curtain is made at the time of opening the door and a cold shower occurs for a certain time even when the door is closed in consideration of the preservation of high food resistance due to frequent opening of the refrigerator.

In the core technology of the present invention, a cold air passage (27) having a cold air discharge portion (29) is provided on the upper surface of the refrigerating compartment along the front side of the door, and is formed from the cooler (17) inside the cold air passage (27). An air curtain fan 21 for transferring cold air to the cold air discharge unit 29 is installed, and the door on / off contact signal detected by the door switch 26 is connected to the microcomputer 20 to be applied. The signal output from the first output terminal O1 of the microcomputer 20 is connected to be applied to the input element 34 of the SSR 33 via the inverter 23 and is photocoupled to the input element 34. The output element 35 of the SSR 33 is connected so that the commercial AC voltage supplied to the air curtain fan 21 is switched, and the signal output from the first output terminal O1 of the microcomputer 20 is switched. Logic level is output when the door is opened, and pulse width modulated in the form of pulse width when the door is closed. It is output to adjust the cold air output of the air curtain by the flow angle control.

Description

Cold room overcooling device

The present invention relates to a refrigerating chamber air curtain device that can reduce the temperature variation in the vicinity of the door due to frequent opening / closing of the refrigerator door and also minimizes the outflow of cold air inside the door when the door is opened. The present invention relates to a refrigerating compartment supercooling preventing apparatus that can prevent excessive cooling phenomenon when a high internal temperature is rapidly reduced during door closing by using a method.

Referring to the flow of the refrigerant for freezing the refrigerator in general.

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.

Thereafter, the refrigerant is sufficiently cooled while passing through the thick plate pipe and the wire condenser pipe to become a liquefied state, 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 drops to about minus 40 degrees. The cold air produced in the cooler is mainly fed into the freezer by a freezer fan (hereinafter referred to as F fan), and a part of the cooler fan (hereinafter It is weak because it is an R fan), and it is fed into the fridge.

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

However, since the maintenance of the internal temperature of the refrigerator is achieved by controlling the compressor and the cooling fan based on the temperature sensing output of the temperature sensor, the internal temperature of the refrigerator is the point of installation of the temperature sensor that actually senses the internal temperature. Only by specifying the temperature of the will have a problem that does not become the total average value of the internal temperature.

In the high temperature distribution of the refrigerator, the space is designed to be relatively narrow and in the freezer with a small number of open doors, the deviation is low, so the overall temperature is maintained evenly. However, the refrigerator is designed with a relatively large space and frequent door opening occurs. In the refrigerating chamber, the temperature deviation is bound to appear large.

In particular, the frequent opening of the door of the refrigerating chamber eventually makes the internal temperature near the inside of the door much higher than the temperature of the other parts of the refrigerating chamber, so the foods placed in this area have a short shelf life.

An object of the present invention is to reduce the time it takes to cool the internal temperature of the refrigerator compartment to the set temperature of the refrigerator, and also to minimize the partial temperature deviation between the positions of the internal temperature for frequent opening of the door. To provide a refrigerator compartment subcooling prevention device for preventing unwanted subcooling during rapid rapid internal temperature drop in accordance with the operation of the air curtain in the refrigerator applied.

A feature of the present invention is to form a cold air passage having a cold air discharging portion (slit or a plurality of openings) at the top of the front side of the door side along the trimming plate partitioning the freezer compartment and the refrigerating compartment in the refrigerator, and from the cooler inside the cold passage An air curtain fan for forcibly conveying the cold air produced to the cold air discharge portion of the upper portion of the front side of the door side, and by the microcomputer to input the on / off contact signal of the door switch during opening and closing of the freezer door of the refrigerator When operating the air curtain fan, the air curtain fan is controlled by the voltage change by the thyristor flow angle control method that switches to the pulse width modulated output waveform from the microcomputer to control the air cooler by lowering the cold air output than when the door is closed. To manipulate the RPM.

1 is a cross-sectional view of a refrigerator for explaining the air curtain device installed in the refrigerating compartment according to the present invention.

Figure 2 is a circuit diagram of an air curtain adjusting device according to the present invention.

Figure 3 is an angle waveform diagram of Figure 2 for explaining the output waveform for air curtain fan control according to the present invention.

4 is a flow chart for explaining the operation of the present invention.

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

20: microcomputer 21: air curtain fan

22: R (refrigerated) fan 23, 24: inverter

25: photo coupler 26: door switch

27: cold air passage 28: F (frozen) fan

29: cold air discharge part 30: protection circuit

31: rectifier circuit 32: commercial power

33: SSR 36: Relay

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

1 is a cross-sectional structural view of a refrigerator showing a schematic structure of an air curtain device of the present invention.

As shown here, a cold air passage 27 having a cold air discharge portion 29 along the upper end of the front side is installed at the upper end of the refrigerating compartment side of the trimming plate partitioning the freezer compartment and the refrigerating compartment of the refrigerator.

Inside the cold air passage 27, an air curtain fan 21 for forcibly transferring cold air made from the cooler 17 to the cold air discharge portion 29 formed along the upper end of the door side front part is provided.

The air curtain fan 21 is configured to be driven and controlled by the microcomputer 20 that receives the on-contact signal of the door switch 26 when the freezer door is opened, which will be described below.

2 is a circuit diagram for driving control of the present invention air curtain device.

As referred to herein, the door open detection signal generated from the refrigerator door switch of the refrigerator is applied to the input terminal I1 of the system control microcomputer 20 of the refrigerator.

Looking specifically at the circuit configuration, the switch on the contact generated when the door switch 26 detects the door opening of the refrigerator, the voltage of the commercial AC power supply 32 is rectified through the rectifier circuit 31 and then the photo It is connected to be applied to the input terminal side (photo diode side) of the coupler 25.

The logic signal output of the Vcc level appearing on the output terminal side (phototransistor side) of the photo coupler 25 is configured to be connected to the input terminal of the microcomputer 20 via the CR protection circuit 30.

In addition, the pulse width modulation output in the form of a pulse string output from the first output terminal O1 of the microcomputer 20 is inverted through the inverter 23 and connected to be applied to the input element 34 of the SSR 33. By means of the element of the SSR 33, the commercial AC power source 32 to be supplied at the operating voltage to the air curtain fan 21 is connected so as to be switched.

In addition, the logic level signal output from the second output terminal O2 output from the microcomputer 20 is connected to be provided as a drive signal of the relay 36 through the inverter 24 and connected by the contact of the relay 36. The R fan 22 is connected to the 220V driving commercial AC voltage is applied.

Referring to the operation relationship of the refrigerator air curtain system according to the circuit configuration of the device of the present invention configured as described above are as follows.

The refrigerating compartment door switch 26 is installed on a trimming plate, which is a plate of the freezer compartment and the refrigerating compartment, and when the refrigerating compartment door of the refrigerator is opened, a switch-on contact is generated.

At this time, the on-contact signal causes the AC voltage of the commercial power supply 32 to be input to the rectifier circuit 31 to be converted into a DC voltage, and then to the input side of the photocoupler 25.

Since the input side of the photocoupler 25 is made of photodiode and its output side is made of phototransistor, the output terminal of the photocoupler 25 has a logic of Vcc level which is electrically isolated from the voltage level of the input side. The output value is obtained.

The logic output value of the photocoupler 25 may be applied to the input terminal I1 of the microcomputer 20 through the CR protection circuit 30.

Accordingly, the microcomputer 20 determines whether the door of the refrigerating chamber is opened or not as the contact of the door switch 26.

When the door switch 26 is detected to be turned on by the door opening, the microcomputer 20 outputs a high level logic during the first preset time T1 of the previously set air curtain.

This high level logic value drives the input element 34 of the SSR 33 through the inverter 23, which is then photocoupled to the output element 35 of the SSR 33 and thus the air curtain fan 21. ) 220V commercial AC power supply 32 is supplied to the cold air curtain has a relatively large output.

In other words, the air curtain fan 21 is rotated at a high RPM to produce a large cold air discharge output is set to 220V.

The first operation time T1 is preferably set to about 30 seconds and may be set as required or differently depending on season.

After the air curtain fan 21 is operated for the first predetermined time through this process, the operation of the air curtain fan is terminated as it is regardless of whether the refrigerator compartment door is closed.

This is to prevent the failure of the compressor, such as the air curtain function is executed indefinitely when the refrigerator door is not completely closed due to a user mistake.

On the other hand, if the door is not open condition in the above step, the door is closed, so the microcomputer performs the next step of determining whether the refrigeration fan (22) is operating.

Herein, when it is detected that the refrigeration fan 22 is operating, the microcomputer 20 executes a step of turning off the air curtain fan 21 and ending the air curtain operation mode.

However, if the refrigeration fan is not in operation at this stage, the microcomputer executes the step of operating the air curtain fan for a second preset operation time T2.

In this case, the pulse width modulated output in the form of a pulse string appears in the second output terminal O2 of the microcomputer 20.

This pulse width modulation output is level-inverted via the inverter 23 and applied to the input element 34 of the SSR 33.

3 is an input / output waveform diagram of the long SSR, wherein (B) shows the waveform of the input device and (A) shows the waveform of the output device.

As referred to herein, it can be seen that the distribution angle of the commercial AC voltage supplied to the air curtain fan is changed by the duty ratio of the pulse waveform applied to the input element 34 of the SSR 33.

Therefore, the magnitude of the voltage applied to the air curtain fan can be changed by programming the microcomputer so that the pulse width of the pulse width modulation signal output from the second output terminal of the microcomputer can be variably output. Will be.

The second operation time T2 is preferably set to about 2 minutes and may be set as required or differently depending on season.

Thereafter, it is determined whether the refrigeration fan 22 operation signal is turned on during the operation of the air curtain fan 21 during the second set time T2. When the refrigeration fan operation signal based on the R sensor is generated, the operation of the air curtain fan is immediately performed. If it is off and there is no refrigeration fan operating signal, start the air curtain fan for the second predetermined operation time, and then turn off and end.

The present invention described above, due to the frequent opening and closing of the freezer door of the refrigerator, the food placed on the door side of the refrigerator is placed in a relatively poor temperature condition compared to the food disposed inside the In order to solve the problem of poor storage, the air curtain device is placed on the trimming plate side of the upper part of the inside of the refrigerator, and when the user opens the door, the air is formed at this time by allowing the air to be blown out by a separate fan for a certain period of time. By blocking the alternating current between the ambient atmosphere temperature and the outside air temperature by the curtain, it is possible to minimize the change in the internal temperature due to the opening of the door.

In addition, the present invention, when the door is closed after the door open, the high temperature inevitably rises than before the opening, in which case the cold air shower by the air curtain is executed within the range that the cooling fan is not operating immediately after the door is closed. By doing so, the internal temperature can be quickly reached to the previous temperature value within a very fast time, thereby increasing the preservation of the refrigerated food.

In particular, the present invention is to determine whether the door is open or closed, and when switching the refrigerating compartment cooling and air curtain function, air curtain for the purpose of maintaining a high temperature inside temperature to be executed for a predetermined time from the door closing time rather than cold air discharge output when the door is opened. By lowering the output during operation, a unique effect of preventing excessive cooling of the refrigerating compartment in a refrigerator having an air curtain function is exhibited.

Claims (2)

In the high temperature and instant cooling device of the refrigerator using the air curtain system, On the upper surface of the refrigerating chamber, a cold air passage 27 having a cold air discharge portion 29 is provided along the front side of the door, and inside the cold air passage 27, the cold air generated from the cooler 17 is discharged above the cold air discharge portion ( 29, the air curtain fan 21 for transferring to the door, and the door on / off contact signal detected by the door switch 26 is applied to the microcomputer 20, the first of the microcomputer 20 The signal output from the output terminal O1 is connected to be applied to the input element 34 of the SSR 33 via the inverter 23, Refrigerant room overcooling prevention device, characterized in that by the output element 35 of the SSR (33) coupled to the input element 34 is connected to the commercial AC voltage supplied to the air curtain fan 21 is switched . According to claim 1, wherein the signal output from the first output terminal (O1) of the microcomputer 20 is a logic level is output when the door is opened, when the door is closed is output in the form of a pulse width modulated pulse string to control the flow angle Refrigeration chamber overcooling prevention device characterized in that for adjusting the air curtain cold air output by.