KR19980026842U - Cooling fan of refrigerator machine room - Google Patents

Abstract

The present invention relates to a cooling fan of a refrigerator machine room, wherein a cooling fan that is operated to cool the high temperature inside the machine room generated from the compressor and the condenser while the refrigerant is repeatedly circulated along the freezing cycle, regardless of the temperature inside the machine room. In order to solve the conventional problem of not only efficient cooling by being linked to the operation at the same time, but also operating the cooling fan at the same time as the compressor is operated even though the temperature of the machine room is not very high. Is detected only when the temperature is above a certain temperature, so that the cooling fan is driven separately from the operation of the compressor, and when the temperature is lower than that, it is turned off to reduce unnecessary power consumption. One end of in suction pipe To attach the temperature sensor to the characteristic.

Description

Cooling fan of refrigerator machine room

The present invention relates to a cooling fan of a refrigerator machine room, and more particularly, a cooling fan of a refrigerator machine room to turn on / off the operation of the cooling fan only when the temperature inside the machine room corresponds to an appropriate temperature by using a temperature sensor. It is about.

Typically, the machine room of the refrigerator is a condenser that liquefies the refrigerant gas by releasing heat while changing the refrigerant gas circulating along the refrigeration cycle from the low temperature low pressure state to the high temperature high pressure through the compressor 20 ( 24) Follow a series of cycles to cool the refrigerator due to the latent heat of evaporation as it evaporates through the evaporator after passing through the capillary tube, a means of lowering the pressure to prevent the liquefied refrigerant from entering the evaporator at high temperature and high pressure. There are components that are important for repeated cycling.

When the refrigerant is circulated along the cooling cycle as described above, the refrigerant gas vaporized in the evaporator and causing a phase change to a low-temperature low-pressure gas state flows into the compressor 20 through the suction pipe 22 and changes to high temperature and high pressure. In the compressor 20, a high heat of about 90 to 100 ° C. is generated, and due to the high heat radiated from the condenser 24, the inside of the machine room 10 located at the lower part of the refrigerator generates high heat. In order to prevent this, the cooling fan 12 is installed at one side of the inside of the machine room 10 to cool the inside of the machine room 10 while cooling the compressor 20 and the condenser 22.

However, since the cooling fan 12 is operated in conjunction with the driving of the compressor 20, the cooling fan 12 is softened by being driven by the compressor 20 for cooling, even though the temperature inside the machine room 10 is not so high. (12) was operated, and the disadvantage that unnecessary power was consumed was highlighted.

The present invention has been made to solve the above problems in consideration of the above-mentioned problems, it is possible to reduce unnecessary power consumption by driving the cooling fan separately from the compressor only when the temperature around the compressor installed inside the machine room of the refrigerator is above a certain temperature. To make it a technical task.

1 is a front view showing a machine room structure of a conventional refrigerator.

Figure 2 is a front view showing the machine room structure of the refrigerator with a temperature sensor according to the present invention.

Figure 3 is a cooling fan drive circuit diagram by a temperature sensor according to the present invention.

Figure 4 is a flow chart of the cooling fan drive of the refrigerator machine room according to the present invention.

Explanation of symbols on the main parts of the drawings

10 machine room 12 cooling fan

20 Compressor 22 Suction Pipe

40: temperature sensor 50: micom

60: drive IC70: switch

In order to achieve the above technical problem, the present invention is characterized by attaching a temperature sensor connected in circuit with a microcomputer to a suction pipe adjacent to the compressor so that a cooling fan can be driven separately from the compressor.

Hereinafter, with reference to the accompanying drawings a preferred embodiment according to the present invention will be described in more detail.

Figure 2 shows the shape of the temperature sensor 40 according to the present invention is attached to one end of the suction pipe 22, Figure 3 is a temperature sensor 40 according to the present invention the microcomputer 50 4 is a flowchart illustrating a control process of the cooling fan 12 by the temperature sensor 40 according to the present invention.

2 to 4, the temperature sensor 40 is attached to one end of the suction pipe 22 flowing into the compressor 20 inside the refrigerator machine room 10.

A dummyster or a resistance thermometer is widely used as the temperature sensor 40. Here, AN6701, which is a monolithic IC temperature sensor, is used as a type of IC temperature sensor.

The AN6701 uses the temperature dependence of the current and voltage characteristics in the semiconductor pn junction, and is excellent in the linearity of the output, and can integrate a sensor driving circuit, a signal processing circuit, etc. in addition to the temperature sensing section, and is enclosed in a small package. Therefore, it is very good to use.

In addition, it has a use temperature range of -10 to 80 ° C., and thus has high sensitivity, excellent linearity, high precision, and fast thermal response, and is widely used.

The circuit connection relationship between the microcomputer 50 and the temperature sensor 40, for example, the AN6701, is as follows.

After the two grounded capacitors C1 and C2 serving as parameters are connected to the input terminal a of the microcomputer 50 and only two grounded resistors R1 and R2 are connected in series, the temperature sensing sensor ( 40) is connected.

In addition, the output terminal (b) of the microcomputer 50 is connected to the drive IC (60) connected in series with the resistor (R3), and a small contactless switch 70 that can be durable and high-speed switching The cooling fan 12 driving circuit has an equivalent to the circuit formed between the output terminal b and the driving IC 60 and is connected to the driving IC 60 so as to be switched by an inductive action.

The present invention having such a configuration adjusts parameter values such as capacitors C1 (C2) and resistors R1 (R2) connected to the AN6701 sensor 40, and the temperature that the sensor 40 can detect is 30 to 80 degrees. When the temperature of the refrigerator machine room 10 sensed within this range is 70 ° C. or more, the microcomputer 50 sends a control signal through the output terminal b. The control pulse passed through R3 is controlled by the driver IC 60 to control the current and voltage, thereby turning on the solid state switch 70 of the cooling fan 12 driving circuit including the equivalent circuit. ) Is driven.

In addition, the sensing area AN6701 sensor 40 senses the temperature inside the refrigerator machine room 10 and continuously transmits a pulse to the microcomputer 50, the microcomputer 50 determines the received pulse as described above. If the condition is satisfied, the cooling fan 12 is continuously driven.

When the temperature sensed in the machine room 10 is 70 ° C. or less, the microcomputer 50 outputs a control signal for turning off the driving of the cooling fan 12 through the output terminal b. By the control signal, the drive IC 60 operates to turn off the solid state switch 70 of the cooling fan 12 drive circuit by appropriately adjusting the current value and the voltage value.

Here, the AN6701 sensor 40 senses the temperature inside the machine room 10 and continuously transmits the control signal to the microcomputer 50 even after the cooling action of the cooling fan 12 occurs or after the OFF operation occurs.

As such, the present invention, which allows the driving of the cooling fan 12 installed in the machine room 10 by the temperature sensor 40 to be appropriately adjusted, is within the scope of the gist of those skilled in the art. It will be readily appreciated that various modifications are possible in.

As described above, the present invention designed to control the operation of the cooling fan by a temperature sensor attached to one end of the suction pipe located in the machine room of the refrigerator, regardless of the temperature inside the machine room and the drive of the compressor. In addition, by improving the conventional case that caused unnecessary power consumption of the associated cooling fan by detecting the temperature inside the machine room separately from the operation of the compressor, if the temperature rises above a certain level, the cooling fan is driven to cool the inside of the machine room, If it is less than this, it is configured to operate to automatically turn off the drive of the cooling fan has the effect of preventing excessive power consumption.

The present invention is intended to prevent excessive consumption of power by preventing the cooling fan used to cool the inside of the machine room of the refrigerator.

Claims (2)

In the cooling fan 12 configured to interlock with the compressor 20 of the refrigerator machine room 10 including the suction pipe 22 and the condenser 24, The refrigerator characterized in that the temperature sensor 40 is attached to a part of the suction pipe 22 so that the cooling fan 12 can be driven by sensing the temperature inside the machine room 10 separately from the compressor 20. Cooling fan in the machine room. The cooling fan of claim 1, wherein the temperature sensor (40) is an AN6701 sensor (40).