KR940006908B1 - Method of removing frost in evaporater - Google Patents

Abstract

sensing a temperature of the evaporator; checking whether a sensed temperature from a temperature sensor is much higher than the temperature of the evaporator; if so, driving a heater and a fan motor to defrost; if not, checking whether the sensed temperature from the temperature sensor is slightly higher than the temperature of the evaporator; if so, driving only the fan motor to defrost; displaying the driving steps; and checking whether frost is eliminated, thereby greatly improving cooling efficiency.

Description

How to remove air conditioner's evaporator

1 is a front view of the evaporator defrosting apparatus applied to the present invention.

2 is a control block diagram of an evaporator defrosting device applied to the present invention.

3 is a flowchart of an evaporator defrosting apparatus according to the present invention.

4 is a block diagram of a conventional air conditioner defroster.

* Explanation of symbols for main parts of the drawings

1: evaporator 2: temperature sensor

3: heater: Micom

B: key input part c: room temperature sensor

D: Display part E: Compressor drive part

Bar: Fan motor drive part: Evaporator temperature sensor

Ah: Heater drive part

The present invention relates to an evaporator defrosting method of an air conditioner, and in particular, an evaporator generated by an ambient temperature difference by mounting a temperature sensor and a heater to an evaporator of an air conditioner that is cooled by changing a room temperature to a low temperature using a refrigerant cycle. This method relates to a method of removing the evaporator defrost of an air conditioner that detects the frost from the temperature sensor and selects and drives the heater or fan motor according to the detected temperature of the evaporator to greatly improve the cooling efficiency. .

The air conditioner is operated by controlling the compressor and fan motor according to the room temperature detected as a room temperature sensor. This causes the heat exchange with the surroundings in the evaporator is not properly made to reduce the cooling efficiency.

Therefore, as a method for removing the frost generated in the evaporator, when the room temperature decreases, the room temperature sensor senses the room temperature, turns off the compressor and the fan motor, and the frost contained in the evaporator is caused by the relatively hot wind around the evaporator. When the frost melts slowly due to natural convection, the room temperature rises before the frost melts, and if the compressor and the fan motor are driven on and off, the frost is caught again before the frost melts. . Therefore, conventionally, in order to solve this problem, as shown in FIG. 4, a heater is installed on one side of the indoor exchanger of the air conditioner, and the heater and the blower are electrically connected to shorten the defrosting time.

That is, since the blower 8 blowing in the indoor heat exchanger 10 and the heater 9 arranged in the heat exchanger 10 start the defrosting operation and the relay 11 switches and is connected in series, the heater ( 9) the voltage applied to the blower 8 is lowered, and the amount of low air flow is lowered. Also, the heat exchanger 10 is heated by the energization of the heater 9, and the forced heat exchange is performed while the amount of low wind is generated. The heat absorbed from the room rises due to the heating by the heater 9 while the heat absorbing from the heat sink is increased.

Therefore, as the endothermic amount of the refrigeration cycle during defrosting increases, the amount of heat supplied to the outdoor side heat exchanger 5 increases, and the amount of heat supplied to the outdoor side heat exchanger 5 increases and the defrost time is shortened.

Therefore, in the conventional defrosting apparatus, the user selectively performs defrosting using the heat generation of the heater and the low airflow of the blower, which not only increases the inconvenience, but also causes a problem of failing to obtain a stepwise defrosting effect according to the temperature of the heat exchanger. will be.

An object of the present invention is to detect the frost on the evaporator generated by the temperature difference of the ambient temperature by the temperature sensor, and by selectively driving the heater and the fan motor according to the detected temperature to force defrosting, In order to achieve the above object, the present invention is equipped with a temperature sensor for detecting the frost and a heater for defrosting the air conditioner in the evaporator of the air conditioner, and the temperature of the evaporator from the temperature sensor. The evaporator temperature sensing step of detecting, the temperature comparison judgment step of comparing the temperature detected by the temperature sensor and the temperature of the evaporator, and the heater and the fan motor by driving the heater according to the temperature detected in the temperature comparison judgment step Heater to remove, fan motor driving step, fan motor driving step to remove the frost by driving only the fan motor, defrost completion After complete removal of sex determination step it is characterized in that one to the steady operation.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. 1 is a front view showing an evaporative defrosting method applied to the present invention, in which the low temperature low pressure refrigerant absorbs and vaporizes the surrounding heat by a refrigeration cycle and changes the room temperature to a low temperature. It is equipped with a temperature sensor (2) for sensing the temperature of the evaporator (1), and a heater (3) for removing the defrost of the evaporator (1) while driving in accordance with the temperature detected by the temperature sensor (2) have.

2 is a control block diagram of the evaporator defrosting method applied to the present invention, and compares the signal input from each part with a predetermined program to control each part, and A key input unit (B) for inputting a signal of a signal, a room temperature sensor unit (C) for sensing a room temperature, and the microcomputer which has processed a signal input from the key input unit (B), a room temperature sensor (C) The air conditioner is composed of a display unit (D) for displaying the control signal from (A), a compressor driver for driving the compressor on and off (e), and a fan motor driver (bar) for driving the fan motor on and off. The heater according to the control signal of the microcomputer (A) according to the temperature detected from the evaporator temperature sensor (G) and the evaporator temperature sensor (G) to detect the temperature of the evaporator in the micom (A) On and off That is the connection by the heater driving unit (a).

3 is a flow chart of the evaporator defrosting method of the air conditioner according to the present invention, the evaporator temperature detection step 100 for detecting the temperature of the evaporator from the temperature sensor 2, and the evaporator temperature detection step 100 Heater for removing frost by driving the heater, fan motor when the temperature detected in the evaporator temperature comparison determination step 200 and the evaporator temperature comparison determination step 200 is very high than the evaporator temperature Fan motor drive step 300 and the evaporator temperature comparison determination step 400 to determine whether the temperature detected in the evaporator temperature comparison determination step 200 is slightly higher than the temperature of the evaporator, and slightly higher in the step 400 Defrosting the fan motor driving step 500 for driving only the fan motor, the display step 600 for displaying the steps 200 and 300, and the defrosting from the temperature sensor 2 to determine whether defrosting is completed. Completion determination step 700 is made.

Referring to the effects of the present invention made as described above are as follows. First, when a predetermined key input signal corresponding to the operation of the air conditioner is input from the key input unit (b), the microcomputer (a) controls the key input signal and displays it on the display unit (d). By controlling the compressor driving unit (e) and the fan motor driving unit (bar) respectively by the temperature signal input from the) to cool the air while driving the compressor and the fan motor. In the evaporator 1, heat is exchanged with the surroundings, and frost is caused by a temperature difference around the evaporator 1 by on / off driving of the compressor and the fan motor. In this case, the microcomputer senses the evaporator temperature of FIG. Through the step 100, the evaporator temperature sensor unit of FIG. 2 detects the temperature of the evaporator 1 from the temperature sensor 2 mounted on the evaporator 1.

As described above, in the state where the temperature of the evaporator is sensed, the microcomputer (a) undergoes an evaporator temperature comparison step (200) comparing the temperature detected in the evaporator temperature detection step (l00) with the actual temperature of the evaporator, and the evaporator (l). When the sensing temperature of the evaporator (l) is very high than the actual temperature of the evaporator, the microcomputer (a) turns off the compressor and goes to the heater and fan motor driving step (300) and the heater driving part (e) of FIG. The fan motor driving part (a) is driven to defrost the frost on the evaporator 1 by heating the heater 3 and blowing the fan motor, and at this time, the detected temperature of the evaporator 1 in the evaporator temperature comparison determination step 200. Is slightly higher than the actual temperature of the evaporator, the microcomputer (a) go to the evaporator temperature comparison step (400) to determine whether a little frost is a little frost in the evaporator (1) fan motor driving step (500) Go to Turning off the compressors and drive only the fan motor driving section (F) thereby defrosting the frost in the evaporator (l) to the fan motor. At this time, if it is determined that the frost is not satisfactory in the evaporator temperature comparison step 400, the normal operation is continued, and when the heater and the fan motor are driven in the heater, the fan motor driving step 300 and the fan motor driving step 500. In the display step 600, the display unit (D) is driven to display the driving state, and the microcomputer (a) goes to the defrosting completion determination step (700) of the temperature detecting sensor of the evaporator temperature holding sensor part (g). Detecting the frost state of the evaporator (1) from (2), and if the frost is removed in the evaporator (1), the normal operation is performed, and if the frost is not removed, go to the evaporator temperature detection step (l00) and the evaporator (1). ) Until the frost is removed.

As described above, the present invention is equipped with a temperature sensor and a heater in the evaporator of the air conditioner to be fitted on the evaporator by the on-off operation of the compressor and the fan motor when the air conditioner is cooled indoors while heat exchange with the surroundings. Defrost is completely detected by the temperature sensor, and the heater or fan motor can be forced to be defrosted according to the sensed temperature state. Even before it is done, it can solve the problem of being frosted again, thereby providing an effect that can greatly improve the cooling efficiency.

Claims (1)

In the defrosting method of the air conditioning to automatically defrost the frost by a microcomputer by mounting a temperature sensor and a heater on a predetermined portion of the evaporator, the evaporator temperature detection step 100 for detecting the temperature of the evaporator from the temperature sensor When the evaporator temperature comparison determination step 200 compares the temperature detected by the evaporator temperature detection sensor 100 with the evaporator temperature and the temperature detected by the evaporator temperature comparison determination step 200 is very high than the evaporator temperature, the heater A heater, a fan motor driving step 300 for defrosting by driving a fan motor, an evaporator temperature comparison step 400 for determining whether the sensed temperature is slightly higher than the evaporator temperature, and the evaporator temperature comparison step 400 At a little higher, the fan motor driving step 500 for driving only the fan motor and defrosting, the display step 600 for displaying the steps 300 and 400, and the steps 300 and 4 00) The defrosting defrosting method of the air conditioner, characterized in that the defrosting completion step (7⑾) to determine whether the defrosting is completed from the temperature sensor (2) at the time of defrosting.