KR100487779B1 - A control method of air conditioner - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an air conditioner, and more particularly, to an operation control method of an air conditioner for controlling the compressor so that the operation frequency of the compressor is extended in multiple stages.

According to the present invention, according to the change in the indoor piping temperature of the indoor heat exchanger, the operation frequency of the compressor is varied in several stages, and as a result, the operation time of the compressor is extended until the indoor piping temperature reaches 0 degrees. . Therefore, the driving time of the air conditioner is extended, resulting in higher operating efficiency. In addition, the user can quickly reach a comfortable room temperature.

Description

A control method of air conditioner

The present invention relates to an air conditioner, and more particularly, to an operation control method of an air conditioner as the compressor is driven, thereby extending the driving time of the air conditioner by controlling the operation frequency in multiple stages.

In general, an air conditioner drives a heating cycle and a cooling cycle according to a user's request, creates a warm room in a cold winter by operation of the heating cycle, and cools a room in a hot summer by the operation of the cooling cycle. In addition, the air conditioner controls the humidity in the room, and controls the air in the room to a comfortable clean state.

The circulation cycle of the air conditioner configured as described above consists of a heating cycle when the indoor heat exchanger functions as a condenser, and constitutes a cooling cycle when the indoor heat exchanger functions as an evaporator.

1 is a schematic diagram of a cooling / heating cycle of a general air conditioner.

In the heating operation by the heating cycle, the compressor 3 first compresses the refrigerant. The compressed refrigerant is delivered to the indoor heat exchanger (1). At this time, the refrigerant flowing in the indoor heat exchanger 1 discharges heat to the indoor side, and warm wind is discharged to the indoor side. And the refrigerant passing through the indoor heat exchanger (1) is sucked into the outdoor heat exchanger (2). At this time, the outdoor heat exchanger (2) performs the evaporation operation to discharge the cold wind to the outside.

On the other hand, in the cooling operation by a cooling cycle, the compressor 3 first compresses a refrigerant. The compressed refrigerant is delivered to the outdoor heat exchanger (2). The outdoor heat exchanger 2 condenses the delivered refrigerant and delivers the condensed refrigerant to the indoor heat exchanger 1. Therefore, as the indoor heat exchanger 1 is driven, the refrigerant absorbs heat of indoor air, and cold wind is discharged to the indoor side.

In the heating operation by the above-described heating cycle, the refrigerant flowing in the indoor heat exchanger 1 is at a high temperature, so that the piping of the indoor heat exchanger 1 does not freeze. However, during the cooling operation by the cooling cycle, the refrigerant flowing in the indoor heat exchanger 1 is at a low temperature, and the piping of the indoor heat exchanger 1 is cooled when driven for a long time. Therefore, in the process of discharging the air sucked in the room through the cooled pipe to the room, when the pipe temperature reaches 0 ° C. or lower and becomes very low, indoor heat exchange due to a large temperature difference between the air introduced from the room and the cooled pipe. Freezing occurs in machine 1. In this way, if freezing occurs in the indoor heat exchanger (1), heat exchange is not normally performed, resulting in low efficiency.

Therefore, in order to prevent this, when the compressor 3 is driven and the indoor piping temperature drops to 0 ° C., the driving of the compressor 3 is stopped for a predetermined time to increase the indoor piping temperature. The driving control of the compressor 3 prevents a large difference between the air introduced from the room and the cooled pipe temperature, thereby preventing freezing from occurring in the indoor heat exchanger 1.

Figure 2 is a state diagram of the indoor piping temperature measured as the air conditioner according to the prior art is driven.

According to an operation signal input by the user, the controller controls the compressor to be driven at a preset operating frequency of the compressor. Due to the operation of the compressor, the compressed refrigerant is introduced into the pipe. Accordingly, the indoor piping temperature is lowered as shown in FIG. 2 in proportion to the operation time of the compressor.

Looking at the drive control of the compressor according to the operation of the conventional air conditioner in more detail as follows.

In order to operate the air conditioner in the cooling cycle, the compressor is driven at the operating frequency of the compressor preset in the control unit so that the compressed refrigerant is introduced into the indoor pipe of the indoor heat exchanger. At the same time, the indoor fan and the outdoor fan are controlled to be driven by the air volume set in the controller. At this time, the indoor pipe is configured with a temperature sensing unit to measure the temperature of the indoor pipe. Then, the measured pipe temperature is transmitted to the controller. Accordingly, the controller detects the transmitted temperature signal to determine the temperature of the indoor pipe.

Therefore, when the compressor is driven for T hours, the pipe temperature detected by the temperature sensing unit gradually decreases from 'C' ° C to 'B' ° C, 'A' ° C and lowers below '0' ° C, and receives the temperature signal. The controller controls the indoor fan to operate with weaker wind than the set air volume, and simultaneously stops driving the compressor and the outdoor fan. Accordingly, the indoor piping temperature is prevented from being lowered any more, thereby preventing freezing of the indoor piping.

As shown in the figure, when the t time elapses and the pipe temperature rises above C ° C., the temperature is sensed by the temperature sensing unit and the temperature signal is transmitted to the controller. The controller determines the temperature signal and controls the compressor to operate at the preset operating frequency again. At the same time, the control unit controls the indoor fan and the outdoor fan to be driven at a predetermined air volume. Accordingly, cool wind is discharged to the indoor side again.

However, as the pipe temperature is constantly driven at the same operating frequency until the pipe temperature reaches 0 ° C, the following problems occur.

Conventionally, the compressor was constantly driven at a relatively high operating frequency, and the same operation frequency was operated until the indoor piping temperature reached 0 ° C. Accordingly, due to the relatively high operating frequency, the pipe temperature reaches 0 ° C within a short time, and as a result, the on / off driving time of the compressor becomes frequent, resulting in a decrease in the operating efficiency of the compressor.

In addition, the compressor was driven, the refrigerant was compressed, the refrigerant was supplied to the indoor piping, the indoor piping temperature reached 0 ° C or less, and the cycle until the driving of the compressor was stopped was short. This means that the time for exhausting the compressed air is shortened, resulting in lower comfort of the indoor space.

Accordingly, an object of the present invention is to provide an operation control method of an air conditioner that extends the compressor driving time by varying the operating frequency of the compressor according to the indoor piping temperature.

The operation control method of the air conditioner according to the present invention for achieving the above object comprises a first step of supplying a refrigerant to the indoor piping by driving the compressor at the maximum operating frequency in accordance with the operation signal input by the user; A second step of controlling the operation frequency of the compressor to be varied in multiple stages according to the temperature detection value of the indoor pipe after the first step control; A third step of stopping the driving of the compressor when the temperature of the indoor pipe reaches the minimum temperature by the driving of the second step; The first, second, and third steps may be repeated until the stop signal of the user is input. In the present invention, the first step includes operating frequency of the compressor when the temperature range of the indoor pipe falls. It is characterized by controlling so as to be late.

Looking at the drive control of the compressor controlled according to the operation of the air conditioner according to the present invention as follows.

3 is a control block diagram for preventing freezing generated in the indoor heat exchanger as the air conditioner according to the present invention is driven.

As shown in the figure, a power supply unit 40 for supplying power to the product, a key input unit 10 for inputting a control signal, a temperature sensing unit 20 provided in the indoor pipe and sensing the temperature of the indoor pipe; , A compressor (70) for compressing a refrigerant, an outdoor fan (60) for discharging heat generated by the driving of the outdoor unit, an indoor fan (50) for driving heat-exchanged air to the room, and a user input And a control unit 30 for controlling the air conditioner to be driven according to a control signal input by the user.

Power is supplied to the air conditioner main body through the power supply unit 40, and when the user inputs an operation control signal through the key input unit 10 mounted to the indoor unit, the operation control signal is transmitted to the control unit 30. The controller 30 drives the air conditioner according to the operation control signal.

In order to operate the air conditioner, the compressor 70 is first driven, and at the same time, the indoor fan 50 and the outdoor fan 60 are driven to control the heat-exchanged air to be effectively discharged into the room. At this time, the control unit 30 controls the temperature sensing unit 20 provided in the indoor heat exchanger to sense the temperature of the indoor piping, so that the drive of the compressor 70 is variable in multiple stages according to the temperature of the indoor piping. As described above, the air conditioner is driven and displayed on the display unit 80 so as to check the operation control signal input by the user.

With the above control configuration, the driving control process of the air conditioner to be described below is as follows.

Figure 4 is a state diagram of the indoor piping temperature measured as the air conditioner according to the present invention is driven, Figure 5 is a flow chart of the operation of the operation of the air conditioner according to the present invention is controlled in accordance with the indoor piping temperature.

As shown in the figure, when the user inputs the driving control signal through the key input unit 10 (step 100), the signal is transmitted to the controller 30. The control unit 30 controls the compressor 70 to be driven according to the driving signal and controls the indoor fan 50 and the outdoor fan 60 to be driven by the set wind (step 110). In this case, the control unit 30 is set to the operating frequency for driving the compressor 70 and the air flow rate of the indoor fan 50 and the outdoor fan 60 and the like.

As the compressor 70 is driven as described above, the compressed refrigerant is introduced into the indoor pipe of the heat exchanger. At this time, the compressor 70 is driven at the maximum operating frequency. After a predetermined time has elapsed while the compressor 70 flows into the pipe of the indoor heat exchanger, the pipe temperature of the indoor heat exchanger drops from the 'C' ° C to reach 'B' ° C. Then, the temperature detecting unit 20 detects the pipe temperature of the indoor heat exchanger (step 120), and transmits the temperature signal to the control unit 30.

Accordingly, when the controller 30 determines that the pipe temperature of the indoor heat exchanger detected by the temperature sensing unit 20 has reached 'B' ° C. (step 130), the operating frequency of the compressor 70 is varied. To control. That is, the controller 30 controls the compressor 70 driven at the maximum operating frequency to be driven at the second operating frequency smaller than the maximum operating frequency (step 140).

And as described above is driven for a predetermined time at a second operating frequency to supply the refrigerant, and when the pipe temperature of the indoor heat exchanger is further lowered to reach 'A' ℃ due to the supplied refrigerant, the temperature sensing unit 20 is Detect. Then, the detected temperature signal is transmitted to the controller 30. Accordingly, the controller 30 controls to be driven at a third operating frequency having a value smaller than the second operating frequency of the current compressor 70 (operation 160).

Due to the control of the controller 30, the compressor 70 is driven at the third operating frequency, thereby reducing the speed at which the refrigerant is supplied to the pipe of the indoor heat exchanger. Therefore, the time until the pipe temperature of the indoor heat exchanger decreases to reach '0' ° C. is longer by 'α' time than the prior art, and consequently, the driving time of the compressor 70 is extended. This means that the cool air is discharged to the indoor side longer.

After the indoor piping temperature of the indoor heat exchanger reaches '0' ° C. (step 170), the compressor 70 stops driving for t hours (step 180). At this time, the air volume of the indoor fan 50 and the outdoor fan 60 which are driven in the preset wind direction set in the controller 30 is changed. That is, the indoor fan 50 is driven by a weak wind smaller than the set air volume to discharge wind into the room, and the outdoor fan 60 stops driving.

When the indoor piping temperature of the indoor heat exchanger falls below 0 ° C, the reason for stopping the driving of the compressor 70 is that the compressor 70 continues to be driven to supply refrigerant to the indoor piping, thereby increasing the temperature of the piping. This is because, in a very low state, when it meets the sucked indoor air higher than the pipe temperature, freezing occurs in the indoor pipe of the indoor heat exchanger. Therefore, in order to prevent this, when the pipe temperature of the indoor heat exchanger falls below '0' ° C., the driving of the compressor 70 is stopped to prevent the coolant from being supplied to the indoor pipe.

As the driving of the compressor 70 is stopped as described above, the flow chart of the refrigerant supplied to the indoor heat exchanger is stopped, and the temperature of the indoor pipe of the indoor heat exchanger increases in proportion to time. Therefore, if the 't' time elapses after the operation of the compressor 70 is stopped, and the indoor pipe temperature of the indoor heat exchanger rises above 'C' ° C. (step 190), the compressor 70 again returns to the maximum operating frequency. Driven by the cooling cycle. As the cooling cycle progresses, the refrigerant is supplied to the indoor piping of the indoor heat exchanger, so that the temperature of the indoor piping is lowered again. Accordingly, heat is exchanged through the indoor pipe, and cool air is discharged to the room. If the user does not input the driving stop signal, step 110 to step 190 are repeated. According to an embodiment of the present invention, C ° is set to 7 ° C, B ° to 6 ° C, and A ° to 3 ° C. To control the operation of the compressor.

In an embodiment of the present invention, the temperature sensing unit senses temperature using a thermistor. However, this is only one embodiment, and any other device capable of sensing temperature is possible in nature.

As described above, according to the present invention, it is a basic technical idea to control the operation frequency of the compressor to vary according to the indoor piping temperature so that the driving time of the air conditioner is relatively long.

The rights of the present invention are not limited to the embodiments described above, but are defined by the claims, and those skilled in the art can make various modifications and adaptations within the scope of the claims. It is self-evident.

Therefore, the operation control method of the air conditioner according to the present invention can expect the following effects.

By variablely controlling the operating frequency of the compressor until the temperature of the indoor piping reaches '0' ℃, it is possible to extend the operation time of the compressor relatively. Due to the longer driving time of the compressor, the time for supplying the refrigerant to the indoor heat exchanger becomes longer, and as a result, cool wind can be discharged to the indoor side for a longer time.

As a result, the operation efficiency of the compressor is increased, and the air cooled by heat exchange is discharged for a longer period of time, thereby providing a comfortable indoor environment to the user, and the user using the product according to the present invention can maximize the satisfaction with the product. Can be.

1 is a simplified diagram of a cooling / heating cycle of a typical air conditioner.

Figure 2 is a state diagram of the indoor piping temperature measured as the air conditioner according to the prior art is driven.

3 is a control configuration for preventing freezing generated in the indoor smoke exchanger as the air conditioner according to the present invention is driven.

Figure 4 is a state diagram of the indoor piping temperature measured as the air conditioner according to the invention is driven.

5 is an operation control flow chart in which the driving of the air conditioner according to the present invention is controlled according to the indoor piping temperature.

      Explanation of symbols on the main parts of the drawings

10: key input unit 20: temperature detection unit

30: control unit 40: power supply unit

50: indoor fan 60: outdoor fan

70 compressor 80 display unit

Claims (2)

A first step of driving a compressor at a maximum operating frequency according to an operation signal input by a user and supplying refrigerant to indoor piping; A second step of controlling the operating frequency of the compressor according to the temperature range of the plurality of indoor pipes after the first step control; A third step of stopping the driving of the compressor when the temperature of the indoor pipe reaches the minimum temperature by the driving of the second step; The first, second, and third steps are repeated until the stop signal of the user is input. The method of claim 1, The first step is, And controlling the operation frequency of the compressor to be slowed down when the temperature range of the indoor pipe falls.