KR102160036B1 - Air conditioner system and method for controlling therefor - Google Patents

Abstract

An air conditioner system and a control method thereof, comprising: when a request for cooling operation is generated, measuring an indoor air temperature immediately before starting a compressor and an indoor heat exchanger temperature immediately before starting a compressor; Measuring a first current indoor heat exchanger temperature when a predetermined first time elapses after starting the compressor; Determining whether the valve is first clogged based on the indoor air temperature immediately before starting the compressor, the indoor heat exchanger temperature immediately before starting the compressor, and the first current indoor heat exchanger temperature; And stopping the drive of the compressor when it is determined that the valve is first clogged.

Description

Air conditioner system and its control method {AIR CONDITIONER SYSTEM AND METHOD FOR CONTROLLING THEREFOR}

It relates to an air conditioner system and a control method thereof.

A general air conditioner is a device that is used for indoor cooling or heating purposes. It circulates refrigerant between indoor and outdoor units, absorbing surrounding heat when liquid refrigerant vaporizes, and releasing the heat when liquefied. Cooling or heating can be performed by In a typical air conditioner, it is common to install one indoor unit in one outdoor unit.

On the other hand, the compressor applied to the air conditioner is a component corresponding to the core part of the air conditioner, and when a failure occurs, the product cannot be operated, and there is a risk of an explosion accident due to an increase in internal pressure.

An aspect of an air conditioner system and a control method thereof is to provide an air conditioner system and a control method thereof for diagnosing a clogging of a valve to smoothly flow a refrigerant to protect a compressor.

An air conditioner control method according to an aspect of the disclosed invention includes: when a request for cooling operation is generated, measuring an indoor air temperature just before starting a compressor and an indoor heat exchanger temperature just before starting the compressor; Measuring a first current indoor heat exchanger temperature when a predetermined first time elapses after starting the compressor; Determining whether a valve is first clogged based on an indoor air temperature immediately before starting the compressor, an indoor heat exchanger temperature immediately before starting the compressor, and the first current indoor heat exchanger temperature; And stopping the drive of the compressor when it is determined that the valve is first clogged.

In addition, the step of determining whether the valve is first clogged includes comparing the difference between the indoor heat exchanger temperature immediately before starting the compressor and the first current indoor heat exchanger temperature with the first temperature reference value, and comparing the indoor air temperature immediately before starting the compressor and the first current indoor heat exchanger temperature. Comparing the difference in temperature of the heat exchanger with a second temperature reference value, and as a result of the comparison, if each difference is less than or equal to the first temperature reference value and the second temperature reference value, it may be a step of determining as a primary blockage of the valve.

In addition, the difference between the indoor heat exchanger temperature immediately before starting the compressor and the first current indoor heat exchanger temperature is less than or equal to the first reference temperature value, and the difference between the indoor air temperature immediately before starting the compressor and the first current indoor heat exchanger temperature is less than the second temperature reference value. In the case of or equal to, after the step of determining whether the valve is first clogged, before the step of stopping the drive of the compressor, opening the valve according to a preset value; Returning the valve to a state before opening according to a preset value when a predetermined second time elapses after opening the valve; During the first test period, the difference between the indoor heat exchanger temperature immediately before starting the compressor and the first current indoor heat exchanger temperature, and the difference between the indoor air temperature immediately before starting the compressor and the first current indoor heat exchanger temperature is the first temperature reference value and the second temperature, respectively. Comparing with a reference value; And as a result of the comparison, the difference between the indoor heat exchanger temperature immediately before starting the compressor and the first current indoor heat exchanger temperature is less than or equal to the first reference temperature value, and the difference between the indoor air temperature immediately before starting the compressor and the first current indoor heat exchanger temperature is a second temperature. If it is less than or equal to the reference value, the step of final determining as the first blockage of the valve; may further include.

Further, after the step of stopping the driving of the compressor, measuring the indoor air temperature immediately before restarting the compressor and the indoor heat exchanger temperature immediately before restarting the compressor; Restarting the compressor; Measuring a second current indoor heat exchanger temperature when a predetermined third time elapses after restarting the compressor; The difference between the indoor heat exchanger temperature immediately before restarting the compressor and the second current indoor heat exchanger temperature and the difference between the indoor air temperature immediately before restarting the compressor and the second current indoor heat exchanger temperature are compared with the first temperature reference value and the second temperature reference value. Determining whether the vehicle is blocked; And stopping the operation of the compressor when it is determined that the valve is blocked secondarily.

In addition, after the step of determining whether the valve is secondarily clogged, before the step of stopping the operation of the compressor, opening the valve according to a preset value; During the second test period, the difference between the indoor heat exchanger temperature immediately before restarting the compressor and the second current indoor heat exchanger temperature, and the difference between the indoor air temperature immediately before restarting the compressor and the second current indoor heat exchanger temperature are the first temperature reference value and the second temperature, respectively. Comparing with a reference value; As a result of the comparison, the difference between the indoor heat exchanger temperature immediately before restarting the compressor and the second current indoor heat exchanger temperature is less than or equal to the first reference temperature value, and the difference between the indoor air temperature immediately before restarting the compressor and the second current indoor heat exchanger temperature is the second temperature reference value. If it is less than or equal to, the step of finally determining as the secondary clogging of the valve; may further include.

An air conditioning system according to an aspect of the disclosed invention includes: a compressor; An indoor air temperature sensor measuring the indoor air temperature; An indoor heat exchanger temperature sensor measuring the temperature of the indoor heat exchanger; A valve that controls the flow of fluid; And a control unit for controlling the operation of the compressor by comparing the indoor air temperature measured by the indoor air temperature sensor and the indoor heat exchanger temperature measured by the indoor heat exchanger temperature sensor with a reference value for determining valve clogging. May include;

The control unit includes: a valve clogging check unit configured to determine whether a valve is clogged by comparing the indoor air temperature and the indoor heat exchanger temperature measured by the indoor air temperature sensor and the indoor heat exchanger temperature sensor with a valve clogging determination reference value; A valve control unit controlling an opening degree of the valve according to a determination result of the valve clogging check unit; And a compressor control unit that drives the compressor or stops driving the compressor according to a determination result of the valve clogging check unit.

In addition, the valve clogging check unit compares the difference between the indoor heat exchanger temperature just before starting the compressor and the current indoor heat exchanger temperature after starting the compressor with the first temperature reference value, and the difference between the indoor air temperature immediately before starting the compressor and the current indoor heat exchanger temperature after starting the compressor. Compared with the second temperature reference value, as a result of the comparison, if each difference is less than or equal to the first temperature reference value and the second temperature reference value, it may be determined that the valve is clogged.

According to an aspect of the air conditioner system and its control method, the clogging of the valve is estimated through measurement and analysis of the indoor air temperature and the indoor heat exchanger temperature, and the valve is tested according to the estimated result to determine the clogging of the compressor. Since the operation is controlled, it is possible to expect an effect that failure due to continuous operation of the compressor in an abnormal refrigerant flow state can be prevented in advance.

1 is a diagram showing the structure of an air conditioner.
2 is a diagram showing the configuration of an air conditioner system.
3 is a diagram showing in detail the configuration of the control unit of FIG. 2.
4 is a flowchart illustrating a method of controlling an air conditioner.
5 is a flowchart illustrating in detail a procedure for performing a first test of FIG. 4.

Objects, specific advantages and novel features of the present invention will become more apparent from the following detailed description and preferred embodiments in conjunction with the accompanying drawings. In adding reference numerals to elements of each drawing in the present specification, it should be noted that, even though they are indicated on different drawings, only the same elements are to have the same number as possible. In addition, in describing the present invention, when it is determined that a detailed description of related known technologies may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted. In this specification, terms such as first and second are used to distinguish one component from other components, and the component is not limited by the terms.

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

1 is a diagram showing the structure of an air conditioner.

As shown in FIG. 1, the air conditioning apparatus 1 may include an outdoor unit 10 and an indoor unit 20. In this case, the outdoor unit 10 and the indoor unit 20 may be connected to transmit and receive power and communication signals between each other.

First, the outdoor unit 10 includes a compressor 11 that compresses a refrigerant into a gaseous state of high temperature and high pressure, a four-way valve 12 that controls the flow direction of the high temperature and high pressure gas refrigerant compressed by the compressor 11, and the compressor 11 An outdoor fan that forcibly blows outdoor air by an outdoor fan motor 15 so that heat exchange is performed in the outdoor heat exchanger 13 and the outdoor heat exchanger 13 that receives the compressed high-temperature, high-pressure gas refrigerant to exchange heat with outdoor air ( 14), it may include an electronic expansion valve 17 for reducing and expanding the heat exchanged refrigerant while controlling the flow rate of the refrigerant. At this time, the electronic expansion valve (EEV) 17 may control the degree of superheating and the degree of subcooling of the refrigerant according to its opening degree. In addition, an accumulator 16 may be installed on the suction side of the compressor 11 to convert the refrigerant flowing into the compressor 11 into a completely gaseous gas.

In addition, the indoor unit 20 is an indoor heat exchanger 21 that receives refrigerant and exchanges heat with indoor air, and an indoor fan motor 23 forcibly blowing indoor air so that heat exchange occurs in the indoor heat exchanger 21. A fan 22 may be included. In addition, among the pipes connected to the indoor heat exchanger 21, the inlet pipe where the refrigerant is sucked during cooling operation has an electronic expansion valve 24 for expanding the refrigerant, and an indoor heat exchanger that detects the temperature of the inlet pipe of the indoor heat exchanger 21. The temperature sensor 26 may be installed. In addition, among the pipes connected to the indoor heat exchanger 21, a refrigerant control valve 25 may be installed in an outlet pipe through which refrigerant is discharged during cooling operation.

FIG. 2 is a diagram illustrating a configuration of an air conditioner system, and FIG. 3 is a diagram illustrating a configuration of a control unit of FIG. 2 in detail.

As shown in FIG. 2, the air conditioning system 100 may include an indoor air temperature sensor 110, an indoor heat exchanger temperature sensor 120, a compressor 130, a valve 140, and a control unit 150. . In this case, the indoor air temperature sensor 110, the indoor heat exchanger temperature sensor 120, and the control unit 150 may be provided on the indoor unit side.

In more detail, the indoor air temperature sensor 110 may measure the indoor air temperature.

The indoor heat exchanger temperature sensor 120 may measure the temperature of the indoor heat exchanger. In this case, measuring the temperature of the indoor heat exchanger may mean measuring the temperature of the indoor heat exchanger and surrounding components related to the indoor heat exchanger.

The compressor 130 is configured to compress or pressurize a refrigerant. At this time, the compressor 130 may be driven by the engine through a poly V-belt or multiple V belts, and the refrigerant flowing from the evaporator is sucked into the compressor in a low-temperature, low-pressure gaseous state, and then the refrigerant is compressed to achieve high temperature and high pressure. It can be transferred to the condenser in the gaseous state.

The valve 140 is a configuration for controlling the flow of a fluid, and may mean a movable mechanism capable of opening and closing a passage in order to allow a fluid to pass through, block, or control.

In this case, the valve 140 may be an electronic expansion valve provided on the indoor unit side, and is not limited thereto, and may be an ON or OFF valve applied to an air conditioner. For example, a solenoid valve type valve applied to an air conditioner system is also possible. The electronic expansion valve may depressurize the medium temperature and high pressure liquid refrigerant discharged from the outdoor unit (10 in FIG. 1) to the low temperature and low pressure liquid refrigerant. In addition, the solenoid valve can be applied to stop the liquefied refrigerant from flowing out of the cooler or the radiator by the evaporator when the temperature is lowered.

The control unit 150 compares the indoor air temperature measured by the indoor air temperature sensor 110 and the indoor heat exchanger temperature measured by the indoor heat exchanger temperature sensor 120 with a reference value for determining the clogging of the valve, and It is possible to control the operation of the compressor 130 by determining. In this case, the reference value for determining valve clogging will be defined to mean a temperature reference value for determining whether a valve provided in the air conditioner system 100 is in a normal state.

As shown in FIG. 3, the control unit 150 may include a valve clogging check unit 151, a valve control unit 153, and a compressor control unit 155.

The valve clogging check unit 151 compares the indoor air temperature and the indoor heat exchanger temperature measured by the indoor air temperature sensor 110 and the indoor heat exchanger temperature sensor 120 with a reference value for determining the clogging of the valve, and You can judge whether or not.

In addition, the valve clogging check unit 151 compares the difference between the indoor heat exchanger temperature immediately before starting the compressor and the current indoor heat exchanger temperature after starting the compressor with the first temperature reference value, and compares the indoor air temperature immediately before starting the compressor and the current indoor heat exchanger temperature after starting the compressor. The difference in degrees is compared with the second temperature reference value, and as a result of comparison, if each difference is less than or equal to the first temperature reference value and the second temperature reference value, it may be determined that the valve is clogged. That is, the valve clogging check unit 151 compares the indoor air temperature and the indoor heat exchanger temperature before starting the compressor 130 and the indoor heat exchanger temperature after starting the compressor 130, and if the difference between them does not differ by more than the reference temperature, the valve Is to judge that is blocked.

The valve control unit 153 may control the degree of opening of the valve 140 according to the determination result of the valve clogging check unit 151. For example, when it is estimated that the valve is clogged, the valve control unit 153 performs several tests while opening and driving the valve 140 to the maximum and finally determines the clogging of the valve.

The compressor control unit 155 may drive the compressor 130 or may stop driving the compressor 130 according to a determination result of the valve clogging check unit 151.

4 is a flowchart illustrating a method of controlling an air conditioner, and FIG. 5 is a flowchart illustrating in detail a procedure for performing a first test of FIG. 4.

First, as shown in FIG. 4, when a request for cooling operation is generated (S101), the air conditioning system 100 can measure the indoor air temperature Tr1 just before starting the compressor and the indoor heat exchanger temperature Te1 just before starting the compressor. Yes (S103).

Next, the air conditioner system 100 may measure the first current indoor heat exchanger temperature Te2 when a preset first time elapses after starting the compressor (S105, S107). In this case, the first time refers to an elapsed time for checking valve clogging after driving the compressor, and may be, for example, 3 minutes after driving the compressor. In addition, the first current indoor heat exchanger temperature may be defined to mean the indoor heat exchanger temperature at a point in time when the first time elapses after the compressor is driven.

Next, the air conditioning system 100 is based on the indoor air temperature (Tr1) just before starting the compressor, the indoor heat exchanger temperature (Te1) immediately before starting the compressor, and the first current indoor heat exchanger temperature (Te2). You can judge whether or not.

In more detail, the air conditioning system 100 compares the difference between the indoor heat exchanger temperature Te1 immediately before starting the compressor and the first current indoor heat exchanger temperature Te2 with the first temperature reference value, and the indoor air temperature immediately before starting the compressor ( The difference between Tr1) and the first current indoor heat exchanger temperature Te2 may be compared with the second temperature reference value (S109).

As a result of the comparison, if each difference is less than or equal to the first temperature reference value and the second temperature reference value, it may be determined as a primary blockage of the valve 140. In this case, the valve 140 may be an electronic expansion valve, and is not limited thereto, and may be any valve that can be turned on or off applied to the air conditioner system. For example, a solenoid valve type valve applied to the air conditioner system 100 may be possible.

Thereafter, the air conditioner system 100 may perform a first test before final determination of the first clogging of the valve 140, and after performing the first test, step S109 is continuously performed again for the first test time to perform the valve ( 140) can be finally determined whether the primary clogging (S111, S113).

In more detail, as a result of the comparison in step S109, the difference between the indoor heat exchanger temperature Te1 immediately before starting the compressor and the first current indoor heat exchanger temperature Te2 is less than or equal to the first reference temperature value, and the indoor air temperature immediately before starting the compressor. When the difference between (Tr1) and the first current indoor heat exchanger temperature (Te2) is less than or equal to the second temperature reference value, as shown in FIG. 5, the air conditioner system 100 has a valve 140 (eg, electronic The expansion valve) may be opened according to a preset value (S201). At this time, the degree of opening of the valve 140 is a value set by the operator, and should be set to be greater than the degree of opening of the valve 140 before the first test. For example, the valve 140 may be set to open to the maximum.

Next, the air conditioner system 100 may return to the state before opening the valve 140 according to the preset value when a preset second time elapses after the valve 140 is opened (S203, S205).

Next, the difference between the indoor heat exchanger temperature (Te1) immediately before starting the compressor and the first current indoor heat exchanger temperature (Te2) continuously during the first test period, and the indoor air temperature (Tr1) immediately before starting the compressor and the first current indoor heat exchanger temperature. The difference of (Te2) may be compared with the first temperature reference value and the second temperature reference value, respectively.

As a result of comparison, the difference between the indoor heat exchanger temperature (Te1) immediately before starting the compressor and the first current indoor heat exchanger temperature (Te2) is less than or equal to the first reference temperature value, and the indoor air temperature (Tr1) immediately before starting the compressor and the first current indoor When the difference in the heat exchanger temperature Te2 is less than or equal to the second temperature reference value, it may be finally determined as the first clogging of the valve 140 (S113).

When it is determined that the valve 140 is first clogged, the air conditioning system 100 may stop driving the compressor 130 (S115). At this time, the air conditioning system 100 may reset the control unit 150 (eg, a microcomputer).

That is, the air conditioner system 100 checks the indoor air temperature and the indoor heat exchanger temperature through step S109, and when it is estimated that the valve 140 is clogged, the indoor air conditioner returns to the maximum after opening the valve 140 to the maximum. The air temperature and the indoor heat exchanger temperature are checked to determine the clogging of the valve, and the present invention is not limited thereto, and steps S111 and S113 may be omitted.

Next, the air conditioner system 100 may measure the indoor air temperature Trl' just before restarting the compressor and the indoor heat exchanger temperature Te1' just before restarting the compressor (S117).

Next, the air conditioning system 100 may restart the compressor 130 (S119). At this time, the air conditioner system 100 may restart the compressor 130 after a preset time elapses after stopping the compressor.

Next, when a preset third time elapses after restarting the compressor 130, the air conditioning system 100 may measure the second current indoor heat exchanger temperature Te2' (S121).

Next, the air conditioning system 100 exchanges a second current indoor heat exchange with the difference between the indoor heat exchanger temperature (Te1') immediately before restarting the compressor and the second current indoor heat exchanger temperature (Te2'), and the indoor air temperature immediately before restarting the compressor (Tr1'). It is possible to determine whether the valve 140 is secondarily blocked by comparing the difference in temperature Te2' with the first temperature reference value and the second temperature reference value, respectively (S123).

As a result of checking in step S123, the difference between the indoor heat exchanger temperature (Te1') immediately before restarting the compressor and the second current indoor heat exchanger temperature (Te2') is less than or equal to the first temperature reference value, and the indoor air temperature (Tr1') immediately before restarting the compressor. When the difference between the and the second current indoor heat exchanger temperature Te2' is less than or equal to the second temperature reference value, the air conditioning system 100 may open the valve 140 according to a preset value (S125).

Next, the air conditioner system 100 continuously performs the difference between the indoor heat exchanger temperature (Te1') immediately before restarting the compressor and the second current indoor heat exchanger temperature (Te2') and the indoor air temperature immediately before restarting the compressor (Tr1'). ) And the second current indoor heat exchanger temperature Te2' may be compared with the first temperature reference value and the second temperature reference value, respectively (S127).

As a result of the comparison, the difference between the indoor heat exchanger temperature (Te1') immediately before restarting the compressor and the second current indoor heat exchanger temperature (Te2') is less than or equal to the first reference temperature value, and the difference between the indoor air temperature (Tr1') immediately before restarting the compressor and 2 If the difference between the current indoor heat exchanger temperature Te2' is less than or equal to the second temperature reference value, it may be finally determined as a secondary clogging of the valve 140.

In this case, the first test time may be set longer than the second test time. The second test is a step performed after the first test, and is to prevent the compressor 130 from being overwhelmed due to a longer test time with the compressor 130 being driven for a long time compared to the first test time. .

Next, when it is determined that the valve 140 is blocked secondarily, the air conditioning system 100 may stop the operation of the compressor (S129). In this case, the air conditioner system 100 may stop the compressor operation and output an error display. Meanwhile, stopping the compressor operation in step S129 means completely stopping the operation of the compressor, and stopping the operation of the compressor in step S115 may mean a temporary stop before restarting the compressor.

Through the above-described air conditioner control method, it is possible to self-detect the valve clogging of the air conditioner, and thus, an effect of preventing a compressor failure due to continuous operation of an abnormal refrigeration cycle can be expected. In addition, it is possible to detect and respond to continuous haptic defects that may occur due to insufficient cooling load response.

Although the present invention has been described in detail through specific examples, this is for explaining the present invention in detail, and the present invention is not limited thereto, and those of ordinary skill in the art within the spirit of the present invention It is clear that the transformation or improvement is possible.

All simple modifications to changes of the present invention belong to the scope of the present invention, and the specific scope of protection of the present invention will be made clear by the appended claims.

1: air conditioning unit 10: outdoor unit
11, 130: compressor 12: four-way valve
13: outdoor heat exchanger 14: outdoor fan
15: outdoor fan motor 16: accumulator
17, 24: electronic expansion valve 20: indoor unit
21: indoor heat exchanger 22: indoor fan
23: indoor fan motor 25: refrigerant control valve
26: indoor heat exchanger temperature sensor 100: air conditioning system
110: indoor air temperature sensor 120: indoor heat exchanger temperature sensor
140: valve 150: control unit
151: valve clogging check unit 153: valve control unit
155: compressor control unit

Claims (11)

When a request for cooling operation is generated, measuring the indoor air temperature immediately before starting the compressor and the indoor heat exchanger temperature immediately before starting the compressor;
Measuring a first current indoor heat exchanger temperature when a predetermined first time elapses after starting the compressor;
Determining whether a valve is first clogged based on an indoor air temperature immediately before starting the compressor, an indoor heat exchanger temperature immediately before starting the compressor, and the first current indoor heat exchanger temperature; And
When it is determined that the valve is first clogged, including the step of stopping the drive of the compressor,
The step of determining whether the valve is first clogged,
The difference between the indoor heat exchanger temperature immediately before starting the compressor and the first current indoor heat exchanger temperature is less than or equal to a first temperature reference value, and the difference between the indoor air temperature immediately before starting the compressor and the first current indoor heat exchanger temperature is less than a second temperature reference value. If it is less than or equal to, the air conditioner control method is determined as the primary blockage of the valve.
delete The method according to claim 1,
The difference between the indoor heat exchanger temperature immediately before starting the compressor and the first current indoor heat exchanger temperature is less than or equal to the first temperature reference value, and the difference between the indoor air temperature immediately before starting the compressor and the first current indoor heat exchanger temperature is the second temperature. Less than or equal to the reference value,
After the step of determining whether the valve is first clogged, before the step of stopping the drive of the compressor,
Opening the valve according to a preset value;
When a predetermined second time elapses after opening the valve, returning the valve to a state before opening according to a predetermined value;
During a first test period, the difference between the indoor heat exchanger temperature immediately before starting the compressor and the first current indoor heat exchanger temperature is compared with the first temperature reference value, and the indoor air temperature immediately before starting the compressor and the first current indoor heat exchanger temperature Comparing the difference of with the second temperature reference value; And
As a result of the comparison, the difference between the indoor heat exchanger temperature immediately before starting the compressor and the first current indoor heat exchanger temperature is less than or equal to the first temperature reference value, and the difference between the indoor air temperature immediately before starting the compressor and the first current indoor heat exchanger temperature is the When the second temperature is less than or equal to the reference value, the air conditioner control method further comprising the step of finally determining that the first blockage of the valve.
The method of claim 3,
After the step of stopping the drive of the compressor,
Measuring an indoor air temperature immediately before restarting the compressor and an indoor heat exchanger temperature immediately before restarting the compressor;
Restarting the compressor;
Measuring a second current indoor heat exchanger temperature when a predetermined third time elapses after restarting the compressor;
The difference between the indoor heat exchanger temperature immediately before restarting the compressor and the second current indoor heat exchanger temperature is compared with the first temperature reference value, and the difference between the indoor air temperature immediately before restarting the compressor and the second current indoor heat exchanger temperature is the second temperature. Comparing with a reference value to determine whether the valve is secondarily blocked; And
The air conditioner control method further comprising stopping the operation of the compressor when it is determined that the valve is blocked secondarily.
The method of claim 4,
After the step of determining whether the valve is secondarily clogged, before the step of stopping the operation of the compressor,
Opening the valve according to a preset value;
During the second test period, the difference between the indoor heat exchanger temperature immediately before restarting the compressor and the second current indoor heat exchanger temperature is compared with the first temperature reference value, and the indoor air temperature immediately before restarting the compressor and the second current indoor heat exchanger temperature Comparing the difference of with the second temperature reference value; And
As a result of the comparison, the difference between the indoor heat exchanger temperature immediately before restarting the compressor and the second current indoor heat exchanger temperature is less than or equal to the first temperature reference value, and the difference between the indoor air temperature immediately before restarting the compressor and the second current indoor heat exchanger temperature is the When the second temperature is less than or equal to the reference value, the air conditioner control method further comprising the step of finally determining that the second clogging of the valve.
The method of claim 5,
The first test time is longer than the second test time air conditioner control method.
The method according to claim 1,
The valve is an air conditioner control method of an electronic expansion valve or a solenoid valve.
compressor;
An indoor air temperature sensor measuring the indoor air temperature;
An indoor heat exchanger temperature sensor measuring the temperature of the indoor heat exchanger;
A valve that controls the flow of fluid; And
A control unit for determining the clogging of the valve based on the indoor air temperature measured by the indoor air temperature sensor and the indoor heat exchanger temperature measured by the indoor heat exchanger temperature sensor and controlling the operation of the compressor,
The control unit,
The difference between the indoor heat exchanger temperature immediately before starting the compressor and the first current indoor heat exchanger temperature is less than or equal to the first temperature reference value, and the difference between the indoor air temperature immediately before starting the compressor and the first current indoor heat exchanger temperature is less than the second temperature reference value. If equal to or equal to, the air conditioner system comprising a valve clogging check unit that determines that the valve is clogged.
The method of claim 8,
The control unit,
A valve control unit controlling an opening degree of the valve according to a determination result of the valve clogging check unit; And
An air conditioner system further comprising a compressor control unit configured to drive the compressor or stop driving the compressor according to a determination result of the valve clogging check unit.
delete The method of claim 8,
The valve is an air conditioner system which is an electronic expansion valve or a solenoid valve.

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