KR101929854B1 - Diagnosis method of air conditioner - Google Patents

Abstract

The present invention relates to a diagnostic control method for a multi-type air conditioner, and more particularly, to a test operation control of a multi-type air conditioner to which an indoor unit incapable of communication is applied.
A method for diagnosing and controlling a multi-type air conditioner according to an exemplary embodiment of the present invention includes a multi-mode air conditioner including an outdoor unit, a first indoor unit for bidirectional communication with the outdoor unit, and a second indoor unit for transmitting a unidirectional AC relay signal to the outdoor unit Wherein the second indoor unit receives a trial operation command for performing a trial operation; Performing a first trial operation for diagnosing an assembled state of the multi-type air conditioner during a first predetermined reference time while the second indoor unit blows air into the air-conditioned space; Performing a second test operation in which the outdoor unit receives the AC relay signal from the second indoor unit and drives the compressor provided in the outdoor unit to circulate the refrigerant to determine whether the refrigerant is normally supplied to the second indoor unit; Performing the determination that the second indoor unit determines the commissioning result of the second indoor unit as pass or fail based on the first commission or the second commission; And the first indoor unit displays the result of the trial operation.
According to the present invention, it is possible to implement the test run control even when an indoor unit which can not communicate is applied, and can transmit an accurate test run determination result to the installer and the user of the air conditioner.

Description

{DIAGNOSIS METHOD OF AIR CONDITIONER}

The present invention relates to a diagnostic control method for a multi-type air conditioner, and more particularly, to a test operation control of a multi-type air conditioner to which an indoor unit incapable of communication is applied.

Generally, an air conditioner is a device that cools, heats, or purifies the intake air using the movement of heat generated by the evaporation and condensation process of the refrigerant, and discharges the air to harmonize the air in the indoor space.

For example, the air conditioner adjusts the indoor air condition to a cool air condition in the summer, adjusts the indoor air condition to a warm heating condition in winter, adjusts the indoor humidity, and controls the indoor air to a pleasant clean condition.

The air conditioner includes a plurality of indoor units installed in an indoor space and discharging cold air or warm air into the indoor space, and a multi-type outdoor unit installed outside and connected to a plurality of indoor units to supply refrigerant to a plurality of indoor units.

The multi-type air conditioner, to which a plurality of indoor units are connected, checks whether components of the product such as sensors, fans, and motors are erroneously assembled and operated normally through a test mode during installation, and checks whether the indoor- do.

To this end, the indoor unit is provided with various detecting units for detecting indoor information such as room temperature and indoor heat exchanger temperature, and bidirectional communication function for transmitting the operation information and indoor information inputted by the user to the outdoor unit and receiving the operation control signal from the outdoor unit And a printed board assembly (PBA).

Accordingly, when a plurality of indoor units are connected to an outdoor unit to implement a multi-unit air conditioner, a plurality of indoor units must be equipped with various detecting units and a PBA having a bidirectional communication function, thereby increasing the manufacturing cost of the air conditioner

Further, in the case of a single-type indoor unit in which bidirectional communication is not possible (for example, when there is only an inflow refrigerant temperature detection unit in the indoor unit) or when various detection units are not installed, it is difficult to realize trial operation of the multi- .

An object of the present invention is to provide a diagnosis control method of a multi-type air conditioner that realizes trial operation of an indoor unit which can not communicate by only AC relay signal recognition in a multi-air conditioner.

A method for diagnosing and controlling a multi-type air conditioner according to an exemplary embodiment of the present invention includes a multi-mode air conditioner including an outdoor unit, a first indoor unit for bidirectional communication with the outdoor unit, and a second indoor unit for transmitting a unidirectional AC relay signal to the outdoor unit Wherein the second indoor unit receives a trial operation command for performing a trial operation; Performing a first trial operation for diagnosing an assembled state of the multi-type air conditioner during a first predetermined reference time while the second indoor unit blows air into the air-conditioned space; Performing a second test operation in which the outdoor unit receives the AC relay signal from the second indoor unit and drives the compressor provided in the outdoor unit to circulate the refrigerant to determine whether the refrigerant is normally supplied to the second indoor unit; Performing the determination that the second indoor unit determines the commissioning result of the second indoor unit as pass or fail based on the first commission or the second commission; And the first indoor unit displays the result of the trial operation.

The first reference time includes a time at which the temperature of the second heat exchanger provided in the second indoor unit is saturated to the temperature of the air conditioning space.

The execution of the blowing includes the continuous operation from the start of blowing in the first commissioning stage to the end of commissioning.

The first trial run may further include determining that the test run result is " failed " if an abnormality is found in at least one component, and setting the AC relay signal of the second indoor air timer to OFF do.

The first trial run may further include entering the second trial run after the predetermined first reference time elapses if the assembled state of the parts is normal.

In addition, the second commissioning entry point of the first indoor unit and the second commissioning entry point of the second indoor unit may be the same.

Further, the second commissioning step may include: confirming the number of currently commissioned indoor units; Opening the electronic expansion valve by opening the electronic expansion valve corresponding to the number of the indoor units to be tested; And operating the compressor at an operating frequency corresponding to the number of the indoor units to be commissioned.

In order to confirm the number of the currently-commissioned indoor units, the outdoor unit confirms the number of the currently-commissioned indoor units based on the communication signal transmitted from the first indoor unit or the AC relay signal transmitted from the second indoor unit .

The determination based on the second test run may be performed by dividing the compressor into a plurality of temperature ranges according to the second room temperature before the compressor is operated and setting the test run determination criteria differently depending on the temperature ranges .

Further, when the second room temperature before the operation of the compressor is equal to or lower than a preset first room temperature boundary value, the control unit further determines that the commissioning result of the second indoor unit is " acceptable ".

When the second room temperature before the compressor operation exceeds the first room temperature boundary value and is equal to or lower than the second room temperature boundary value, the second room temperature immediately before the determination minus the second heat exchanger temperature just before the determination Quot; pass " if the value exceeds the first reference temperature.

If the value obtained by subtracting the second heat exchanger temperature immediately before the determination from the second room temperature just before the determination is higher than the first reference temperature and the second heat exchanger temperature just before the determination is higher than the third reference temperature, And determining that the commissioning result of the indoor unit is " passed ".

When the second room temperature before the compressor operation is above the second room temperature boundary value, the value obtained by subtracting the second heat exchanger temperature immediately before the determination from the second room temperature immediately before the determination is greater than the second reference temperature , &Quot; pass " is determined.

If the value obtained by subtracting the second heat exchanger temperature immediately before the determination from the second room temperature immediately before the determination is higher than the second reference temperature and the second heat exchanger temperature just before the determination is higher than the fourth reference temperature, And determining that the commissioning result of the indoor unit is " passed ".

The step of performing the determination may further include continuously operating the second indoor unit until the third reference time, which is the time at which the determination of the first indoor unit is completed, if the test operation result is " Pass "; And setting the AC relay to ON after the elapse of the third reference time.

Further, performing the determination may include detecting a second heat exchanger temperature after the commissioning determination if the commissioning result is " acceptable "; And setting the AC relay to ON if the second heat exchanger temperature after the commissioning determination is larger than " the second heat exchanger temperature measured immediately before the judgment and the fifth reference temperature ".

Further, performing the determination further includes setting the AC relay to OFF when the trial operation result is " failed ".

Further, in order to display the trial operation result, the outdoor unit receives the AC relay signal from the second indoor unit; The outdoor unit communicates the commissioning result to the first indoor unit according to the AC relay signal; And the first indoor unit displays the result of the trial operation.

According to the present invention, it is possible to implement the test run control even when an indoor unit which can not communicate is applied, and can transmit an accurate test run determination result to the installer and the user of the air conditioner.

Further, according to the present invention, since the addition of the sensor unit and the change of the PBA specification are not required to implement the test run control, the cost can be reduced.

1 is a refrigerant cycle diagram of a multi-type air conditioner according to an embodiment of the present invention.
2 is a control block diagram of a multi-type air conditioner according to an embodiment of the present invention.
3 is a flowchart illustrating a diagnosis and control method of a multi-type air conditioner according to an embodiment of the present invention.
FIG. 4 is a flowchart illustrating a first test operation step among diagnostic control methods according to an embodiment of the present invention.
FIG. 5 is a flowchart illustrating a second test operation step among diagnostic control methods according to an embodiment of the present invention.
FIG. 6 is a flowchart showing a determination step among diagnostic control methods according to an embodiment of the present invention.
FIG. 7 is a flowchart illustrating a test operation result display step among diagnostic control methods according to an embodiment of the present invention.

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

1 is a refrigerant cycle diagram of a multi-type air conditioner according to an embodiment of the present invention.

Referring to FIG. 1, the multi-type air conditioner may include an outdoor unit 100, a first indoor unit 200, and a second indoor unit 300.

The outdoor unit 100 may be installed outdoors.

The first indoor unit 200 is installed in the first indoor space, is capable of performing bidirectional communication with the outdoor unit, and can perform cooling or heating operation to air-cool or heat the air in the first indoor space.

The second indoor unit 300 is installed in the second indoor space and can not communicate with the outdoor unit and can perform cooling or heating operation to air-cool or heat the air in the second indoor space.

The outdoor unit 100 includes a compressor 101, an outdoor heat exchanger 102, an outdoor fan 103, a first distribution pipe 104, a first flow control valve 105, a second flow control valve 106, A two-minute pipe 107, an accumulator 108, an oil separator 109, an outdoor temperature detector 121, a discharge temperature detector 123, and a four-way valve 176.

The compressor (101) can suck and compress the low-temperature and low-pressure refrigerant and discharge it in a high-temperature and high-pressure state.

The compressor 101 is a capacity variable type compressor and can change the capacity of the compressor 101 by changing the operation frequency in accordance with the capacity required by the indoor units 200 and 300. [

The outdoor heat exchanger 102 can perform heat exchange with outdoor air.

The outdoor fan (103) is rotated by the fan motor (M1) to assist heat exchange by forcibly blowing air around the outdoor heat exchanger (102).

The first distribution pipe 104 distributes the refrigerant supplied from the outdoor heat exchanger 102 to the first indoor unit 200 and the second indoor unit 300 during the cooling operation and supplies the refrigerant to the first indoor unit 200 and the second indoor unit 300 during the heating operation, And can supply the refrigerant supplied from the indoor unit 200 and the second indoor unit 300 to the outdoor heat exchanger 102, respectively.

Here, the first distribution pipe 104 is a pipe for connecting the refrigerant pipes of the plurality of indoor units 200 and 300 to the refrigerant pipe of one outdoor unit 100, and is connected to the first hole and the first hole, Have a plurality of second holes different from each other.

That is, the refrigerant pipe drawn out from the outdoor heat exchanger 102 is connected to the first hole of the first distribution pipe 104, and the refrigerant pipe of the first indoor unit 200 and the second indoor unit 300 ) Are connected to each other.

Accordingly, during the cooling operation, the refrigerant heat-exchanged in the outdoor heat exchanger 102 is supplied to the first indoor unit 200 and the second indoor unit 300 through the first distribution pipe 104, and during the heating operation, 1 refrigerant heat exchanged with the first indoor unit 200 and the second indoor unit 300 is supplied to the outdoor heat exchanger 102.

The first flow rate control valve 105 is disposed between the refrigerant pipes connected to the first indoor unit 200 among the refrigerant pipes connected to the first distribution pipe 104, The pressure and the temperature of the gas can be lowered.

The second flow control valve 106 is disposed between the refrigerant pipes connected to the second indoor unit 300 among the refrigerant pipes connected to the first distribution pipe 104, The pressure and the temperature of the gas can be lowered.

Here, the first and second flow control valves 105 and 106 may include an electronic expansion valve (EEV) capable of adjusting the opening degree of the refrigerant to control the flow rate of the refrigerant.

The second distribution pipe 107 can collect the refrigerant supplied from the first indoor unit 200 and the second indoor unit 300 and supply the refrigerant to the compressor 101 during the cooling operation, And can supply the supplied refrigerant to the first indoor unit 200 and the second indoor unit 300.

The second distribution pipe 107 is a pipe for connecting the refrigerant pipe of one outdoor unit 100 to the refrigerant pipe of the plurality of indoor units 200 and 300. The second distribution pipe 107 is connected to the first hole and the first hole, And may include a plurality of second holes having different directions.

The refrigerant pipe connected to the suction side of the compressor 101 is connected to the first hole of the second distribution pipe 107 and the refrigerant pipe connected to the refrigerant pipe of the first indoor unit 200 and the second indoor unit 300 ) May be connected to the refrigerant pipe.

Accordingly, during cooling, refrigerant supplied to the first indoor unit 200 and the second indoor unit 300 can be collected through the second distribution pipe 107 and supplied to the compressor 101, 101 may be supplied to the first indoor unit 200 and the second indoor unit 300 through the second distribution pipe 107. [

The accumulator 108 is disposed on the suction side of the compressor 101 and separates the liquid refrigerant in the refrigerant flowing into the compressor 101 from the plurality of indoor units 200 and 300 so that the liquid refrigerant flows into the compressor 101 The compressor 105 can be prevented from being damaged.

For example, the accumulator 108 collects and vaporizes the liquid refrigerant that has not evaporated in the evaporator, and is allowed to flow into the compressor 101.

That is, when the evaporator is not completely evaporated, the refrigerant entering the accumulator 108 is a mixture of liquid and gaseous state. The accumulator 108 vaporizes the liquid refrigerant so that only the gaseous refrigerant is sucked into the compressor .

The oil separator 109 is disposed between the accumulator 108 and the compressor 101 to separate the oil contained in the vapor of the refrigerant discharged from the compressor 101 and return it to the compressor 101, The oil film is formed on the surface of the heat exchanger and the indoor heat exchanger to prevent the heat transfer effect from being deteriorated and the lubricating oil is insufficient in the compressor 101 and the lubricating action is prevented from being lowered.

The outdoor temperature detection unit 121 is installed in any one of the outdoor units 100 and can detect the outdoor temperature of the outdoor space.

The discharge temperature detection unit 123 is disposed on the discharge side of the compressor 101 and can detect the temperature of the refrigerant discharged from the compressor 101. [

The four-way valve 176 is provided at the outlet side of the compressor 105, and can change the flow direction of the refrigerant according to the cooling or heating operation.

The four-way valve 176 guides the high-temperature and high-pressure refrigerant discharged from the compressor 101 to the first and second indoor units 200 and 300 while the refrigerant is being discharged from the compressor 101 during the heating operation and supplies the refrigerant at low temperature and pressure of the outdoor heat exchanger 102 to the accumulator 108 ). That is, the refrigerant can flow in the direction of the dotted arrow.

On the other hand, the four-way valve 176 guides the high-temperature and high-pressure refrigerant discharged from the compressor 105 to the outdoor heat exchanger 102 during the cooling operation and supplies the refrigerant of low temperature and low pressure of the first and second indoor units 200 and 300 to the accumulator (108). That is, the refrigerant can flow in the direction of the solid line arrow.

Hereinafter, the cooling operation will be described.

The first indoor unit 200 can perform bidirectional communication with the outdoor unit and can cool the first indoor space.

The first indoor unit 200 includes a first indoor heat exchanger 205, a first indoor fan 275, a first indoor inflow refrigerant temperature detection unit 223, a first indoor outflow refrigerant temperature detection unit 225, And a temperature detector 221.

The first indoor heat exchanger 205 is connected to the first flow control valve 105 and the refrigerant supplied through the first flow control valve 105 is vaporized and can perform heat exchange with the indoor air when the refrigerant is vaporized.

The first indoor fan 275 is rotated by the fan motor M2 to forcibly blow the heat-exchanged air into the first indoor space.

The first indoor inflow refrigerant temperature detection unit 223 is installed in the inflow side refrigerant pipe of the first indoor heat exchanger 205 and detects the temperature of the refrigerant flowing to the inflow side refrigerant pipe of the first indoor heat exchanger 205 have.

The first outdoor refrigerant temperature detection unit 225 is installed in the refrigerant pipe at the outlet side of the first indoor heat exchanger 205 and detects the temperature of the refrigerant flowing in the refrigerant pipe at the outlet side of the first indoor heat exchanger 205 have.

The first indoor temperature detection unit 221 can detect the temperature of the first indoor space.

The second indoor unit 300 can not communicate with the outdoor unit, can transmit the AC relay signal to the outdoor unit, and can cool the second indoor space.

The second indoor unit 300 may include a second indoor heat exchanger 305, a second indoor fan 375, a second heat exchanger temperature detector 323, and a second indoor temperature detector 321.

The second indoor heat exchanger 305 is connected to the second flow control valve 106 and the refrigerant supplied through the second flow control valve 106 is vaporized and can perform heat exchange with the indoor air when the refrigerant is vaporized.

The second indoor fan 375 is rotated by the fan motor M3 to forcibly blow the heat-exchanged air into the second indoor space.

The second heat exchanger temperature detector 323 is provided on the intermediate side of the second indoor heat exchanger 305 and can detect the average temperature of the refrigerant in the second indoor heat exchanger 305. [

The second indoor temperature detection unit 321 can detect the temperature of the second indoor space.

2 is a control block diagram of a multi-type air conditioner according to an embodiment of the present invention.

2, the outdoor unit includes an outdoor unit power supply unit 110, an outdoor unit detection unit 120, an outdoor unit communication unit 130, an outdoor control unit 140, a storage unit 150, a test run progress control unit 160, 170).

The outdoor unit power supply unit 110 can supply electric power to the outdoor unit 100.

The outdoor unit detection unit 120 may include an outdoor temperature detection unit 121, a discharge temperature detection unit 123, a current detection unit 125, a frequency detection unit 127, and a power detection unit 129.

The outdoor temperature detection unit 121 is installed in any one of the outdoor units 100 and can detect the outdoor temperature of the outdoor space.

The discharge temperature detection unit 123 is disposed on the discharge side of the compressor 101 and can detect the temperature of the refrigerant discharged from the compressor 101. [

The current detection unit 125 can detect the operation current of the outdoor unit 100. [

The frequency detecting unit 127 is connected to the output side of the inverter unit (not shown), detects the frequency applied to the compressor from the inverter unit, and transmits the detected frequency to the outdoor control unit 140.

The power detector unit 129 is connected to the AC relay unit 330 of the second indoor unit 300 to detect whether the second indoor unit 300 is powered on or off and transmits the detected power on or off signal to the outdoor controller 140).

The outdoor communication unit 130 may communicate with the first indoor unit 200 in response to a command from the outdoor control unit 140.

That is, the outdoor unit communication unit 130 receives the operation information and indoor information from the first indoor unit 200 during operation of the first indoor unit 200, transmits the operation information and the indoor information to the outdoor control unit 140, To the first indoor unit (200).

The outdoor control unit 140 is electrically connected to the outdoor temperature detection unit 121, the discharge temperature detection unit 123, the current detection unit 125, the frequency detection unit 127, and the power detection unit 129, And it is possible to perform overall control of the outdoor unit 100.

If the user or the installer generates a test run command through the second input unit 315 of the second indoor unit 300, the outdoor control unit 140 can receive the test run command from the second indoor control unit 340.

Thus, the second indoor control unit 340 and the outdoor control unit 140 can share that a test run command has occurred.

In addition, the outdoor control unit 140 may receive the AC relay signal from the second indoor unit 300 and perform the second commissioning step.

That is, the outdoor control unit 140 drives the compressor 101 and opens the second flow control valve 106 (hereinafter, mixed with the electronic expansion valve) on the side of the second indoor unit 300 to circulate the refrigerant Can be done.

Since the outdoor control unit 140 can receive the unidirectional AC relay signal from the second indoor unit 300, the outdoor control unit 140 predicts the commissioning state of the second indoor unit 300 based on whether the AC relay signal is received And can transmit the result to the first indoor unit 200 capable of communication.

That is, the outdoor control unit 140 can receive the AC relay signal transmitted from the AC relay unit 330 of the second indoor unit 300 through the power detection unit 129.

The outdoor control unit 140 may then transmit the determination result of the second indoor unit 300 to the first indoor communication unit 230 of the first indoor unit 200 through the outdoor unit communication unit 130.

Additional functions of the outdoor control unit 140 will be described in more detail with reference to FIG. 3 to FIG.

The storage unit 150 stores data (temperature detection value, frequency detection value, power detection value, valve opening value, reference temperature, reference time, etc.) generated during operation of the multi-type air conditioner, You can store the necessary software and so on.

The commissioning progress control unit 160 can determine the degree of progress of the commissioning and provide the commissioning progress ratio information to the outdoor control unit 140.

The outdoor control unit 140 transmits the test progress rate information to the first indoor unit 200 so that the progress of the first indoor unit 200 can be displayed.

The outdoor unit driving unit 170 may include a compressor driving unit 171, an outdoor fan driving unit 173, a first flow control valve driving unit 178, and a second flow control valve driving unit 179.

The compressor driving unit 171 can control the operation of the compressor 101 (see FIG. 1). The compressor driving unit 171 may include an inverter (not shown).

The inverter unit receives an AC power of a fixed frequency and a fixed voltage from a commercial power source, rectifies the AC power, smoothens (DC) the DC power, removes a pulsating component to convert the DC component into a DC component, and supplies the DC component voltage to the outdoor controller 140 (Not shown) of the compressor 101 (see Fig. 1) by varying the voltage and the frequency corresponding to the control command.

The outdoor fan drive unit 173 can control the operation (on / off) and the rotation speed of the outdoor fan 103 (see FIG. 1) according to the drive command of the outdoor control unit 140.

The four-way valve driving unit 175 can control the four-way valve 176 (see FIG. 1) according to the drive command of the outdoor control unit 140 to switch the flow direction of the refrigerant according to the cooling or heating operation.

The first flow rate regulating valve driving unit 178 opens or closes the first flow rate regulating valve 105 according to the drive command of the outdoor controller 140. When the first flow rate regulating valve 105 is opened, The first flow control valve 105 can be opened by an opening corresponding to the drive command.

The second flow rate regulating valve driving unit 179 opens or closes the second flow rate regulating valve 106 according to the drive command of the outdoor controller 140. When the second flow rate regulating valve 106 is opened, The second flow control valve 106 can be opened by an opening corresponding to the drive command.

The first indoor unit 200 is installed in the first indoor space, and is capable of bidirectional communication with the outdoor unit. The first indoor unit 200 can air-cool the first indoor space by performing cooling operation.

The first indoor unit 200 includes a first indoor unit power supply unit 210, a first input unit 215, a first indoor unit sensing unit 220, a first indoor unit communication unit 230, a first indoor control unit 240, A display unit 260, and a first indoor fan driving unit 270.

The first indoor unit power supply unit 210 is connected to an external commercial power supply, receives AC power from a commercial power supply, and converts the AC power into a power required for operation of each component.

The first indoor unit electric power supply unit 210 can directly receive an on or off command from the user.

For example, when the operation ON command is inputted, the operation power is supplied to each component, and when the operation OFF command is inputted, the operation power supply to each component can be cut off.

The first input unit 215 can receive a driving command and operation information from a user. Here, the operation command may include a drive command according to the power on / off of the first indoor unit 200 and a first indoor unit trial operation command. It may also include information such as a target temperature, a wind direction, and an operation mode corresponding to the wind speed setting.

The first indoor unit sensing unit 220 may include a first indoor temperature detection unit 221, a first inlet refrigerant temperature detection unit 223, and a first outlet refrigerant temperature detection unit 225. The first indoor unit sensing unit 220 is the same as that shown in FIG.

The first indoor unit communication unit 230 may perform bidirectional communication with the outdoor unit 100 in response to a command from the first indoor control unit 240. [

Through the bidirectional communication, the outdoor unit 100 and the first indoor unit 200 can exchange various information generated during operation.

The first indoor control unit 240 includes a first indoor unit power supply unit 210, a first input unit 215, a first indoor unit sensing unit 220, a first indoor unit communication unit 230, a first display unit 260, 1 indoor fan driving unit 270 and can perform overall control of the first indoor unit 200. [

When the user or the installer generates a test run command through the first input unit 215, the first indoor control unit 240 can receive the test run command and transmit the test run command to the outdoor control unit 140.

In this way, the first indoor control unit 240 and the outdoor control unit 140 can share the occurrence of the test run command.

Also, the first indoor control unit 240 and the outdoor control unit 140 can perform the trial operation of the multi-type air conditioner. The commissioning may include a first commissioning step, a second commissioning step, and a judging step.

The first test operation step is a step of operating the first indoor fan 275 of the first indoor unit 200 to control the assembling state and driving state of various mechanical devices and electrical components of the outdoor unit 100 and the first indoor unit 200 Check.

The second test operation step confirms whether the normal refrigerant flows between the outdoor unit 100 and the first indoor unit 200 while the compressor 101 of the outdoor unit 100 is operated.

The first determination step determines whether piping connection between the outdoor unit 100 and the first indoor unit 200 is normally performed based on the operation results of the first and second test operation steps.

The second determination step is for determining whether the first indoor unit 200 is normally supplied with the required amount of refrigerant.

The first determination step and the second determination step may be integrated into one determination step.

The first indoor control unit 240 receives the determination result of the second indoor unit 300 through the first indoor unit communication unit 230 and receives the determination result of the first indoor unit 200 and the second indoor unit 300 through the first display unit 260. [ It is possible to display the trial operation result of the controller 300.

Additional functions of the first indoor control unit 240 will be described in more detail with reference to FIG. 3 to FIG.

The first display unit 260 is provided in the first indoor unit 200, and can display a driving state of the multi-type air conditioner and display a guidance message or warning generated during the operation of the multi-type air conditioner.

In particular, the first display unit 260 may display the test run progress and the test run results so that the user can directly confirm the test run results.

The first display unit 260 may be a light emitting device such as an LCD panel or an LED. Also, the first display unit 260 may include a speaker.

If the first display unit 260 is a LCD panel, the progress status of the diagnostic control up to the present can be displayed as a percentage (%), or the whole test operation can be divided into 0 to 99 steps to display each progress step And may be displayed by other methods such as a graph.

When the first display unit 260 is an LED, a plurality of LEDs may be provided and the progress of the trial operation may be displayed through the number of LEDs that are turned on.

The first display unit 260 may display a trial operation result of the first indoor unit 200 and the second indoor unit 300 in response to a control command of the first indoor control unit 240.

When the first display unit 260 includes a speaker, the degree of progress can be guided through the speaker by voice.

The first indoor fan driving unit 270 may control the operation (ON / OFF) and the rotating speed of the first indoor fan 275 in response to a control command of the first indoor control unit 240.

The second indoor unit 300 is installed in the second indoor space and can not communicate with the outdoor unit. The second indoor unit 300 can air-cool the second indoor space by performing cooling operation.

The second indoor unit 300 includes a second indoor unit power supply unit 310, a second input unit 315, a second indoor unit sensing unit 320, an AC relay unit 330, a second indoor control unit 340, (360), and a second indoor fan driver (370).

The second indoor unit power supply unit 310 is connected to an external commercial power supply, receives AC power from a commercial power supply, and converts the AC power into a power required for operation of each component.

The second indoor unit electric power supply unit 310 can directly receive an on or off command from the user.

For example, when the operation ON command is inputted, the operation power is supplied to each component, and when the operation OFF command is inputted, the operation power supply to each component can be cut off.

The second input unit 315 can receive the operation command and the operation information from the user. Here, the driving command may include a driving command according to the power on / off of the second indoor unit 300 and a second indoor unit trial driving command. It may also include information such as a target temperature, a wind direction, and an operation mode corresponding to the wind speed setting.

The second indoor unit sensing unit 320 may include a second indoor temperature detecting unit 321 and a second heat exchanger temperature detecting unit 323. The second indoor unit sensing unit 320 is the same as that shown in FIG.

The AC relay unit 330 may transmit the AC relay signal to the outdoor unit 100 in response to a command from the second indoor control unit 340.

Through the unidirectional transmission, the second indoor unit 300 can transmit the operation state (ON or OFF) of the second indoor unit 300 to the outdoor unit 100.

The second indoor control unit 340 includes a second indoor unit electric power supply unit 310, a second input unit 315, a second indoor unit sensing unit 320, an AC relay unit 330, a second display unit 360, And is electrically connected to the indoor fan driving unit 370, so that the overall control of the second indoor unit 300 can be performed.

When the user or the installer generates a test operation command through the second input unit 315, the second indoor control unit 340 can receive the test operation command and transmit the test operation command to the outdoor control unit 140.

Thus, the second indoor control unit 340 and the outdoor control unit 140 can share that a test run command has occurred.

In addition, the second indoor control unit 340 and the outdoor control unit 140 can perform the trial operation of the multi-function air conditioner. The commissioning may include a first commissioning step, a second commissioning step, and a judging step.

The first test operation step may be performed while the second indoor fan 375 of the second indoor unit 300 is operated and the assembly state and the driving state of various mechanical devices and electrical components of the outdoor unit 100 and the second indoor unit 300, Can be confirmed.

The second test run step can confirm whether the normal refrigerant flows between the outdoor unit 100 and the second indoor unit 300 while the compressor 101 of the outdoor unit 100 is operated.

The determining step may determine whether the second indoor unit 300 is normally supplied with the required amount of refrigerant.

The second indoor control unit 340 may transmit the test operation result of the second indoor unit 300 to the outdoor unit 100 through the AC relay unit 330.

The second indoor control unit 340 may display a result of the trial operation of the second indoor unit 300 through the second display unit 360.

Additional functions of the second indoor control unit 340 will be described in more detail with reference to FIG. 3 to FIG.

The second display unit 360 is provided in the second indoor unit 300, and can display a driving condition of the multi-type air conditioner and can display a warning message or warning generated in the operation of the multi-type air conditioner.

Particularly, the second display unit 360 can display the test run progress and the test run result so that the user can directly confirm the test run results.

The second display unit 360 may be a light emitting device such as an LCD panel or an LED. Also, the second display unit 360 may include a speaker.

When the second display unit 360 is a LCD panel, the progress status of the diagnostic control up to the present can be displayed as a percentage (%), or the entire test operation can be divided into 0-99 steps to display each progress step And may be displayed by other methods such as a graph.

When the second display unit 360 is an LED, a plurality of LEDs may be provided and the progress of the trial operation may be displayed through the number of LEDs that are turned on.

The second display unit 360 may display a test operation result of the second indoor unit 300 in response to a control command of the second indoor control unit 340.

When the second display unit 360 includes a speaker, the degree of progress can be guided through the speaker by voice.

The second indoor fan drive unit 370 can control the operation (ON / OFF) and the rotation speed of the second indoor fan 375 (see FIG. 1) in response to the control command of the second indoor control unit 340.

Hereinafter, a diagnostic control method of the multi-function air conditioner will be described with reference to FIGS. 1 and 2. FIG.

3 is a flowchart illustrating a diagnosis and control method of a multi-type air conditioner according to an embodiment of the present invention.

In particular, the present invention is intended to allow the user to directly confirm whether the multi-type air conditioner is normally installed or not by performing a trial operation after installation of the multi-type air conditioner.

The diagnosis control method of FIG. 3 may be performed by controlling the outdoor control unit 140, the first indoor unit control unit 240, and the second indoor control unit 340 shown in FIG.

3, when the user generates a test run command through the second input unit 315 of the second indoor unit 300, the second indoor control unit 340 receives the test run command and transmits the test run command to the outdoor control unit 140 (1100).

In this way, the second indoor control unit 340 and the outdoor control unit 140 share that a test run command has occurred.

The diagnostic control method of the multi-unit air conditioner may include a first commissioning step 1200, a second commissioning step 1300, a determining step 1400, and a commissioning result displaying step 1500.

The first commissioning step 1200 is performed by operating the second indoor fan 375 of the second indoor unit 300 while operating various mechanical devices of the outdoor unit 100, the first indoor unit 200, and the second indoor unit 300 And assembled state and driving state of electric component parts.

The second test operation 1300 can confirm whether a normal refrigerant flows between the outdoor unit 100 and each of the indoor units (the first indoor unit and the second indoor unit) while the compressor 101 of the outdoor unit 100 is operated.

The determination step 1400 can determine whether the required amount of refrigerant is normally supplied to each of the indoor units (the first indoor unit and the second indoor unit).

The test operation result display step 1500 may display the determination results of the first indoor unit 200 and the second indoor unit 300 in the first display unit 260 of the first indoor unit 200. [

FIG. 4 is a flowchart illustrating a first test operation step among diagnostic control methods according to an embodiment of the present invention.

The second input unit 315 receives the test operation command from the user and can transmit the test operation command to the second indoor control unit 340.

When the second indoor controller 340 receives the start-up command, the first start-up operation can be performed.

First, the second indoor control unit 340 may check the assembly state of components (sensors, motors, etc.) (1110).

The assembly status of components can be checked by checking the responses that may occur when the components are assembled normally.

Second, the second indoor control unit 340 operates the second indoor fan 375 to blow air into the air conditioning space in which the second indoor unit 300 is installed (step 1120).

Here, the second indoor fan 375, which has started to operate in the first commissioning step 1200, can be continuously operated until the commissioning is terminated.

Third, the second indoor control unit 340 may determine whether an abnormality is found in the part (1130).

If an abnormality is found in at least one of the components during operation of the second indoor fan 375 ("Yes" in 1130), the process may proceed to step 1470 of the determination step 1400 to be described later ).

If the assembled state of the parts is all normal (No in step 1130) during the operation of the second indoor fan 375, the user can move to step 1140. [

Fourth, the second indoor controller 340 may determine whether the elapsed driving time of the second indoor fan 375 is equal to or greater than the first reference time t1 (1140).

If the elapsed time of the operation of the second indoor fan 375 is less than the preset first reference time t1 (NO in 1140), the second indoor controller 340 may move to step 1110 (step 1140) .

If the elapsed time of the operation of the second indoor fan 375 is equal to or longer than the first reference time t1 (YES in 1140), the second indoor controller 340 may move to step 1150 (1140).

That is, the second outdoor control unit 340 continues the diagnosis of the parts and the operation of the second indoor fan 375 until the preset first reference time t1 is reached ("No" in 1140) When the elapsed time of the operation of the fan 375 reaches the preset first reference time t1, it enters the second commissioning step 1300 (see FIG. 3) ("Yes" in 1140).

Here, the time to enter the second commissioning step 1300 (see FIG. 3) may be equally applied to the first indoor unit 200 and the second indoor unit 300.

The operation of the second indoor fan 375 during the first predetermined reference time t1 in the state where the compressor 101 is stopped corresponds to the operation in which the temperature of the second heat exchanger 305 of the second indoor unit 300 So as to saturate the temperature of the air conditioning space to prevent a judgment error.

Therefore, the first reference time t1 may be set to a time at which the temperature of the second heat exchanger 305 of the second indoor unit 300 is saturated to the temperature of the air conditioning space.

Fifth, the second indoor control unit 340 may detect the second indoor temperature Tr1 which is the temperature before the compressor 101 is operated (1150).

The second room temperature Tr1 before the compressor 101 is operated can be used to determine whether the required amount of refrigerant is normally supplied to each of the indoor units (the first indoor unit and the second indoor unit) in the determination step 1400. [

FIG. 5 is a flowchart illustrating a second test operation step among diagnostic control methods according to an embodiment of the present invention.

The second indoor control unit 340 commands the outdoor unit 100 to transmit the AC relay signal for driving the compressor 101. The AC relay unit 330 receives the command of the second indoor control unit 340, So that the relay signal can be transmitted to the outdoor unit 100.

The power detection unit 129 of the outdoor unit 100 receives the AC relay signal from the AC relay unit 330 of the second indoor unit 300 and can transmit the AC relay signal to the outdoor control unit 140.

Referring to FIG. 5, when the outdoor control unit 140 receives the AC relay signal from the second indoor unit 300, the outdoor control unit 140 may perform the second test operation step 1300.

That is, the outdoor control unit 140 drives the compressor 101 to open the second flow control valve 106 (hereinafter, described in combination with the electronic expansion valve) of the second indoor unit 300, The refrigerant can be circulated in order to check whether or not the refrigerant is normally supplied.

First, the outdoor control unit 140 can confirm the number of the indoor units to be commissioned (operation 1320).

The number of indoor units to be commissioned can be checked by receiving a communication signal with an indoor unit for commissioning or receiving an AC relay signal.

If the first indoor unit 200 and the second indoor unit 300 are both operated in the case where the indoor unit is composed of the first indoor unit 200 capable of communicating with the second indoor unit 300 incapable of communicating with the first indoor unit 200, The number of indoor units to be tested is " 1 " when only one indoor unit of the first indoor unit 200 and the second indoor unit 300 is tested.

Second, the outdoor control unit 140 may open the electronic expansion valve at the electronic expansion valve opening (Vo or Vom) corresponding to the number of the indoor units to be commissioned (1330).

Here, the opening degree Eo of the electronic expansion valve Vo is the opening degree of the electronic expansion valve in the single operation mode in which the number of the indoor units to be commissioned is one, and the opening degree Vom of the electronic expansion valve is the opening degree of the electronic expansion valve in the multi-

The electronic expansion valve opening value may include an appropriate value for diagnosis depending on the model of the air conditioner.

Third, the outdoor control unit 140 may operate the compressor 101 at an operation frequency (Cf or Cfm) corresponding to the number of indoor units to be commissioned (1340).

Here, the operating frequency Cf of the compressor 101 is the operating frequency of the compressor 101 in the single operation in which the commissioning indoor unit is one, and the operating frequency Cfm is the operating frequency of the compressor 101 in the multi- It is the operating frequency.

The frequencies are classified to differentiate the operating frequency according to the sum of the indoor required capacities in order to secure the reliability of the cooling cycle and to increase discrimination power.

Fourth, the outdoor control unit 140 may compare the number of the indoor units that have been previously tested and the number of the indoor units that are currently in operation (Step 1350).

If the number of the indoor units that have been previously tested is not equal to the number of the indoor units that are currently to be tested (1350 is NO), the outdoor control unit 140 sets the operation frequency Cf Or Cfm) (1360).

Also, the outdoor control unit 140 may change the electronic expansion valve opening value (Vo or Vom) to correspond to the number of the indoor units to be currently commissioned (1370).

Then, the outdoor control unit 140 can move to step 1320. [

(Cf or Cfm) of the compressor 101 and the electronic expansion valve opening (Vo or Vom) of the flow rate control valves 105 and 106 are set to be larger than the number of the indoor units (Cf or Cfm) of the compressor 101 and the electronic expansion valve opening degree (Vo or Cfm) of the flow rate control valves 105 and 106, if the number of the indoor units that are currently commissioned is smaller than the number of the indoor units Vom).

The difference between the operating frequency (Cf or Cfm) of the compressor (101) and the electronic expansion valve opening (Vo or Vom) of the flow rate control valves (105, 106) by dividing the case of single operation and multi- (Cf or Cfm) of the compressor 101 and the opening degree (Vo or Vom) of the electronic expansion valves of the flow rate control valves 105 and 106 are varied according to the sum of the operating capacities of the multiple air conditioners To increase discrimination power.

If the number of the indoor units that have been previously tested is the same as the number of the indoor units that are currently being tested (1350 is YES), the outdoor control unit 140 can move to step 1380. [

Fifth, the outdoor control unit 140 may determine whether the driving elapsed time of the compressor 101 is equal to the second reference time t2 (1380).

If the elapsed time of the operation of the compressor 101 is different from the second reference time t2 ("No" in 1380), the outdoor control unit 140 may move to step 1320. [

That is, the outdoor control unit 140 can continue to operate the compressor 101 until the second reference time t2 is reached.

If the elapsed time of the operation of the compressor 101 is equal to the second reference time t2 (YES in 1380), the outdoor control unit 140 can move to step 1400. [

That is, the outdoor control unit 140 can enter the determination step.

FIG. 6 is a flowchart showing a determination step among diagnostic control methods according to an embodiment of the present invention.

Since the second indoor unit 300 can not communicate with the outdoor unit 100 and can not receive the command from the outdoor control unit 140, the indoor control unit 340 performs the test operation mode separately.

However, since the outdoor control unit 140 can receive the unidirectional AC relay signal from the second indoor unit 300, the outdoor control unit 140 predicts the commissioning state of the second indoor unit 300 based on whether the AC relay signal is received And can transmit the result to the first indoor unit 200 capable of communication.

The first indoor unit 200 can receive the test operation status and the result of the second indoor unit through the first indoor unit communication unit 230 and can receive the test result of the second indoor unit through the first display unit 260, The commissioning status and results can be displayed.

That is, the second indoor unit 300, which is incapable of communication, performs the trial operation independently. However, the outdoor unit 100 may display the result of the trial operation of the second indoor unit on the first indoor unit by receiving the AC relay signal.

Referring to FIG. 6, the second indoor control unit 340 may detect the second room temperature Tr and the second heat exchanger temperature Te, which are the temperatures immediately before the determination, in operation 1410.

Then, the second indoor control unit 340 can divide the compressor into a plurality of temperature regions in accordance with the second room temperature Tr1 before the compressor is operated, and set the test run determination criteria differently according to each temperature region.

For example, the second indoor control unit 340 divides the measured second indoor temperature Tr1, which is the temperature before the compressor 101 is operated, into three ranges, and judges whether or not the appropriate amount of refrigerant is satisfied in each range can do.

First, when the second room temperature Tr1 before the compressor 101 is operating is equal to or less than the first room temperature boundary value T1 (Yes in 1415), the second indoor control unit 340 controls the second indoor unit Tr1 300) can be determined as " pass " (1415, 1445)

Here, the first room temperature boundary value T1 is a temperature boundary value capable of distinguishing the low temperature region and the normal temperature region.

For example, when the first indoor temperature boundary value T1 is 20 degrees and the second room temperature Tr1 before the compressor 101 is 17 degrees, the second indoor unit 300 operates normally, The second indoor controller 340 determines that a proper amount of refrigerant is supplied to the second indoor unit 300 because the temperature Tr1 has a sufficiently low value.

Second, if the second room temperature Tr1 before the compressor 101 is above the first room temperature boundary T1 and below the second room temperature boundary T2 ("No" in 1415 and 1420 YES "), the second indoor control unit 340 may perform step 1425 (1415, 1420).

Here, the second room temperature boundary value T2 is a value that is larger than the first room temperature boundary value T1, and the second room temperature boundary value T2 is a temperature boundary value that can distinguish the room temperature region from the high temperature region .

If the value obtained by subtracting the second heat exchanger temperature Te immediately before the determination from the second room temperature Tr immediately before the determination is greater than the first reference temperature Tc1 (Yes in 1425) The controller 340 performs step 1430. If the value obtained by subtracting the second heat exchanger temperature Te immediately before the determination from the second room temperature Tr immediately before the determination is equal to or lower than the first reference temperature Tc1 &Quot; No "). The second indoor control unit 340 determines the trial operation result as " failed " (1425, 1470).

Here, the more the refrigerant supplied to the second heat exchanger 305 is, the lower the value of the second heat exchanger temperature Te immediately before the determination, and the smaller the refrigerant supplied, the lower the second heat exchanger temperature (Te) has a high value.

That is, when the amount of circulating refrigerant in the cooling cycle is insufficient, since the vapor phase ratio is higher than the liquid phase ratio of the refrigerant passing through the heat exchanger 305, the average second heat exchanger temperature Te immediately before the judgment is higher than when the refrigerant amount is sufficient Value.

On the other hand, when the circulating refrigerant amount in the cooling cycle is sufficient, since the liquid phase ratio is higher than the vapor phase ratio of the refrigerant passing through the heat exchanger 305, the average second heat exchanger temperature Te immediately before the judgment is larger than the case where the refrigerant amount is insufficient And a low value.

The first reference temperature Tc1 is a condition (1415 " 1 ") in which the second room temperature Tr1 before the compressor 101 is operating exceeds the first room temperature boundary value T1 and is equal to or lower than the second room temperature boundary value T2. The second indoor control unit 340 determines whether or not the second indoor unit 300 is operating at the second indoor temperature Tr ("Yes" in Step 1420) And the minimum difference value of the second heat exchanger temperature Te immediately before the determination.

If the second heat exchanger temperature Te immediately before the determination is above the third reference temperature Tc3 (Yes of 1420 and Yes of 1425 and Yes of 1430), the second indoor control unit (1430, 1445). If the second heat exchanger temperature Te is lower than the third reference temperature Tc3 immediately before the determination (1420, 1445), the control unit 340 determines that the commissioning result of the second indoor unit 300 is " The second indoor control unit 340 determines that the commissioning result of the second indoor unit 300 is " failed " (1430, 1470).

The third reference temperature Tc3 is set to a condition 1415 of " NO " in which the second room temperature Tr1 before the compressor 101 is operated exceeds the first room temperature T1 and is equal to or lower than the second room temperature T2 Of the second heat exchanger temperature Te immediately before the determination as a criterion for determining whether or not an appropriate amount of refrigerant is being supplied to the second indoor unit 300 in the second indoor control unit 340 Temperature value.

Since the phase change of the refrigerant in the second heat exchanger 305 is performed, the phase change of the refrigerant can not be normally performed when the second heat exchanger 305 does not operate normally.

As a result, the ratio of the liquid phase in the refrigerant existing in the second heat exchanger 305 becomes higher than the ratio of the vapor phase, and the heat exchange is not normally performed.

Therefore, when the temperature of the second heat exchanger (Te) immediately before the determination is lowered to the third reference temperature (Tc3) or lower by the cool liquid refrigerant present in the second heat exchanger (305), the second indoor control unit (340) It is determined that an appropriate amount of the refrigerant is not supplied to the second indoor unit 300 and the test operation result is determined as " failed ".

However, when the second heat exchanger 305 operates normally, the phase change of the refrigerant is normally performed.

As a result, the refrigerant present in the second heat exchanger 305 has a proper ratio of the liquid phase to the vapor phase, and heat exchange is normally performed.

Therefore, the liquid refrigerant present in the second heat exchanger 305 and the gaseous refrigerant cause the temperature (Te) of the second heat exchanger immediately before the determination to exceed the third reference temperature (Tc3) The controller 340 determines that an appropriate amount of refrigerant is being supplied to the second indoor unit 300 and determines that the commissioning result is " acceptable ".

Third, when the second room temperature Tr1 before the compressor 101 is operated exceeds the second room temperature boundary value T2 ("NO" in 1415 and "NO" in 1420), the second indoor controller 340 May perform step 1435 (1415, 1420).

If the value obtained by subtracting the second heat exchanger temperature Te immediately before the determination from the second room temperature Tr immediately before the determination is greater than the second reference temperature Tc2 ("Yes" in 1435) If the value obtained by subtracting the second heat exchanger temperature Te immediately before the determination from the second room temperature Tr immediately before the determination is equal to or less than the second reference temperature Tc2 in step 1440, &Quot; No ") The second indoor control unit 340 determines the trial operation result as " failed " (1435, 1470).

Here, the more the refrigerant supplied to the second heat exchanger 305 is, the lower the value of the second heat exchanger temperature Te immediately before the determination, and the smaller the refrigerant supplied, the lower the second heat exchanger temperature (Te) has a high value.

That is, when the amount of circulating refrigerant in the cooling cycle is insufficient, since the vapor phase ratio is higher than the liquid phase ratio of the refrigerant passing through the heat exchanger 305, the average second heat exchanger temperature Te immediately before the judgment is higher than when the refrigerant amount is sufficient Value.

On the other hand, when the circulating refrigerant amount in the cooling cycle is sufficient, since the liquid phase ratio is higher than the vapor phase ratio of the refrigerant passing through the heat exchanger 305, the average second heat exchanger temperature Te immediately before the judgment is larger than the case where the refrigerant amount is insufficient And a low value.

The second reference temperature Tc2 is set at a condition that the second room temperature Tr1 before the compressor 101 is operating exceeds the second room temperature boundary value T2 in the case of "No" in 1415 and "No" in 1420) The second indoor control unit 340 determines the second indoor temperature Tr just before the determination, which is a criterion for determining whether an appropriate amount of refrigerant is being supplied to the second indoor unit 300, It is the minimum difference value of temperature Te.

Here, the second reference temperature Tc2 may have a value smaller than the first reference temperature Tc1.

Even if the same amount of refrigerant flows in the second indoor unit, the degree to which the second room temperature Tr immediately before the determination falls may vary depending on the second room temperature Tr1 before the compressor 101 is operated. The higher the second room temperature Tr1 before operation, the lower the degree to which the second room temperature Tr just before the judgment falls.

Therefore, when the second room temperature Tr1 before the operation of the compressor 101 is above the second room temperature boundary value T2, the second reference temperature Tc2 is a value smaller than the first reference temperature Tc1 So that the accuracy of the determination can be increased.

If the second heat exchanger temperature Te immediately before determination is above the fourth reference temperature Tc4 ("No" in 1420 and "Yes" in 1435 and "Yes" in 1440) (1440, 1445). If the temperature of the second heat exchanger (Te) immediately before the determination is lower than the fourth reference temperature (Tc4) (1420, 1445) The second indoor control unit 340 determines 1440 and 1470 the result of the trial operation of the second indoor unit 300 as " failed ".

The fourth reference temperature Tc4 is set to the second reference temperature Tc4 in the condition (No in 1415 and No in 1420) in which the second room temperature Tr1 before the compressor 101 is operated is higher than the second room temperature T2 The indoor controller 340 is a minimum temperature value of the second heat exchanger temperature Te immediately before the determination as a criterion for determining whether an appropriate amount of refrigerant is being supplied to the second indoor unit 300. [

Since the phase change of the refrigerant in the second heat exchanger 305 is performed, the phase change of the refrigerant can not be normally performed when the second heat exchanger 305 does not operate normally.

As a result, the ratio of the liquid phase in the refrigerant existing in the second heat exchanger 305 becomes higher than the ratio of the vapor phase, and the heat exchange is not normally performed.

Therefore, when the temperature of the second heat exchanger (Te) immediately before the determination is lowered to the fourth reference temperature (Tc4) or lower by the cool liquid refrigerant present in the second heat exchanger (305), the second indoor controller (340) It is determined that an appropriate amount of the refrigerant is not supplied to the second indoor unit 300 and the test operation result is determined as " failed ".

However, when the second heat exchanger 305 operates normally, the phase change of the refrigerant is normally performed.

As a result, the refrigerant present in the second heat exchanger 305 has a proper ratio of the liquid phase to the vapor phase, and heat exchange is normally performed.

Therefore, the liquid refrigerant present in the second heat exchanger 305 and the gaseous refrigerant cause the temperature (Te) of the second heat exchanger immediately before determination to exceed the fourth reference temperature (Tc4) The controller 340 determines that an appropriate amount of refrigerant is being supplied to the second indoor unit 300 and determines that the commissioning result is " acceptable ".

Here, the fourth reference temperature Tc4 may have a value larger than the third reference temperature Tc3.

Even if the same amount of refrigerant flows into the second indoor unit, the degree to which the second heat exchanger temperature Te falls immediately before the determination may vary depending on the second room temperature Tr1 before the compressor 101 is operated. 101 may be lower, the degree to which the second heat exchanger temperature Te just before the determination falls may be lower.

Therefore, when the second room temperature Tr1 before the operation of the compressor 101 is above the second room temperature boundary value T2, the fourth reference temperature Tc4 is a value larger than the third reference temperature Tc3 So that the accuracy of the determination can be increased.

Hereinafter, a process of determining whether the second indoor control unit 340 has passed or failed the trial operation result has been described. Hereinafter, a process after the acceptance or rejection determination of the trial operation result will be described.

The second indoor control unit 340 continuously operates the second indoor unit 300 until the determination of the first indoor unit 200 is completed and then terminates the operation of the second indoor unit 300, 100 and the first indoor unit 200 are terminated and the operation of the second indoor unit 300 can be terminated.

First, the second indoor control unit 340 detects the second heat exchanger temperature Te1 after the commissioning determination (1450).

If the elapsed time of the judgment is the third reference time t3 (Yes in 1455), the second indoor control unit 340 sets the AC relay to ON and ends the operation of the second indoor unit 1455 , 1465, 1490).

If the elapsed time of the judgment is not the third reference time t3 and the second heat exchanger temperature Te1 after the trial run determination is "the second heat exchanger temperature Te + the fifth reference temperature Tc5 measured immediately before the determination, Quot; No " in 1455 and " No " in 1460), the second indoor controller 340 moves to step 1450. [

Here, the third reference time t3 indicates a time when the determination of the first indoor unit 200 is completed, and the fifth reference temperature Tc5 indicates that the second indoor control unit 340 controls the outdoor unit 100 and the first indoor unit 200, Means a difference value between the second heat exchanger temperature Te1 after the determination made after the determination as a reference for sensing the operation completion of the indoor unit 200 and the second heat exchanger temperature Te measured immediately before the determination.

In this case, the second indoor control unit 340 can continuously operate the second indoor unit 300 until the determination of the first indoor unit 200 is completed.

This is because, when the second indoor unit 300 is turned off, the flow of the refrigerant temporarily flows into the first indoor unit 200, so that an error may occur in the determination period for detecting whether the refrigerant is short. In the second indoor unit 300, The second indoor controller 340 performs the operation of the second indoor unit 300 until the determination time of the first indoor unit 200 because the determination time of the first indoor unit 200 is earlier than the determination time of the first indoor unit 200, 200).

If the elapsed time of the judgment is not the third reference time t3 and the second heat exchanger temperature Te1 after the trial run determination is "the second heat exchanger temperature Te + the fifth reference temperature Tc5 measured immediately before the determination, The second indoor control unit 340 sets the AC relay to ON and terminates the operation of the second indoor unit 1455, 1465, 1490, if it is larger than " .

The second indoor unit 300 can not communicate with the outdoor unit 100 and can not receive the command from the outdoor unit 140. The second indoor unit 300 can not receive commands from the outdoor unit 100 and the first indoor unit 200, It is necessary to detect the end of the operation and terminate the operation of the second indoor unit 300.

Therefore, when the operation of the outdoor unit 100 and the first indoor unit 200 is terminated, the second heat exchanger temperature Te1 after the determination is raised, and the second indoor control unit 340 determines the second heat exchanger temperature The first indoor unit 200 and the second indoor unit 200 are in a state where the operation of the outdoor unit 100 and the first indoor unit 200 is completed.

If the result of the trial operation is not successful, the second indoor control unit 340 sets the AC relay to OFF and ends the operation of the second indoor unit (1475, 1490).

In addition, if the trial operation result is not acceptable, the second indoor control unit 340 can stop driving the second indoor fan 375.

FIG. 7 is a flowchart illustrating a test operation result display step among diagnostic control methods according to an embodiment of the present invention.

First, the outdoor control unit 140 receives the AC relay signal transmitted from the AC relay unit 330 of the second indoor unit 300 through the power detection unit 129 (1510).

Then, when the received AC relay signal is ON, the outdoor control unit 140 informs the first indoor unit 200 that the determination result of the second indoor unit 300 is acceptable (1520, 1530).

However, if the received AC relay signal is OFF, the outdoor control unit 140 informs the first indoor unit 200 that the determination result of the second indoor unit 300 is rejected (1520, 1540).

At this time, the outdoor control unit 140 can transmit the determination result of the second indoor unit 300 to the first indoor communication unit 230 of the first indoor unit 200 through the outdoor unit communication unit 130.

The first indoor control unit 240 of the first indoor unit 200 receives the determination result of the second indoor unit 300 through the first indoor communication unit 230 and receives the determination result of the first indoor unit 300 through the first display unit 260. [ The test results of the indoor unit 200 and the second indoor unit 300 may be displayed (1550).

100: outdoor unit 110: outdoor unit electric power supply unit
120: outdoor unit detecting unit 130: outdoor unit communication unit
140: outdoor control unit 150: storage unit
160: test run progress ratio control unit 170: outdoor-
200: first indoor unit 210: first indoor unit electric power supply unit
215: first input unit 220: first indoor unit sensing unit
230: first indoor unit communication unit 240: first indoor control unit
260: first display section 270: first indoor fan drive section
300: second indoor unit 310: second indoor unit electric power supply unit
315: second input unit 320: second indoor unit sensing unit
330: AC relay unit 340: second indoor control unit
360: second display portion 370: second indoor fan driving portion

Claims (18)

A diagnosis control method of a multi-type air conditioner including an outdoor unit, a first indoor unit for performing bidirectional communication with the outdoor unit, and a second indoor unit for transmitting a unidirectional AC relay signal to the outdoor unit,
Receiving a commissioning command for performing the commissioning of the second indoor unit;
Performing a first trial operation for diagnosing an assembled state of the multi-type air conditioner during a first predetermined reference time while the second indoor unit blows air into the air-conditioned space;
Performing a second test operation in which the outdoor unit receives the AC relay signal from the second indoor unit and drives the compressor provided in the outdoor unit to circulate the refrigerant to determine whether the refrigerant is normally supplied to the second indoor unit;
Performing the determination that the second indoor unit determines the commissioning result of the second indoor unit as pass or fail based on the first commission or the second commission;
And the first indoor unit displays the result of the trial operation. The method according to claim 1,
The first reference time may be,
And the temperature of the second heat exchanger provided in the second indoor unit is saturated to the temperature of the air conditioning space. The method according to claim 1,
The above-
And starting operation of blowing air in the first commissioning step and continuing operation until the commencement of the commissioning. The method according to claim 1,
Performing the first commissioning comprises:
Further comprising determining that the trial operation result is " failed " when an abnormality is found in at least one of the components, and setting the AC relay signal of the second indoor unit to OFF. The method according to claim 1,
Performing the first commissioning comprises:
And if the assembled state of the parts is normal, entering the second commissioning step after the predetermined first reference time elapses. The method according to claim 1,
Wherein the second ventilation start time of the first indoor unit and the second ventilation start time of the second indoor unit are the same. The method according to claim 1,
Wherein the second test-
Check the number of indoor units currently commissioned;
Opening the electronic expansion valve by opening the electronic expansion valve corresponding to the number of the indoor units to be tested;
Further comprising operating the compressor at an operating frequency corresponding to the number of indoor units to be commissioned. 8. The method of claim 7,
To confirm the number of indoor units that are currently running the test,
And confirming the number of indoor units currently being operated on the basis of the communication signal received from the first indoor unit or the AC relay signal received from the second indoor unit by the outdoor unit. The method according to claim 1,
Performing the determination based on the second commissioning comprises:
Further comprising: dividing the compressor into a plurality of temperature regions according to a second room temperature before the compressor is operated; and setting the test run determination criterion differently according to each temperature region. 10. The method of claim 9,
When the second room temperature before the operation of the compressor is equal to or lower than a preset first room temperature boundary value,
And determining that the commissioning result of the second indoor unit is " acceptable ". 10. The method of claim 9,
If the second room temperature before the compressor is above the first room temperature boundary value and below the second room temperature boundary value,
Further comprising determining that the commissioning result is " passed " when the value obtained by subtracting the second heat exchanger temperature immediately before the determination from the second room temperature immediately before the determination is greater than the first reference temperature. 12. The method of claim 11,
When the value obtained by subtracting the second heat exchanger temperature immediately before the determination from the second room temperature immediately before the determination is greater than the first reference temperature,
And determining that the trial operation result of the second indoor unit is " acceptable " if the temperature of the second heat exchanger immediately before the determination exceeds the third reference temperature. 10. The method of claim 9,
When the second room temperature before the compressor is operated exceeds the second room temperature boundary value,
Further comprising determining that the commissioning result is " passed " when the value obtained by subtracting the second heat exchanger temperature immediately before the determination from the second room temperature immediately before the determination is greater than the second reference temperature. 14. The method of claim 13,
When the value obtained by subtracting the second heat exchanger temperature immediately before the determination from the second room temperature immediately before the determination is greater than the second reference temperature,
And determining that the trial operation result of the second indoor unit is " acceptable " if the temperature of the second heat exchanger immediately before the determination exceeds the fourth reference temperature. The method according to claim 1,
Performing the determination may comprise:
If the commissioning result is " passed "
Continuously operating the second indoor unit up to a third reference time which is a time at which the determination of the first indoor unit is completed;
Further comprising setting the AC relay to ON after the third reference time elapses. The method according to claim 1,
Performing the determination may comprise:
If the commissioning result is " passed "
Detecting a second heat exchanger temperature after the commissioning determination;
Further comprising setting the AC relay to ON if the second heat exchanger temperature after the commissioning determination is greater than the " second heat exchanger temperature measured before determination " + fifth reference temperature " Control method. The method according to claim 1,
Performing the determination may comprise:
Further comprising setting the AC relay to OFF when the trial operation result is " failed ". The method according to claim 1,
The display of the commissioning result
The outdoor unit receives an AC relay signal from the second indoor unit;
The outdoor unit communicates the commissioning result to the first indoor unit according to the AC relay signal;
And the first indoor unit displays the result of the trial operation.

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