KR101816307B1 - Control method for air conditioning apparatus - Google Patents

Abstract

A method of controlling an air conditioner according to an embodiment of the present invention includes: executing an indoor unit control application installed in a portable terminal; Displaying a corresponding indoor unit on a display unit of the portable terminal by a photographing unit built in the portable terminal; Setting a wind direction and / or a wind condition of a corresponding indoor unit displayed on the display unit according to a movement of the portable terminal; The set wind direction and / or wind condition is transmitted to the indoor unit; And the operation of the indoor unit is performed according to the wind direction and / or the wind condition.

Description

[0001] The present invention relates to a control method for an air conditioning apparatus,

The present invention relates to a control method of an air conditioner.

Generally, an air conditioner is a household appliance that supplies hot air or cold air to an indoor space by operation of a refrigerant cycle.

In recent years, a large number of portable terminals capable of accessing the Internet as well as a smart phone, downloading a document, a game program, a document file, and the like can be freely executed and a telephone conversation is possible.

In recent years, a home network system capable of controlling the operation of electric appliances including household appliances installed in a home using a portable terminal has been widely used in newly-built apartments or general households.

As described above, remote control can be performed from a remote place without directly operating various home appliances including the air conditioner, and the usability is greatly improved.

An object of the present invention is to provide an air conditioner control method for remotely controlling an indoor unit of an air conditioner by using a portable terminal such as a smart phone.

In particular, it is an object of the present invention to provide an air conditioner control method capable of checking an airflow of an indoor unit in an augmented reality realized in a portable terminal and controlling an airflow (a wind direction) by the movement of the portable terminal.

Another object of the present invention is to provide an air conditioner control method capable of controlling the amount of airflow by the movement of the portable terminal.

According to another aspect of the present invention, there is provided a method of controlling an air conditioner, including: executing an indoor unit control application installed in a portable terminal; Displaying a corresponding indoor unit on a display unit of the portable terminal by a photographing unit built in the portable terminal; Setting a wind direction and / or a wind condition of a corresponding indoor unit displayed on the display unit according to a movement of the portable terminal; The set wind direction and / or wind condition is transmitted to the indoor unit; And the operation of the indoor unit is performed according to the wind direction and / or the wind condition.

The control method of the air conditioner according to the embodiment of the present invention configured as described above has the following effects.

First, there is an advantage that the operation control can be performed using a portable terminal even when the wireless remote controller for entering the operating condition of the air conditioner is lost or damaged.

Second, since wireless communication methods such as Wi-Fi, Bluetooth, and Zigbee can be used, the range of remote control is widened and the convenience of use is increased.

Third, there is an advantage that the loss of the portable terminal is low. That is, when the portable terminal can not be found, there is an advantage that the position of the portable terminal can be immediately checked by calling the portable terminal.

Fourth, since the control can be performed using the portable terminal, there is an advantage that the inconvenience of periodically replacing the battery of the remote controller is solved.

Fifth, it is possible to visually confirm the airflow phenomenon of the indoor unit by using the augmented reality, and the airflow can be easily changed based on the confirmed result.

Sixth, since the wind direction and wind amount can be controlled only by tilting the portable terminal, the ease of use is increased.

1 is a system diagram schematically illustrating a network system according to an embodiment of the present invention.
BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a portable terminal, a portable terminal, and a smart meter.
3 is a diagram illustrating a method of recognizing a corresponding indoor unit using an augmented reality screen provided in an indoor unit control application;
4 is a view showing a screen in a state where a synchronization operation between the portable terminal and the indoor unit is completed;
FIGS. 5 and 6 are diagrams showing a manner in which a wind direction or a wind amount is set by tilting the portable terminal. FIG.
7 is a flowchart illustrating a method of controlling an indoor unit according to an embodiment of the present invention.
8 is a flowchart illustrating a method of controlling an indoor unit according to another embodiment of the present invention.
9 to 12 are diagrams showing contents of a notification signal output based on information transmitted from a smart meter.

Hereinafter, a configuration of a network system including an air conditioner according to an embodiment of the present invention, and a method of operating a system, that is, a method of controlling an air conditioner will be described in detail with reference to drawings and flowcharts.

1 is a system diagram schematically illustrating a network system according to an embodiment of the present invention.

1, a network system according to an embodiment of the present invention includes an indoor unit 10 of an air conditioner that supplies cold air or warm air to a room, and a smart phone capable of wireless communication with the indoor unit 10 And a wireless router (1) and / or a wireless router (2) for enabling internet communication with the portable terminal (20) and the indoor unit (10). And may further include a computer connected to the wire / wireless router 1 by wire or wirelessly. The network system may further include a smart meter 30 for transmitting power consumption information to the indoor unit 10 and / or the portable terminal 20. Here, the power consumption information includes information on a rate per unit watt of power supplied to the house indoors, information on the amount of power currently consumed, and information on whether or not the currently consumed amount of power has reached a set peak value Information, and the like. In addition, it can include all energy information related to smart grid.

In detail, the portable terminal 20 and the indoor unit 10 may include a communication module for wireless communication. The communication module may include a Bluetooth module, a WiFi module, a ZigBee module, and the like. Of course, the smart meter 30 may also be equipped with the wireless communication module described above to enable wireless communication with the portable terminal 20 and the indoor unit 10. Also, the indoor unit 10 may be connected to the indoor unit 10 so as to be capable of wired communication using power line communication (PLC).

Meanwhile, the indoor unit 10 may be equipped with a camera 12 for photographing the face of the user and a voice recorder 11 for recording voice of the user. Of course, the portable terminal 20 may also include a camera and a sound recorder.

The portable terminal 20 is capable of one-to-one communication with the indoor unit 10 through the communication module for wireless communication. Accordingly, the user can input the operation condition through the control panel mounted on the indoor unit 10 or input the operation condition through the portable terminal 20. [ When the operation condition is inputted through the portable terminal 20, the inputted operation condition is transmitted to the indoor unit 10 through the communication module, and the speed or direction of the indoor fan is adjusted according to the transmitted operation condition The angle of the device 13 is set or changed.

FIG. 2 is a block diagram illustrating the configuration of a portable terminal, an indoor unit, and a smart meter capable of mutual wireless communication among network systems according to an embodiment of the present invention.

Referring to FIG. 2, the portable terminal 20 that constitutes the network system according to the embodiment of the present invention includes a smart phone or a tablet PC that has been recently launched.

In detail, the portable terminal 20 includes a controller 200, a key input unit 210 for inputting specific commands and information to the controller 200, and a controller 210 for controlling the state of the portable terminal 20, A voice input unit 230 for inputting voice of the user, a voice output unit 240 for outputting the voice recorded by the user, An angular velocity sensor 260 and an acceleration sensor 270 for sensing the movement of the portable terminal 20 and a communication module 280 for wireless communication with the indoor unit 10. [ A GPS module 290 for confirming the position of the portable terminal 20, and a memory 295 for storing various information and data. The portable terminal 20 includes a recently introduced smart phone and includes a portable terminal capable of a call function, an internet connection, a program download function, and a one-to-one wireless communication.

In detail, the key input unit 210 includes an input button or a touch panel included in the portable terminal 20, the photographing unit 250 includes a camera mounted on the portable terminal 20, The input unit 230 includes a sound recorder mounted on the portable terminal 20 and the sound output unit 230 includes a speaker mounted on the portable terminal 20.

The angular velocity sensor 260 includes a gyro sensor or a gravity sensor for sensing the inclination or the rotation angle of the portable terminal 20. The acceleration sensor 270 senses a speed or an acceleration of the portable terminal 20 in a specific direction.

In addition, the communication module 280 includes Bluetooth, Wi-Fi, and ZigBee as described above. The display unit 220 includes a liquid crystal panel included in the portable terminal 20.

The indoor unit 10 includes a control unit 100, a key input unit 110, an audio input unit 130 and an audio output unit 140, a photographing unit 150, a display unit 120, A communication module 180 and a memory 170. Fig. The air conditioner further includes a driving unit 160 for driving the fan 161, the compressor 162 and the wind direction adjusting unit 163 mounted on the indoor unit 10. The driving unit 160 drives the fan 161, The compressor 162 and the motor drive for controlling the amount of electric current supplied to the drive motor for driving the wind direction adjuster 163.

Since the photographing unit 150, the voice input unit 130 and the voice output unit 140, the display module 120 and the communication module 180 are the same as those provided in the portable terminal 20, Duplicate descriptions are omitted.

As shown in the figure, the portable terminal 20 and the indoor unit 10 can independently receive information from the Internet or exchange information with each other through the communication modules 280 and 180 installed in the indoor units. That is, the weather information or the product information of the indoor unit can be downloaded to the Internet through the communication module 280 of the portable terminal 20. The indoor unit 10 can also be connected to the Internet through the communication module 180. [ The portable terminal 20 can be connected to the Internet through an access point (Wi-Fi communication) using the wireless router (wireless router) 1 or the wireless router 2 as an intermediary, (10). This is called Infrastructure Networking.

Also, the portable terminal 20 and the indoor unit 10 can perform peer-to-peer communication by using the communication modules 180 and 280. For example, when the communication modules 180 and 1280 are WiFi modules, direct communication can be performed without passing through a wireless router through WiFi-Direct networking or Ad-Hoc networking.

In detail, Wi-Fi direct refers to a technology capable of communicating at a high speed using a communication standard such as 802.11a, b, g, or n regardless of the installation of a wireless LAN access point (AP). That is, the portable terminal 20 and the indoor unit 10 can communicate wirelessly without passing through a wireless LAN access point (wireless router or wireless router described above). This technology has recently attracted a great deal of attention as a communication technology for wirelessly connecting the indoor unit 10 and the portable terminal 20 via wireless without an internet network.

The ad-hoc network (or the ad-hoc mode) is a network that does not have a fixed wired network and communicates only with a mobile host. Since there is no restriction on the movement of the host and no wired network and a base station are needed, This is inexpensive. That is, even if there is no wireless LAN access point (AP), wireless communication is enabled during the terminal period. Therefore, in the ad-hoc mode, the portable terminal 20 and the indoor unit 10 can communicate wirelessly even without the wireless LAN connection device.

Bluetooth communication is a widely known short range wireless communication method in which a pairing process is performed between a Bluetooth module built in the portable terminal 20 and a Bluetooth module built in the indoor unit 10, This is possible.

Like the Bluetooth communication, one-to-one wireless communication using ZigBee pairing is also possible.

Of course, the smart meter 30 can exchange data with the portable terminal 20 or the indoor unit 10 through the wireless communication method as described above.

Hereinafter, the augmented reality provided in the portable terminal 20 is used to recognize the corresponding indoor unit 10 so that the recognized wind direction (air flow) of the indoor unit 10 is visually expressed, and the operation of the portable terminal 20 A method for changing the air volume and the air volume by tilting or linearly moving the portable terminal will be described in detail with reference to the drawings.

To this end, the portable terminal 20 is provided with an augmented reality screen, and an indoor unit control application for controlling the wind direction and the wind amount of the indoor unit 10 by only moving the portable terminal 20 is installed.

The indoor unit 10 and the portable terminal 20 should be configured to have a Bluetooth pairing, a ZigBee pairing, an ad-hoc network, or a Wi-Fi direct network before establishing and executing the indoor unit control application. For example, the Bluetooth pairing is performed in the setting mode of the portable terminal 20, and the serial number or the password of the Bluetooth communication module built in the indoor unit 10 is inputted. Then, the list of the paired indoor units 10 is stored in the portable terminal 20, and a state in which bidirectional communication is possible is maintained.

3 is a diagram illustrating a method of recognizing a corresponding indoor unit using an augmented reality screen provided in an indoor unit control application.

3, when the indoor unit control application installed in the portable terminal 20 is executed, the augmented reality screen as shown in the display unit 220 of the portable terminal 20 and the frame 21 for receiving the indoor unit Is displayed. Here, the augmented reality screen may be a photographing unit 250 built in the portable terminal 20, that is, an actual indoor screen photographed by the camera, or may be stored in the memory 275 of the portable terminal 20 It may be an imaginary space image.

The inside of the frame 21 is provided in an empty form and the photographing unit 250 is turned on so that the state of the indoor unit 10 enters the frame 21. [ When the indoor unit 10 enters the frame 21, the portable terminal 20 recognizes the specific indoor unit 10 that has entered the frame 21. [ Various methods can be used to allow the portable terminal 20 to recognize the indoor unit 10 using the augmented reality screen.

For example, an identifier for recognizing a target object such as a QR code or a bar code is attached to the front surface of the indoor unit 10, and the identifier is photographed by the photographing unit 250. The control unit of the portable terminal 20 may decode or interpret the photographed image information so that the indoor unit 10 can be recognized. The portable terminal 20 can recognize the indoor unit 10 that has entered the frame 21 by using various methods and these ideas are all included in the scope of the present invention.

Specifically, when the indoor unit control application is executed, pop-up information indicating that the position of the indoor unit is aligned with the frame 21 can be displayed. When the indoor unit 10 enters the frame 21, the indoor unit 10 is photographed and the image of the photographed indoor unit 10 is left while the frame 21 disappears.

When the indoor unit control application is executed, the portable terminal 20 uploads a list of indoor units registered as a communication target to the control unit of the portable terminal 20 through a pairing process or the like. The uploaded registered indoor unit 10 information may be displayed on the display unit 220 of the portable terminal 20 or may not be displayed externally. When the indoor unit 10 received in the frame 21 is recognized, the indoor unit 10 and the portable terminal are wirelessly connected through the operation matching the information registered in the list. At the same time, synchronization with the indoor unit 10 is performed.

4 is a view showing a screen in a state where a synchronization operation between the portable terminal and the indoor unit is completed.

4, when synchronization is established between the portable terminal 20 and the indoor unit 10, the operation information of the indoor unit 10 is transmitted to the portable terminal 20, and based on the transmitted information, Or the wind direction information is displayed on the display unit 220 in the form of an image.

In detail, the display unit 220 of the portable terminal 20 may display the information on the wind volume and the wind direction in a dot pattern of a specific color. For example, the number of points to be displayed may be determined according to the air flow rate, and the point may be displayed on either the left or right side depending on the wind direction.

5 and 6 are views showing a manner of setting a wind direction or a wind amount by tilting the portable terminal.

5, the augmented reality screen is displayed on the display unit 220, and the wind direction can be determined by operating the portable terminal 20 in a state where the wind amount and the wind direction image are displayed on the augmented reality screen.

For example, as shown in the drawing, the left deflection angle is determined according to the inclination angle of the portable terminal 20 when tilted to the left, and at the same time, the number of points indicating the wind direction increases to the left side and decreases to the right side .

Conversely, when the portable terminal 20 is tilted to the right, the wind direction and the wind direction image will be reversed.

Referring to FIG. 6, it is possible to set the overturning direction through the operation of tilting the portable terminal 20 forward, and to set the overturning direction through the backward tilting operation.

As described above, when the portable terminal 20 is tilted, the angular velocity sensor 260 incorporated in the portable terminal 20 operates to detect the tilt angle, and the wind direction is determined according to the sensed result value.

When the wind direction is set together with the wind direction setting, the portable terminal 20 is linearly moved in a specific direction so that the acceleration sensor 270 incorporated in the portable terminal 20 is operated.

For example, if the air flow rate is to be increased, the portable terminal 20 may be moved forward at a predetermined speed while tilting the portable terminal 20 in a specific direction so that the acceleration sensor 270 senses the moving speed of the portable terminal 20 have. Conversely, if the air volume is to be reduced, the portable terminal 20 can be moved backward.

The memory 295 of the portable terminal 20 stores a rotation direction and an angle value of the wind direction adjusting device corresponding to the tilting direction and angle detected by the angular velocity sensor 260, The air volume corresponding to the sensed acceleration value and the fan rotation speed value corresponding to the air volume can be stored in the form of a look-up table.

Also, in the memory of the indoor unit 10, the rotation direction and angle of the wind direction adjusting device corresponding to the tilting direction and angle detected by the angular velocity sensor 260, the air flow rate corresponding to the acceleration value, The rotational speed value of the fan can be stored in the form of a look-up table.

7 is a flowchart illustrating a method of controlling an indoor unit according to an embodiment of the present invention.

Referring to FIG. 7, in this embodiment, the method of adjusting the wind direction and the wind amount using the portable terminal 20 described above is summarized in a time-series manner.

First, when the indoor unit control application is executed (S11), the photographing unit 250 built in the portable terminal 20 is turned on (S12). When an augmented reality screen in which a frame is displayed is output to the display unit 220 of the portable terminal 20 and the corresponding indoor unit 10 is aligned within the frame, At the same time, the synchronization operation is performed (S13). This is the same as described above. Of course, it is assumed that the portable terminal 20 is registered as a communicable object through a one-to-one wireless communication network setting process between the portable terminal 20 and the indoor unit before the recognition and synchronization of the indoor unit.

On the other hand, when the synchronization operation is completed, the operation state of the corresponding indoor unit 10 is displayed on the augmented reality screen in an image form (S14). That is, the current operation information on the wind direction and the wind amount is displayed in an image form on the screen.

In this state, the portable terminal 20 is operated by the user (S15), and the angular velocity sensor and the acceleration sensor operate accordingly to detect the tilting direction, the tilting angle, and the moving speed of the portable terminal 20 S16). Then, the wind direction and wind amount conditions corresponding to the sensed result value are selected (S17). Then, the operation conditions of the wind direction and the air flow rate are transmitted from the portable terminal 20 to the indoor unit 10 (S18), and the operation of the indoor unit is started or changed according to the transmitted operation conditions (S19). At the same time, an image matching the changed wind direction and air volume is displayed on the augmented reality screen (S20).

In addition, there are two ways in which the selected operating conditions are transmitted. First, the operating condition determined by the operation of the portable terminal 20 is converted into an electric signal by the control unit of the portable terminal 20, and the converted electric signal can be transmitted to the control unit of the indoor unit 10. That is, the rotation angle of the air conditioner corresponding to the selected fan speed value and the rotation speed of the indoor fan corresponding to the selected air flow rate value is calculated, and the calculated rotation speed of the indoor fan and the current supply Lt; / RTI > is generated. Then, the generated electric signal is transmitted to the controller of the indoor unit 10 through the wireless communication module.

In the second method, the operation condition determined by the operation of the portable terminal 20 is transmitted to the control unit of the indoor unit 10, and then the control unit of the indoor unit 10 converts the operation condition into the electric signal. That is, the control unit of the portable terminal 20 calculates only the wind direction and air amount values corresponding to the selected operation conditions, and transmits the calculated wind direction and air amount values to the control unit of the indoor unit 10. [ The control unit of the indoor unit 10 calculates the rotation speed of the indoor fan and the rotation angle of the air conditioner corresponding to the transmitted wind direction and air amount value and generates an electric signal corresponding to the calculated rotation speed and rotation angle So that the indoor fan and the wind direction adjusting device can be driven.

1 and 2, the smart meter 30, which provides the amount of electric power and electric power charge information supplied indoors, is connected to the portable terminal 20 or the indoor unit 10 To be wirelessly connected. Thus, the indoor unit 10 can be economically operated according to the current power consumption amount and the current power cost. That is, when the user selects a desired air volume condition by shaking the portable terminal 20 and it is determined that it is necessary to control power consumption in the middle of the operation of the indoor unit 10 with the selected air volume, The operating state of the engine 10 can be controlled. Hereinafter, this control method will be described in detail with reference to a flowchart.

8 is a flowchart showing a method of controlling an indoor unit according to another embodiment of the present invention.

Referring to FIG. 8, in this embodiment, as a parameter for setting the operating condition of the indoor unit 10, in addition to the operating conditions calculated by the operation of the portable terminal 20, the power consumption information transmitted from the smart meter Is added.

In detail, the portable terminal 20 receives power consumption information from the smart meter 30 in a state where the indoor unit 10 is operating (S30) according to the control method described with reference to FIG. 7 (S31). The power consumption information includes a power rate per unit wattage at the present time, an amount of power consumption at the current time, an electricity rate for the amount of power consumption, and a maximum allowable power consumption amount set by the user. The maximum allowable power consumption is defined and explained as a peak value of the power consumption below.

On the other hand, based on the power consumption information transmitted from the smart meter 30, a notification signal indicating the current power consumption of the indoor unit is output through the portable terminal 20 or the indoor unit 10 (S32). Here, the notification signal is a notification signal that notifies the user of the situation when the current power consumption per unit watt is at or near the peak value at the present time when the indoor unit 10 is operating, May refer to an alarm signal to guide the driver to change the operating state.

The method of displaying the notification signal on the portable terminal 20 or the indoor unit 10 may be a method of displaying a warning sound or a warning light or a character or an avatar on the screen of the portable terminal 20 or the indoor unit 10 .

A message is displayed on the display unit, that is, the screen of the portable terminal 20 or the indoor unit 10, to confirm whether or not to approve any requirements presented through the notification signal. Then, a process of determining whether the requirement is approved by the user is performed (S33).

In detail, when the user approves or selects the requirement or inquiry for the notification signal, the operating condition of the indoor unit 10 is changed to the approved contents (S34). On the other hand, if the notification signal is not accepted, the previously input operation condition is maintained or the indoor unit is automatically stopped (S35). The type of the notification signal will be described below again.

In this way, when the information transmitted from the smart meter 30 is used as an additional parameter, the indoor unit 10 can be economically operated, and as a result, power consumption can be reduced.

9 to 12 are views showing contents of a notification signal output based on information transmitted from a smart meter.

9 is a signal for notifying the current consumption power amount when the current consumption amount is adjacent to or exceeding the peak value set by the user and requesting to change the operating condition of the indoor unit 10. [

The notification signal is outputted to the screen of the portable terminal 20 or the indoor unit 10, and when the approval is made by the user, the indoor unit operation is terminated. On the contrary, if the user does not approve the operation, the operation status of the indoor unit is maintained.

10 is a signal requesting to change the indoor unit operation condition in a section where the current time is the highest power rate per unit of wattage.

As shown in the figure, the indoor unit operation can be requested to be terminated in the section where the electric power charge per unit wattage is the highest, and when the user approves the operation, the indoor unit operation is terminated.

11, when the current power consumption amount reaches or exceeds the peak value, or when the current power fee per unit watt is the highest, the operation state of the indoor unit 10 with the low power consumption operation condition To be changed.

 If the request is approved by the user, the operation state is changed to the recommended operation mode presented by the controller of the portable terminal 20 or the indoor unit 10, and if the approval is not made, the previous operation state is maintained.

12 is a signal for forcibly stopping the operation of the indoor unit 10 by the control unit of the portable terminal 20 or the indoor unit 10, rather than being selected by the user.

That is, when the current power consumption reaches or exceeds the peak value, or when the current time is in the interval where the power charge per unit wattage is the highest, the operation of the indoor unit is forced to be ended regardless of the intention of the user. In this case, the process of confirming whether or not the user is authorized is unnecessary. In FIG. 8, the indoor unit 10 is automatically stopped when the notification signal is output.

Claims (20)

Executing an indoor unit control application installed in the portable terminal;
Displaying an indoor space image captured by a photographing unit built in the portable terminal and a frame for recognizing the indoor unit on a display unit of the portable terminal;
Photographing the indoor unit by operation of the photographing unit when the indoor unit is located within the frame;
A step of recognizing the indoor unit from image information of the indoor unit photographed;
Synchronizing the recognized indoor unit and the portable terminal;
The current wind direction and air volume information of the indoor unit transmitted to the portable terminal by the synchronization operation is displayed on the display unit as a dot image of a specific color;
Setting a wind direction and a wind amount condition of the corresponding indoor unit displayed on the display unit according to the movement of the portable terminal;
The set wind direction and air condition conditions are transmitted to the indoor unit;
Changing the operation of the indoor unit according to the transmitted wind direction and air condition; And
And changing the point image of the specific color according to the wind direction and air volume information of the indoor unit to be changed,
The dot image of the specific color may be,
Wherein the number is increased or decreased according to the air flow rate, and is displayed so as to be biased in a certain direction according to the air flow direction.
The method according to claim 1,
Wherein the portable terminal and the indoor unit are connected to each other in a one-to-one wireless communication manner before the execution of the indoor unit control application. 3. The method of claim 2,
Wherein the one-to-one wireless communication is performed by one of Bluetooth pairing, ZigBee pairing, Wi-Fi direct networking, and ad-hoc networking. The method according to claim 1,
Wherein the screen displayed on the display unit comprises:
Further comprising a space image stored in advance in the portable terminal. The method according to claim 1,
Wherein the photographed indoor unit image is combined with the indoor space image. The method according to claim 1,
Wherein the step of recognizing the indoor unit from the photographed image information of the indoor unit recognizes an identifier attached to the indoor unit in the image information of the indoor unit.
The method according to claim 6,
Wherein the identifier comprises a bar code and a QR code.
delete The method according to claim 1,
Wherein the step of setting the wind direction and air condition conditions of the indoor unit comprises:
And detecting an inclination direction and an angle by an angular velocity sensor built in the portable terminal when the tilting operation of the portable terminal is performed. 10. The method of claim 9,
Wherein the step of setting the wind direction and air condition conditions of the indoor unit comprises:
And detecting a moving direction and a speed by an acceleration sensor built in the portable terminal according to movement of the portable terminal. 11. The method of claim 10,
A wind direction is determined by a tilting direction and an angle detected by the angular velocity sensor,
Wherein the air flow rate is determined by the moving speed detected by the acceleration sensor. 12. The method of claim 11,
In the memory of the portable terminal or the indoor unit,
A rotation angle of the wind direction adjusting device corresponding to a value sensed by the angular velocity sensor,
An air volume corresponding to a value sensed by the acceleration sensor and
Wherein the rotation speed value of the fan corresponding to the air flow rate is stored in the form of a look-up table. The method according to claim 1,
Wherein the set air volume condition is transmitted to the indoor unit,
An operation condition corresponding to the set air flow condition is converted into an electric signal in the portable terminal,
And the converted electric signal is transmitted to the control unit of the indoor unit. The method according to claim 1,
Wherein the set air volume condition is transmitted to the indoor unit,
An operating condition corresponding to the set air flow condition is transmitted from the portable terminal to the indoor unit,
Wherein the control unit of the indoor unit converts the operation condition into an electric signal. The method according to claim 1,
Further comprising receiving power information from the smart meter, the power information including at least one of a power consumption amount, a power rate per watt, and a power consumption peak value to the indoor unit or the portable terminal. 16. The method of claim 15,
Further comprising the step of generating a notification signal for requesting permission to change the air condition condition based on the received power information. 17. The method of claim 16,
And the operation of the indoor unit is automatically stopped after the notification signal is generated. 17. The method of claim 16,
The approval signal is issued to the notification signal, and the operating state of the air conditioner is changed according to the approval. 17. The method of claim 16,
Wherein the operation state of the indoor unit is maintained according to the air condition condition if the notification signal is not approved. 17. The method of claim 16,
The notification signal includes:
Wherein the air conditioner comprises at least one of a sound, a light, a character, and an avatar.

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