KR102550356B1 - Air-conditioner and Method thereof - Google Patents

Abstract

The present invention relates to an air conditioner and a method for controlling the same, wherein a control menu for discharge ports is provided through a controller connected to the air conditioner, so that the operation of the indoor unit is controlled through the controller, and a plurality of discharge ports provided in the indoor unit are provided. , it can be easily individually controlled according to the user's choice, and by determining the user's position and aligning the position of the vane displayed according to the user's position, the position of the vane displayed on the screen and the vane actually controlled There is an effect of improving user convenience by making the positions the same.

Description

Air conditioner and control method thereof {Air-conditioner and Method thereof}

The present invention relates to an air conditioner and a control method thereof, and relates to an air conditioner that selectively controls a plurality of outlets for discharging cold and hot air into a room, and a control method thereof.

Air conditioners are installed to provide a more comfortable indoor environment to humans by discharging cold and hot air into the room to adjust the indoor temperature and to purify the indoor air to create a comfortable indoor environment. In general, an air conditioner includes an indoor unit configured as a heat exchanger and installed indoors, and an outdoor unit configured as a compressor and a heat exchanger to supply refrigerant to the indoor unit.

The air conditioner is controlled by separating the indoor unit composed of a heat exchanger and the outdoor unit composed of a compressor and heat exchanger. The refrigerant heat-exchanged in the heat exchanger of the indoor unit flows back into the compressor of the outdoor unit through the refrigerant pipe. Accordingly, the indoor unit discharges hot and cold air into the room through heat exchange using a refrigerant.

Such an air conditioner has a plurality of outlets and discharges hot and cold air in a plurality of directions.

The air discharged through the outlet is controlled by setting the wind direction and air volume. In general, these settings are uniformly applied to a plurality of discharge ports.

Air discharged from the plurality of outlets is controlled in the same setting regardless of the user's location or user's request, and there is a problem that cannot be individually controlled.

Correspondingly, a plurality of outlets are controlled through a wired remote control, etc., but even when such a menu is provided, the user cannot easily recognize the individual control of the outlet, and the menu configuration is complicated, so that one of the plurality of outlets There is a problem in that it is not practically used because of the inconvenience of operation until the setting is changed by selecting .

An object of the present invention relates to an air conditioner and a control method thereof, in which at least one discharge port is selected and individually controlled for a plurality of outlets for discharging cold and hot air into a room, and a control method thereof.

An air conditioner according to the present invention includes an indoor unit that controls a direction of discharged air by controlling a plurality of vanes installed at a plurality of discharge ports; and a controller connected to the indoor unit to set operation of the indoor unit and an opening angle of the vanes, wherein the controller outputs a control screen for setting opening angles of the plurality of vanes and determines a user's position. Thus, the position of the vane is aligned so that the plurality of vane images displayed on the control screen and the position of the vane coincide.
When a direction finding key is selected, the controller controls a first vane among the plurality of vanes to operate, and when one of the plurality of vane images displayed on the control screen is selected, the selected vane image is displayed as the first vane. and automatically aligning the positions of the plurality of vane images displayed on the control screen.
In the control method of an air conditioner according to the present invention, a plurality of vane images corresponding to a plurality of vanes installed at a plurality of outlets of the indoor unit are included on a screen of a controller for setting the operation setting of the indoor unit and the opening angle of the vanes. displaying the control screen; operating a first vane among the plurality of vanes when a direction finding key is selected; selecting one of the plurality of vane images; matching the selected vane image to the first vane; and a system for arranging and displaying the positions of the plurality of vane images displayed on the control screen.

The air conditioner and its control method according to the present invention configured as described above provides a control menu for the outlet of the indoor unit through a controller connected to the indoor unit, and can conveniently individually control a plurality of outlets according to selection. By determining the position of the vane and aligning the position of the vane displayed according to the user's position, the position of the vane displayed on the screen and the position of the vane actually controlled are the same, thereby improving user convenience.

1 is a diagram showing the configuration of an air conditioner including a controller according to an embodiment of the present invention.
2 is an exemplary view showing an installation example of an indoor unit and a controller installed in an indoor space.
3A is a block diagram showing the configuration of the indoor unit of FIG. 1 according to an embodiment of the present invention.
Figure 3b is a block diagram showing the configuration of the controller of Figure 1 according to an embodiment of the present invention.
4 is a block diagram showing a configuration for controlling an indoor unit by a controller according to an embodiment of the present invention.
5 is a reference diagram for explaining a control screen of a controller according to an embodiment of the present invention.
6 is a diagram referenced to describe a main screen among control screens of a controller according to an embodiment of the present invention.
7 is a diagram referenced to describe a discharge outlet setting screen among control screens of a controller according to an embodiment of the present invention.
8 is a reference diagram for explaining a direction finding screen for aligning the location of a discharge port among discharge port setting screens of a controller according to an embodiment of the present invention.
9 is a diagram referenced to describe a method for aligning the position of an outlet of a controller according to an embodiment of the present invention.
10 is a flowchart referenced to explain a method for controlling an outlet of an air conditioner according to an embodiment of the present invention.

Advantages and features of the present invention, and methods of achieving them, will become clear with reference to the detailed description of the following embodiments taken in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be implemented in various different forms, and only these embodiments make the disclosure of the present invention complete, and common knowledge in the art to which the present invention belongs. It is provided to completely inform the person who has the scope of the invention, and the present invention is only defined by the scope of the claims. Like reference numbers designate like elements throughout the specification.

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

1 is a diagram showing the configuration of an air conditioner including a controller according to an embodiment of the present invention.

As shown in FIG. 1, the air conditioner includes a plurality of indoor units 20 (21 to 26), at least one outdoor unit 10, and a plurality of remote controllers 30 (31 to 36) respectively connected to the plurality of indoor units. , and a central controller 50 connected to the plurality of indoor units 20 and the outdoor unit 10 to control and monitor their operations.

In addition, the air conditioner includes a controller 80 that controls the indoor unit by transmitting and receiving data to and from the indoor unit.

The central controller 50 controls the operation of the plurality of indoor units 20 and the outdoor unit 10 in response to input user commands, and periodically receives and stores corresponding data on the operation states of the plurality of indoor units and outdoor units. and outputs the operating status through the monitoring screen.

The central controller 50 is connected to the plurality of indoor units 20 to perform operation setting, lock setting, schedule control, group control, peak control for power use, demand control, etc. for the indoor unit. In addition, although one central controller 50 is described as an example, a plurality of central controllers may be provided and connected to each other, and in some cases may be connected through a predetermined network.

When the operation setting of the indoor unit is changed by the remote controller 30 or the controller 80, the central controller 50 receives and stores the corresponding data. In addition, when a conflict occurs in settings input through the central controller 50, the remote control 30, or the controller 80, the central controller 50 gives priority to the remote controller 30 or the controller 80, and the indoor unit and the outdoor unit can control.

The central controller 50 is connected to an external network (not shown), performs authentication for external access through the network, and processes requests through the external connection.

The remote controller 30 is connected to the indoor unit by wire or wireless communication, inputs user commands to the indoor unit, and receives and outputs data from the indoor unit. The remote controller 30 may transmit a user command to the indoor unit according to a connection method with the indoor unit, perform one-way communication without receiving data from the indoor unit, or perform bi-directional communication for transmitting and receiving data with the indoor unit.

The remote controller 30 is connected to one of a plurality of indoor units, transmits a control command to the connected indoor unit, and outputs information on the connected indoor unit. For example, the first remote controller 31 is connected to the first indoor unit 21 and the second remote controller 32 is connected to the second indoor unit 22 . In some cases, a single remote controller is connected to a plurality of indoor units, and settings of the plurality of indoor units can be changed simultaneously through a single remote controller.

The controller 80 is connected to the indoor unit by wireless communication, inputs user commands to the indoor unit, and receives and outputs data from the indoor unit.

At this time, the controller 80 may be connected to a nearby indoor unit among the plurality of indoor units according to the location of the controller. The controller may be connected to a plurality of indoor units for each of the plurality of indoor units, first to sixth indoor units. The controller 80 is basically connected to each indoor unit on a one-to-one basis, but may be connected to a plurality of indoor units at the same time. However, when transmitting/receiving data even when connected to a plurality of indoor units, the controller transmits data to one indoor unit at a time.

For example, when the controller 80 is close to the first indoor unit 21, it is connected to the first indoor unit and controls the first indoor unit, and when it is close to the sixth indoor unit 26, it can control the sixth indoor unit. . In some cases, when the first indoor unit 21 and the second indoor unit 22 are located at a short distance, the controller 80 may be connected to the first indoor unit 21 and the second indoor unit 22 at the same time. However, in this case, data is transmitted to one indoor unit at a time, and data can be transmitted by designating the transmitted indoor unit.

The controller 80 has a control program for the indoor unit installed, executes the control program according to a user input, and outputs a control screen for controlling the operation of the indoor unit.

The controller 80 transmits operation settings for the temperature, wind direction, and operation mode of the indoor unit to the indoor unit in response to a user command input through the control screen, and controls the outlet of the indoor unit.

The air conditioner will be described as including an outdoor unit 10 and an indoor unit 20 as an example, but may further include at least one unit of a ventilation unit, an air purifier, a humidifier, and a heater, and these units include an indoor unit and an outdoor unit It can operate in conjunction with the operation of

The outdoor units 10 are connected to the plurality of indoor units 20 through refrigerant pipes, and supply refrigerant to the indoor units. In addition, the outdoor unit 10 periodically communicates with a plurality of indoor units to transmit/receive mutual data, change operations according to operation settings changed from the indoor unit, and also transmits the operating state of the indoor unit to the central controller 50.

The indoor unit 20 includes an expansion valve (not shown) that expands the refrigerant supplied from the outdoor unit 10, an indoor heat exchanger (not shown) that exchanges heat with the refrigerant, and allows indoor air to flow into the indoor heat exchanger, and the heat-exchanged air flows into the room. It includes an indoor fan (not shown) for exposure, a plurality of sensors (not shown), and a control means (not shown) for controlling the operation of the indoor unit.

In addition, the indoor unit 20 includes a discharge port (not shown) for discharging heat-exchanged air, and a wind direction adjusting means (not shown) for opening and closing the discharge port and controlling the direction of the discharged air is provided in the discharge port. The indoor unit controls the intake air and the discharged air by controlling the rotational speed of the indoor fan, and adjusts the air volume. The indoor unit 20 may further include an output unit for displaying operating state and setting information of the indoor unit and an input unit for inputting setting data. At this time, the indoor unit 20 may transmit setting information for air conditioner operation to the remote controller 30, output the output through the remote controller, and receive data.

The outdoor unit 10 operates in a cooling mode or a heating mode in response to data received from the connected indoor unit 20 or a control command from the controller 50, and supplies refrigerant to the connected indoor unit.

The outdoor unit 10 includes at least one compressor (not shown) that compresses the refrigerant and discharges high-pressure gaseous refrigerant, and an accumulator (not shown) that separates gaseous refrigerant and liquid refrigerant from the refrigerant to prevent non-vaporized liquid refrigerant from entering the compressor. (not shown), an oil separator (not shown) for recovering oil from the refrigerant discharged from the compressor, an outdoor heat exchanger (not shown) for condensing or evaporating the refrigerant by heat exchange with outdoor air, and a more smooth heat exchange of the outdoor heat exchanger. An outdoor fan (not shown) that introduces air into the outdoor heat exchanger and discharges the heat-exchanged air to the outside, a four-way valve (not shown) that changes the flow path of the refrigerant according to the operation mode of the outdoor unit, and at least one that measures the pressure A pressure sensor (not shown), at least one temperature sensor (not shown) for measuring temperature, and a control component for controlling the operation of the outdoor unit and communicating with other units. The outdoor unit 10 further includes a number of other sensors, valves, supercooling devices, etc., but descriptions thereof will be omitted below.

2 is an exemplary view showing an installation example of an indoor unit and a controller installed in an indoor space.

As shown in FIG. 2 , an indoor unit having a plurality of outlets is installed in an indoor space, and a remote controller 30 is connected to the indoor unit 20 .

In addition, the controller 80 is connected to the indoor unit 20 to set the operation of the indoor unit or control the outlet. The controller 80 operates independently of the remote controller 30 and transmits a user command input to the indoor unit.

The indoor unit 20 can set priorities for the controller 80 and the remote control 30, and when control commands are input at the same time or conflicting control commands are input, either one is selected according to the preset priority. of control commands can be executed.

Although the indoor unit 20 is described as being a ceiling type as an example, it may also be applied to a wall-mounted type or a stand type equipped with a plurality of outlets.

The indoor unit 20 discharges hot and cold air in four directions including first through fourth discharge ports. The indoor unit 20 includes vanes for opening and closing the discharge ports for the first to fourth discharge ports and adjusting the direction of discharged air. The first to fourth vanes 151 to 154 are installed in the first to fourth discharge ports, respectively, to adjust the wind direction.

A suction port for sucking indoor air into the indoor unit is provided at the center of the indoor unit 20 .

The controller 80 may be a portable terminal, a tablet PC, a notebook computer, a wearable device including a watch type terminal, a dedicated controller for an air conditioner, a local controller for an air conditioner, and the like.

The controller 80 transmits a control command to the indoor unit 20 through short-range wireless communication such as infrared communication, Bluetooth, Beacon, or Zigbee, or wireless communication using Wi-Fi, WiBro, or a mobile communication network.

The controller 80 controls operation settings for the operation mode, temperature, and air volume of the indoor unit, and also controls opening and closing of a plurality of outlets provided in the indoor unit, and discharge angles.

3A is a block diagram showing the configuration of the indoor unit of FIG. 1 according to an embodiment of the present invention.

As shown in FIG. 3A, the indoor unit 20 includes a heat exchanger, a plurality of valves, and a plurality of sensors, as described above, and includes a unit communication unit 120, a unit input unit 130, and a unit output unit 140. , a vane driving unit 150, a fan driving unit 160, an indoor fan 170, a plurality of vanes 151 to 154, and a unit control unit 110 that controls overall operation of the indoor unit.

In addition, the indoor unit 20 further includes a data unit (not shown) for storing control data for driving vanes and indoor fan, communication data for communication with the outdoor unit, central controller, remote controller, and controller, and transmitted/received data.

The unit communication unit 120 communicates with other units including the outdoor unit 10 and the central controller 50 . Also, the unit communication unit 120 communicates with the remote controller 30 or the controller 80.

The unit communication unit 120 includes a plurality of communication modules and can communicate with the outdoor unit, remote controller, and controller using different communication methods.

The unit communication unit 120 receives data according to a communication method between air conditioner units, transmits data on the operating state of the indoor unit, receives a control command from the remote controller 30 or the controller 80, and controls the unit control unit 110. ) is authorized. The unit communication unit 120 includes a communication module corresponding to the communication method of the controller 80 to receive a control command of the indoor unit. Also, the unit communication unit 120 may transmit data of the indoor unit to the controller 80 .

For example, the unit communication unit 120 may exchange data with the indoor unit 20 or the outdoor unit 10 through RS 232, RS 422, or RS485 communication protocols. In addition, the unit communication unit 120 may exchange data with the indoor unit 20, the outdoor unit 10, the central controller 50, or the controller 80 through ZigBee, Wi-Fi, or Bluetooth protocols.

The unit input unit 130 includes at least one button, switch, and touch input means to input user commands or predetermined data to the indoor unit. However, when the indoor unit is a ceiling type, the unit input unit 130 is not provided, and the remote controller 30 receives data through the controller 80 .

The unit output unit 140 includes at least one of a lamp controlled to turn on or off, a speaker, and a display unit to output the operating state of the indoor unit.

The lamp outputs whether the indoor unit is in operation according to whether it is lit, the color of the lighting, or whether it is blinking, and the speaker outputs a predetermined warning sound and effect sound to output the operating state of the indoor unit. The display unit may output an operation setting or operating state of the indoor unit in a combination of at least one of letters, numbers, and images.

The indoor fan 170 discharges the cold and hot air heat-exchanged by the heat exchanger into the room through the discharge port.

The fan driver 160 controls driving of a motor that operates the indoor fan 170 . The fan driver 160 controls the on/off of the indoor fan 170 in response to the control signal of the unit controller 110 and also controls the indoor fan 170 to operate at a set speed.

The vane driving unit 150 controls opening and closing of the first to fourth vanes 151 to 154 provided in the first to fourth discharge ports in response to a control signal from the unit control unit 110 . In addition, the vane driving unit 150 controls the opening angle of each of the first to fourth vanes 151 to 154 to change the direction of discharged wind. The opening angles of the first to fourth vanes 151 to 154 are varied by the vane driver 150 to change the wind direction of the discharged air. At this time, a louver for adjusting the wind direction in the left and right directions may be further provided at each discharge port.

Each vane may have an opening angle set within a range of 0 to 90 degrees, and the opening angle is changed step by step according to the setting.

The vane driver 150 sets the opening angle of each vane step by step according to the control command of the unit control unit 110 . For example, since the vane driving unit 150 is in a closed state at 0 degree, the opening angle of the vane can be controlled in 5 steps within the range of 15 to 75 degrees in units of 15 degrees, excluding 0 degrees. The opening angle of the vane can be set from 3 to 9 steps according to settings.

In addition, when setting the swing mode, the vane driver 150 continuously changes the opening angle of the vane within a range of 15 degrees to 75 degrees without step division.

The unit controller 110 operates the indoor unit in response to data received from the remote controller 30, the controller 80, the central controller 50, and the outdoor unit 10 through the unit input unit 130 or the unit communication unit 120. is set, controls the indoor unit to discharge hot and cold air through the discharge port, and outputs the operating state of the indoor unit through the unit output unit 140.

The unit control unit 110 causes the indoor unit to operate in a designated operation mode in response to the indoor temperature and desired temperature input through the provided sensor, and applies a control signal to the indoor fan 170 to discharge air at a set air volume.

In addition, the unit control unit 110 applies a control signal to the vane driver 150 according to the set opening angle to control the opening and closing and opening angles of the first to fourth vanes.

The unit control unit 110 stores operating state data of the indoor unit in a data unit (not shown) and transmits the operating state data to other units or controllers through the unit communication unit 120 .

Figure 3b is a block diagram showing the configuration of the controller of Figure 1 according to an embodiment of the present invention.

As shown in FIG. 3B, the controller 80 includes an input unit 230, a display unit 240, a terminal communication unit 220, a data unit 250, a sensor unit (not shown), and a terminal that controls the overall operation of the controller. A control unit 210 is included.

In addition, the controller 80 includes a camera (not shown), is provided with an input/output interface for connection with an external device, and may include various other components, but a description thereof will be omitted below.

The input unit 230 includes input means such as buttons, switches, or touch pads, and generates key input data for operation control.

The display unit 240 outputs the operating state of the controller 80, outputs the operation state of the indoor unit and the connection state with the indoor unit when communicating with the indoor unit 20, and also includes a control menu for controlling the operation of the indoor unit. Display the control screen.

In displaying information processed by the controller 80, the display unit 240 displays a UI (User Interface) or GUI (Graphic User Interface) related to a function to be performed. When connected to the indoor unit 20 through the terminal communication unit 220, the display unit 240 outputs a control menu for controlling the indoor unit through a UI or GUI.

The display unit 240 may include a touch screen, and the touch screen may operate as an input unit. The touch screen is implemented by forming a mutual layer structure or integrally forming a touch sensor and a display unit, and functions as an input unit that provides an input interface between the controller 80 and the user, and at the same time provides an output interface between the controller 80 and the user. can provide In this case, the display unit 240 may include a touch sensor to receive a user command by a touch method. Using this, when a touch is made to the display unit 240, the touch sensor detects the touch, and the terminal control unit 210 can generate a control command corresponding to the touch based on this. Contents input by the touch method may be letters or numbers, or menu items that can be instructed or designated in various modes. The display unit 240 may include a liquid crystal display (LCD), a thin film transistor-liquid crystal display (TFT LCD), an organic light-emitting diode (OLED), and a flexible display. ), a 3D display, and an e-ink display.

The controller 80 may further include a speaker, a lamp, and the like as an output means, as well as a display unit, and the speaker outputs the data of the controller 80 as a predetermined sound, and outputs a warning sound or a sound effect in some cases.

The data unit 250 stores an execution program for each function of the controller 80, data for controlling the operation of the controller, and data transmitted and received through the terminal communication unit 220. Also, in the data unit 250, execution programs are stored as applications, and data according to each application is stored. In particular, applications for connecting to and controlling the indoor unit are stored in the data unit 250 .

The data unit 250 is electrically connected to the terminal control unit 210, and may be various storage devices such as ROM, RAM, EPROM, flash drive, hard drive, etc. in terms of hardware.

The sensor unit (not shown) may include a plurality of sensors to detect an object or a human body adjacent to the controller 80, detect pressure, determine the position of the controller, and detect tilt or motion of the controller.

The terminal communication unit 220 includes a communication module for the controller to connect to a predetermined network or communicate with other devices. For example, the terminal communication unit 220 includes a mobile communication module (not shown) for transmitting and receiving data by accessing a mobile communication network, a short-range communication module for communicating with a device within a predetermined distance, a wireless Internet module, a GPS module, A plurality of communication modules such as a broadcast receiving module may be further included.

The mobile communication module transmits and receives a radio signal with at least one of a base station, an external terminal, and a server on a mobile communication network. The wireless signal may include a voice call signal, a video call signal, or various types of data according to text/multimedia message transmission/reception. The short-range communication module may use Bluetooth, Radio Frequency Identification (RFID), Infrared Data Association (IrDA), Ultra Wideband (UWB), ZigBee, Beacon, or the like. Hereinafter, the short-distance communication module will be described as an example of Bluetooth.

The terminal control unit 210 executes a program stored in the data unit 250, that is, an application for controlling the indoor unit, and outputs a control screen including a control menu for controlling the indoor unit through the display unit 240, and input unit 230 It receives data from the display unit 240 and outputs it through the display unit 240, controls input and output data, and stores the data in the data unit 250.

The terminal control unit 210 transmits data on the operation setting of the indoor unit input through the control screen to the indoor unit 20 through the terminal communication unit 220, and outputs the received data of the indoor unit through the display unit 240. do.

When communicating with the initial indoor unit 20, the terminal controller 210 registers the indoor unit as a connection target through mutual authentication. The terminal controller 210 stores the information of the registered indoor unit 20 in the data unit 250, and activates the short-range communication module of the terminal communication unit 220 when the indoor unit 20 matching the stored data is located within a predetermined distance. It is connected to the indoor unit 20 through and controlled to transmit and receive data.

When there are multiple registered indoor units within a predetermined distance, the terminal control unit 210 connects the plurality of indoor units through the terminal communication unit 220, displays information on the connected indoor units through the display unit 240, and transmits data. It transmits data to one of the indoor units.

When there is a registered indoor unit within a predetermined distance, the terminal control unit 210 may configure a combination of at least one of letters, numbers, and images to output a guide according to whether or not the indoor unit is connected through the display unit 240.

In addition, when the terminal controller 210 is connected to the indoor unit 20 through the terminal communication unit 220, an application for controlling the indoor unit can be automatically executed and a control screen for controlling the indoor unit can be displayed through the display unit 240. there is. Also, when an application for controlling an indoor unit is executed, the terminal controller 210 searches for an indoor unit that can be connected within a predetermined distance through the terminal communication unit 220, and outputs information about the indoor unit through the display unit.

4 is a block diagram showing a configuration for controlling an indoor unit by a controller according to an embodiment of the present invention.

The controller 80 configured as shown in FIG. 3B described above executes an application and processes data accordingly, as shown in FIG. 4 .

The application for controlling the indoor unit is executed by the application execution unit 211 of the terminal control unit 210, and data for the application is processed. The application execution unit 211 calls application data from the remote control data 251 to configure a control menu, implements a corresponding control screen, and outputs it through the display unit 240 . The application execution unit 211 manages the configuration of the control screen and the input and output of data through the control screen.

When a specific function is selected through the control screen, the service processing unit 212 calls data for the corresponding function from the remote control data and processes the requested service, that is, data for the selected function.

For example, when the opening angle of the first vane is set to be changed through the control screen, the service processing unit 212 calls indoor unit data according to the change in opening angle of the first vane, and provides information about the change in opening angle of the first vane. A control command is generated and service processing is performed to transmit it to the indoor unit.

The service processing unit 212 applies a control command generated for a requested service, for example, a vane opening angle change, to the signal generator 221 of the terminal communication unit 220 so that it is transmitted to the indoor unit.

The signal generating unit 221 converts the control command input from the service processing unit 212 into a signal for communication with the indoor unit. When the reception target is designated, the signal generator 221 applies the converted signal including information on the reception target to the transmitter 222 .

The transmitter 222 outputs the converted signal according to the designated communication method. When transmitting a control command to the indoor unit through infrared communication, the transmitter 222 transmits an infrared signal corresponding to the converted signal.

Accordingly, the indoor unit 20 receives the signal transmitted from the transmitter 222, reconverts the converted signal, extracts a control command, and controls the operation of the indoor unit in response to the control command. Accordingly, the indoor unit 20 changes the opening angle of the first vane according to the received control command.

5 is a reference diagram for explaining a control screen of a controller according to an embodiment of the present invention.

As shown in FIG. 5 , the controller 80 executes an application to output a control screen to control the indoor unit 20 through the display unit 240 .

The control screen includes a main screen 301 and an outlet setting screen 302 .

As shown in a of FIG. 5, the main screen 301 is composed of a main menu 390, a setting information menu 320, and an operation setting menu 330.

The main menu 390 includes a control key 392 for the main screen 301 and a bain key 393 for the outlet setting screen 302 . In addition, the main menu 390 displays the name 391 of the indoor unit or application to be controlled, and has a power key 394 for setting operation/stop of the indoor unit.

When the control key 3921 is selected in the main menu 390, the main screen 301 is displayed, and when the bain key 393 is selected, the outlet setting screen 302 is displayed on the display unit 240.

Screen conversion and menu configuration according to key input within the control screen are processed by the application execution unit 211 .

The setting information menu 320 includes an operation mode area 323, a temperature setting key 322, and a temperature information area 324.

In the driving mode area 323, the driving mode selected through the driving setting menu 330 is displayed as a combination of at least one of letters, icons, and images. In the operation mode area 323, any one of the cooling mode, heating mode, dehumidification mode, and ventilation mode is displayed as an icon corresponding to each operation mode.

The temperature setting key 322 moves within the temperature selection area 321, and sets a desired temperature for the indoor unit as one of the temperature steps 325 displayed in the temperature selection area 321 is selected.

At this time, the color of the temperature selection area 321 may be changed to correspond to the driving mode, and the color may be changed and displayed according to the position of the temperature setting key 322 . In addition, when an operation mode that does not require temperature setting is set, the temperature step is not displayed.

The temperature information area 324 can display the desired temperature selected by the temperature setting key 322 and also the indoor temperature of the indoor unit. At this time, the temperature unit key 326 changes the temperature unit so that the temperature displayed in the temperature information area 324 is displayed in Celsius or Fahrenheit.

The operation setting menu 330 includes a cooling mode key 331 for setting an operation mode, a heating mode key 332, a dehumidification mode key 333, a ventilation mode key 334, an air volume setting key 335, and a transmission key. (336).

When one of the cooling mode key 331, heating mode key 332, dehumidification mode key 333, and fan mode key 334 is selected, the operation mode of the indoor unit is set, and the air volume setting key 335 Air volume is set in 4 stages.

The transmission key 336 transmits a control command for the changed setting to the indoor unit.

When at least one of the operation mode, temperature, and air volume is selected through the main screen 301 and the transmission key 336 is selected, a control command for the changed setting is transmitted to the indoor unit 20 .

When the transmission key 336 is input, the service processing unit 212 of the terminal control unit 210 calls data for the changed operation setting, generates a control command for the setting, and applies it to the signal generating unit. Accordingly, a signal according to the control command is transmitted to the indoor unit through the transmitter.

As shown in b of FIG. 5, the outlet setting screen 302 includes a main menu 390, an indoor unit image area 340, a vane selection menu 360, an opening angle setting menu 370, and a direction finding key ( 351), manual change keys 358 and 359, standard key 381, swing key 382, and transmission key 383.

Descriptions of the same menus or keys as those of the main screen 301 shown in a of FIG. 5 will be omitted.

The indoor unit image area 340 displays an image of the indoor unit and vane images 341 to 345 corresponding to the first to fourth vanes of the indoor unit. At this time, the first to fourth vane images are displayed in different colors. The first to fourth vane images 341 to 345 respectively correspond to the first to fourth vessels 151 to 154 of the indoor unit.

When one vane is selected through the vane selection menu 360, a vane image corresponding to the selected vane in the indoor unit image area 340 is activated and displayed.

The vane selection menu 360 is composed of a plurality of vane keys 361 to 364 corresponding to the first to fourth vane images 341 to 344, and the opening angles set for each vane are displayed in the vane keys. A plurality of bain keys 361 to 364 may be selected in plurality, and the selected bain key is activated and displayed. For example, a non-selected bain key may be displayed in an achromatic color, a selected bain key may be displayed in color, and a selected bain key may be displayed with a thick border.

In the opening angle setting menu 370, the opening angle is set for at least one vane selected from among the plurality of vane keys 361 to 364 of the vane selection menu 360 according to the movement of the setting key 371. The setting key 371 is changed corresponding to the control step of the opening angle of the vane, and each step 372 of the opening angle may be indicated by a dot position or a number.

The standard key 381 changes the opening angle of the vane selected through the vane key to a preset standard angle. At this time, the standard angle may be changed according to the setting, for example, the standard angle may be set to 45 or 60 degrees.

The swing key 382 sets a swing mode in which the opening angle is continuously changed with respect to the selected vane.

The direction finding key 351 determines the user's location, arranges the location of the vane according to the user's location, and displays it on the screen.

The manual change keys 358 and 359 change the position of the vane image of the indoor unit image area 340 and the corresponding vane in a clockwise or counterclockwise direction to manually align them. According to the number of manipulations of the manual change key, the position of the vane corresponding to the vane image is sequentially changed.

The direction finding key and the manual change key change the first to fourth vanes 151 to 154 of the indoor unit corresponding to the first to fourth vane images 341 to 344 in accordance with the user's position.

The cancel key 357 cancels the change when the correspondence between the vane image and the vane is changed by the direction search key and the manual change key. The cancel key 357 restores the corresponding relation between the vane image and the vane to a state before being changed.

The transmission key 383 transmits a control command for the changed setting to the indoor unit. If the transmission key is not selected after changing the setting, the changed setting is not transmitted to the indoor unit.

6 is a diagram referenced to describe a main screen among control screens of a controller according to an embodiment of the present invention.

As shown in FIG. 6 , the setting information menu 320 of the main screen 301 is changed and displayed according to the driving mode.

As shown in a of FIG. 6, when the cooling mode key 331 is selected, a cooling icon 323a corresponding to the cooling mode is displayed in the operation mode area 323 of the setting information menu 320. The temperature selection area 321a is displayed in a color corresponding to the cooling mode. For example, it may be displayed in blue. In addition, the desired cooling temperature 324a is displayed according to the position of the temperature setting key 322.

As shown in b of FIG. 6, when the heating mode key 332 is selected, a heating icon 323b corresponding to the heating mode is displayed in the operation mode area 323 of the setting information menu 320. The temperature selection area 321b is displayed in a color corresponding to the heating mode. For example, it can be displayed in red or orange. In addition, the desired heating temperature 324b is displayed according to the position of the temperature setting key 322.

As shown in FIG. 6C , when the dehumidification mode key 333 is selected, a dehumidification icon 323c corresponding to the dehumidification mode is displayed in the operation mode area 323 of the setting information menu 320. The temperature selection area 321c is displayed in a color corresponding to the dehumidification mode. For example, it may be displayed in green. In the case of dehumidification mode, temperature setting is unnecessary, so the desired temperature is not displayed.

As shown in d of FIG. 6 , when the ventilation mode key 334 is selected, a ventilation icon 323d corresponding to the ventilation mode is displayed in the operation mode area 323 of the setting information menu 320 . The temperature selection area 321d is displayed in a color corresponding to the dehumidification mode. In the case of fan mode, temperature setting is unnecessary, so the desired temperature is not displayed.

7 is a diagram referenced to describe a discharge outlet setting screen among control screens of a controller according to an embodiment of the present invention.

As shown in FIG. 7 , the controller 80 individually controls the opening/closing and opening angles of the vanes provided in the outlets for the plurality of outlets provided in the indoor unit through the outlet setting screen 302 .

As shown in a of FIG. 7 , in case of controlling any one of the plurality of discharge ports, the discharge port may be controlled by selecting a bain key or a vane image to be controlled from among the plurality of bain keys.

In the outlet setting screen 302, a vane to be controlled can be selected through a vane key or a vane image selection in the indoor unit image area 340.

When the first vane key 361 is selected from the vane selection menu 360, the first vane key 361 is activated and displayed, and corresponding to the first vane key 361, the first vane image 341 is activated and displayed. Also, when the first vane image 341 of the indoor unit image area 340 is selected, the first vane key 361 is activated and displayed.

According to the selection of the vane key, the vane image corresponding to the first vane key 361 among the vane images 341 to 344 corresponding to the first to fourth vanes of the indoor unit image area 340 is activated and displayed. The first ban key 361 corresponds to the first ban image 341, the second ban key 362 corresponds to the second ban image 342, and the third ban key 363 corresponds to the third ban image. 343, and the fourth bain key 364 corresponds to the fourth vane image 344.

The first to fourth vane images 341 to 344 respectively correspond to the first to fourth vanes 151 to 154 of the indoor unit. Each vane image is displayed in a different color, and when activated by the selection of a vane key, the corresponding color is displayed or the color density is changed and displayed.

After selecting the first vane key 361, as the setting key 371 of the opening angle setting menu 370 is moved in either the first direction 373a or the second direction 373b, the first vane The opening angle of the vane corresponding to the key is set.

When the transmission key 383 is selected, a control command for setting the changed opening angle is transmitted to the indoor unit, and the opening angle of the vane is changed.

For example, when the vane of the indoor unit corresponding to the first vane key 361 or the first vane image 341 is the first vane, the vane driving unit changes the first vane 151 to the set opening angle.

As shown in b of FIG. 7 , the controller 80 may select a plurality of vanes through the outlet setting screen 302 to control opening angles of the plurality of vanes.

For example, when the second bain key 362 and the fourth bain key 364 or the second and fourth bain images 342 and 344 are selected, the selected bain key and bane image are activated and displayed.

After selecting a vane to be controlled through the vane key or vane image, when the setting key 371 of the opening angle setting menu 370 is changed from the first point 371a to the second point 371b, the second and The opening angle displayed in the fourth beinkeys 362 and 364 is changed to a position corresponding to the second point and displayed.

After the plurality of vanes are selected, if the opening angle is changed through the opening angle setting menu 370, the setting of the opening angle of the selected plurality of vanes is simultaneously changed.

For vanes that are not selected, the opening angle according to the existing setting is maintained.

For example, when the second vane 152 corresponds to the second vane key 362 and the fourth vane 154 corresponds to the fourth vane key 364, the second and fourth vanes 152 ( 154) is changed to an opening angle corresponding to the second point.

As shown in c of FIG. 7, when the standard key 381 is selected, the opening angle of at least one vane selected through the vane key or vane image is set as the standard angle.

When the standard key 381 is selected while the first to fourth bain keys 361 to 364 are selected, the first to fourth vanes 151 to 154 corresponding to the first to fourth bain keys 361 to 364 ) is changed to the standard angle. For example, the standard angle is 45 degrees or 60 degrees, and can be changed according to settings.

In addition, when the standard key 381 is input, the position of the setting key 371 of the opening angle setting menu 370 is also changed to the position of the standard angle.

On the other hand, if the standard key 381 is selected after the third bain key 363 is selected, the opening angle of the third bain key is changed to the standard angle. When the transmission key 383 is selected, the opening angle of the vane corresponding to the third vane key is changed to the standard angle.

As shown in d of FIG. 7 , when the swing key 382 is selected, the swing mode is set.

When setting the swing mode, the selected vane moves within the range of the controllable opening angle, and the opening angle is continuously changed.

When the swing key 382 is selected while the first to fourth vane keys 361 to 364 are selected, the first to fourth vanes 151 to 154 corresponding to the first to fourth vane keys 361 to 364 ) becomes a swing action.

When the swing key 382 is selected, all of the first to fourth bain keys 361 to 364 are automatically selected and the swing mode is set.

At this time, when only some of the first to fourth vane keys 361 to 364 are selected, the swing mode can be set only for the selected vane.

Accordingly, the controller 80 can individually control the outlets of the connected indoor units through the outlet setting screen 302 .

8 is a reference diagram for explaining a direction finding screen for aligning the location of a discharge port among discharge port setting screens of a controller according to an embodiment of the present invention.

When the direction finding key 351 is selected in b of FIG. 5 described above, a direction finding screen 352 is displayed as shown in FIG. 8 . The direction finding screen 352 may be displayed as a pop-up window on the outlet setting screen 302 or may be displayed as a separate screen.

As shown in a of FIG. 8, the direction finding screen 352 includes a guide image 352d, a guide message 352a, a cancel key 352c, and a next key 352b.

The guidance image 352d displays an image explaining the progress of direction finding to the user, and a guide message 352a displays a method for direction finding in text.

The controller 80 determines the location of the user through the direction finding screen 352 and aligns the location of the vane of the indoor unit 20 according to the location of the user. To facilitate signal transmission, the controller 80 guides the controller 80 toward the indoor unit through a guide image and a guide message.

If the cancel key 352c is selected, direction finding is canceled and the screen for setting the outlet 302 is returned.

When the next key 352b is selected, the terminal control unit 210 generates a control command for operating one of the plurality of vanes of the indoor unit and transmits it through the terminal communication unit 220. For example, the terminal controller 210 may transmit a control command to operate the first vane 151 .

When the next key 352b is selected on the direction finding screen 352, the vane selection screen 353 is displayed as shown in b of FIG.

The vane selection screen 353 includes a vane selection image 353d, a vane selection message 353a, a next key 353b, and a cancel key 353c.

When one of the plurality of vanes of the indoor unit operates according to the control command transmitted through the direction finding screen through the vane selection message 353a, the controller 80 induces the user to select a vane operating at the user's position.

When one of the plurality of vane images displayed on the vane selection image 353d is selected by the user (353e) and the next key 353b is selected, the terminal controller 210 Aligns the position so that the selected vane image and the first vane correspond.

If the cancel key 353c is selected, direction finding is canceled and the outlet setting screen 302 is returned.

Also, upon selection of the next key 353d, the position alignment screen 354 is displayed.

As shown in c of FIG. 8, the position alignment screen 354 displays a guide message 354a indicating that the vane position has been aligned and a changed vane image 354d.

When the next key 354b is selected, information on the changed vane position is stored and the display unit 240 returns to the outlet setting screen 302. On the other hand, if the cancel key 354c is selected, vane position alignment is canceled and returned to the previous state, and the display unit 240 returns to the outlet setting screen 302 .

The controller 80 changes and stores the correspondence between the position of the vane image on the outlet setting screen 302 and the position of the vane of the actual indoor unit according to the user's position through direction finding. Accordingly, the controller 80 matches the vane selected by the user on the outlet setting screen 302 with the vane actually controlled at the user's position.

9 is a diagram referenced to describe a method for aligning the position of an outlet of a controller according to an embodiment of the present invention.

As shown in a of FIG. 9, the indoor unit 20 is fixedly installed, but the position of the user (P1 to P4) is changed, so the position of the vane displayed on the screen and the position of the vane of the indoor unit depend on the position of the user. is relatively changed.

As shown in b of FIG. 9, on the outlet setting screen 302 (A), the first vane image 341 is number 1, the second vane image 342 is number 2, and the third vane image 343 is No. 3, the fourth vane image 344 is disposed No. 4.

The user looking at the indoor unit from the first position (P1), the first vane 151 is No. 1, the second vane 152 is No. 2, and the third vane is the same as the vane position on the outlet setting screen 302. 153 is shown as number 3, and the fourth vane 154 is shown as number 4.

Accordingly, when the opening angle is changed by selecting the first vane image 341, the first vane at the first position operates.

However, in the case of a user looking at the indoor unit from the second position P2, the fourth vane 154 is located at the position of the first vane image 341, different from the position of the vane on the outlet setting screen 302.

Accordingly, when the opening angle is changed by selecting the first vane image 341, the first vane 151 operates, but from the user's point of view, the vane corresponding to the position of the second vane image operates. It is shown.

That is, the position of the vane selected on the outlet setting screen 302 and the vane actually operating are different.

In the case of a user looking at the indoor unit from the third position (P3), when the opening angle is changed by selecting the first vane image 341 on the outlet setting screen 302, the first vane 151 operates, but , From the user's point of view, the vane corresponding to the position of the third vane image is seen to operate.

In addition, in the case of a user looking at the indoor unit from the fourth position (P4), when the opening angle is changed by selecting the first vane image 341, it is seen that the vane corresponding to the position of the fourth vane image operates. .

Therefore, since the position of the vane of the indoor unit is relatively changed according to the user's position, the user's position is determined through direction finding and the position of the vane displayed on the screen is aligned correspondingly to determine the vane selected by the user and the vane that actually operates. make this match

As shown in c of FIG. 9 , when the terminal control unit 210 aligns the position of the vane through direction finding, the relative positional relationship between the vane displayed on the screen and the vane according to the user's position is shown in c of FIG. 9 save as done

When generating a control command for vane control, the terminal control unit 210 operates a vane selected from among a plurality of vanes based on the stored positional relationship.

Accordingly, when the user located at the third position P3 selects the first vane image through the outlet setting screen 302 and changes the opening angle, the opening angle of the third vane is changed. At this time, it is seen that the vane at the same position as the first vane image is controlled at the user's position.

10 is a flowchart referenced to explain a method for controlling an outlet of an air conditioner according to an embodiment of the present invention.

As shown in FIG. 10 , when the application is executed, the controller 80 outputs a menu for vane control and an outlet setting screen 302 through the display unit 240 (S410).

When direction finding is selected (S420), a direction finding screen is displayed so that a signal is transmitted to the indoor unit, and a vane selection screen is output to guide the user to select a vane that actually moves from the user's position.

When one of the plurality of vanes is selected (S440), the controller 80 determines the user's position according to the position of the selected vane (S450).

The controller 80 aligns the position of the vane image displayed on the outlet setting screen 302 with the position of the vane of the indoor unit according to the position of the user (S460), and stores the positional relationship as data.

The controller 80 causes the screen of the display unit 240 to return to the outlet setting screen 302, which is the vane control menu (S470), and activates and displays a vane selected from among a plurality of vane images or vane keys according to a user's input. Do (S480).

The opening angle setting for the vane selected through the opening angle setting menu 370 is input (S490). In addition, the opening angle can be set to the standard angle through the standard key, and when the swing key is selected, the swing mode is set.

When the transmission key is selected, the terminal control unit 210 checks the vane to be controlled from data on the aligned vane position corresponding to the position of the selected vane (S500), and generates a control command for the input setting to control the indoor unit (S500). 20) (S510).

Accordingly, the signal is transmitted to the indoor unit through the terminal communication unit, and the indoor unit changes the opening angle of the selected vane according to the control command.

Accordingly, in the present invention, an indoor unit having a plurality of discharge ports may be individually controlled by selecting at least one of the plurality of discharge ports. In addition, by aligning the position of the vane displayed on the screen according to the position of the user, the position of the vane displayed on the screen and the position of the vane actually controlled at the user's position are identical, thereby improving user convenience.

Even though all components constituting an embodiment of the present invention have been described as operating in combination, the present invention is not necessarily limited to these embodiments. Within the scope of the object of the present invention, depending on embodiments, all components may be selectively combined with one or more to operate.

The above description is merely an example of the technical idea of the present invention, and various modifications and variations can be made to those skilled in the art without departing from the essential characteristics of the present invention.

10: outdoor unit 20: indoor unit
50: central controller 80: controller
110: unit control unit 120: unit communication unit
150: vane driving unit 151 to 154: vane
210: terminal control unit 220: terminal communication unit
301: main screen 302: outlet setting screen

Claims (13)

an indoor unit that controls the direction of discharged air by controlling the plurality of vanes installed at the plurality of discharge ports;
A controller connected to the indoor unit to set an operation of the indoor unit and an opening angle of the vane;
The controller outputs a control screen for setting opening angles of the plurality of vanes,
By determining the user's position, the vane position is aligned and displayed so that the plurality of vane images displayed on the control screen and the position of the vane coincide,
The controller controls a first vane of the plurality of vanes to operate when a direction finding key is selected,
When any one of the plurality of vane images displayed on the control screen is selected, the selected vane image is matched with the first vane to automatically align the positions of the plurality of vane images displayed on the control screen air conditioner.
delete According to claim 1,
The air conditioner according to claim 1 , wherein the controller determines a user's relative position with respect to the plurality of vanes based on the first vane and the selected vane image. According to claim 1,
When the manual change key is selected, the controller manually aligns the positions of the vanes by changing the positions of the plurality of vanes corresponding to the plurality of vane images in a clockwise or counterclockwise direction in response to a key input. air conditioner that does. According to claim 1,
When the vane position is aligned according to the user's position, the controller transmits vane position data to the indoor unit,
An air conditioner characterized in that for operating a designated vane among the plurality of vanes according to a control command input from the controller. According to claim 1,
The air conditioner of claim 1 , wherein the indoor unit controls the plurality of vanes in response to a control command input from the controller so that air current is discharged through a designated outlet. According to claim 1,
The air conditioner according to claim 1 , wherein the controller transmits information about the discharge port selected through the control screen, air volume and wind direction information to the indoor unit. According to claim 1,
The air conditioner according to claim 1 , wherein the controller transmits an opening angle of the vane, a swing state, and an air volume to the indoor unit for the outlet selected through the control screen. displaying a control screen including a plurality of vane images corresponding to a plurality of vanes installed in a plurality of outlets of the indoor unit, on a controller for setting operation settings of the indoor unit and opening angles of vanes;
operating a first vane among the plurality of vanes when a direction finding key is selected;
selecting one of the plurality of vane images;
matching the selected vane image to the first vane; and
A control method of an air conditioner comprising: arranging and displaying positions of the plurality of vane images displayed on the control screen. According to claim 9,
The method of controlling an air conditioner further comprising determining a user's position with respect to the plurality of vanes based on the first vane and the selected vane image. According to claim 9,
selecting a manual change key on the control screen;
The control method of the air conditioner further comprising; sequentially changing the position of the vane corresponding to the vane image in response to the number of inputs of the manual change key. According to claim 9,
After aligning the vane positions, transmitting the vane position data to the indoor unit; and
The method of controlling an air conditioner further comprising controlling the indoor unit to operate a designated vane among the plurality of vanes according to a control command input from the controller. According to claim 9,
activating an outlet corresponding to the selected vane image when one of the plurality of vane images on the control screen is selected;
The method of controlling an air conditioner further comprising setting an opening angle, whether or not to swing, and an air volume of a vane corresponding to the vane image.

Images