KR102629025B1 - Ceiling type air conditioner - Google Patents

Abstract

This embodiment relates to a ceiling-type air conditioner, which includes a discharge panel having an outlet through which air is discharged to the outside, a plurality of air guide assemblies mounted on the discharge panel to guide the air discharged to the outlet, and a plurality of air guide assemblies. It includes a control unit that independently controls each, and each of the plurality of air guide assemblies includes a guide member that changes the airflow direction of the air passing through the outlet, an air guide having a light emitting mechanism that irradiates light to the guide member, and a guide member; It includes a lifting mechanism that raises and lowers the light emitting mechanism together, and the control unit can differently control the light emitting mechanism of the air guide with the lifting mechanism stopped and the light emitting mechanism of the air guide with the lifting mechanism operating.

Description

Ceiling type air conditioner

The present invention relates to a ceiling-type air conditioner, and more specifically, to a ceiling-type air conditioner having a plurality of air guides.

An air conditioner is a device that creates a more comfortable indoor environment for users.

An air conditioner can cool or heat a room using a refrigeration cycle device having a compressor, condenser, expansion device, and evaporator through which refrigerant circulates.

Air conditioners can be classified into stand-type air conditioners, wall-mounted air conditioners, and ceiling-type air conditioners depending on their installation location.

Ceiling air conditioners are installed on the ceiling and can discharge cold or warm air into the room.

An air outlet through which air is discharged may be formed in the ceiling-type air conditioner, and a wind direction control member may be disposed at the air outlet to control the wind direction of the air discharged toward the room. The wind direction control member may be rotatably disposed at the air outlet.

The wind direction control member can control the vertical wind direction of the air discharged from the air outlet, and can determine the airflow of the air discharged from the ceiling-type air conditioner according to its arrangement angle.

The purpose of the present invention is to provide a ceiling-type air conditioner that can independently control the airflow direction and simultaneously provide the user with an airflow control situation.

A ceiling air conditioner according to an embodiment of the present invention includes a discharge panel having an outlet through which air is discharged to the outside, a plurality of air guide assemblies mounted on the discharge panel to guide the air discharged to the outlet, and a plurality of air guides. It includes a control unit that independently controls the guide assemblies, each of the plurality of air guide assemblies includes a guide member that changes the airflow direction of the air passing through the outlet, an air guide having a light emitting device that irradiates light to the guide member, It may include a lifting mechanism that elevates the guide member and the light emitting device together.

The air guide may further include an upper mounter to which each of the guide member and the light emitting mechanism is coupled and which is raised and lowered by an elevating mechanism.

The control unit can turn on the light emitting devices of the plurality of air guide assemblies when the ceiling air conditioner is turned on.

The control unit may control the light emitting devices of the plurality of air guide assemblies to emit light of the same color.

The ceiling air conditioner has a plurality of operation modes, and the control unit can change the color of light emitted by the light emitting devices of the plurality of air guide assemblies when the operation mode is changed.

The ceiling air conditioner further includes a receiver that receives an external signal, and the control unit controls at least according to the airflow control signal if the signal received by the receiver is an airflow control signal for raising or lowering at least one air guide among the plurality of air guide assemblies. The lifting mechanism can be controlled so that one air guide goes up and down.

The airflow control signal may be a height adjustment signal that changes the height of the air guide to the user's desired height.

The control unit may dim the light emitting device of the air guide assembly corresponding to the height adjustment signal at least once.

The airflow control signal is an operation mode signal that sets the cooling operation mode or the heating operation mode, and the control unit adjusts the air guide to the cooling set height if the operation mode signal is a signal that sets the cooling operation mode, and the control unit adjusts the air guide to the cooling set height, and the operation mode signal sets the heating operation mode. If the signal is set to , the air guide is adjusted to the heating set height, and the cooling set height may be higher than the heating set height.

The airflow control signal is an auto-variable signal that sets the cooling operation auto-variable mode or the heating operation auto-variable mode, and the control unit raises and lowers the air guide in the first lifting range if the auto-variable signal is a signal that sets the cooling operation auto-variable mode. If the auto-variable signal is a signal that sets the heating operation auto-variable mode, the air guide is raised/lowered in the second lift/lower range, and the first lift/lower range may be higher than the second lift/lower range.

The control unit may dim the light emitting device of the air guide being raised and lowered by the lifting device among the plurality of air guide assemblies at least once.

The receiving unit may further receive a light control signal for controlling at least one light emitting device among the plurality of air guide assemblies, and the controller may turn on or off the light emitting device of the air guide assembly corresponding to the received light control signal.

The air guide includes a pair of light emitting devices, one of which may face one end of the guide member, and the other of the pair of light emitting devices may face the other end of the guide member.

The control unit can turn on or turn off a pair of light emitting devices simultaneously.

The air guides of the plurality of air guide assemblies may be arranged along a virtual circle larger than the outlet.

The control unit may control the light emitting devices of the plurality of air guide assemblies so that the number of light emitting devices turned on during the operation mode is greater than the number of light emitting devices turned on during the additional function.

Additional functions may include a filter cleaning function, a defrost function, and a reservation setting function.

A ceiling air conditioner according to an embodiment of the present invention includes a discharge panel having an outlet through which air is discharged to the outside, a plurality of air guide assemblies mounted on the discharge panel to guide the air discharged to the outlet, and a plurality of air guides. It includes a control unit that independently controls the guide assemblies, each of the plurality of air guide assemblies includes a guide member that changes the airflow direction of the air passing through the outlet, an air guide having a light emitting device that irradiates light to the guide member, It includes a lifting mechanism that elevates the guide member and the light emitting device together, and the control unit can differently control the light emitting device of the air guide with the lifting mechanism stopped and the light emitting device of the air guide with the lifting mechanism operating.

The ceiling air conditioner further includes a receiver for receiving an external signal, and the control unit controls air flow corresponding to the air flow control signal when the signal received by the receiver is an air flow control signal for raising or lowering at least one air guide among the plurality of air guides. The light emitting mechanism of the air guide corresponding to the air flow control signal can be dimmed at least once while operating the guide's lifting mechanism.

The control unit can maintain the light emitting mechanism of the air guide in which the airflow control signal is not received by the receiver.

According to an embodiment of the present invention, the airflow direction of discharged air can be independently controlled through a plurality of air guides, and at the same time, there is an effect of easily informing the user of the airflow state of the discharged air.

According to an embodiment of the present invention, there is an advantage that the guide member and the light emitting device can be simultaneously raised and lowered through the upper mounter.

According to an embodiment of the present invention, there is an advantage in that the power status of the ceiling air conditioner can be informed to the user through a light emitting device included in a plurality of air guide assemblies.

According to an embodiment of the present invention, there is an advantage in that the operating mode in which the ceiling air conditioner is operating can be informed to the user by changing the color of the light emitted by the light emitting device included in the plurality of air guide assemblies.

According to an embodiment of the present invention, there is an advantage in that the user can be notified of the air guide assembly to which the height adjustment signal has been input among a plurality of air guide assemblies.

According to an embodiment of the present invention, there is an advantage of informing the user which air guide assembly is currently being lifted out of the plurality of air guide assemblies.

According to an embodiment of the present invention, there is an advantage that the user can arbitrarily control the light emitting devices included in the plurality of air guide assemblies.

According to an embodiment of the present invention, the air guide includes a pair of light emitting devices, so there is an advantage in that it can inform the user of the airflow state of the discharged air even if an error occurs in one of the light emitting devices.

According to an embodiment of the present invention, there is an advantage in that a user can easily know the operating state of the air guide even if he or she is far from the ceiling air conditioner.

1 is a perspective view of a ceiling-type air conditioner according to an embodiment of the present invention.
Figure 2 is a bottom view of a ceiling-type air conditioner according to an embodiment of the present invention.
Figure 3 is a longitudinal cross-sectional view of a ceiling-type air conditioner according to an embodiment of the present invention.
Figure 4 is a bottom view of the indoor unit shown in Figures 1 and 3.
Figure 5 is a perspective view of the discharge panel shown in Figures 1 to 3.
Figure 6 is a perspective view when the suction panel is separated from the discharge panel shown in Figure 5.
Figure 7 is a perspective view showing the discharge path of the discharge panel according to an embodiment of the present invention.
Figure 8 is a plan view showing the suction flow path and the discharge flow path of the discharge panel according to an embodiment of the present invention.
Figure 9 is a cross-sectional view taken along line X-X' of Figure 5.
Figure 10 is a cross-sectional view taken along line Y-Y' of Figure 5.
Figure 11 is an exploded perspective view of a discharge panel according to an embodiment of the present invention.
Figure 12 is a perspective view showing the control unit and main euro body according to an embodiment of the present invention.
Figure 13 is an enlarged perspective view of a portion of the main euro body according to an embodiment of the present invention.
Figure 14 is a plan view showing the control unit and main euro body according to an embodiment of the present invention.
Figure 15 is a bottom view showing the main euro body according to an embodiment of the present invention.
Figure 16 is an enlarged perspective view of the inner flow path body according to an embodiment of the present invention.
Figure 17 is a plan view of an inner euro body according to an embodiment of the present invention.
Figure 18 is an enlarged perspective view of an air guide, an elevating guide, and an elevating mechanism according to an embodiment of the present invention.
Figure 19 is a perspective view when the elevator guide shown in Figure 18 is separated.
Figure 20 is a cross-sectional view when a ceiling-type air conditioner forms a horizontal airflow according to an embodiment of the present invention.
Figure 21 is a cross-sectional view of a ceiling-type air conditioner forming a vertical airflow according to an embodiment of the present invention.
Figure 22 is an enlarged cross-sectional view of an air guide according to an embodiment of the present invention.
Figure 23 is a perspective view showing an outer cover, an elevating guide, and an air guide together when there are a plurality of air guide assemblies according to an embodiment of the present invention.
Figure 24 is a perspective view when the outer cover shown in Figure 23 is separated from the lifting guide.
Figure 25 is a perspective view showing a view diagonally from the bottom of a ceiling-type air conditioner including a plurality of air guide assemblies according to an embodiment of the present invention.
Figure 26 is a perspective view showing a plurality of air guides shown in Figure 25 being raised and lowered in the same manner.
Figure 27 is a perspective view showing some of the plurality of air guides shown in Figure 26 lowered further.
Figure 28 is a perspective view showing some of the plurality of air guides shown in Figure 26 raised further.
Figures 29 and 30 are perspective views showing the light emitting devices of some of the plurality of air guides shown in Figure 26 turned off.
Figure 31 is a perspective view showing the operation of the light emitting device when the ceiling air conditioner shown in Figure 26 is used as an additional function.

Hereinafter, specific embodiments of the present invention will be described in detail along with the drawings.

Figure 1 is a perspective view of a ceiling-type air conditioner according to an embodiment of the present invention, Figure 2 is a bottom view of a ceiling-type air conditioner according to an embodiment of the present invention, and Figure 3 is a ceiling view according to an embodiment of the present invention. This is a longitudinal cross-sectional view of the type air conditioner, and Figure 4 is a bottom view of the indoor unit shown in Figures 1 and 3.

The ceiling air conditioner of this embodiment includes an indoor unit (1) and a discharge panel (2). The ceiling-type air conditioner may further include a suction panel (3) installed on the discharge panel (2).

<Indoor unit>

The indoor unit (1) may be equipped with a blower (4) and a heat exchanger (5). The indoor unit (1) can suck air, exchange heat with the refrigerant, and then blow it to the discharge panel (2). The indoor unit 1 may form the main body of a ceiling-type air conditioner.

The indoor unit (1) has an area (15) where air is sucked into the indoor unit (1) and areas (7) (8) (9) (10) where the air inside the indoor unit (1) is blown to the discharge panel (2). It may further include a partitioning indoor unit euro body 13.

The indoor unit 1 may further include a drain unit 14 disposed below the heat exchanger 5.

<Air intake of indoor unit and air discharge of indoor unit>

An inner suction hole 6 may be formed in the indoor unit 1 through which air sucked through the suction panel 3 is sucked into the interior of the indoor unit 1. Additionally, a plurality of blowing passages 7, 8, 9, and 10 may be formed in the indoor unit 1 to guide the discharge of air that has passed through the heat exchanger 5.

The indoor unit 1 can discharge air in a downward direction through a plurality of ventilation passages 7, 8, 9, and 10. The indoor unit 1 may form a plurality of discharge air streams that are blown downward within the indoor unit 1. These plural discharge air streams may be blown in parallel directions.

The outer perimeter of the indoor unit 1 may have a polygonal shape. A plurality of ventilation passages 7, 8, 9, and 10 may be formed on the bottom of the indoor unit 1 to be open in the vertical direction. The indoor unit 1 can discharge a plurality of vertical airflows blowing downward through its bottom.

The indoor unit 1 can be installed suspended from the ceiling. The indoor unit 1 may be supported by a fastening member such as an anchor bolt fixed to the ceiling. A fastening portion 12 to which a fastening member is fastened may be formed in the indoor unit 1, as shown in FIGS. 1 and 4 .

The indoor unit 1 may include a chassis 11 that forms the exterior. The chassis 11 may be an indoor unit body that forms the exterior of the indoor unit.

<Chassis of indoor unit>

The chassis 11 may be mounted on the ceiling using fastening members such as anchor bolts. The chassis 11 may be provided with a protruding fastening portion 12 to which fastening members such as anchor bolts are fastened.

The chassis 11 may be composed of a combination of a plurality of members. The chassis 11 may be formed in a polyhedral shape with an open bottom and a space formed inside.

The chassis 11 may have a space inside which the blower 4 and the heat exchanger 5 are accommodated. The chassis 11 may have a shape in which each of the four front, rear, left, and right sides and the top surface are closed.

<Blower of indoor unit>

The blower 4 may be placed inside the chassis 11. The blower 4 may be mounted on the top of the chassis 11.

The blower 4 may be mounted on the chassis 11 so that at least a portion of the blower 4 is located inside the heat exchanger 5.

The blower 4 may be mounted on the upper hollow portion 20 of the discharge panel 2, which will be described later.

The blower 4 may be configured as a centrifugal blower that sucks air from its lower side and blows it in a centrifugal direction. The blower 4 may include a motor 41 and a centrifugal fan 42 connected to the motor 41. The blower 4 may include an orifice 43 that guides air sucked into the centrifugal fan 42.

The motor 41 may be mounted so that the rotation shaft connected to the centrifugal fan 42 protrudes downward.

The centrifugal fan 42 may be configured as a turbo fan.

The orifice 43 may be installed to be located inside the chassis 11. The orifice 43 may be installed in the indoor unit euro body 13, which will be described later. The inner suction hole 6 may be formed in the orifice 43.

The air that has passed through the suction panel (3) can be sucked into the centrifugal fan (42) through the inner suction hole (6) of the orifice (43), and can be sucked into the centrifugal fan (42) in the centrifugal direction of the centrifugal fan (42). can be blown through.

Air blown in the centrifugal direction from the centrifugal fan 42 may flow to the heat exchanger 5 disposed surrounding the outer circumference of the centrifugal fan 42 and exchange heat with the heat exchanger 5.

<Heat exchanger of indoor unit>

The heat exchanger 5 may be bent at least once. The heat exchanger 5 may be formed to be smaller in size than the chassis 11 and placed inside the chassis 11.

The heat exchanger 5 may be arranged inside the chassis 11 in a square shape or a hollow cylindrical shape.

The heat exchanger 5 may be installed spaced apart from each other on the inner surface of the chassis 11. A passage through which air is guided to blowing passages 7, 8, 9, and 10, which will be described later, may be formed between the heat exchanger 5 and the inner surface of the chassis 11.

The heat exchanger 5 may be bent to form a space S1 inside which the blower 4 is accommodated. The heat exchanger 5 may include four heat exchange units facing different sides of the chassis 11. The heat exchanger 5 may surround the outer circumferential surface of the blower 4 on the outside of the blower 4.

<Drain unit of indoor unit>

The drain unit 14 may be formed with an open upper surface, and a space in which the lower part of the heat exchanger 5 can be accommodated may be formed.

<Indoor unit Eurobody>

The indoor unit euro body 13 may be coupled to the drain unit 14. A hollow portion 15 through which air can pass in the vertical direction may be formed in the indoor unit flow path body 13. The hollow portion 15 may be an indoor unit air intake port that can suck air from the lower portion of the indoor unit 1 into the interior of the indoor unit 1. The hollow portion 15 may be an area where air is sucked into the indoor unit 1.

<Multiple ventilation passages of the indoor unit>

The indoor unit euro body 13 may be disposed on the inner lower part of the chassis 11. The indoor unit euro body 13 can form the bottom exterior of the indoor unit 1.

Each of the plurality of ventilation passages 7, 8, 9, and 10 formed in the indoor unit 1 may have a polygonal cross-sectional shape. Each of the plurality of ventilation passages 7, 8, 9, and 10 may have a rectangular cross-sectional shape.

The plurality of blowing passages 7, 8, 9, and 10 may be areas through which air inside the indoor unit 1 is blown to the discharge panel 2.

A plurality of ventilation passages (7) (8) (9) (10) may be formed to be spaced apart from the inner suction hole (6).

As shown in FIG. 4, the plurality of blowing passages (7) (8) (9) (10) include a left blowing passage (7), a right blowing passage (8), a front blowing passage (9), It may include a rear blowing passage (10).

As shown in FIG. 4, a plurality of blowing passages (7) (8) (9) (10) may be formed along a rectangular virtual line 17, and a plurality of blowing passages (7) (8) (9) )(10) can be formed one on each side of the rectangular virtual line 17.

The left air passage 7 may be located close to the left side 1A of the left side 1A and the right side 1B of the indoor unit 1 and may be long in the front-back direction.

The right blowing passage 8 may be located close to the right side 1B of the left side 1A and the right side 1B of the indoor unit 1, and may be long in the front-back direction.

The front blowing passage 9 may be located close to the front side 1C of the front side 1C and the back side 1D of the indoor unit 1 and may be long in the left and right directions.

The rear blowing passage 10 may be located close to the rear surface 1D of the front surface 1C and the rear surface 1D of the indoor unit 1 and may be long in the left and right directions.

<Formation location of multiple ventilation passages>

A plurality of blowing passages (7) (8) (9) (10) may be formed in the indoor unit euro body 13, and a plurality of blowing passages (7) (8) (9) (10) may be formed in the indoor unit euro body (13). 13) can be formed to be spaced apart from each other.

A plurality of blowing passages (7) (8) (9) (10) may be formed between the indoor unit flow path body (13) and the inner surface of the chassis (11), and a plurality of blowing passages (7) (8) (9) (10) may be formed between the indoor unit euro body 13 and the inner surface of the chassis 11 to be spaced apart from each other.

The plurality of ventilation passages (7) (8) (9) (10) may be four opening areas with different positions and parallel opening directions, and the indoor unit (1) has these plurality of ventilation passages (7) (8). (9)(10) Air may be discharged through.

The indoor unit 1 may be a 4-way discharge type indoor unit whose discharge directions form four vertical airflows parallel to each other.

Meanwhile, the indoor unit 1 may further include a receiver 27 that receives external signals.

<Receiving unit>

The receiving unit 27 can receive external signals. Specifically, the receiver 27 can receive a signal from a remote control device such as a remote control or portable terminal.

The receiver 27 can receive a control signal to control the operation of the ceiling air conditioner. The control signal may include a power on/off signal of the ceiling air conditioner, an operation mode setting signal, a light emitting device control signal, etc. However, this is only an example and will be explained in detail later.

The receiving unit 27 may be mounted on the indoor unit 1. Alternatively, the receiving unit 27 may be included in the control unit 17 of the discharge panel 2.

Based on the signal received by the receiver 27, the control unit 17, which will be described later, can control the indoor unit 1 or the discharge panel 2.

The discharge panel 2 may have a circular outer circumference 2A. The discharge panel 2 may have a flat bottom surface 2B.

The discharge panel 2 may be coupled to the indoor unit 1 and may guide air that has passed through the plurality of blowing passages 7, 8, 9, and 10 to be discharged to the outside. The discharge panel (2) may be disposed below the indoor unit (1) together with the suction panel (3). The discharge panel (2) together with the suction panel (3) may form a lower body assembly disposed below the indoor unit (1).

The discharge panel 2 may be coupled to the lower part of the indoor unit 1, and may guide air blown downward through a plurality of blowing passages 7, 8, 9, and 10 into the room. .

The discharge panel 2 can receive air blown in four directions parallel to each other from the indoor unit 1 and guide the discharge around the lower part of the discharge panel 2.

The discharge panel (2) converts the airflow of air blown vertically, especially downwardly, from the indoor unit (1) into the horizontal direction (H1) to guide the discharge, or at an acute angle to the horizontal direction (H1), as shown in FIG. The discharge can be guided by switching to the lower inclined direction (H2) having an inclination angle (θ) of .

The discharge panel 2 may be composed of a combination of a plurality of members 50, 60, 70, and 90.

The ceiling-type air conditioner may include an air guide 100 that is positioned to be raised and lowered on the discharge panel 2 and guides air passing through the outlet 25. In addition, the ceiling-type air conditioner may further include a lifting guide 110 for guiding the air guide 100 up and down, and a lifting mechanism 120 for lifting the air guide 100.

As shown in FIG. 3, the discharge panel 2 has a slit 57 through which the air guide 100 can be lowered around the outlet 25 of the discharge panel 2 or raised into the interior of the discharge panel 2. This can be formed.

Figure 5 is a perspective view of the discharge panel shown in Figures 1 to 3, and Figure 6 is a perspective view when the suction panel is separated from the discharge panel shown in Figure 5. Figure 7 is a perspective view showing the discharge flow path of the discharge panel according to an embodiment of the present invention, Figure 8 is a plan view showing the suction flow path and discharge flow path of the discharge panel according to an embodiment of the present invention, and Figure 9 is Figure 5. is a cross-sectional view taken along line X-X', and Figure 10 is a cross-sectional view taken along line Y-Y' of Figure 5.

<Suction panel>

As shown in FIGS. 9 and 10, the suction panel 3 may be disposed at the lower portion of the inner flow path body 60. A portion of the suction panel 3 may be disposed to face the lower hollow portion 68. The suction panel 3 may be disposed on the bottom of the inner euro body 60. A plurality of through holes 31 through which air is sucked into the lower hollow portion 68 may be formed in the suction panel 3. All or part of the plurality of through holes 31 may be located below the lower hollow portion 68.

Here, the through hole 31 may be an air intake port through which indoor air is sucked into the ceiling-type air conditioner.

<Discharge panel>

A suction passage 16 may be formed in the discharge panel 2 to guide air that has passed through the suction panel 3 into the interior of the indoor unit 1. Additionally, a discharge passage 18 may be formed in the discharge panel 2 to guide the air discharged from the plurality of blowing passages 7, 8, 9, and 10 into the room.

<Suction path of discharge panel>

A suction passage 16 may be formed in the discharge panel 2 to guide the air passing through the suction panel 3 to the hollow portion 15 (see FIG. 3) of the indoor unit 1. A hollow portion may be formed in the discharge panel 2 through which air passing through the suction panel 3 is sucked into the interior of the indoor unit 1. The hollow portion of the discharge panel 2 may be formed to penetrate the center of the discharge panel 2 in the vertical direction. The hollow portion may be the suction passage 16 of the discharge panel 2. Hereinafter, the suction passage of the discharge panel 2 and the hollow portion of the discharge panel 2 will be described using the same reference numeral '16'.

As shown in FIG. 8, the suction passage 16 may be located inside the discharge passage 18 and may be formed separately from the discharge passage 18.

The suction passage 16 may have a circular or square cross-sectional shape in the horizontal direction. The rectangular shape of the suction passage 16 may include a rectangular shape close to a circular shape. Here, a quadrangle that is close to a circle may mean a quadrangle that has two pairs of opposite sides and whose four corners are rounded.

The suction passage (H) with a circular cross-sectional shape is smaller than the suction passage (16) with a square cross-sectional shape, and the suction passage (16) with a square cross-sectional shape has a larger suction area inside the discharge panel (2). This can help ensure rapid intake of air.

As shown in FIGS. 5 and 8, the ceiling-type air conditioner can accommodate the control unit 17 in the suction passage 16.

The control unit 17 can independently control a plurality of air guide assemblies (T), which will be described later.

The control unit 17 may be placed in the suction passage 16, which has a square or close to square cross-sectional shape, so as not to interfere with the flow of air as much as possible.

On the other hand, when the shape of the control unit 17 is square, it may not be easy to install the square control part 17 in the suction passage H, which has a circular cross-sectional shape. Additionally, the area where the square control unit 17 blocks the circular suction passage H may be excessive, and the amount of air intake through the circular suction passage H may be reduced.

That is, it is desirable for the suction passage 16 of the discharge panel 2 to have a square cross-sectional shape or a shape as close to a square as possible.

<Discharge flow path of discharge panel>

At least one inlet may be formed in the discharge panel 2. The discharge panel 2 may be formed with a plurality of ventilation passages 7, 8, 9, and 10 and a plurality of inlets 21, 22, 23, and 24 corresponding to them. An arc-shaped or circular-shaped outlet 25 may be formed in the discharge panel 2. A connection passage 26 may be formed in the discharge panel 2 to connect a plurality of inlets 21, 22, 23, and 24 and the outlet 25.

The discharge passage 18 of the discharge panel 2 may include a plurality of inlets 21, 22, 23, and 24, a connection passage 26, and an outlet 25.

Air discharged from the ventilation passages (7) (8) (9) (10) of the indoor unit (1) may flow into the connection passage (26) through a plurality of inlets (21) (22) (23) (24). The air that has passed through the connection passage 26 can be discharged to the outside of the discharge panel 2 through the outlet 25.

<Inlet of discharge panel>

The inlets 21, 22, 23, and 24 formed in the discharge panel 2 may correspond 1:1 to the blowing passages 7, 8, 9, and 10 formed in the indoor unit 1.

The inlets 21, 22, 23, and 24 formed in the discharge panel 2 are the left inlet 21 communicating with the left blowing passage 7 in the up and down direction, and the left inlet 21 communicating with the right blowing passage 8 in the up and down direction. A right inlet (22) that communicates, a front inlet (23) that communicates in the up and down direction with the front blow passage (9), and a rear inlet (24) that communicates in the up and down direction with the rear blow passage (10). It can be included.

The left inlet 21 and the right inlet 22 may be spaced apart in the left and right directions with the suction passage 16 formed in the discharge panel 2 in between. The left inlet 21 and the right inlet 22 may be formed to be long and parallel to each other. Each of the left inlet 21 and the right inlet 22 may be formed to be long in the front-to-back direction.

The front inlet 23 and the rear inlet 24 may be spaced apart in the front-back direction with the suction passage 16 formed in the discharge panel 2 interposed therebetween. The front entrance 23 and the rear entrance 24 may be long and parallel to each other. Each of the front entrance 23 and the rear entrance 24 may be long in the left and right directions.

<Size and shape of the entrance>

The cross-sectional size of each of the plurality of inlets 21, 22, 23, and 24 may be the same as the cross-sectional size of each of the plurality of blowing passages 7, 8, 9, and 10.

The cross-sectional shape of the inlets 21, 22, 23, and 24 may be the same as the cross-sectional shape of the ventilation passages 7, 8, 9, and 10.

The cross-sectional shape of the inlets 21, 22, 23, and 24 may be polygonal. Here, the polygonal shape of the inlets 21, 22, 23, and 24 may include a shape in which at least one corner portion is rounded to have a predetermined curvature.

The cross-sectional shape of the inlets 21, 22, 23, and 24 may be square, particularly rectangular, like the cross-sectional shape of the blowing passages 7, 8, 9, and 10. Here, the rectangular shape of the inlets 21, 22, 23, and 24 may be elongated in the horizontal direction, and may include a shape in which at least one side or at least one vertex is rounded.

Hereinafter, the inlets 21, 22, 23, and 24 will be described as polygonal inlets 21, 22, 23, and 24.

The plurality of polygonal inlets 21, 22, 23, and 24, like the ventilation passages 7, 8, 9, and 10 of the indoor unit 1, have a rectangular imaginary line 19, Figures 7 and 8. reference), and a plurality of such polygonal inlets 21, 22, 23, and 24 may be formed, one on each side of the rectangular virtual line 19.

The rectangular virtual line 19 of the discharge panel 2 shown in FIGS. 7 and 8 and the rectangular virtual line 17 of the indoor unit 1 shown in FIG. 4 have the same size and can coincide in the vertical direction. .

<Exit of discharge panel>

The outlet 25 may be an air outlet through which air conditioned in the ceiling-type air conditioner is discharged to the outside of the ceiling-type air conditioner.

The number of outlets 25 may be smaller than the polygonal inlets 21, 22, 23, and 24. The outlet 25 may be larger than each of the plurality of polygonal inlets 21, 22, 23, and 24.

<Shape and number of exits>

The outlet 25 may be arc-shaped, and in this case, a plurality of outlets may be formed in the discharge panel 2. When the outlet 25 is arc-shaped, the plurality of outlets 25 may be spaced apart in the circumferential direction of the discharge panel 2 and may be formed along a circular virtual line. When the outlet 25 has an arc shape, the arc shape may include an arc shape such as a 'C' shape, an arc shape, or a semicircle shape.

The outlet 25 may have a circular shape, and in this case, one outlet 25 may be formed in the discharge panel 2. Here, when the outlet 25 is circular, circular may mean including an oval shape, and its cross-sectional shape may be formed in a closed loop shape.

The outlet 25 may be an opening through which air passing through the connection passage 26 is discharged to the outside of the discharge panel 2.

The discharge panel 2 may be exposed to the interior while coupled to the lower part of the indoor unit 1, and the outlet 25 may be exposed to the interior together with the bottom of the discharge panel 2.

<Connection flow path of discharge panel>

The connection passage 26 can guide air introduced through the polygonal inlets 21, 22, 23, and 24 to the outlet 25.

The connection passage 26 may be an airflow conversion discharge passage that converts the airflow of air sucked through the plurality of polygonal inlets 21, 22, 23, and 24 and guides it to the outlet 25. The connection passage 26 may be an airflow mixing discharge passage that mixes the air sucked through the plurality of polygonal inlets 21, 22, 23, and 24 and guides it to the outlet 25.

<Relationship between inlet and connection flow path and relationship between outlet and connection flow path>

A plurality of polygonal inlets 21, 22, 23, and 24 may be located at one end of the connection passage 26 in the air flow direction, and the outlet 25 may be located at the other end of the connection passage 26 in the air flow direction. can do.

<Shape of connection channel>

The connection passage 26 may have a closed-loop cross-sectional shape in the horizontal direction. The connection passage 26 may be formed in a shape whose cross-sectional area gradually increases as it goes downward.

The connection passage 26 may be formed to convert a vertical air flow into a horizontal air flow, and for this purpose, its vertical cross-sectional shape may be curved. The connection passage 26 may have a vertical cross-sectional shape that spreads outward as it goes downward.

Referring to Figures 7 and 8, the rectangular virtual line 19 where the multiple polygonal inlets 21, 22, 23, and 24 are located is not only higher than the outlet 25, but also smaller than the outlet 25. It can be. In this case, the first distance D1 between the side of the quadrangular virtual line 19 and the outlet 25 may be different from the second distance D2 between the vertex of the quadrangular virtual line 19 and the outlet 25. there is.

The first distance D1 may be longer than the second distance D2, and the distance between the square virtual line 19 and the circular exit 25 may repeat increases and decreases along the circumferential direction. The first distance D1 may gradually decrease as it gets closer to the vertex of the virtual rectangular line 19.

Considering this distance difference (D1-D2), the connection passage 26 may be formed so that its horizontal widths (D3) and (D4) in the circumferential direction are not the same.

The horizontal widths D3, D4 of the connection passage 26 may alternately increase and decrease along the outlet 25, and may repeat the increase and decrease.

The connection passage 26 is a first area 26A formed below the polygonal inlets 21, 22, 23, and 24 according to the positional relationship with the polygonal inlets 21, 22, 23, and 24. and a second area 26B formed below the periphery of the polygonal entrances 21, 22, 23, and 24.

The second area 26B may be located next to the first area 26A in the horizontal direction.

The first area 26A and the second area 26B may be alternately positioned along the outlet 25 in the circumferential direction of the discharge panel 2.

Referring to FIGS. 7 and 8 , the horizontal width D1 of the first area 26A may be larger than the horizontal width D2 of the second area 26B. Here, the comparison of the horizontal widths D1 and D2 is a comparison at the same height.

The horizontal width D1 of the first area 26A may gradually decrease as it approaches the second area 28B.

Referring to FIG. 7, the horizontal width D3 of the first area 26A increases and then decreases clockwise along the outlet 25, and the horizontal width D4 of the second area 26B increases and decreases clockwise along the outlet 25. It can be decreased and increased clockwise along (25). In this case, the average horizontal width D3 of the first area 26A may be greater than the average horizontal width D4 of the second area 26B.

The upper end (26C) of the connection passage (26) has a plurality of polygonal inlets (21) (22) (23) (24) and an outlet (25). It may be a closer area. The cross-sectional shape of the upper end 26C is generally formed as a square ring shape, but the vertex of the upper end 26C may be curved.

The lower end of the connection passage 26 may be an outlet 25, and its cross-sectional shape may be circular.

In order to correspond to the shape of the upper end (26C) and the shape of the outlet 25, the connecting passage 26 may be formed from a square ring shape to a shape that gradually approaches a circular shape as it goes from the upper end 26C to the outlet 25. there is.

The upper end 26C of the connection passage 26 is located below the polygonal inlet 21, 22, 23, and 24 and has a region having a first curvature (hereinafter referred to as the first curvature region 26D), It is located below the periphery of the polygonal inlet 21, 22, 23, and 24 and may include an area having a second curvature greater than the first curvature (hereinafter referred to as the second curvature area 26E).

The second curved area 26E may be an area extending horizontally from the first curved area 26D. That is, the first curved area 26D and the second curved area 26E may be alternately positioned in the horizontal direction along the upper end 26C of the connection passage 26.

And, the outlet 25 may have a third curvature that is greater than the first curvature. The third curvature of outlet 25 may be equal to, smaller than, or greater than the second curvature.

As the connection passage 26 moves downward, its cross-sectional shape may gradually become closer to a circular shape.

Among the connection passages 26, the passage located below the first curvature area 26D may have a shape in which the curvature gradually increases.

Among the connection passages 26, the passage located below the second curvature area 26E may have a constant, gradually decreasing, or gradually increasing curvature as it goes downward.

When the second curvature is the same as the third curvature, the curvature of the passage located below the second curvature area 26E of the connection passage 26 may be maintained constant in the downward direction.

When the second curvature is smaller than the third curvature, the curvature of the passage located below the second curvature area 26E of the connection passage 26 may gradually increase in the downward direction.

When the second curvature is greater than the third curvature, the curvature of the passage located below the second curvature area 26E of the connection passage 26 may gradually decrease in the downward direction.

When the ceiling air conditioner operates, air passing through the plurality of polygonal inlets 21, 22, 23, and 24 may fall into the first area 26A, and some of this air may fall into the first area 26A. It may flow from (26A) to the outlet (25) and then be discharged through the outlet (25). Meanwhile, the remainder of the air that fell into the first area 26A may flow from the first area 26A to the second area 26B and then be discharged from the second area 26B through the outlet 25. .

That is, in this embodiment, the air flowing into the plurality of polygonal inlets 21, 22, 23, and 24 can be discharged to the outlet 25 while spreading widely in the horizontal direction in the connecting passage 26, and the ceiling type air conditioner can discharge conditioned air to the entire area of the outlet (25).

Figure 11 is an exploded perspective view of a discharge panel according to an embodiment of the present invention, Figure 12 is a perspective view showing a control unit and a main flow path body according to an embodiment of the present invention, and Figure 13 is a main flow path according to an embodiment of the present invention. It is an enlarged perspective view of a part of the body, Figure 14 is a plan view showing the control unit and the main flow path according to an embodiment of the present invention, and Figure 15 is a bottom view showing the main flow path according to an embodiment of the present invention. Figure 16 is an enlarged perspective view of the inner flow path body according to an embodiment of the present invention, and Figure 17 is a plan view of the inner flow path body according to an embodiment of the present invention.

The discharge panel 2 may include a main euro body 50 and an inner euro body 60 coupled to the main euro body 50. The discharge panel 2 may further include an outer cover 70 that guides the air passing through the blowing passages 7, 8, 9, and 10 to the connection passage 26. The discharge panel 2 may further include a deco cover 90 coupled to the main euro body 50.

The discharge panel 2 allows air to flow in and pass between a pair of spaced apart guides 54 and 64. Air may be discharged and guided in the direction guided by the pair of guides 54 and 64.

<A pair of guides>

One of the pair of guides 54 and 64 may be formed on the main euro body 50, and the other of the pair of guides 54 and 64 may be formed on the inner euro body 60. there is.

This pair of guides 54 and 64 includes an outer guide 54 located relatively outside, and an inner guide 64 located inside the outer guide 54 and spaced apart from the outer guide 54. can do.

<Location and connection path of outer guide and inner guide>

The outer guide 54 may be formed on the main euro body 50. The outer guide 54 may be formed on the inner circumferential surface of the main euro body 50.

And, the inner guide 64 may be formed on the inner euro body 60. The inner guide 64 may be formed on the outer circumferential surface of the inner euro body 60.

The connection passage 26 may be formed between the inner guide 64 and the outer guide 54. The connection passage 26 can guide air introduced through the polygonal inlets 21, 22, 23, and 24 to the outlet 25.

<Suction path of discharge panel>

The discharge panel 2 may be formed with a suction passage 16 open in the vertical direction, and the suction passage 16 has alternating flat surfaces F1 and curved surfaces R1 along the inner circumference of the discharge panel 2. It can be formed as

In the suction passage 16, a pair of planes (F1) orthogonal to each other may be connected by a curved surface (R1), and a pair of curved surfaces (R1) may be connected by a plane (F1). The suction passage 16 may be formed by four flat surfaces (F1) and four curved surfaces (R1).

The suction flow path 16 may be formed in the main flow path 50 and the inner flow path 60, respectively. The upper hollow portion 20 formed in the main euro body 50 and the lower hollow portion 68 formed in the inner euro body 60 may communicate in the vertical direction.

The upper hollow portion 20 and the lower hollow portion 68 may have the same shape, and each may include a flat surface F1 and a curved surface R1, as shown in FIGS. 14 to 16. .

<Main Eurobody>

An upper hollow portion 20 penetrating in the vertical direction may be formed in the main euro body 50. The upper hollow portion 20 may function as an intake passage 16 through which air passing through the intake panel 3 is sucked into the indoor unit 1. The upper hollow portion 20 may be located on the upper side of the suction panel 3 and may be located below the inner suction hole 6 of the indoor unit 1.

The main euro body 50 may have an opening forming a plurality of polygonal inlets 21, 22, 23, and 24 between the outer circumference and the upper hollow portion 20.

<Size of main euro body>

The main flow path body 50 may be formed larger than the indoor unit 1 and may cover the indoor unit 1 at the lower part of the indoor unit 1. The main flow body 50 may include an area facing the indoor unit 1 in a vertical direction and an area facing the periphery of the indoor unit 1 in a vertical direction.

<Main Eurobody service hole and deco cover>

A service hole 59 may be formed in the main euro body 50 facing the fastening part 12 that fastens the indoor unit 1 to the ceiling. Service holes 59 may be formed in the main euro body 50 as many as the number of fastening portions 12. The service hole 59 may be an opening formed to be open in the vertical direction. The service hall 59 may have an open side. The discharge panel 2 may further include a decoration cover 90 that covers the service hole 59. The decoration cover 90 can form the outer edge of the discharge panel 2.

<Detailed structure of the main eurobody>

The main euro body 50 may include an upper body portion 51, an outer body portion 52, and a connection portion 53.

The upper body portion 51 may be formed with an upper hollow portion 20 penetrating in the center in the vertical direction. The upper body portion 51 may be connected to the outer body portion 52, which is larger than the upper body portion 52, through a connection portion 53.

The outer body portion 52 may be formed larger than the upper body portion 51 . The height of the outer body portion 52 may be lower than the height of the upper body portion 51.

The connection part 53 can connect the upper body part 51 and the outer body part 52 of different heights and sizes.

<Upper body part of main Eurobody>

The upper body portion 51 may be formed in a closed loop cross-sectional shape. The inner peripheral surface 51A of the upper body portion 51 may form an upper hollow portion 20.

The upper hollow portion 20 may have a square cross-sectional shape, but the four vertices may be rounded. The inner peripheral surface 51A of the upper body portion 51 may have flat surfaces F1 and curved surfaces R1 alternately formed along the inner peripheral surface.

The upper body portion 51 may form the upper flow path of the connection passage 26 together with the outer cover 70, and the connection passage 26 is the upper connection between the upper body portion 51 and the outer cover 70. May include euros.

The upper body portion 51 may form polygonal inlets 21, 22, 23, and 24, and the portion located below the polygonal inlets 21, 22, 23, and 24 is the outer cover. Together with (70), the upper passage of the connection passage (26) can be formed.

The outer peripheral surface 51B of the upper body portion 51 may form polygonal inlets 21, 22, 23, and 24 together with the connecting portion 53 and the outer cover 70. Polygonal inlets 21, 22, 23, and 24 may be formed between the upper body portion 51, the connection portion 53, and the outer cover 70.

The outer peripheral surface 51B of the upper body portion 51 may be spaced apart from one surface 70A of the outer cover 70. The polygonal inlets 21, 22, 23, and 24 may be formed to penetrate in the vertical direction between the outer circumferential surface 51B of the upper body portion 51 and one surface 70A of the outer cover 70. .

The upper body portion 51 may be formed in a square shape, but the four corners may be rounded.

The outer peripheral surface of the upper body portion 51 may include an upper plane (F2) and lower curved surfaces (R3) (R4) lower than the upper plane (F2). Additionally, the outer cover 70 may have one surface 70A facing the upper plane F2 and the lower curved surfaces R3 and R4 in the horizontal direction.

The upper plane F2, together with the connecting portion 53 and the outer cover 70, may form a polygonal inlet 21, 22, 23, or 24.

The lower curved surfaces R3 and R4 may form the upper flow path of the connection flow path 26 together with the outer cover 70.

The upper body portion 51 may include an upper guide 51C having an upper plane F2 formed thereon, and a lower guide 51D having lower curved surfaces R3 and R4 formed along the outer circumferential surface.

The upper plane F2 may be a horizontally long plane and may face one side 70A of the outer cover 70 in the horizontal direction.

The polygonal inlets 21, 22, 23, and 24 are formed in an approximately rectangular shape between the upper plane F2, the side end 53C of the connection portion 53, and one surface 70A of the outer cover 70. You can.

The lower curved surfaces R3 and R4 may be curved surfaces with a curvature close to a plane. Air passing through the polygonal inlets 21, 22, 23, and 24 may be guided to the lower curved surfaces R3 and R4.

The lower curved surfaces R3 and R4 include a region (R3, hereinafter referred to as the third region) facing one side 70A of the outer cover 70 in the horizontal direction, and an area facing the connection portion 53 in the horizontal direction ( R4, hereinafter referred to as the fourth region) may be included.

The area between the third area R3 and one surface 70A of the outer cover 70 may be an area where air passing through the polygonal inlets 21, 22, 23, and 24 flows in.

Additionally, the space between the fourth region R4 and the connection portion 53 may be a space where air sucked through adjacent polygonal inlets can be mixed.

The third region (R3) and the fourth region (R4) may have different curvatures.

The third region R3 may be a curved surface close to a plane, and the curvature of the third region R3 may be smaller than the curvature of the fourth region R4.

The fourth region (R4) may have a more curved shape than the third region (R3).

An empty space may be formed in the radial direction of the discharge panel 2 between the lower curved surfaces R3 and R4 of the upper body portion 51 and one surface 70A of the outer cover 70, and the horizontal space of this empty space may be formed. The direction width may repeatedly increase and decrease in the circumferential direction of the discharge panel (2).

<Outer body part>

The main euro body 50 may include an outer guide 54 that is spaced apart from the inner guide 64. The outer guide 54 may include an outer curved surface 55 that is convex toward the inner guide 64. The outer guide 54 may be part of the outer body portion 52.

The outer body portion 52 may include a mounting portion 56 formed in a ring shape and an outer guide 54 formed around the inner circumference of the mounting portion 56.

<Mounting part of outer body>

The mounting portion 56 may be formed in a ring-shaped plate shape. The mounting portion 56 may be equipped with an outer cover 70, a decor cover 90, and an elevating guide 110.

<Outer Body Department Outerwear Guide>

The outer guide 54 may face the outer circumferential surface of the inner euro body 60. An outer curved surface 55 that is convex toward the inner euro body 60 may be formed on the outer guide 54.

The outer guide 54 may include a first guide 54A in which an outer curved surface 55 is convex toward the inner euro body 60. The outer guide 54 may further include a second guide 54B connected to a side connection portion 53B, which will be described later.

The first guide 54A and the second guide 54B may be alternately positioned along the outer guide 54.

The first guide 54A may be an extension whose size gradually expands toward the bottom.

The outer curved surface 55 may be a surface of the first guide 54A that faces the outer circumferential surface of the inner euro body 60.

The second guide 54B may be a non-expandable portion whose size is constant in the vertical direction.

<Connection part>

The upper part of the connection part 53 may be connected to the upper body part 51, and the lower part may be connected to the outer body part 52.

The upper part of the connection part 53 may be connected to the outer circumference of the upper body part 51, and the lower part may be connected to the top of the outer body part 52. The lower part of the connection part 53 may be connected to the upper end of the outer guide 54.

The connection portion 53 may include an upper connection portion 53A and a side connection portion 53B.

The upper connection portion 53A may extend horizontally from the upper outer circumference of the upper body portion 51. The upper connection portion 53A may be formed perpendicular to the side connection portion 53B.

The upper connection portion 53A may face the outer circumferential surface of the inner euro body 60 in the vertical direction.

The upper connection portion 53A may have a side end 53C perpendicular to the upper plane F2, and the polygonal inlets 21, 22, 23, and 24 are located along the upper plane F2 of the upper body portion 51. It may be formed into a polygon by the side end 53C of the upper connection portion 53A and one surface 70A of the outer cover 70.

The side connection portion 53B may extend downward from the upper connection portion 53A and be connected to the outer body portion 52. The side connection portion 53B may be connected to the upper part of the outer body portion 52.

The side connection portion 53B may be formed to be long in the vertical direction and may face the fourth region R4 formed on the outer peripheral surface 51B of the upper body portion 51 in the horizontal direction.

<Number and location of connections>

A plurality of connection portions 53 may be formed between the upper body portion 51 and the outer body portion 52. The plurality of connection portions 53 may be formed to be spaced apart from each other. The number of connection parts 53 may be equal to the number of polygonal inlets 21, 22, 23, and 24. The discharge panel 2 may have an inlet formed between a pair of adjacent connecting portions 53.

<Internal space of the main Eurobody>

A space (S2) with an open bottom may be formed inside the main euro body 50. The main euro body 50 may have a space S2 with an open bottom formed inside the outer guide 54. The space S2 of the main euro body 50 may be formed to be larger than the outer circumference of the upper hollow portion 20. The space S2 of the main euro body 50 may be an empty space surrounded by the connection portion 53 and the outer guide 54.

The discharge panel 2 may be formed with a slit 57 through which the air guide 100 passes. A slit 57 may be formed on the side of the outlet 25 .

<Slit in the main Eurobody>

A slit 57 through which the air guide 100 passes may be open in the vertical direction in the main euro body 50. The slit 57 may be formed in the outer body portion 52. The slit 57 may be formed in the mounting portion 56 of the outer body portion 52. The slit 57 may have the same shape as the air guide 100. When the shape of the air guide 100 is arc-shaped, the slit 57 may be arc-shaped. The slit 57 may be formed slightly larger than the air guide 100. The number of slits 57 may be the same as the number of air guides 100.

A pair of ribs 58 may be formed to be spaced apart from each other on the main euro body 50, and a slit 57 may be formed between the pair of ribs 58 in the vertical direction. The air guide 100 can be lifted and guided by a pair of ribs 58 while passing through the slit 57, and the air guide 100 can be lifted and lowered more stably by the pair of ribs 58. .

The outer body portion 52 may form the lower flow path of the inner flow path 60 and the connecting flow path 26. The connection passage 26 may include a lower connection passage between the inner lower body 60 and the outer body portion 52.

The lower end of the outer body portion 52 may form the lower end of the outer circumferential surface of the inner euro body 60 and the outlet 25.

<Inner Eurobody>

The inner euro body 60 may be disposed below the upper body portion 51.

The inner flow path 60 may be coupled to the periphery of the upper hollow portion 20 to form the main flow path 26 and the outlet 25 with the main flow path 50. The outlet 25 and the connection passage 26 may be formed between the inner flow path body 60 and the outer body portion 52.

The inner euro body 60 may have its upper surface 69 coupled to the periphery of the upper hollow portion 20.

The upper surface 69 of the inner euro body 60 may be in contact with the lower surface of the upper body portion 51.

The inner euro body 60 may be formed to gradually expand downward.

The inner euro body 60 may have a lower hollow portion 68 through which air passes in the vertical direction. The lower hollow portion 68 may function as an intake passage 16 through which air passing through the intake panel 3 is sucked into the indoor unit 1.

When the blower (4) is driven, the air passing through the lower hollow part (68) of the inner flow path body (60) passes through the upper hollow part (20) of the main flow path body (50) and can be sucked into the indoor unit (1). there is.

The outer cover 70 may be combined with the main euro body 50 and may form a polygonal inlet 21, 22, 23, or 24 together with the main euro body 50.

The outer circumferential surface of the inner euro body 60 has an inlet opposing surface 65A facing the polygonal inlets 21, 22, 23, and 24 in the vertical direction, and a connection part facing the connection part 53 in the vertical direction. It may include an opposing surface 65B.

The inlet opposing surface 65A and the connecting portion opposing surface 65B may be formed alternately along the outer circumferential surface of the inner euro body 60.

The inlet opposing surface 65A may be gentler than the connection opposing surface 65A.

The upper surface 69 of the inner euro body 60 is overall formed in a square ring shape, but the vertex portion may be curved.

The outer perimeter of the upper surface (69) of the inner euro body (60) includes a fifth region (R5) having the same curvature as the third region (R3) and a sixth region (R6) having the same curvature as the fourth region (R4). can do. The fifth region (R5) and the sixth region (R6) may be alternately positioned along the outer circumference of the inner euro body 60.

The lower end 67 of the inner euro body 60 may have a circular shape.

The outer circumferential surface 65 of the inner euro body 60 is formed to correspond to the upper outer circumferential shape of the inner euro body 60 and the shape of the lower end 67 of the inner euro body 60. As it moves from the outer circumference to the lower end 67 of the inner euro body 60, it may be formed from a square ring shape to a shape that gradually approaches a circular shape.

<Location and shape of inner euro body>

The upper part of the inner euro body 60 may be inserted and accommodated in the space S2 of the main euro body 50 and the lower end may be lower than the main euro body 50.

The inner euro body 60 may be formed to gradually expand downward. The upper end of the inner guide 64 may face the outer guide 54 in a horizontal direction. Additionally, the lower end of the inner guide 64 may face the outer guide 54 in the vertical direction.

The inner euro body 60 may have an inner guide 64 formed on its outer circumferential surface. An inner curved surface 65 may be formed on the outer circumference of the inner euro body 60. The inner guide 64 may include an inner curved surface 65. The outer circumferential surface of the inner guide 64 may be the inner curved surface 65, and hereinafter, the outer circumferential surface and the inner curved surface of the inner guide 64 will be described using the same reference numeral '65'.

The inner guide 64 may include a concavely recessed inner curved surface 65. The upper end 66 of the inner curved surface 65 may face the outer curved surface 55 in the horizontal direction. The top 66 of the inner curved surface 65 may be the outer perimeter of the top surface 69 of the inner euro body 60. The lower end 67 of the inner curved surface 65 may face the outer curved surface 55 in the vertical direction.

Among the connection passages 26, the lower passage may be formed between the inner guide 64 and the outer guide 54.

The outlet 25 may be formed between the lower outer circumference of the inner guide 64 and the outer guide 54.

The inner euro body 60 may include an outlet end 67 spaced apart from the outer guide 54 in the vertical direction. The outlet end 67 may be the same as the lower end 67 of the inner curved surface 65, and hereinafter, the lower end and the outlet end of the inner curved surface 65 will be described using the same reference numeral '67'.

<Inner Eurobody exit end and outer guide>

The outlet end 67 may form an outer guide 54 and an outlet 25. That is, the outlet 25 may be formed between the outlet end 67 and the outer guide 54.

The outlet end 67 of the inner euro body 60 may be the lower outer circumference of the inner guide 64. The lower end of the inner guide 64 may be the lower outer circumference of the inner guide 64, and the outlet end 67 of the inner euro body 60 may be the lower end of the inner guide 64.

The inner euro body 60 may be composed of a combination of a plurality of members.

The inner euro body 60 is a flow path forming body 61 in which at least a portion of the outer circumferential surface is disposed to face the main flow path body 50 to form the main flow path body 50, the outlet 25, and the connecting flow path 26. ) and a strength reinforcement body 62 combined with the flow path forming body 61.

<Fluid forming body>

The upper end of the flow path forming body 61 may be coupled to the lower part of the upper body portion 51. The flow path forming body 61 may have a hollow portion formed therein that is open in the vertical direction. The outer circumference of the flow path forming body 61 may be the inner guide 64.

<Strength reinforced body>

The strength reinforcement body 62 is formed to protrude upwardly on the inner circumference of the lower reinforcement body 62A and the lower reinforcement body 62A, which is coupled to the lower surface of the flow path forming body 61. It may include an upper reinforcement body (62B) interpolated into the hollow portion. The strength reinforcement body 62 may include a strength reinforcement rib 62C protruding from the upper reinforcement body 62B. The strength reinforcing rib 62C may be inserted into a fitting slot formed on the inner circumferential surface of the flow path forming body 61 and may be coupled to the flow path forming body 61.

<Outer Cover>

The outer cover 70 may be mounted to be spaced apart from the upper body portion 51. The outer cover 70 may be disposed on at least one of the lifting guide 110 and the outer body portion 52.

At least one outer cover 70 may be disposed on the upper part of the outer body portion 52.

The outer cover 70 may cover the lifting mechanism 120. The outer cover 70 may be a lifting mechanism cover that protects the lifting mechanism 120. The outer cover 70 can cover the lifting mechanism 120 and the lifting guide 110 together.

The outer cover 70 may be seated on the first guide 54A, and may guide the air flowing into the polygonal inlets 21, 22, 23, and 23 to the first guide 54A, and The air flowing into the inlet may be guided to the first guide (54A) along one surface (70A) of the outer cover (70), and this air may be guided to the outlet (25) along the outer curved surface (55) of the first guide (54A). ) can flow.

<Detailed structure of the outer cover>

The upper portion of one surface 70A of the outer cover 70 forms an entrance, and the upper portion of one surface 70A may be flat rather than curved.

The outer cover 70 includes an upper cover part 71 that covers the upper surface of the lifting guide 110 and the lifting mechanism 120, a euro body part 72 extending downward from the upper cover part 71, and an upper It may include a side cover part 73 that extends downward from the cover part 71 and covers all or part of the outer circumferential surface of the lifting guide 110.

<Euro body part of outer cover>

The euro body portion 72 may form the main euro body 50 and polygonal inlets 21, 22, 23, and 24. The euro body portion 72 may be seated on the outer guide 54 to be spaced apart from the upper body portion 51. The euro body portion 72 may face the outer surface of the upper body portion 51, and has a polygonal inlet 21, 22, 23 (23) between the outer surface of the upper body portion 51 and the euro body portion 72. 24) can be formed. The euro body portion 72 can guide the air introduced into the polygonal inlets 21, 22, 23, and 24 to the outer guide 54.

The number of outer covers 70 may be equal to the number of polygonal entrances 21, 22, 23, and 24.

The flow path body portion 72 may form the upper flow path of the connecting flow path 26 together with the upper body portion 51 and the connecting portion 53. The lower end of the euro body portion 72 may be in contact with the upper end of the outer guide 54. The lower end of the euro body portion 72 may be supported by being seated on the upper end of the outer guide 54. Among the connection passages 26, the upper passage may be formed between the upper body portion 51 and the flow path body portion 72. The euro body portion 72 may face the second region F formed on the outer peripheral surface 51B of the upper body portion 51. The euro body portion 72 may have a flat plate shape on the side facing the second region (F).

The outer cover 70 may form a receiving space between the euro body portion 72 and the side cover portion 73 to accommodate a portion of the lifting guide 110 and the lifting mechanism 120. The bottom of the receiving space of the outer cover 70 may be open.

The lower end of the side cover portion 73 may be in contact with the lifting guide 110 or the mounting portion 56. The lower end of the side cover portion 73 may be supported by being seated on the lifting guide 110 or the mounting portion 56.

The receiving space of the outer cover 70 may be formed between the euro body portion 72 and the side cover portion 73, and its upper surface may be closed by the upper cover portion 71 and its bottom may be formed in an open shape. there is.

<Deco Cover>

The deco cover 90 may include a lower plate 91 that covers the lower surface of the mounting portion 56, and a hollow cylinder portion 92 protruding from the outer periphery of the lower plate 91. The hollow cylinder portion 92 may be formed larger than the outer body portion 52. The hollow tubular portion 92 may surround and protect the outer peripheral surface 52A of the outer body portion 52.

Figure 18 is an enlarged perspective view of the air guide, lifting guide, and lifting mechanism according to an embodiment of the present invention, Figure 19 is a perspective view when the lifting guide shown in Figure 18 is separated, and Figure 20 is an implementation of the present invention. Figure 21 is a cross-sectional view of a ceiling-type air conditioner according to an example when forming a horizontal airflow, Figure 21 is a cross-sectional view of a ceiling-type air conditioner according to an embodiment of the present invention when forming a vertical airflow, and Figure 22 is an embodiment of the present invention. This is an enlarged cross-sectional view of an air guide according to an example.

A ceiling-type air conditioner according to an embodiment of the present invention may include an air guide assembly (T) as shown in FIG. 19.

<Air guide assembly>

The air guide assembly (T) is mounted on the discharge panel (2) and can guide the air discharged to the outlet (25).

The air guide assembly (T) may include an air guide 100 and a lifting mechanism 120 that raises and lowers the air guide 100.

<Air Guide>

As shown in FIGS. 20 and 21, the air guide 100 is disposed to be raised and lowered on the main flow path body 50 and can vary the airflow of air discharged to the outlet 25.

When the air guide 100 is lowered, the air discharged through the outlet 25 may hit the air guide 100 and then be guided in the direction guided by the air guide 100. When the air guide 100 rises, the air discharged through the outlet 25 may pass through the lower end 103 of the air guide 100. The air guide 100 may be a flow guide that can change the air flow path while being raised and lowered.

The air guide 100 may have a curved shape, as shown in FIGS. 18 and 19. The air guide 100 may be formed in a circular shape or an arc shape.

<Main functions of Air Guide>

The air guide 100 can guide air exiting the outlet 25 while located outside the outlet 25, and may be an outer air guide, an outer wind direction control member, or an outer flow path guide. The air guide 100 is disposed on the discharge panel 2 to be able to descend next to the outlet 25 and can guide the air discharged to the outlet 25.

<Exit location, bottom position of outer guide, and bottom position of air guide>

Exit (25) is It may be between the outlet end 67 of the inner euro body 60 and the lower end 54C of the outer guide 54.

The distance (D5) from the central axis of the main euro body (50) to the lower end (54C) of the outer guide (54) is longer than the distance (D6) from the central axis of the inner euro body (60) to the outlet end (67). You can.

The distance (D7) from the central axis of the main euro body (50) to the lower end (103) of the air guide (100) may be longer than the distance (D5) from the central axis of the inner euro body (60) to the outlet end (67). there is.

<Detailed structure of air guide>

The air guide 100 may include a guide member 104 that changes the air flow direction of the air discharged to the outlet 25, and a light emitting device 108 that irradiates light to the guide member 104. The air guide 100 may further include an upper mounter 107 to which the guide member 104 and the light emitting mechanism 108 are coupled, and which is raised and lowered by the lifting mechanism 120.

The air guide 100 may be provided with a rack 106. The rack 106 may be provided on the upper part of the air guide 100 to protrude upward.

< Guide member>

The guide member 104 may be formed in a circular shape or an arc shape. If the air guide has a circular shape, the guide member 104 may be formed in a circular shape, and if the air guide 100 has an arc shape, the guide member 104 may be formed in an arc shape.

The guide member 104 may be formed of a light-transmitting material.

The guide member 104 may be formed with an inner guide surface 101 that guides the air discharged to the outlet 25. The inner guide surface 101 may face the outlet 25 in a horizontal direction when the air guide 100 is lowered. The inner guide surface 101 may be a concave surface facing the outlet 25 in the horizontal direction.

The inner guide surface 101 may be a flow guide surface that directly guides the air passing through the outlet 25 when the air guide 100 is lowered. The inner guide surface 101 may be a vertical guide surface that converts the air passing through the outlet 25 into a downward air flow.

The inner guide surface 101 may be curved in the horizontal direction and may be flat in the vertical direction.

An outer surface 102 may be formed on the opposite side of the inner guide surface 101. The outer surface 102 may be a convex surface located on the opposite side of the inner guide surface 101.

A light guide pattern that guides the light emitted from the light emitting device 108 may be formed on the outer surface 102.

The guide member 104 may be convexly curved in the direction of the outer surface 102 on which the light guide pattern is formed.

The light guide pattern may include a plurality of grooves formed long along the longitudinal direction of the guide member 104.

A plurality of grooves may be spaced apart in the height direction of the guide member 104. The distance between grooves may be constant. The depth of the plurality of grooves may become deeper toward the lower surface of the guide member 104. Accordingly, light projected from the upper surface direction of the guide member 104 can be uniformly spread throughout the guide member 104 along grooves of different depths.

<Light-emitting device>

The light emitting device 108 may be installed to irradiate light toward one end of the air guide 100. The light emitting device 108 may include a PCB installed in the air guide 100 and a light emitting source such as an LED installed on a side of the PCB facing one end of the air guide 100.

<Upper Mounter>

The upper mounter 107 is combined with the guide member 104 and the light emitting mechanism 108, and can be raised and lowered by the lifting mechanism 120.

The upper mounter 107 may further include a light emitting device receiving portion 109 coupled to a side end of the guide member 104 and a rack mounting portion 106a on which the rack 106 is mounted.

The light emitting device receiving portion 109 may include an inclined plate 109a facing the side end of the guide member 104, and a lower plate 109b formed below the inclined plate 109a to cover the light emitting device 108.

An opening may be formed in the inclined plate 109a. The light emitting device 108 may be coupled to the guide member 104 through the opening. That is, a slant plate 109a is mounted on the side end of the guide member 104, a light emitting device 108 is mounted on the slant plate 109a, and the light emitting device 108 passes through the opening of the slant plate 109a to the guide member 104. ) can be connected to the side end of.

The lower plate 109b formed below the light emitting device receiving portion 109 may be disposed below the light emitting device 108. The lower plate 109b can cover the light emitting device 108 from being seen from below the ceiling-type air conditioner. Therefore, the light emitting device 108 cannot be seen below the ceiling air conditioner. In addition, the light emitted by the light emitting device 108 cannot be seen directly from the bottom of the ceiling-type air conditioner, and only the light transmitted through the guide member 104 can be seen.

The upper mounter 107 is made of an opaque material, so light may not be projected. Accordingly, the light emitted from the light emitting device 108 may be transmitted only to the guide member 104 and not to the upper mounter 107.

The rack 106 may be integrally coupled to the rack mounting portion 106a. Alternatively, the rack mounting portion 106a may be detachable from the rack 106.

<Rack>

The rack 106 may be provided on the upper part of the guide member 104 to protrude upward.

The rack 106 is engaged with the lifting mechanism 120, which will be described later, so that the raising and lowering of the air guide 100 can be controlled by the lifting mechanism 120.

The rack 106 may be mounted on the upper mounter 107.

<Elevation guide>

The lifting guide 110 may be placed on the main flow path body 50.

The lifting guide 110 may include a receiving groove (S3) in which the air guide 100 is raised and accommodated. The receiving groove (S3) may be formed in the lifting guide 110 in a shape with an open bottom. The overall shape of the lifting guide 110 may be the same as that of the air guide 100, and may be formed larger than the air guide 100.

In a ceiling-type air conditioner, a plurality of air guides 100 can be arranged to be raised and lowered together on one lifting guide, and each air guide 100 can be provided with a separate lifting guide 110.

When a plurality of air guides 100 are arranged to enable elevation in one elevator guide, the overall shape of one elevator guide may be circular.

On the other hand, when each lift guide 110 is provided for each of the plurality of air guides 100, the lift guide 110 may be formed in an arc shape like the air guide 100.

In this embodiment, the air guide 100 and the lift guide 110 may each have an arc shape, and in this case, a plurality of lift guides 110 may be arranged along a circular virtual line.

<Elevating mechanism>

The lifting mechanism 120 may be installed on at least one of the main euro body 50, the outer cover 70, and the lifting guide 110.

The lifting mechanism 120 may include a motor 122 and a pinion 124 connected to the rotation shaft of the motor 122 and meshed with the rack 106.

The lifting mechanism 120 can raise the air guide 100 up next to the exit 25, as shown in FIG. 20 in the lifting mode.

In the lifting mode, the lifting mechanism 120 can raise the air guide 100 so that the lower end 103 of the air guide 100 coincides with the lower end 54C of the outer guide 54 in the horizontal direction. In this case, the air guided to the outer curved surface 55 of the outer guide 54 may be guided to the bottom of the decor cover 90 along the lower end 103 of the air guide 100.

The lifting mechanism 120 can lower the air guide 100 next to the exit 25 as shown in FIG. 21 in the lowering mode. The lifting mechanism 120 can lower the air guide 100 so that the lower end 103 of the air guide 100 is spaced apart from the outlet end 67 in the lowering mode.

A plurality of lifting mechanisms 120 may be provided, such as the air guide 100, and each of the air guides 100 may be independently lifted and lowered by different lifting mechanisms 120.

When there are two air guides 100, there may be at least two lifting mechanisms 120. The ceiling-type air conditioner is capable of raising and lowering the arc-shaped air guide 100 by a plurality of lifting mechanisms 120. In this case, the plurality of lifting mechanisms 120 make the arc-shaped air guide 100 more stable. It can be elevated.

<Airflow according to the height of the air guide>

The air discharged through the outlet 25 flows along the bottom 103 of the air guide 100 depending on the height of the air guide 100, or hits the inner guide surface 101 of the air guide 100 and then flows in its direction. This can be converted.

When the air guide 100 is raised deep into the slit 57, the portion located below the slit 57 may be eliminated or minimized.

The ceiling-type air conditioner can form an airflow that is closer to horizontal as the height of the air guide (100) is higher, and the lower the height of the air guide (100) is, the more it can form an airflow that is closer to vertical.

<Airflow when air guide rises>

First, when the lifting mechanism 120 raises the air guide 100 as shown in FIG. 20, the air guide 100 is raised to a height where its lower end 103 is in contact with the lower end 54C of the outer guide 54. can be raised to

In this case, the air guided to the outer curved surface 55 of the outer guide 54 may be guided to the deco cover 90 along the lower end 103 of the air guide 100.

To explain in more detail, some of the air passing through the connection passage 26 may flow attached to the outer curved surface 55 of the outer guide 54 due to the Coanda Effect.

The air flowing along the outer curved surface 55 of the outer guide 54 can pass over the lower end 103 of the air guide 100 while maintaining the Coanda effect along the lower end 103 of the air guide 100. , may flow to the bottom of the decor cover 90.

In this case, the air passing through the outlet 25 is guided along the bottom 103 of the air guide 100 and the bottom of the decor cover 90, and can be discharged as a nearly horizontal airflow, and is discharged to the outlet 25. The condensed air can be dispersed by spreading widely throughout the room.

<Airflow when lowering the air guide>

On the other hand, when the lifting mechanism 110 lowers the air guide 100 as shown in FIG. 21, a part of the air guide 100 including its lower end 103 may be lowered below the slit 57. At this time, the air guide 100 may be arranged to protrude downward between the outer guide 54 and the decor cover 90.

When the air guide 100 is lowered as described above, the inner guide surface 101 of the lower part of the air guide 100 may face the inner curved surface 65 of the inner guide 64 in the horizontal direction.

The flow direction of the air passing through the outlet 25 may be changed after a portion of it hits the inner guide surface 101 of the air guide 100.

The air hitting the inner guide surface 101 of the air guide 100 is blocked by the air guide 100 and cannot flow in the horizontal direction, but flows downward in the direction guided by the inner guide surface 101 of the air guide 100. The direction of flow may be bent.

In particular, the air flowing along the outer curved surface 55 of the outer guide 54 may change its flow direction to the downward direction after hitting the inner guide surface 101 of the air guide 100.

The air discharged through the outlet 25 may be guided by the air guide 100 and discharged as a nearly vertical airflow. In this case, the air discharged through the outlet 25 has an inner curved surface 65 around the lower end 67. It may be concentrated and discharged in a downward direction.

<Air flow control signal>

The ceiling-type air conditioner can be configured so that the user can directly adjust the height of the air guide 100 by operating a remote control device such as a remote control or mobile terminal.

In this case, the height of the air guide 100 can be set to at least two levels. It is preferable that the ceiling-type air conditioner is configured so that the user can adjust the height of the air guide 100 at least 3 levels and up to 10 levels.

The receiving unit 27 may receive an airflow control signal from a user or administrator through a remote control device or a central control computer.

The control unit 17 can adjust the height of the air guide 100 based on the airflow control signal received through the receiver 27.

The airflow control signal according to the present invention includes a height adjustment signal that changes the height of the air guide 100 to the user's desired height, an operation mode signal that sets the airflow operation mode to a cooling operation mode or a heating operation mode, and an automatic cooling operation or heating operation mode. It may include an automatic variable signal.

<Air guide height according to height adjustment signal>

First, the height adjustment signal will be explained.

When a height adjustment signal is received, the control unit 17 is capable of continuously raising or lowering the air guide 100 from the current height to the desired height so that it reaches the desired height.

Additionally, the height adjustment signal may include a rising signal to raise the height by one step from the current height, and a falling signal to lower the current height by one step. When an upward signal is received, the control unit 17 is capable of raising the air guide 100 by one step from the current height. And, when the lowering signal is received, the control unit 17 is capable of lowering the air guide 100 by one step from the current height.

Hereinafter, for convenience of explanation, the height of the air guide 100 will be described as being adjustable in 6 steps. In addition, the case where the height of the air guide 100 is highest is described as 1st stage (P1), and the case where the height of the air guide 100 is lowest is described as 6th stage (P6). The second stage (P2), the third stage (P3), the fourth stage (P4), and the fifth stage (P6) may be between the first stage (P1) and the sixth stage (P6).

When the height of the air guide 100 is currently at the 4th stage (P4), when a rising signal is received, the control unit 17 operates the lifting mechanism 120 to raise the height of the air guide 100 to the 3rd stage (P3). The motor 122 can be controlled.

In addition, when the lowering signal is received when the current height of the air guide 100 is 4 steps (P4), the control unit 17 operates the lifting mechanism ( The motor 122 of 120) can be controlled.

In addition, when the current height of the air guide 100 is 4 levels (P4) and the desired height is input as 2 levels (P2), the control unit 17 sets the height of the air guide 100 to 4 levels (P4). The motor 122 of the lifting mechanism 120 can be controlled to rise to the second stage (P2).

<Air guide height according to operation mode signal>

The operation mode signal may include a signal for setting the cooling operation mode and a signal for setting the heating operation mode.

The control unit 17 can control the height of the air guide 100 in the cooling operation mode and the height of the air guide 100 in the heating operation mode to be different from each other.

When the receiver 27 receives an operation mode signal set to the cooling operation mode, the control unit 17 can control the motor 122 of the lifting mechanism 120 so that the air guide 100 reaches the cooling set height. .

And, when the receiver 27 receives the operation mode signal set to the heating operation mode, the control unit 17 controls the motor 122 of the lifting mechanism 120 so that the air guide 100 reaches the heating set height. You can.

The cooling set height may be set higher than the heating set height.

When the height of the air guide (100) is adjusted at least three levels, the cooling set height can be the highest among the heights of the air guide (100). And, the heating set height may be the lowest among the heights of the air guide (100).

The cooling airflow is a descending airflow with a higher density than indoor air, and the cooling set height during cooling operation may be the highest set height among the heights at which the air guide 100 is raised and lowered.

Conversely, the heating airflow is an ascending airflow with a lower density than indoor air, and the heating set height during heating operation may be the lowest set height among the heights at which the air guide 100 is raised and lowered.

When the height of the air guide (100) is configured to be adjustable in 6 stages, the control unit can adjust the height of the air guide (100) to the highest stage (P1) during cooling operation, and during heating operation, the air guide (100) can be adjusted to the highest stage (P1). ) can be adjusted to the lowest level 6 (P6).

The 1st stage (P1) with the highest height of the air guide 100 is the standard height of the cooling operation mode, and the 6th stage (P6) with the lowest height of the air guide 100 is the standard height of the heating operation mode. There is a single number.

Meanwhile, in the cooling operation mode as described above, the user or manager can input a rising signal, a falling signal, or a desired height, and the control unit 17 adjusts the height of the air guide 100 at the cooling set height using a command entered by the user. It can be adjusted according to the height.

In addition, in the heating operation mode as described above, the user or manager can input a rising signal, a falling signal, or a desired height, and the control unit 17 adjusts the height of the air guide 100 at the heating set height using the command entered by the user. It can be adjusted according to the height.

In this case, the ceiling-type air conditioner can adjust the height of the air guide 100 by giving priority to the user's input rather than the reference height according to the operation mode signal.

<Air guide height according to auto variable mode>

The user or administrator can enter the auto variable mode, and in this case, the control unit 17 can control the motor 122 of the lifting mechanism 120 so that the air guide 100 repeatedly rises and falls.

The auto variable mode may include a cooling operation auto variable mode and a heating operation auto variable mode.

According to the auto variable mode, the control unit 17 can repeat raising or lowering the height at least three to four levels without adjusting the height one level at a time.

For example, the control unit 17 lowers the air guide 100 from the 1st stage (P1) to the 4th stage (P4), then raises it again from the 4th stage (P4) to the 1st stage (P1), and The same descent and rise can be repeated, and in this case, the air guide 100 can change the wind direction of the airflow while automatically being lifted to the first (P1) height and the fourth (P4) height.

As another example, the control unit may repeat lowering the air guide 100 from the 3rd stage (P3) to the 6th stage (P6) and then raising it again from the 6th stage (P6) to the 3rd stage (P3). The same descent and rise can be repeated, and in this case, the air guide 100 can change the wind direction of the airflow while automatically being lifted to the 3rd (P3) height and 6th (P6) height.

The auto variable mode can be used for both cooling and heating operations.

The lifting mechanism 120 can lift and lower the air guide 100 in the first lifting range when in the cooling operation automatic variable mode. And, the lifting mechanism 120 can raise and lower the air guide 100 in the second lifting range when in the heating operation automatic variable mode.

Here, the first lifting range may be set higher than the second lifting range. Additionally, the highest stage of the first lifting range may be higher than the highest stage of the second lifting range, and the lowest stage of the first lifting range may be higher than the lowest stage of the second lifting range.

The lowest stage of the first lifting range may be higher, equal to, or lower than the highest stage of the second lifting range.

For example, in the cooling operation automatic variable mode, the control unit 17 lowers the air guide 100 from the 1st stage (P1) to the 4th stage (P4), and then lowers the air guide 100 from the 4th stage (P4) to the 1st stage (P1). You can raise it to , and repeat the descent and rise as above.

In the cooling operation auto variable mode, the air discharged through the outlet 25 may flow as a horizontal airflow or an inclined airflow close to horizontal while the air guide 100 is in the first stage (P1) or the second stage (P2), While the air guide 100 is in the third stage (P3) or fourth stage (P4), it can flow in an inclined air flow that is closer to vertical than when it is in the first stage (P1) or second stage (P2).

Meanwhile, in the heating operation automatic variable mode, the control unit 17 lowers the air guide 100 from the 3rd stage (P3) to the 6th stage (P6) and then raises it again from the 6th stage (P6) to the 3rd stage (P3). can be repeated.

In the heating operation auto variable mode, the air discharged through the outlet (25) may flow as a vertical airflow or an inclined airflow close to vertical while the air guide (100) is in the 5th stage (P5) or 6th stage (P6), During the time when the air guide 100 is in the 3rd (P3) or 4th (P4) stage, it can flow in an inclined air flow that is closer to horizontal than when it is in the 5th (P5) or 6th stage (P6).

Figure 23 is a perspective view showing the outer cover, the lift guide, and the air guide together when there are a plurality of air guide assemblies according to an embodiment of the present invention, and Figure 24 is a view showing the outer cover shown in Figure 23 separated from the lift guide. It is a perspective view, and Figure 25 is a perspective view showing a ceiling-type air conditioner including a plurality of air guide assemblies according to an embodiment of the present invention viewed diagonally from below, and Figure 26 is a plurality of the air conditioners shown in Figure 25. It is a perspective view showing the air guides being raised and lowered equally, Figure 27 is a perspective view showing some of the plurality of air guides shown in Figure 26 being further lowered, and Figure 28 is a perspective view showing the plurality of air guides shown in Figure 26. It is a perspective view showing some of the air guides being raised further, Figures 29 and 30 are perspective views showing the light emitting devices of some of the plurality of air guides shown in Figure 26 being turned off, and Figure 31 is Figure 26. This is a perspective view showing the additional function of the plurality of air guides shown in .

In a ceiling-type air conditioner, a single circular air guide can be arranged to be able to go up and down, and a plurality of arc-shaped air guides 100 can be arranged to be able to go up and down independently of each other.

<Single air guide and shape of air guide>

When a ceiling-type air conditioner includes one circular air guide, the ceiling-type air conditioner can form a horizontal airflow when one circular air guide is raised, and a vertical airflow when one circular air guide is lowered. can be formed. That is, when one circular air guide is raised and lowered, the ceiling-type air conditioner can form only one horizontal airflow or only one vertical airflow.

<Multiple air guides and shape of air guides>

A ceiling-type air conditioner may include a plurality of arc-shaped air guides, and the plurality of arc-shaped air guides may be raised and lowered independently of each other. In this case, some of the plurality of air guides may be raised to form a horizontal air flow, and the remaining air guides may be lowered to form a vertical air flow. That is, when a plurality of arc-shaped air guides 100 are raised and lowered independently of each other, the ceiling air conditioner can form a three-dimensional airflow that is a mixture of horizontal and vertical airflows, and these three-dimensional airflows can be composed of various combinations. there is.

<Airflow control set>

In this embodiment, the outer cover 70, the lifting guide 110, and the air guide assembly (T) may constitute an airflow control set (A) (B) (C) (D). As shown in FIG. 23, a plurality of airflow control sets (A) (B) (C) (D) may be arranged along a circular virtual line (O). In this case, the air guides 100 of the plurality of air guide assemblies T may be arranged along a virtual circle larger than the outlet 25.

The control unit 17 can independently control a plurality of air guide assemblies (T) included in the air flow control set (A) (B) (C) (D).

First, as shown in FIG. 24, the lifting mechanism 120 includes first and second lifting mechanisms 120 connected to the first air guide 100a among the four air guides 100a, 100b, 100c, and 100d. -1) (120-2), the third and fourth lifting mechanisms (120-3) (120-4) connected to the second air guide (100b), and the fifth connected to the third air guide (100c), It may include a sixth lifting mechanism (120-5) (120-6) and a seventh and eighth lifting mechanism (120-7) (120-8) connected to the fourth air guide (100d).

Each of the first to eighth lifting mechanisms 120 may include a motor 122, and each motor 122 may be independently controlled by the control unit 17 of the ceiling air conditioner.

Specifically, the control unit 17 controls the first and second lifting mechanisms 120-1 and 120-2 to raise and lower the first air guide 100a, and to lift and lower the second air guide 100b. To control the third and fourth lifting mechanisms (120-3) (120-4), and to raise and lower the third air guide (100c), the fifth and sixth lifting mechanisms (120-5) (120-6) are used. By controlling, the seventh and eighth lifting mechanisms (120-7) (120-8) can be controlled to raise and lower the fourth air guide (100d).

Additionally, each of the four air guides 100a, 100b, 100c, and 100d may include a pair of light emitting devices 108. One of the pair of light emitting devices 108 may face one end of the guide member 104, and the other of the pair of light emitting devices 108 may face the other end of the guide member 104.

Specifically, among the four air guides (100a) (100b) (100c) (100d), a pair of light emitting devices included in the first air guide (100a) are first and second light emitting devices (108-1) (108). -2), and the pair of light emitting devices included in the second air guide (100b) are the third and fourth light emitting devices (108-3) (108-4), and the pair of light emitting devices included in the third air guide (100c) The pair of light emitting devices is the fifth and sixth light emitting devices (108-5) (108-6), and the pair of light emitting devices included in the fourth air guide (100d) is the seventh and eighth light emitting devices (108-6). It could be -7)(108-8).

The control unit 17 can simultaneously turn on or turn off a pair of light emitting devices included in each air guide among the four air guides 100a, 100b, 100c, and 100d. Specifically, the control unit 17 can simultaneously turn on or turn off the first and second light emitting devices 108-1 and 108-2, and the third and fourth light emitting devices 108-3 and 108 -4) can be turned on or off simultaneously, the fifth and sixth light emitting devices (108-5) (108-6) can be turned on or turned off simultaneously, and the seventh and eighth light emitting devices (108-5) (108-6) can be turned on or turned off simultaneously. 108-7)(108-8) can be turned on or off at the same time.

<Operation of control unit>

According to one embodiment, the control unit 17 may receive an external signal through the receiver 27 installed in the indoor unit 1.

According to another embodiment, the control unit 17 may directly receive external signals by including a receiving unit that receives external signals.

The receiving unit 27 may receive an airflow control signal that raises and lowers at least one air guide 100 among the plurality of air guide assemblies (T). Since the air flow control signal is the same as previously described, it will be omitted here.

When the air flow control signal is received by the receiver 27, the control unit 17 can control the lifting mechanism 120 to raise and lower the at least one air guide 100.

Additionally, the control unit 17 may control at least one light emitting device among the plurality of air guide assemblies (T).

<Light emitting device control>

As shown in FIG. 25, the air guide 100 of the plurality of air guide assemblies T is raised inside the slit 57, and the portion located below the slit 57 is absent or minimized. This may be a case where the power of the ceiling-type air conditioner is turned off, or the ceiling-type air conditioner may be turned on, but the height of the air guide 100 is at level 1 (P1).

When the power of the ceiling-type air conditioner is turned off, the light emitting devices 108 of the plurality of air guide assemblies (T) may be in an off state.

When the ceiling air conditioner is turned on, the control unit 17 can turn on all the light emitting devices 108 of the plurality of air guide assemblies (T).

Hereinafter, for convenience of explanation regarding the operation of the light emitting device, the 'solid arrow' shown in the drawing indicates the light that the light emitting device 108 irradiates at a constant rate, and the 'dotted line arrow' indicates that the light emitting device 108 has at least one The explanation will be made assuming that the light is dimmed and irradiated.

In addition, in the present invention, dimming is explained on the assumption that the light emitting device 108 irradiates light by repeatedly turning on and off at preset periods. That is, dimming at least once indicates that the light emitting device 108 emits light so that it flickers. The period at which the light blinks can be set by user input.

The control unit 17 can turn on the light emitting devices 108 of the plurality of air guide assemblies (T) when the ceiling air conditioner is turned on. The first and second light emitting devices (108-1) (108-2) radiate light toward the center of the first air guide (100a), and the third and fourth light emitting devices (108-3) (108-4) ) radiates light toward the center of the second air guide (100b), and the fifth and sixth light emitting devices (108-5) (108-6) irradiate light toward the center of the third air guide (100c). And, the seventh and eighth light emitting devices (108-7) (108-8) can irradiate light toward the center of the fourth air guide (100d).

At this time, the control unit 18 can control the light emitting devices 108-1 to 108-8 of the plurality of air guide assemblies T to emit light of the same color.

<Light emitting device control according to operation mode>

Meanwhile, a ceiling-type air conditioner may have multiple operation modes. When the operation mode is changed, the control unit 17 can change the color of light emitted by the light emitting devices 108-1 to 108-8 of the plurality of air guide assemblies T. For example, when operating in the cooling operation mode, the control unit 17 controls the plurality of light emitting devices 108-1 to 108-8 to emit blue light, and when changing to the heating operation mode, the plurality of light emitting devices 108-1 to 108-8 are controlled to emit blue light. (108-1 to 108-8) can be controlled to emit orange light, but this is only an example.

<Control of light emitting device according to the raising/lowering of air guide>

When the receiver 27 receives an airflow control signal for raising and lowering at least one air guide (100a, 100b, 100c, and 100d) among the plurality of air guide assemblies (T), the control unit 17 responds to the airflow control signal. Accordingly, the lifting mechanism 120 can be controlled so that at least one air guide (100a) (100b) (100c) (100d) is raised and lowered.

Additionally, the control unit 17 can control the light emitting mechanism 108 together with the lifting mechanism 120.

According to one embodiment, the control unit 17 includes a light emitting device 108 of the air guide 100 in which the lifting mechanism 120 is stopped, and a light emitting device 108 of the air guide 100 in which the lifting device 120 is operating. ) can be controlled differently. For example, the control unit 17 irradiates light constantly to the light emitting device 108 of the air guide 100 when the lifting mechanism 120 is stopped, and to the light emitting device 108 of the air guide 100 where the lifting mechanism 120 is operating. The light emitting device 108 can be controlled to dim at least once. The ceiling air conditioner according to the present invention has the advantage of being able to inform the user of the air guide 100 in which the lifting mechanism 120 is operating by varying the light irradiation method.

For another example, the control unit 17 determines the amount of light emitted by the light emitting device 108 of the air guide 100 in which the lifting mechanism 120 is stopped to the light emitting device 108 in the air guide 100 in which the lifting mechanism 120 is operating. (108) can be controlled to be less than the amount of light irradiated.

For another example, the control unit 17 determines the color of the light emitted by the light emitting device 108 of the air guide 100 in which the lifting mechanism 120 is stopped and the color of the light emitted by the light emitting device 108 in the air guide 100 in which the lifting mechanism 120 is operating. The color of the light emitted by the light emitting device 108 can be controlled to be different.

The ceiling air conditioner according to the present invention has the advantage of being able to inform the user of the air guide 100 in which the lifting mechanism 120 is operating by varying the amount or color of light.

According to another embodiment, the control unit 17 may dim the light emitting device 108 of the air guide 100 being lifted by the lifting device 120 at least once.

For example, as shown in FIG. 27, the control unit 17 dims the light emitting devices 108-7 and 108-8 of the descending air guide 100d at least once and dims the other air guide 100a (100a). The light emitting mechanisms 108-1, 108-2, 108-3, 108-4, 108-5, and 108-6 of 100b) (100c) can be controlled to emit light at a constant rate. Alternatively, the control unit 17 dims the light emitting devices 108-7 and 108-8 of the rising air guide 100d at least once, as shown in Figure 28, and other air guides 100a and 100b. The light emitting devices 108-1, 108-2, 108-3, 108-4, 108-5, and 108-6 of (100c) can be controlled to emit light at a constant rate.

The ceiling air conditioner according to the present invention has the advantage of being able to inform the user of the air guide 100 being lifted by dimming the light emitting device 108 of the air guide 100 being lifted.

According to another embodiment, when the height adjustment signal is received by the receiver 27, the control unit 17 operates the lifting mechanism 120 of the air guide 100 corresponding to the height adjustment signal and operates the height adjustment signal. The light emitting device 108 of the air guide 100 can be dimmed at least once.

For example, as shown in FIG. 27, the control unit 17 sends any one of the plurality of air guides 100a, 100b, 100c, and 100d to the receiver 27 at the current height. When receiving a height adjustment signal to adjust to a lower height, the light emitting mechanism 108-7 and 108-8 of the air guide 100d are dimmed at least once while operating the lifting mechanism 120 of the air guide 100d. You can do it.

On the contrary, as shown in FIG. 28, the control unit 17 sends any one of the plurality of air guides 100a, 100b, 100c, and 100d to a receiver 27 higher than the current height. When receiving a height adjustment signal to adjust the height, the light emitting mechanism (108-7) (108-8) of the air guide (100d) can be dimmed at least once while operating the lifting mechanism (120) of the air guide (100d). there is.

<Control of light emitting devices according to light control signals>

The receiving unit 27 may receive a light control signal that controls at least one light emitting device 108 among the plurality of air guide assemblies (T).

In the present invention, the light control signal is a signal that controls the light emitting device 108 included in the air guide 100. Specifically, the light control signal is a signal that turns on or off the power of the light emitting device 108, a signal that dims the light emitting device 108, a signal that changes the color of the light emitted by the light emitting device 108, and a signal that changes the color of the light emitted by the light emitting device 108. ) may include a signal that controls the brightness (amount of light) of the irradiated light.

When the receiver 27 receives the light control signal, the control unit 17 can control at least one light emitting device 108 among the plurality of air guide assemblies (T). In this case, the control unit 17 can control the light emitting mechanism 108 regardless of the operation of the lifting mechanism 120.

For example, as shown in FIG. 29, when the control unit 17 receives a light control signal that turns off at least one light emitting device 120 among the plurality of air guide assemblies (T), it responds to the received light control signal. A pair of light emitting devices 108-7 and 108-8 included in the air guide 100d can be turned off. That is, the control unit 17 turns off a pair of light emitting devices (108-7) (108-8) corresponding to one air guide (100d) and turns off the remaining air guides (100a) (100b) (100c). It can be controlled to turn on the corresponding light emitting devices (108-1) (108-2) (108-3) (108-4) (108-5) (108-6).

In particular, as shown in Figure 30, when at least one air guide (100d) is raised deeply into the slit 57, the light emitting mechanism (108-7) (108-8) of the raised air guide (100d) The light emitted from may be difficult for users to observe. In this case, the user inputs a light control signal that turns off the light emitting devices 108-7 and 108-8 of the air guide 100d raised inside the slit 57, thereby turning off the light emitting devices 108-7 and 108. -8) has the effect of reducing the power consumed.

<Light emitting device control according to automatic settings>

Meanwhile, as shown in FIG. 30, when at least one air guide (100d) is raised deeply into the slit 57, the control unit 17 controls the air raised into the slit 57 regardless of the light control signal. The light emitting mechanisms 108-7 and 108-8 of the guide 100d can be automatically turned off. Specifically, the control unit 17 may detect the rising height of the air guide 100 included in each of the plurality of air guide assemblies (T) through a sensing unit (not shown). When the air guide 100 rises above the preset depth of the slit 57, the control unit 17 can automatically turn off the light emitting device 108 of the air guide 100.

<Control of light emitting devices according to additional functions>

Additional functions may be set in the ceiling air conditioner according to the present invention.

In the present invention, the additional function may mean ancillary functions required for the cooling/heating function other than the function of the ceiling air conditioner to cool or heat the room. Additional functions may include a filter cleaning function, a defrost function, and a reservation setting function, but since this is only an example, other additional functions or fewer additional functions may be included.

The filter cleaning function is a function in which a filter cleaning unit (not shown) installed in a ceiling-type air conditioner removes foreign substances from the filter (not shown). The ceiling-type air conditioner may include a filter disposed on the suction panel 3 and a filter cleaning unit disposed to move along the filter. In this case, the filter cleaning unit moves along the filter and removes foreign substances attached to the filter. It can be separated from .

When the ceiling-type air conditioner performs the filter cleaning function as described above, it is desirable to display externally that the ceiling-type air conditioner is currently performing the filter cleaning function.

The defrost function is a function that defrosts frost on an outdoor heat exchanger (not shown) installed in an outdoor unit (not shown) connected to a ceiling-type air conditioner. If frost forms on the outdoor heat exchanger during the heating operation mode, the ceiling-type air conditioner and the outdoor unit may be switched from the heating operation mode to the cooling operation mode. In this case, the high-temperature/high-pressure refrigerant discharged from the compressor of the outdoor unit flows into the outdoor heat exchanger to remove frost deposited on the surface of the outdoor heat exchanger. If all the frost on the outdoor heat exchanger is defrosted during the cooling operation mode as described above, the ceiling air conditioner and the outdoor unit can be switched back to the heating operation mode.

When the ceiling-type air conditioner performs the defrost function as described above, it is desirable to display externally that the ceiling-type air conditioner is currently performing the defrost function.

The reservation setting function is a function that schedules the ceiling air conditioner to operate automatically based on user input. The user can input various commands in advance, such as power-on time, power-off time, desired temperature, and desired humidity, through a remote control device such as a remote control or mobile terminal, and the ceiling air conditioner follows the various commands entered in this way. It can be controlled.

It is desirable for the ceiling-type air conditioner to display externally that the above reservation has been entered.

The receiver 27 may receive an air flow control signal that sets an operation mode for cooling/heating the room, or an additional function setting signal that sets the above additional functions. Based on the signal received by the receiver 27, the control unit 17 can operate in any operation mode for cooling/heating the room or execute additional functions.

In this case, the control unit 17 sets the light emitting devices 108 of the plurality of air guide assemblies T so that the number of light emitting devices 108 turned on during the additional function is less than the light emitting devices 108 turned on during the operation mode. can be controlled.

Specifically, when the additional function is set, the control unit 17 can turn on the light emitting device 108 included in one air guide 100 among the plurality of air guide assemblies T. For example, as shown in Figure 31, the light emitting devices (108-7) (108-8) included in one air guide (100d) are turned on, and the remaining air guides (100a) (100b) (100d) are turned on. The light emitting devices (108-1) (108-2) (108-3) (108-4) (108-5) (108-6) included in can be turned off.

Meanwhile, when using the additional function of the filter cleaning function, the control unit 17 can display differently when the filter cleaning unit is currently operating and when the filter cleaning unit is currently stopped.

For example, the control unit 17 controls the light emitting device so that the colors (e.g., green and orange) of the light emitted by the on-light emitting device are different when the filter cleaning unit is currently operating and when the filter cleaning unit is currently stopped. You can control it.

Through this, the user has the advantage of being able to know whether the ceiling air conditioner is operating in operation mode or executing an additional function.

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

Accordingly, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention, but are for illustrative purposes, and the scope of the technical idea of the present invention is not limited by these embodiments.

The scope of protection of the present invention should be interpreted in accordance with the claims below, and all technical ideas within the equivalent scope should be construed as being included in the scope of rights of the present invention.

2: Discharge panel 17: Control unit
25: Exit 27: Receiving unit
T: Air guide assembly 100: Air guide
104: Guide member 108: Light emitting mechanism
120: Elevating mechanism

Claims (20)

a discharge panel having an outlet through which air is discharged to the outside;
a plurality of air guide assemblies mounted on the discharge panel to guide air discharged to the outlet;
Comprising a control unit that independently controls the plurality of air guide assemblies,
Each of the plurality of air guide assemblies
an air guide (100) having a guide member (104) that changes the direction of airflow of the air passing through the outlet, and a light emitting device (108) that irradiates light to the guide member (104);
It includes a lifting mechanism 120 that elevates the guide member 104 and the light emitting device 108 together,
The air guide includes a pair of light emitting devices,
A ceiling-type air conditioner wherein one of the pair of light emitting devices faces one end of the guide member, and the other one of the pair of light emitting devices faces the other end of the guide member. According to paragraph 1,
The air guide 100 is
A ceiling-type air conditioner further comprising an upper mounter (107) to which each of the guide member (104) and the light emitting device (108) is coupled and which is raised and lowered by the lifting mechanism (120). According to paragraph 1,
The control unit
A ceiling-type air conditioner that turns on the light emitting devices of the plurality of air guide assemblies when the power of the ceiling-type air conditioner is turned on. According to paragraph 3,
The control unit
A ceiling-type air conditioner that controls the light emitting devices of the plurality of air guide assemblies to emit light of the same color. According to paragraph 3,
The ceiling air conditioner has a plurality of operation modes,
The control unit
A ceiling-type air conditioner that changes the color of light emitted by the light emitting device of the plurality of air guide assemblies when the operation mode is changed. According to paragraph 1,
It further includes a receiving unit that receives an external signal,
The control unit
If the signal received by the receiver is an airflow control signal for raising and lowering at least one air guide among the plurality of air guide assemblies, a ceiling type for controlling the lifting mechanism to raise and lowering the at least one air guide according to the airflow control signal. Air conditioner. According to clause 6,
The airflow control signal is
A ceiling-type air conditioner that is a height adjustment signal that changes the height of the air guide to the user's desired height. In clause 7,
The control unit
A ceiling-type air conditioner that dims the light emitting device of the air guide assembly corresponding to the height adjustment signal at least once. According to clause 6,
The airflow control signal is
It is an operation mode signal that is set to cooling operation mode or heating operation mode,
The control unit
If the operation mode signal is a signal for setting the cooling operation mode, the air guide is adjusted to the cooling setting height. If the operation mode signal is a signal for setting the heating operation mode, the air guide is adjusted to the heating setting height,
A ceiling-type air conditioner in which the cooling set height is higher than the heating set height. According to clause 6,
The airflow control signal is
It is an auto variable signal that is set to cooling operation auto variable mode or heating operation auto variable mode,
The control unit
If the auto-variable signal is a signal that sets the cooling operation auto-variable mode, the air guide is raised and lowered in the first lifting range. If the auto-variable signal is a signal that sets the heating operation auto-variable mode, the air guide is raised and lowered in the second lifting range. Elevate within the lifting range,
A ceiling-type air conditioner wherein the first lifting range is higher than the second lifting range. According to any one of claims 6 to 10,
The control unit
A ceiling-type air conditioner that dims a light emitting device of an air guide being raised and lowered by the lifting mechanism among the plurality of air guide assemblies at least once. According to clause 6,
The receiving unit further receives a light control signal for controlling at least one light emitting device among the plurality of air guide assemblies,
The control unit
A ceiling-type air conditioner that turns on or off the light emitting device of the air guide assembly corresponding to the received light control signal. delete According to paragraph 1,
The control unit
A ceiling-type air conditioner that simultaneously turns on or turns off the pair of light emitting devices. According to paragraph 1,
A ceiling-type air conditioner wherein the air guides of the plurality of air guide assemblies are arranged along an imaginary circle larger than the outlet. According to paragraph 1,
The control unit is a ceiling-type air conditioner that controls the light emitting devices of the plurality of air guide assemblies so that the number of light emitting devices turned on during the operation mode is greater than the number of light emitting devices turned on during the additional function. According to clause 16,
The above additional functions are
Ceiling-type air conditioner with filter cleaning function, defrost function, and reservation setting function. a discharge panel having an outlet through which air is discharged to the outside;
a plurality of air guide assemblies mounted on the discharge panel to guide air discharged to the outlet;
Comprising a control unit that independently controls the plurality of air guide assemblies,
Each of the plurality of air guide assemblies
an air guide having a guide member that changes the direction of airflow of the air passing through the outlet, and a light emitting mechanism that irradiates light to the guide member;
It includes a lifting mechanism that elevates the guide member and the light emitting device together,
The control unit differently controls the light emitting mechanism of the air guide when the lifting mechanism is stopped and the light emitting mechanism of the air guide when the lifting mechanism is operating,
The air guide includes a pair of light emitting devices,
A ceiling-type air conditioner wherein one of the pair of light emitting devices faces one end of the guide member, and the other one of the pair of light emitting devices faces the other end of the guide member. According to clause 18,
It further includes a receiving unit that receives an external signal,
The control unit
If the signal received by the receiver is an airflow control signal for raising or lowering at least one air guide among the plurality of air guides,
A ceiling-type air conditioner that operates the lifting mechanism of the air guide corresponding to the air flow control signal and dims the light emitting device of the air guide corresponding to the air flow control signal at least once. According to clause 19,
The control unit is a ceiling-type air conditioner that maintains the light emitting device of the air guide in which the airflow control signal is not received by the receiver.

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