KR102550360B1 - Air conditioner - Google Patents

Abstract

The present disclosure relates to an air conditioner, and the air conditioner of the present disclosure includes a case in which a suction port and a discharge port are formed; a fan disposed inside the case; a heat exchanger disposed inside the case and exchanging heat with the air introduced through the inlet; a vane motor disposed in the case; a driving link rotatably connected to the vane motor; a first vane disposed in the discharge port and rotatably connected to the driving link; a second vane disposed in the discharge port to be separated from the first vane and rotatably connected to the driving link; a room temperature sensor for measuring the temperature of the air introduced through the inlet; a humidity sensor for measuring the humidity of the air introduced through the inlet; and a controller controlling the vane motor based on the measured values of the indoor temperature sensor and the humidity sensor, wherein the controller is configured to: , by controlling the vane motor so that the distance between the first vane and the second vane is widened, and the distance between the first vane and the second vane is widened in an environment where the temperature and humidity of the room are high, so as to cool the outside of the indoor unit. It has the advantage of preventing dew formation on the vane by rapidly discharging air.

Description

Air conditioner {AIR CONDITIONER}

The present invention relates to an air conditioner, and more particularly, to an air conditioner in which dew formation on vanes is prevented.

An air conditioner is a device that sucks in indoor air, exchanges heat with it, and then supplies the heat-exchanged air to the room.

A heat exchanger is disposed inside the indoor unit of the air conditioner, and air introduced into the indoor unit in a cooling mode is cooled while passing through the heat exchanger and supplied to the room.

However, when the air conditioner is operated in the cooling mode in summer when the temperature and humidity are high, the air around the outlet of the indoor unit drops to the dew point temperature due to the cold air discharged from the indoor unit, causing excessive dew to form on the vanes of the indoor unit.

Korean Publication No. 10-2014-0101284 discloses a structure in which a plurality of vanes are driven at an indoor unit discharge port, but there is a problem in that a method for preventing dew formation on vanes in a high temperature and humidity environment is not disclosed.

Korean Publication Document 10-2014-0101284

An object to be solved by the present invention is to provide an air conditioner that prevents dew formation on vanes.

Another object of the present invention is to provide an air conditioner in which the optimal angle of a vane is changed according to the temperature and humidity of an indoor space.

Another object of the present invention is to provide an air conditioner in which the positional relationship of a plurality of vanes for preventing dew formation is optimized.

Another object of the present invention is to provide an air conditioner in which an angle of a vane continuously changes according to a change in an indoor environment.

The tasks of the present invention are not limited to the tasks mentioned above, and other tasks not mentioned will be clearly understood by those skilled in the art from the following description.

In order to achieve the above object, an air conditioner according to an embodiment of the present invention includes a case in which a suction port and a discharge port are formed; a fan disposed inside the case; a heat exchanger disposed inside the case and exchanging heat with the air introduced through the inlet; a vane motor disposed in the case; a driving link rotatably connected to the vane motor; a first vane disposed in the discharge port and rotatably connected to the driving link; a second vane disposed in the discharge port to be separated from the first vane and rotatably connected to the driving link; a room temperature sensor for measuring the temperature of the air introduced through the inlet; a humidity sensor for measuring the humidity of the air introduced through the inlet; and a controller controlling the vane motor based on measured values of the room temperature sensor and the humidity sensor.

The controller controls the vane motor to widen the gap between the first vane and the second vane when each of the measured values of the room temperature sensor and the humidity sensor is equal to or greater than a preset limit value, thereby increasing the indoor space. Under conditions of excessively high temperature and humidity, the air introduced into the indoor unit is smoothly discharged between the first vane and the second vane, so that dew formation can be prevented.

The controller is configured to widen the gap between the first vane and the second vane when the measurement value of the room temperature sensor is equal to or greater than the preset indoor temperature limit value and the measurement value of the humidity sensor is equal to or greater than the preset humidity limit value in an overhumid condition. The vane motor may be controlled to

The gap may be formed between the lower surface of the first vane and the upper surface of the second vane in the over-humidity condition.

Under the over-humidity condition, the rear end of the first vane may be positioned higher than the front end of the second vane.

The controller may control the vane motor to move the first vane and the second vane in directions opposite to each other in the over-humidity condition.

Under the over-humidity condition, an inclination angle of the first vane with respect to a horizontal direction may be smaller than an inclination angle of the second vane with respect to a horizontal direction.

The air conditioner may include a first vane link rotatably connected to the case and the first vane, respectively; A second vane link rotatably connected to each of the driving link and the second vane may be further included.

Under the over-humidity condition, the first vane link and the second vane link may move in opposite directions.

In the over-humidity condition, the first vane link may be inclined toward the outside of the case.

In the over-humidity condition, the second vane link may be inclined toward the inside of the case.

The controller operates the vane motor to widen the gap between the first vane and the second vane when the overhumidity condition is satisfied and the rear end of the first vane and the front end of the second vane face each other. You can control it.

The controller may control the vane motor to widen a gap between the first vane and the second vane when the over-humidity condition lasts for a predetermined time.

The controller determines that the distance between the first vane and the second vane is narrow when the measured value of the room temperature sensor is less than a preset indoor temperature limit value or the measured value of the humidity sensor is less than a preset humidity limit value. The vane motor may be controlled to

The controller operates the vane motor so that a distance between the first vane and the second vane is widened when each of the measured values of the room temperature sensor and the humidity sensor is equal to or greater than a preset limit value after the release condition. You can control it.

The air conditioner may include a cooling device connected to the case through a pipe; and a pump disposed between the cooling device and the heat exchanger.

Air introduced through the inlet may exchange heat with water flowing in the pipe.

The air conditioner may further include a water temperature sensor for measuring the temperature of water flowing in the pipe.

The controller may control the vane motor to widen a gap between the first vane and the second vane when the measured value of the water temperature sensor is equal to or less than a preset water temperature limit value.

The controller is configured such that the measured value of the room temperature sensor is greater than or equal to a preset room temperature limit value, the measurement value of the humidity sensor is greater than or equal to a preset humidity limit value, and the measurement value of the water temperature sensor is less than or equal to a preset water temperature limit value; When the rear end of the first vane and the front end of the second vane are disposed to face each other, the vane motor may be controlled to widen a gap between the first vane and the second vane.

Details of other embodiments are included in the detailed description and drawings.

According to the air conditioner of the present invention, there are one or more of the following effects.

First, there is an advantage in preventing dew formation on the vanes by rapidly discharging cold air to the outside of the indoor unit due to the widening of the distance between the first vane and the second vane in an environment of high indoor temperature and humidity.

Second, by properly adjusting the angle of the first vane and the second vane in an environment of high indoor temperature and humidity, there is also an advantage of preventing dew formation on the vane.

Third, there is an advantage of maximizing the dew formation prevention effect by optimizing the positional relationship between the first vane and the second vane in an environment with high indoor temperature and humidity.

Fourth, by adjusting the vane angle according to the changing temperature and humidity of the room, there is also an advantage of securing the adaptability of the vane angle to the environment.

The effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the description of the claims.

1 is a schematic system diagram of an air conditioner according to an embodiment of the present invention.
2 is a detailed system diagram of an air conditioner according to an embodiment of the present invention.
3 is a longitudinal cross-sectional view of an indoor unit according to an embodiment of the present invention.
4 is a perspective view of a vane assembly according to an embodiment of the present invention.
5 is a first operational example of a vane assembly according to an embodiment of the present invention.
6 is a second operational example of a vane assembly according to an embodiment of the present invention.
7 is a third operational example of a vane assembly according to an embodiment of the present invention.
8 is a fourth operational example of a vane assembly according to an embodiment of the present invention.
9 is a fifth operational example of a vane assembly according to an embodiment of the present invention.
10 is a sixth operational example of a vane assembly according to an embodiment of the present invention.
11 is a control block diagram schematically illustrating a control method of an air conditioner according to an embodiment of the present invention.
12 is a control block diagram showing in detail a control method of an air conditioner according to an embodiment of the present invention.

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

Hereinafter, the present invention will be described with reference to drawings for explaining an air conditioner according to embodiments of the present invention.

Hereinafter, the entire system of the air conditioner 1 will be described with reference to FIG. 1 . 1 conceptually shows the entire system of the air conditioner (1).

An air conditioner (1) according to an embodiment of the present invention includes an outdoor unit (10), a plurality of indoor units (200) connected to the outdoor unit (10) to adjust the temperature of an indoor space, and a refrigerant circulating through the outdoor unit (10). A relay device 20 through which water circulating through the plurality of indoor units 200 is heat-exchanged may be included.

The plurality of indoor units 200 may include a first indoor unit 200a, a second indoor unit 200b, a third indoor unit 200c, and a fourth indoor unit 200d. The first indoor unit 200a, the second indoor unit 200b, the third indoor unit 200c, and the fourth indoor unit 200d may be disposed separately from each other.

The outdoor unit 10 may cool the refrigerant and supply it to the relay device 20 when the air conditioner 1 is operated in the cooling mode. After the water circulating through the indoor unit 200 is cooled by heat exchange with the refrigerant in the relay device 20 , it may flow into the indoor unit 200 .

The outdoor unit 10 may heat the refrigerant and supply it to the relay device 20 when the air conditioner 1 is operated in the heating mode. Water circulating through the indoor unit 200 may be heated by exchanging heat with the refrigerant in the relay device 20 and then introduced into the indoor unit 200 .

As a cooling device for heating or cooling water circulating through the indoor unit 200, an absorption chiller, a boiler, or a cooling tower may be used in addition to the outdoor unit 10 through which a refrigerant circulates. The outdoor unit 10 may be referred to as a “cooling device”.

The relay device 20 may be disposed inside the outdoor unit 10 or may be separately disposed outside the outdoor unit 10 .

The air conditioner 1 may include three refrigerant pipes 110 , 120 , and 130 connecting the outdoor unit 10 and the relay device 20 . That is, the outdoor unit 10 and the repeater 20 may have a "three pipe connection structure". The refrigerant may circulate between the outdoor unit 10 and the relay device 20 through the three refrigerant pipes 110, 120, and 130.

The three refrigerant pipes 110, 120, and 130 include a high-pressure engine 110 through which high-pressure gaseous refrigerant flows, a low-pressure engine 120 through which low-pressure gaseous refrigerant flows, and a liquid pipe 130 through which liquid refrigerant flows. can include The high-pressure engine 110 may be connected to the discharge side of the compressor 12 disposed in the outdoor unit 10 . The low pressure engine 120 may be connected to the suction side of the compressor 12 . The liquid pipe 130 may be connected to the outdoor heat exchanger 14 disposed in the outdoor unit 10 .

The air conditioner 1 may include a plurality of water pipes connecting the repeater 20 and the plurality of indoor units 200 , respectively. A water supply pipe 150 through which water is supplied from the relay device 20 and a water discharge pipe 152 through which water is discharged to the relay device 20 may be connected to each of the plurality of indoor units 200 . The water pipe may include a water supply pipe 150 and a water discharge pipe 152. The water supply pipe 150 and the water discharge pipe 152 may be provided to correspond to the number of indoor units 200 .

The outdoor unit 10 may include a simultaneous cooling/heating type outdoor unit. The outdoor unit 10 and the repeater 20 may be fluidly connected by the first fluid. The first fluid may be a refrigerant.

The outdoor unit 10 includes a compressor 12 for compressing refrigerant, an outdoor heat exchanger 14 disposed inside the outdoor unit and exchanging heat between external air and the refrigerant, and disposed on one side of the outdoor heat exchanger 14 to form an outdoor heat exchanger. (14) may include an outdoor fan 16 for forming air flow. By driving the outdoor fan 16, outside air flows into the outdoor heat exchanger 14, and heat exchange between the refrigerant and the air can be performed.

The outdoor unit 10 may further include an outdoor expansion valve 18 for expanding refrigerant discharged from the outdoor heat exchanger 14 or supplied to the outdoor heat exchanger 14 .

The plurality of indoor units 200 may include simultaneous cooling and heating type indoor units. Each of the plurality of indoor units 200 and the repeater may be fluidly connected by a second fluid. The second fluid may be water.

Each of the plurality of indoor units 200 includes an indoor heat exchanger 210 disposed inside the indoor unit 200 and exchanging heat between sucked air and water, and disposed on one side of the indoor heat exchanger 210 to form air flow. An indoor fan 260 may be included.

Hereinafter, a detailed system of the air conditioner 1 will be described with reference to FIG. 2 . 2 conceptually shows a detailed system of the air conditioner (1).

The relay device 20 is disposed in relay heat exchangers 22 and 24 for exchanging heat between the refrigerant and water, pumps 26 and 28 for circulating water, and refrigerant pipes 110, 120 and 130 so that the refrigerant flows It may include a plurality of refrigerant valves for adjusting the refrigerant, and a flow path switching device 30 disposed in the water pipe to control the flow of water.

Inside the relay device 20, refrigerant pipes 110, 120, 130 connecting the outdoor unit 10 and the relay heat exchangers 22, 24, and a plurality of indoor units 200 and the relay heat exchangers 22, 24 A water pipe connecting the may be disposed.

The relay device 20 may be disposed inside the outdoor unit 10 . Accordingly, components disposed inside the repeater 20 may also be disposed inside the outdoor unit 10 .

The refrigerant pipes 110, 120, and 130 may include a high-pressure engine 110 through which high-pressure gaseous refrigerant flows, a low-pressure engine 120 through which low-pressure gaseous refrigerant flows, and a liquid pipe 130 through which liquid refrigerant flows. can

The high-pressure engine 110 may include a first high-pressure guide pipe 112 connected to the first intermediate heat exchanger 22 and a second high-pressure guide pipe 114 connected to the second intermediate heat exchanger 24. can In the high-pressure engine 110, a high-pressure branch point 116 branching into a first high-pressure guide pipe 112 and a second high-pressure guide pipe 114 may be formed.

The low pressure engine 120 may include a first low pressure guide pipe 122 connected to the first intermediate heat exchanger 22 and a second low pressure guide pipe 124 connected to the second intermediate heat exchanger 24. can The low pressure engine 120 may have a low pressure branch point 126 branching into a first low pressure guide pipe 122 and a second low pressure guide pipe 124 .

The first low pressure guide pipe 122 and the first high pressure guide pipe 112 are combined with the first refrigerant pipe 128 and connected to the first intermediate heat exchanger 22, and the second low pressure guide pipe 124 and The second high-pressure guide pipe 114 may be joined to the second refrigerant pipe 129 and connected to the second intermediate heat exchanger 24 .

The liquid pipe 130 may include a first liquid guide pipe 132 connected to the first intermediate heat exchanger 22 and a second liquid guide pipe 134 connected to the second intermediate heat exchanger 24 . A liquid pipe branch point 136 branching into the first liquid guide pipe 132 and the second liquid guide pipe 134 may be formed in the liquid pipe 130 .

The plurality of refrigerant valves may change the flow direction of the refrigerant by operating the valves. In addition, the plurality of refrigerant valves can adjust the flow rate of the refrigerant by operating the valves.

The plurality of refrigerant valves are disposed in the first high-pressure guide pipe 112 and the second high-pressure guide pipe 114, respectively, to open and close the first high-pressure guide pipe 112 and the second high-pressure guide pipe 114. (142a, 142b), a low pressure valve disposed in the first low pressure guide pipe 122 and the second low pressure guide pipe 124, respectively, to open and close the first low pressure guide pipe 122 and the second low pressure guide pipe 124. (144a, 144b), the first liquid guide pipe 132 and the second liquid guide pipe 134 disposed in each of the liquid pipe valves for adjusting the flow rate of the refrigerant flowing through the refrigerant pipes (110, 120, 130) ( 146a, 146b).

The water pipe includes inlet pipes 154 and 156 for guiding water to flow into the intermediate heat exchangers 22 and 24 and discharge pipes 160 and 162 for guiding water discharged from the intermediate heat exchangers 22 and 24. can include

The inflow pipes 154 and 156 may guide water passing through the indoor unit 200 to flow to the intermediate heat exchangers 22 and 24 . The discharge pipes 160 and 162 may guide water passing through the intermediate heat exchangers 22 and 24 to flow into the indoor unit 200 .

The inlet pipes 154 and 156 include a first inlet pipe 154 for guiding water to the first intermediate heat exchanger 22 and a second inlet pipe 156 for guiding water to the second intermediate heat exchanger 24. can include The discharge pipes 160 and 162 are the first discharge pipe 160 for guiding water passing through the first intermediate heat exchanger 22 to the indoor unit 200 and the water passing through the second intermediate heat exchanger 24 to the indoor unit. It may include a second discharge pipe 162 guiding to (200).

The first inlet pipe 154 may extend to the water inlet of the first intermediate heat exchanger 22 . The first discharge pipe 160 may extend from the water outlet of the first intermediate heat exchanger 22 . Similarly, the second inlet pipe 156 may extend to the water inlet of the second intermediate heat exchanger 24 . The second discharge pipe 162 may extend from the water outlet of the second intermediate heat exchanger 24 .

Each of the inlet pipes 154 and 156 and the outlet pipes 160 and 162 may extend to the flow path conversion device 30 . The water introduced into the water inlet of the intermediate heat exchanger (22, 24) through the inflow pipe (154, 156) exchanges heat with the refrigerant and then passes through the water outlet of the intermediate heat exchanger (22, 24) to the water discharge pipe (160, 24). 162) can flow.

The water pipe includes a plurality of indoor inlet pipes 170a, 170b, 170c, and 170d for guiding water to flow into each of the plurality of indoor units 200 and a plurality of indoor inlet pipes 170a, 170b, 170c, and 170d for guiding water discharged from each of the plurality of indoor units 200. Indoor discharge pipes 172a, 172b, 172c, and 172d may be included.

Each of the plurality of indoor inlet pipes 170a, 170b, 170c, and 170d and the plurality of indoor discharge pipes 172a, 172b, 172c, and 172d is connected to the flow path switching device 30.

The indoor inflow pipes 170a, 170b, 170c, and 170d include a first indoor inflow pipe 170a coupled to the inlet of the first indoor unit 200a and a second indoor inflow pipe coupled to the inlet of the second indoor unit 200b. It may include a pipe 170b, a third indoor inlet pipe 170c coupled to the inlet of the third indoor unit 200c, and a fourth indoor inlet pipe 170d coupled to the inlet of the fourth indoor unit 200d. there is. Each of the first indoor inflow pipe 170a, the second indoor inflow pipe 170b, the third indoor inflow pipe 170c, and the fourth indoor inflow pipe 170d may be connected to the flow path switching device 30.

The indoor discharge pipes 172a, 172b, 172c, and 172d include a first indoor discharge pipe 172a coupled to the outlet of the first indoor unit 200a and a second indoor discharge pipe 172b coupled to the outlet of the second indoor unit 200b. ), a third indoor discharge pipe 172c coupled to the outlet of the third indoor unit 200c, and a fourth indoor discharge pipe 172d coupled to the outlet of the fourth indoor unit 200d. Each of the first indoor discharge pipe 172a, the second indoor discharge pipe 172b, the third indoor discharge pipe 172c, and the fourth indoor discharge pipe 172d may be connected to the flow path switching device 30.

The intermediate heat exchangers 22 and 24 may be provided so that the refrigerant flow path and the water flow path exchange heat with each other. The relay heat exchangers 22 and 24 may be plate type heat exchangers capable of exchanging heat between water and a refrigerant. The intermediate heat exchangers 22 and 24 may be configured such that passages through which refrigerant flows and passages through which water flows are alternately laminated.

The relay heat exchangers 22 and 24 may be provided in plurality to selectively provide cooling and heating to each of the plurality of indoor units 200 . The intermediate heat exchangers 22 and 24 may include a first intermediate heat exchanger 22 and a second intermediate heat exchanger 24 . The first intermediate heat exchanger 22 can heat water by exchanging heat with the refrigerant, and the second intermediate heat exchanger 24 can cool water by exchanging heat with the refrigerant. The first intermediate heat exchanger 22 may be referred to as a "condenser" and the second intermediate heat exchanger 24 may be referred to as an "evaporator".

However, this is according to one embodiment, and it is a structure in which the first intermediate heat exchanger 22 cools water and the second intermediate heat exchanger 24 heats water, or the first intermediate heat exchanger 22 and Second intermediate heat exchangers 24 may alternate with each other to cool or heat water.

Water flowing in the water pipe can selectively flow into the first intermediate heat exchanger 22 or the second intermediate heat exchanger 24 according to the operation mode of the indoor unit 200 and exchange heat with the refrigerant.

The pumps 26 and 28 may provide pressure so that the water in the inlet pipes 154 and 156 is directed to the intermediate heat exchangers 22 and 24. The pump 200 may be installed in a water pipe to set a flow direction of the second fluid. The second fluid may be water.

The pumps 26 and 28 may be disposed in the indoor inlet pipes 170a, 170b, 170c, and 170d or the indoor discharge pipes 172a, 172b, 172c, and 172d.

The pumps 26 and 28 may include a first pump 26 installed in the first inlet pipe 154 and a second pump 28 installed in the second inlet pipe 156 .

Hereinafter, the structure of the indoor unit 200 will be described with reference to FIG. 3 . 3 is a cross-sectional view showing the internal structure of the indoor unit 200 by cutting it in the vertical direction.

The indoor unit 200 includes a case 203 in which a suction port 201 and a discharge port 202 are formed, a fan 260 disposed inside the case 203, and a suction port 101 disposed inside the case 203. It includes a heat exchanger 210 for exchanging heat with the air introduced through.

The indoor heat exchanger 210 may be referred to as "heat exchanger 210", and the indoor fan 260 may be referred to as "fan 260".

The case 203 may form the exterior of the indoor unit 200 . The case 203 may include an upper body 220 forming a space inside and a lower body 230 disposed below the upper body 220 .

The indoor heat exchanger 210 and the indoor fan 260 may be disposed in the inner space of the upper body 220 . A fan motor 261 providing power to the indoor fan 260 may be disposed in the inner space of the upper body 220 .

The indoor unit 200 includes a grill 240 connected to a case 203 and having an inlet 201 formed therein, a bell mouth 250 disposed between the grill 240 and a fan 260, and a relay heat exchanger 22 , 24) and the indoor heat exchanger 210, and a vane assembly 300 disposed at the discharge port 202.

The grill 240 may be disposed inside the lower body 230 . The grill 240 may be detachably disposed on the case 203 . A plurality of outlets 201 may be formed to be spaced apart from each other in the grill 240 .

Air introduced into the case 203 through the outlet 201 may flow into the pressurized space 250s formed inside the bell mouth 250 .

The indoor fan 260 may suck air outside the case 203 into the case 203 through the suction port 201 and discharge it toward the heat exchanger 210 .

The air discharged toward the heat exchanger 210 by the indoor fan 260 may exchange heat with water introduced into the indoor heat exchanger 210 through the pipe 270 and then flow into the outlet 202 . The pipe 270 may be referred to as a "water pipe" or a "heat exchanger connection pipe".

Air reaching the discharge port 202 may be guided in a flow direction by the vane assembly 300 .

The vane assembly 300 may include a first vane 310 and a second vane 320 disposed spaced apart from each other in the discharge port 202 .

Air arriving at the outlet 202 may be guided in a flow direction by the first vane 310 and the second vane 320, respectively.

A plurality of discharge ports 202 may be formed on the lower surface of the lower body 230 . A plurality of vane assemblies 300 may be provided to correspond to each of the plurality of discharge ports 202 .

The indoor unit 200 includes a controller 281 that controls the driving of the vane assembly 300, a humidity sensor 282 that measures the humidity of air introduced through the suction port 201, and air introduced through the suction port 201. It may include an indoor temperature sensor 283 for measuring the temperature of the heated air and a water temperature sensor 284 for measuring the temperature of the water flowing in the pipe 270.

The controller 281 may control driving of the vane assembly 300 based on measured values of the humidity sensor 282 , the room temperature sensor 283 , and the water temperature sensor 284 .

The humidity sensor 282 may measure the humidity of the indoor space. The indoor temperature sensor 283 may measure the indoor temperature of the indoor space. The water temperature sensor 284 may measure the temperature of water flowing into the indoor heat exchanger 210 .

Hereinafter, the vane assembly 300 assembled to the case 203 will be described with reference to FIG. 4 . 4 is a perspective view showing only the vane assembly 300 in isolation.

The vane assembly 300 includes a block 330 fixed to the case 203, a vane motor 340 fixed to the block 330, and a first vane rotated by receiving power from the vane motor 340 ( 310) and a second vane 320.

The block 330 may be fixed to the lower body 230. Blocks 330 may be arranged so as to correspond to each of the plurality of discharge ports 202 by two. A pair of blocks 330 may be respectively disposed on both sides of the outlet 202 . The block 330 may be fixed to the case 203 through a predetermined fastening member (not shown) inserted into the fastening hole 331 .

The first vane 310 and the second vane 320 may be rotatably connected to a pair of blocks 330 . The first vane 310 and the second vane 320 may be rotatably disposed in the discharge port 202, and may open the discharge port 202 or block the discharge port 202 by rotation.

The vane motor 340 may be seated on the upper side of the block 330 . The vane motor 340 may be fixed to the block 330 .

Hereinafter, a detailed structure of the vane assembly 300 will be described with reference to FIG. 5 . 5 is an enlarged view of the vane assembly 300 disposed in the discharge port 202.

The orientation concept for the description of the vane assembly 300 is defined. Hereinafter, a direction toward the outside of the case 203 is defined as a front, and a direction toward the inside of the case 203 is defined as a rear. However, orientation concepts such as “front” and “rear” used below are for convenience of description, and the front refers to the outer direction of the case 203 and the rear refers to the inner direction of the case 203.

The vane assembly 300 includes a drive link 350 rotatably connected to the block 330 and a first vane link 360 rotatably connected to the block 330 and spaced apart from the drive link 350. , the second vane link 370 rotatably connected to the drive link 350, the first vane 310 rotatably connected to each of the drive link 350 and the first vane link 360, and a block It may include a second vane 320 rotatably connected to each of the 330 and the second vane link 370 .

The driving link 350 may be rotatably connected to the vane motor 340 and may be rotated by receiving power from the vane motor 340 .

The drive link 350 includes a core shaft 351 connected to the vane motor 340, a first drive link body 352 extending long from the core shaft 351, and a first drive from the core shaft 351. The second driving link body 353 extending in a direction crossing the link body 352, the first driving joint 354 protruding from the first driving link body 352, and the second driving link body 353 ) It may include a second drive joint 355 protruding from.

The core shaft 351, the first drive link body 352, the second drive link body 353, the first drive joint 354, and the second drive joint 355 may be integrally formed.

The first vane link 360 may include a first link joint 361 rotatably connected to the block 330 and a second link joint 362 rotatably connected to the first vane 310. can

The second vane link 370 may include a third link joint 371 rotatably connected to the second vane 320 .

The first vane 310 may be rotatably connected to the driving link 350 through the first driving joint 354 . The first vane 310 may be rotatably connected to the first vane link 360 through a second link joint 362 .

The first vane 310 may move together with the first vane link 360 when power is transmitted from the vane motor 340 and the drive link 350 is rotated.

The second vane 320 may be rotatably connected to the second vane link 370 through a third link joint 371 . The second vane 320 may be rotatably connected to the block 330 through a vane joint 321 .

The second vane 320 may move together with the second vane link 370 when power is transmitted from the vane motor 340 and the driving link 350 rotates.

The core shaft 351, the first link joint 361, and the vane joint 321 may have fixed arrangement positions. The positions of the core shaft 351, the first link joint 361, and the vane joint 321 may not change even when the driving link 350 is rotated.

Positions of the first drive joint 354, the second drive joint 355, the second link joint 362, and the third link joint 371 may be changed by rotation of the drive link 350.

In the first vane 310 and the second vane 320, the positions of the first drive joint 354, the second drive joint 355, the second link joint 362, and the third link joint 371 vary. It can be moved as it becomes.

The case 203 may include a discharge guider 290 disposed behind the vane module 300 .

The discharge guider 290 may be spaced apart from the rear of the second vane 320 .

The discharge guider 290 includes a first guide 291 extending in the vertical direction, a second guide 292 extending curvedly forward from the first guide 291, and a vertical direction extending from the second guide 292. It may include a third guide 293 that extends along the bend.

The discharge guider 290 may be disposed to face the second vane 320 . The second guide 292 may be curvedly extended toward the second vane 320 . The third guide 293 may have a groove 293a recessed in a direction away from the second vane 320 .

The first vane 310 and the second vane 320 may be spaced apart from each other, and between the first vane 310 and the second vane 320 there is a gap (G1, G2, G3, G4, G5, G6 ) can be formed. The intervals (G1, G2, G3, G4, G5, G6) between the first vane 310 and the second vane 320 may be referred to as "discharge intervals".

The discharge guider 290 and the second vane 320 may be spaced apart from each other, and intervals D1, D2, D3, D4, D5, and D6 may be formed between the discharge guider 290 and the second vane 320. can The intervals D1 , D2 , D3 , D4 , D5 , and D6 between the discharge guider 290 and the second vane 320 may be referred to as “leakage intervals”.

The discharge intervals G1, G2, G3, G4, G5, and G6 may refer to intervals between the rear end 310b of the first vane 310 and the front end 320a of the second vane 320. . The discharge intervals G1, G2, G3, G4, G5, and G6 may mean the interval between the lower surface 310d of the first vane 310 and the upper surface 320c of the second vane 320. . The discharge intervals (G1, G2, G3, G4, G5, G6) are the rear end 310b of the first vane 310 and the second vane ( 320) may be defined as the interval between the front end 320a, and in the third to sixth modes (P3, P4, P5, P6) to be described later, the lower surface 310d and the first vane 310 2 may be defined as the distance between the upper surfaces 320c of the vanes 320.

The leakage intervals D1 , D2 , D3 , D4 , D5 , and D6 may mean intervals between the third guide 293 and the lower surface 320d of the second vane 320 . The leakage intervals D1 , D2 , D3 , D4 , D5 , and D6 may mean intervals between the groove 293a and the lower surface 320d of the second vane 320 .

Hereinafter, the operating state of the vane assembly 300 according to the discharge modes (P1, P2, P3, P4, P5, P6) of the air conditioner 1 will be described with reference to FIGS. 5 to 10.

The plurality of discharge modes (P1, P2, P3, P4, P5, P6) can be distinguished according to the position change of the vanes (310, 320).

As the vane motor 340 rotates in the first direction (A), the discharge modes are the first discharge mode (P1) (FIG. 5), the second discharge mode (P2) (FIG. 6), and the third discharge mode (P3). ) (FIG. 7), the fourth discharge mode (P4) (FIG. 8), the fifth discharge mode (P5) (FIG. 9), and the sixth discharge mode (P6) (FIG. 10).

The first discharge mode P1 and the second discharge mode P2 may be states when the air conditioner 1 is not under an over-humidity condition, which will be described later.

In the first discharge mode (P1) or the second discharge mode (P2), the air discharged through the discharge port 202 is the upper surface 320c of the second vane 320 and the upper surface of the first vane 310. It flows along the side surface 310c and can be discharged from the front end 310a of the first vane 310 to the outside of the case 203 .

In the first discharge mode P1, the rear end 310b of the first vane 310 and the front end 320a of the second vane 320 may face each other. A first discharge interval G1 may be formed between the rear end 310b of the first vane 310 and the front end 320a of the second vane 320 .

In the first discharge mode P1, a first leakage distance D1 may be formed between the second vane 320 and the discharge guide 290.

In the first discharge mode (P1), the air discharged through the outlet 202 flows forward along the upper surface 320c of the second vane 320 and the upper surface 310c of the first vane 310. Thus, it is possible to implement a forward inclined wind.

The second discharge mode (P2) may be a state when the vane motor 340 is rotated in the first direction (A) at a predetermined angle in the first discharge mode (P1).

In the second discharge mode P2, the rear end 310b of the first vane 310 and the front end 320a of the second vane 320 may face each other. A second discharge interval G2 may be formed between the rear end 310b of the first vane 310 and the front end 320a of the second vane 320 . The second discharge interval G2 may be greater than the first discharge interval G1.

In the second discharge mode P2, a second leakage distance D2 may be formed between the second vane 320 and the discharge guide 290. The second leakage distance D2 may be smaller than the first leakage distance D1.

In the second discharge mode (P2), the air discharged through the outlet 202 flows forward along the upper surface 320c of the second vane 320 and the upper surface 310c of the first vane 310. Thus, it is possible to implement a forward inclined wind.

The third discharge mode (P3), the fourth discharge mode (P4), the fifth discharge mode (P5), and the sixth discharge mode (P6) may be states when the air conditioner 1 is in an overhumid condition to be described later. there is.

In the third to sixth discharge modes (P3, P4, P5, P6), the air discharged through the discharge port 202 may be discharged between the first vane 310 and the second vane 320. . In the third to sixth discharge modes (P3, P4, P5, P6), air discharged through the discharge port 202 is discharged between the first vane 310 and the second vane 320 or the first vane 310 and the second vane 320. It may be discharged forward along the upper surface 310c of the vane 310 .

In the third to sixth discharge modes (P3, P4, P5, P6), by discharging some of the air discharged through the discharge port 202 between the first vane 310 and the second vane 320, By reducing the flow rate flowing along the upper surfaces 310c and 320c of the vanes 310 and 320, the amount of dew forming on the vanes 310 and 320 can be reduced.

The third discharge mode (P3) may be a state when the vane motor 340 is rotated in the first direction (A) at a predetermined angle in the second discharge mode (P2).

In the third discharge mode (P3), the lower surface 310d of the first vane 310 and the upper surface 320c of the second vane 320 may face each other. A third discharge interval G3 may be formed between the lower surface 310d of the first vane 310 and the upper surface 320c of the second vane 320 . The third discharge interval G3 may be greater than the first discharge interval G1 and the second discharge interval G2.

In the third discharge mode P3, a third leakage distance D3 may be formed between the second vane 320 and the discharge guide 290. The third leakage distance D3 may be smaller than the first leakage distance D1 and the second leakage distance D2.

In the third discharge mode P3 , air discharged through the discharge port 202 may be discharged downward through a space between the first vane 310 and the second vane 320 . The air discharged through the space between the first vane 310 and the second vane 320 flows by the lower surface 310d of the first vane 310 and the upper surface 320c of the second vane 320. The direction can be guided, and the inclined wind directed forward and downward can be implemented.

When the positions of the vanes 310 and 320 change from the second discharge mode P2 to the third discharge mode P3, the first vane 310 and the second vane 320 may move in opposite directions. there is. The first vane 310 may be moved forward, and the second vane 320 may be moved rearward. The first vane 310 and the second vane 320 can be moved in opposite directions according to the rotation of the vane motor 340 by the connection relationship between the driving link 350 and the vane links 360 and 370. there is.

In the third discharge mode (P3), the rear end 310b of the first vane 310 may be positioned higher than the front end 320a of the second vane 320. In the third discharge mode P3, the inclination angle θ1 of the first vane 310 in the horizontal direction may be smaller than the inclination angle θ2 of the second vane 320 in the horizontal direction. Accordingly, the flow rate of the forward inclined wind discharged along the upper surface 310c of the first vane 310 can be maintained and the distance G3 between the first vane 310 and the second vane 320 can be maximized. there is. Therefore, while minimizing the flow loss of the forward inclined wind supplied to the room along the first vane 310 and increasing the flow rate of the air discharged between the first vane 310 and the second vane 320, the vane 310, 320) can prevent dew formation.

The condensation may occur when air discharged through the discharge port 202 flows along the upper surfaces 310c and 320c of the vanes 310 and 320 . The condensation may be caused by heat exchange between the cold air reaching the vanes 310 and 320 and the warm air outside the case 203 . According to the present disclosure, the vanes 310 and 320 are rapidly discharged to the outside of the case 203 through the space between the first vane 310 and the second vane 320 to cool air reaching the vanes 310 and 320. can prevent dew formation.

When the positions of the vanes 310 and 320 change from the second discharge mode P2 to the third discharge mode P3, the first vane link 360 and the second vane link 370 move in opposite directions. It can be. The first vane link 360 may be moved to the front (B), and the second vane link 370 may be moved to the rear (C).

The first vane link 360 can move the first vane 310 forward, and the second vane link 370 can move the second vane 320 backward.

In the third discharge mode (P3), the first vane link 360 may be inclined toward the outside of the case 203, and the second vane link 370 may be inclined toward the inside of the case 203. . An inclination angle θ3 of the first vane link 360 with respect to the vertical direction may be smaller than an inclination angle θ4 of the second vane link 370 with respect to the vertical direction. When the position of the vanes 310 and 320 is changed from the second discharge mode (P2) to the third discharge mode (P3), the displacement by which the first vane link 360 is moved corresponds to the movement of the second vane link 370. may be less than the displacement.

Due to the structure of the first vane link 360 and the second vane link 370 described above, the distance between the first vane 310 and the second vane 320 is widened and at the same time the first vane 310 is formed. Accordingly, the flow loss of the air flowing forward can be minimized.

The fourth discharge mode (P4) may be a state when the vane motor 340 is rotated in the first direction (A) at a predetermined angle in the third discharge mode (P4).

In the fourth discharge mode (P4), the lower surface 310d of the first vane 310 and the upper surface 320c of the second vane 320 may face each other. A fourth discharge interval G4 may be formed between the lower surface 310d of the first vane 310 and the upper surface 320c of the second vane 320 . The fourth discharge interval G4 may be greater than the first discharge interval G1 and the second discharge interval G2.

In the fourth discharge mode P4, a fourth leakage interval D4 may be formed between the second vane 320 and the discharge guide 290. The fourth leakage distance D3 may be smaller than the first leakage distance D1 and the second leakage distance D2.

In the fourth discharge mode P4 , air discharged through the discharge port 202 may be discharged downward through a space between the first vane 310 and the second vane 320 . The air discharged through the space between the first vane 310 and the second vane 320 flows by the lower surface 310d of the first vane 310 and the upper surface 320c of the second vane 320. The direction can be guided, and the inclined wind directed forward and downward can be implemented.

The fifth discharge mode (P5) may be a state when the vane motor 340 is rotated in the first direction (A) at a predetermined angle in the fourth discharge mode (P4).

In the fifth discharge mode (P5), the lower surface 310d of the first vane 310 and the upper surface 320c of the second vane 320 may face each other. A fifth discharge interval G5 may be formed between the lower surface 310d of the first vane 310 and the upper surface 320c of the second vane 320 . The fifth discharge interval G5 may be greater than the first discharge interval G1 and the second discharge interval G2.

In the fifth discharge mode P5, a fifth leakage distance D5 may be formed between the second vane 320 and the discharge guide 290. The fifth leakage distance D5 may be smaller than the first leakage distance D1 and the second leakage distance D2.

In the fifth discharge mode P5 , air discharged through the discharge port 202 may be discharged downward through a space between the first vane 310 and the second vane 320 . The air discharged through the space between the first vane 310 and the second vane 320 flows by the lower surface 310d of the first vane 310 and the upper surface 320c of the second vane 320. The direction can be guided, and the inclined wind directed forward and downward can be implemented.

The sixth discharge mode (P6) may be a state when the vane motor 340 is rotated in the first direction (A) at a predetermined angle in the fifth discharge mode (P5).

In the sixth discharge mode (P6), the lower surface 310d of the first vane 310 and the upper surface 320c of the second vane 320 may face each other. A sixth discharge interval G6 may be formed between the lower surface 310d of the first vane 310 and the upper surface 320c of the second vane 320 . The sixth discharge interval G6 may be greater than the first discharge interval G1 and the second discharge interval G2.

In the sixth discharge mode P6, a sixth leakage distance D6 may be formed between the second vane 320 and the discharge guide 290. The sixth leakage distance D6 may be smaller than the first leakage distance D1 and the second leakage distance D2.

In the sixth discharge mode P6 , air discharged through the discharge port 202 may be discharged downward through a space between the first vane 310 and the second vane 320 . The air discharged through the space between the first vane 310 and the second vane 320 flows by the lower surface 310d of the first vane 310 and the upper surface 320c of the second vane 320. The direction can be guided, and the inclined wind directed forward and downward can be implemented.

The discharge intervals G1, G2, G3, G4, G5, and G6 may become wider from the first discharge mode P1 to the sixth discharge mode P6. The flow rate of air discharged into the space between the first vane 310 and the second vane 320 may increase from the first discharge mode P1 to the sixth discharge mode P6.

The leakage intervals D1, D2, D3, D4, D5, and D6 may become narrower from the first discharge mode P1 to the sixth discharge mode P6. A flow rate of air discharged into the space between the second vane 320 and the discharge guide 290 may decrease from the first discharge mode P1 to the sixth discharge mode P6.

Air discharged into the space between the second vane 320 and the discharge guide 290 may be re-introduced into the case 203 through the suction port 201 . Under the condition that dew is formed on the vanes 310 and 320, the dew formed on the vanes 310 and 320 is discharged into the space between the second vane 320 and the discharge guide 290 and reflowed into the case 203. It can be. In the air conditioner 1 of the present disclosure, the vane ( Dew condensed on the 310 and 320 may be prevented from re-introducing into the case 203 .

Hereinafter, a control method of the air conditioner 1 will be described with reference to FIGS. 11 and 12 . 11 is a block diagram schematically showing a control method of the air conditioner 1, and FIG. 12 is a block diagram showing a control method of the air conditioner 1 in detail.

Referring to FIG. 11, the control method of the air conditioner 1 includes determining an over-humidity condition (S100), controlling a vane angle when the over-humidity condition is present (S200), and releasing after the vane angle is controlled. A step of determining a condition (S300) and a step of controlling the vane angle when the release condition is satisfied (S400) may be included.

In the step of determining the over-humidity condition (S100), based on the measured values of the humidity sensor 282, the room temperature sensor 283, and the water temperature sensor 284, it is determined whether dew is formed on the vanes 310 and 320. It may be a step to

The step of controlling the vane angle (S200) may be a step of changing the discharge mode of the vanes 310 and 320 when an over-humidity condition is satisfied.

In the step of determining the release condition (S300), in a state in which the discharge mode of the vanes 310 and 320 is changed by satisfying the excessive humidity condition, the humidity sensor 282, the room temperature sensor 283, and the water temperature sensor 284 It may be a step of determining whether or not the over-humidity condition is satisfied based on the measured value.

The step of adjusting the vane angle according to the release condition (S400) may be a step of returning the angle of the vanes 310 and 320 whose discharge mode is changed by satisfying the over-humidity condition to a state before the change.

The step of determining the over-humidity condition (S100) includes the step of checking the discharge mode of the air conditioner 1 (S110), the step of comparing the humidity value with the humidity limit value (X) (S120), and the indoor temperature value Comparing with the room temperature limit value (Y) (S130), comparing the water temperature value with the water temperature limit value (Z) (S140), and maintaining the angle of the vane when the over-humidity condition is not satisfied (S150) ) may be included.

In the step of checking the discharge mode of the air conditioner 1 (S110), the controller 281 may determine whether the discharge mode of the vanes 310 and 320 is in the first state. The first state may be a first discharge mode P1 or a second discharge mode P2. The controller 281 may determine whether the rear end 310b of the first vane 310 and the front end 320a of the second vane 320 face each other. The controller 281 may determine whether the distance between the rear end 310b of the first vane 310 and the front end 320a of the second vane 320 is equal to or less than a predetermined value.

The controller 281, when the discharge mode of the vanes 310 and 320 corresponds to the first discharge mode P1 or the second discharge mode P2, the humidity sensor 282, the room temperature sensor 283 and the water The measured value of each temperature sensor 284 may be compared with a limit value. The controller 281 maintains the discharge modes of the vanes 310 and 320 when the discharge modes of the vanes 310 and 320 correspond to the third to sixth discharge modes P3, P4, P5, and P6. It can (S150).

In the step of comparing the humidity value with the humidity limit value X (S120), the controller 281 may compare the humidity value measured by the humidity sensor 282 with the preset humidity limit value X. The controller 281 may determine that the excessive humidity condition is satisfied when the humidity value is greater than or equal to the humidity limit value X. The controller 281 may determine that the excessive humidity condition is not satisfied when the humidity value is less than the humidity limit value X. The controller 281 may maintain the discharge mode of the vanes 310 and 320 in the first state when the humidity value is less than the humidity limit value X (S150).

In the step of comparing the room temperature value with the room temperature limit value Y (S130), the controller 281 may compare the room temperature value measured by the room temperature sensor 283 with the preset room temperature limit value Y. . The controller 281 may determine that the overhumidity condition is satisfied when the indoor temperature value is equal to or greater than the indoor temperature limit value X. The controller 281 may determine that the overhumidity condition is not satisfied when the indoor temperature value is less than the indoor temperature limit value Y. The controller 281 may maintain the discharge mode of the vanes 310 and 320 in the first state when the indoor temperature value is less than the indoor temperature limit value Y (S150).

In the step of comparing the water temperature value with the water temperature limit value Z (S140), the controller 281 may compare the water temperature value measured by the water temperature sensor 284 with the preset water temperature limit value Z . The controller 281 may determine that the over-humidity condition is satisfied when the water temperature value is less than or equal to the water temperature limit value Z. The controller 281 may determine that the over-humidity condition is not satisfied when the water temperature value exceeds the water temperature limit value Z. The controller 281 may maintain the discharge mode of the vanes 310 and 320 in the first state when the water temperature exceeds the water temperature limit value Z (S150).

The controller 281 determines that the discharge mode of the air conditioner 1 is in the first state, the humidity value is greater than the humidity limit value (X), the room temperature value is greater than the room temperature limit value (Y), and the water temperature value is When the water temperature is less than the limit value Z, it may be determined that the air conditioner 1 satisfies the overhumidity condition. The controller 281 may control the vane motor 340 to widen the gap between the first vane 310 and the second vane 320 when the air conditioner 1 satisfies the overhumidity condition. The controller 281 may change the discharge mode of the air conditioner 1 to the second state when the air conditioner 1 satisfies the overhumidity condition. The second state may be a third to sixth discharge mode (P3, P4, P5, P6).

The controller 281 may determine that dew formation occurs on the vanes 310 and 320 when the humidity value is high. The controller 281 may determine that dew is formed on the vanes 310 and 320 when the indoor temperature value is high. The controller 281 may determine that as the temperature of the water flowing in the pipe 270 is lower, the temperature of the air discharged through the outlet 202 is lower, and thus dew formation occurs on the vanes 310 and 320 . The humidity limit value (X) may be 72% or more. The indoor temperature limit value Y may be in the range of 24 to 31 degrees Celsius.

The controller 281 may control the vane motor 340 to widen the gap between the first vane 310 and the second vane 320 when the overhumid condition of the air conditioner 1 lasts for a predetermined time. . The controller 281 may change the discharge mode of the air conditioner 1 to the second state when the excessive humidity condition of the air conditioner 1 continues for a predetermined time. The predetermined time may be in the range of 20 minutes to 40 minutes.

The controller 281 may control the vane motor 340 to widen the gap between the first vane 310 and the second vane 320 when the air conditioner 1 satisfies the overhumidity condition (S200). ). The controller 281 may change the discharge mode of the air conditioner 1 to the third to sixth discharge modes (P3, P4, P5, P6) when the air conditioner 1 satisfies the overhumidity condition. Yes (S200). The discharge mode of the air conditioner 1 may be preferably changed to the third discharge mode (P3). When the discharge mode of the air conditioner 1 is changed, the air discharged through the discharge port 202 may be discharged into the space between the first vane 310 and the second vane 320 . The air discharged into the space between the first vane 310 and the second vane 320 flows through the lower surface 310d of the first vane 310 and the upper surface 320c of the second vane 320. can be guided.

The controller 281 may determine whether the overhumidity condition is released in a state in which the discharge mode of the air conditioner 1 is changed (S300).

The controller 281 determines whether the measurement value of the humidity sensor 282 is less than the humidity limit value (X), the measurement value of the room temperature sensor 283 is less than the room temperature limit value (Y), or the measurement of the water temperature sensor 284. When the value exceeds the water temperature limit value Z, it may be determined that the air conditioner 1 satisfies the release condition. The controller 281 may determine that the air conditioner 1 satisfies the release condition when the overhumidity condition is not satisfied in a state in which the discharge mode of the air conditioner 1 is changed.

The controller 281 may control the vane motor 340 to narrow the gap between the first vane 310 and the second vane 320 when the air conditioner 1 satisfies the release condition (S400). ). The controller 281 may change the discharge mode of the air conditioner 1 to the first state when the air conditioner 1 satisfies the release condition (S400).

The controller 281 may keep the distance between the first vane 310 and the second vane 320 widened when the overhumidity condition of the air conditioner 1 is maintained (S310).

The controller 281, even after the air conditioner 1 satisfies the release condition and the discharge mode is changed to the first state, if the air conditioner 1 satisfies the overhumidity condition, the first vane 310 and the second The vane motor 340 may be controlled to widen the gap between the vanes 320 . The controller 281 may change the discharge mode to the first state when the air conditioner 1 satisfies the overhumidity condition and change the discharge mode to the second state when the air conditioner 1 satisfies the release condition. there is.

Although the preferred embodiments of the present invention have been shown and described above, the present invention is not limited to the specific embodiments described above, and in the technical field to which the present invention belongs without departing from the gist of the present invention claimed in the claims. Various modifications and implementations are possible by those skilled in the art, and these modifications should not be individually understood from the technical spirit or perspective of the present invention.

10: outdoor unit 20: relay device
200: indoor unit 201: inlet
202: discharge port 203: case
210: indoor heat exchanger 281: controller
282: Humidity sensor 283: Room temperature sensor
284: water temperature sensor 300: vane assembly
310: first vane 320: second vane
330: block 340: vane motor
350: drive link 360: first vane link
370: second vane link

Claims (15)

a case having an inlet and an outlet;
a fan disposed inside the case;
a heat exchanger which is disposed inside the case, has a pipe through which water flows, and cools the air introduced through the intake by exchanging heat with water in the pipe;
a vane motor disposed in the case;
a driving link rotatably connected to the vane motor;
a first vane disposed in the discharge port and rotatably connected to the driving link;
a second vane disposed in the discharge port to be separated from the first vane and rotatably connected to the driving link;
a room temperature sensor for measuring the temperature of the air introduced through the inlet;
a humidity sensor for measuring the humidity of the air introduced through the inlet;
a water temperature sensor for measuring the temperature of the water flowing in the pipe; and
A controller controlling the vane motor based on measured values of the room temperature sensor, the humidity sensor, and the water temperature sensor;
The controller,
a distance between the first vane and the second vane when each of the measured values of the room temperature sensor and the humidity sensor is greater than or equal to a preset limit value and the measured value of the water temperature sensor is less than or equal to a preset water temperature limit value; An air conditioner that controls the vane motor to widen.
According to claim 1,
The controller,
The vane motor to widen the gap between the first vane and the second vane when the measurement value of the room temperature sensor is equal to or higher than the preset indoor temperature limit value and the measurement value of the humidity sensor is equal to or higher than the preset humidity limit value in an overhumid condition. air conditioner to control.
According to claim 2,
The gap is formed between the lower surface of the first vane and the upper surface of the second vane when the excessive humidity condition occurs.
According to claim 2,
In the case of the over-humidity condition, the rear end of the first vane is positioned higher than the front end of the second vane.
According to claim 2,
The controller,
The air conditioner controls the vane motor so that the first vane and the second vane move in opposite directions when the excessive humidity condition occurs.
According to claim 2,
In the overhumid condition, the inclination angle of the first vane with respect to the horizontal direction is smaller than the inclination angle of the second vane with respect to the horizontal direction.
According to claim 2,
a first vane link rotatably connected to the case and each of the first vanes;
Further comprising a second vane link rotatably connected to each of the drive link and the second vane,
In the over-humidity condition, the first vane link and the second vane link are moved in opposite directions.
According to claim 7,
In the overhumid condition, the first vane link is inclined toward the outside of the case, and the second vane link is inclined toward the inside of the case.
According to claim 2,
The controller,
Air conditioning controlling the vane motor to widen the gap between the first vane and the second vane when the overhumidity condition is satisfied and the rear end of the first vane and the front end of the second vane are disposed to face each other energy.
According to claim 2,
The controller,
An air conditioner controlling the vane motor to widen a gap between the first vane and the second vane when the over-humidity condition lasts for a predetermined time.
According to claim 1,
The controller,
When the measurement value of the room temperature sensor is less than the preset room temperature limit value or the measurement value of the humidity sensor is less than the preset humidity limit value, the vane motor narrows the gap between the first vane and the second vane. air conditioner to control.
According to claim 11,
The controller,
After the release condition, if each of the measured values of the room temperature sensor and the humidity sensor is equal to or greater than a preset limit value, an air conditioning unit controlling the vane motor to widen a gap between the first vane and the second vane. energy.
According to claim 1,
a cooling device connected to the case through the pipe; and
The air conditioner further comprises a pump disposed between the cooling device and the heat exchanger.
delete According to claim 1,
The controller,
The measured value of the room temperature sensor is greater than or equal to a preset room temperature limit value, the measurement value of the humidity sensor is greater than or equal to a preset humidity limit value, and the measurement value of the water temperature sensor is less than or equal to a preset water temperature limit value, and the first vane The air conditioner controls the vane motor to widen the distance between the first vane and the second vane when the rear end of the second vane faces the front end of the second vane.

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