KR20190051677A - Indoor unit of air conditioner - Google Patents

Abstract

The present invention relates to an indoor unit, comprising: a case having a suction port and a discharge port on the bottom surface thereof; and, a discharge vane disposed in the case and guiding the direction of air flow discharged from the discharge port, wherein the discharge vane includes: a vane motor installed in the case and providing a driving force for adjusting the angle of the vane; a rigid link individually and rotatably connected to the vane and the case; and, a cam link coupled to a motor shaft of the vane motor to receive the rotating force from the vane motor, respectively rotatably connected to the vane and the case, and guiding a movement path of the vane while varying the distance with the motor shaft, when rotated by the rotating force of the vane motor. The present invention has advantages in that interference with the discharged air can be minimized through the cam link and the rigid link, and a vertical wind and horizontal wind can be realized.

Description

[0001] The present invention relates to an indoor unit of an air conditioner,

The present invention relates to an indoor unit of an air conditioner, and more particularly, to a ceiling-type indoor unit installed in a ceiling of an indoor unit.

Generally, an air conditioner is composed of a compressor, a condenser, an evaporator, and an inflator, and supplies air or warm air to a building or a room using an air conditioning cycle.

The air conditioner is structurally divided into a separable type in which the compressor is disposed outdoors and an integral type in which the compressor is integrally manufactured.

In the separate type, an indoor heat exchanger is installed in an indoor unit, an outdoor heat exchanger and a compressor are installed in an outdoor unit, and two devices separated from each other are connected to each other by a refrigerant pipe.

In the integrated type, the indoor heat exchanger, the outdoor heat exchanger and the compressor are installed in one case. The integrated type air conditioner includes a window type air conditioner for directly mounting the apparatus on a window, and a duct type air conditioner for connecting the suction duct and the discharge duct to the outside of the room.

The separate type air conditioner is generally classified according to the installation type of the indoor unit.

A stand-type air conditioner in which an indoor unit is vertically installed in an indoor space is referred to as a stand-type air conditioner. A wall-mounted type air conditioner in which an indoor unit is installed on a wall of the room is called a ceiling-type indoor unit.

There is also a system air conditioner which is capable of providing air-conditioned air in a plurality of spaces as one type of a separate type air conditioner.

In the case of a system air conditioner, there is a type in which a plurality of indoor units are provided to air-condition the room, and a type in which air-conditioned air is supplied to each space through the duct.

A plurality of indoor units provided in the system air conditioner may be equipped with a stand type, a wall type or a ceiling type.

In the conventional ceiling-type indoor unit, one vane is provided at the discharge port, and the flow direction of the discharged air is controlled by adjusting the rotation angle of the vane.

However, in the conventional ceiling-type indoor unit, since the discharge direction of the air is controlled by only one vane, there is a limitation in controlling the direction of the discharged air.

Korea Patent No. 10-0679838 B1

It is an object of the present invention to provide an indoor unit of an air conditioner capable of realizing vertical wind and horizontal wind through a cam link and a rigid link.

It is an object of the present invention to provide an air conditioner indoor unit capable of minimizing interference with discharged air through cam links and rigid links and realizing vertical wind and horizontal wind.

The present invention provides an indoor unit of an air conditioner that allows a vane to be positioned below a discharge port and to provide a larger amount of discharge air as horizontal wind when a horizontal wind is formed through a cam link and a rigid link .

The present invention provides an indoor unit of an air conditioner capable of providing a part of a vane to the discharge port side through the cam link and the rigid link to provide a larger amount of discharge air through vertical wind .

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

The present invention minimizes the interference with the discharged air through the cam link and the rigid link, and can realize the vertical wind and the horizontal wind.

The present invention is characterized in that the indoor unit includes a case having a suction port and a discharge port formed on a bottom surface thereof; And a discharge vane disposed in the case and configured to guide a flow direction of air discharged from the discharge port, wherein the discharge vane includes a vane motor installed in the case and providing a driving force for adjusting the angle of the vane; A rigid link rotatably connected to the vane and the case, respectively; A motor for driving the vane motor, a motor for driving the vane motor, a motor for driving the motor, a motor for driving the motor, And a cam link guiding the movement path of the vane.

When the vane is rotated and the discharged air discharged from the discharge port is discharged as horizontal wind, the vane may be positioned below the discharge port.

The vane may be spaced apart from the bottom surface of the case by a predetermined distance and may be positioned lower than the bottom surface of the case when the vane is rotated and the discharged air discharged from the discharge port is discharged in a horizontal wind.

When the vane is rotated and the discharge air discharged from the discharge port is discharged as vertical wind, a part of the vane may be located inside the discharge port.

The cam link includes a cam body disposed in the case and having a guide surface for guiding rotation of the vane on an outer side; A cam arm coupled to the cam body and coupled to the motor shaft and rotated; And a guide arm which is coupled to the cam arm on an upper side so as to be relatively movable with respect to the vane and is movably coupled to a guide surface of the cam body while relatively moving in a longitudinal direction of the cam arm, A motor shaft coupling portion that is coupled to the motor shaft is disposed in the cam arm, and a guide arm coupling portion that is coupled to the guide arm so as to be relatively rotatable with the vane may be disposed.

An elastic member is disposed between the cam arm and the guide arm, and the guide arm can be brought into close contact with the guide surface of the cam body by the elastic force of the elastic member.

The elastic member may be disposed inside the guide arm, one side of the cam may be located inside the cam body, and the other side of the cam may be located inside the guide arm.

The cam body includes a body insertion hole into which the motor shaft is inserted; And a guide slot in which the cam arm is inserted and moved.

The guide surface may be formed along the guide slot.

The vane may include: a first vane coupling portion coupled to the rigid link so as to be rotatable relative to the rigid link; And a second vane coupling portion that is coupled to the cam link so as to be rotatable relative to the cam link, wherein the first vane coupling portion may be located further forward than the second vane coupling portion.

An imaginary straight line B connecting the first vane coupling portion and the second vane coupling portion and a hypothetical straight line G connecting the motor shaft coupling portion and the second vane coupling portion form a predetermined angle, When the discharge air discharged from the discharge port is discharged in a horizontal wind, the angle (c) between the straight line (B) and the straight line (G) may be 90 degrees or less.

When the discharge air is formed in the horizontal wind, the air discharged from the discharge port can be guided through the upper surface of the vane.

An imaginary straight line B connecting the first vane coupling portion and the second vane coupling portion and a hypothetical straight line G connecting the motor shaft coupling portion and the second vane coupling portion form a predetermined angle, When the discharge air discharged from the discharge port is discharged as vertical wind, the angle (c) between the straight line (B) and the straight line (G) may be formed to be more than 180 degrees and less than 270 degrees.

When the discharge air is formed by the vertical wind, the air discharged from the discharge port can be guided through the lower side of the vane.

The present invention is characterized in that the indoor unit includes a case having a suction port and a discharge port formed on a bottom surface thereof; And a discharge vane disposed in the case and guiding a flow direction of air discharged from the discharge port,

Wherein the discharge vane comprises: a vane motor installed in the case and providing a driving force for adjusting the angle of the vane; A rigid link rotatably connected to the vane and the case, respectively; A cam body disposed in the case and having a guide surface for guiding the rotation of the vane outside; A cam arm coupled to the cam body and coupled to the motor shaft and rotated; A guide arm having an upper side coupled to the cam arm so as to be relatively movable, a lower side coupled with the vane so as to be relatively rotatable relative thereto, and being moved relative to the guide surface of the cam body while being relatively moved in the longitudinal direction of the cam arm; And an elastic member disposed between the cam arm and the guide arm and providing an elastic force to the guide arm when the cam arm and the guide arm are relatively moved to closely contact the guide arm with the guide surface of the cam body, A motor shaft coupling portion to be coupled to the motor shaft is disposed in the cam arm, and a guide arm coupling portion that is relatively rotatably coupled with the vane is disposed in the guide arm, the elastic member is disposed inside the guide arm, One side is located inside the cam body, and the other side of the cam is located inside the guide arm.

The indoor unit of the air conditioner according to the present invention has one or more of the following effects.

First, the present invention has the advantage of minimizing the interference with the discharged air through the cam link and the rigid link and realizing the vertical wind and the horizontal wind.

Second, the present invention is advantageous in that when the horizontal wind is formed through the rigid link and the cam link, the vane is positioned below the discharge port, and a larger amount of discharge air can be provided through the horizontal wind.

Third, the present invention is advantageous in that when a vertical airflow is formed through the rigid link and the cam link, a part of the vane is brought into close contact with the discharge port side, and a larger amount of discharged air can be supplied through the vertical wind.

Fourth, since the guide arm can be moved along the surface of the cam body to vary the distance between the motor shaft coupling portion and the second vane coupling portion, when the horizontal wind is formed, the vane is lowered to the lower side There is an advantage that a part of the vane can be positioned inside the discharge port when the vertical wind is formed.

Fifth, the present invention maintains the state where the guide arm is in tight contact with the cam body by the elastic member, so that when the vane forms a vertical wind, a horizontal wind or an inclined wind, the vibration caused by the bouncing of the discharged air against the vane is suppressed There are advantages to be able to.

1 is a perspective view illustrating an indoor unit of an air conditioner according to an embodiment of the present invention.
FIG. 2 is an exploded perspective view of FIG. 1. FIG.
3 is a first perspective view illustrating a discharge vane according to an embodiment of the present invention.
4 is a second perspective view of another angle of the discharge vane according to an embodiment of the present invention.
5 is a plan view of Fig.
6 is a perspective view of the opposite side of the discharge vane shown in Fig.
7 is an exploded perspective view of the cam link shown in Fig.
8 is a view illustrating an operation example of the discharge vane shown in Fig.

BRIEF DESCRIPTION OF THE DRAWINGS The advantages and features of the present invention and the manner of achieving them will become apparent with reference to the embodiments described in detail below with reference to the accompanying drawings. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. To fully disclose the scope of the invention to those skilled in the art, and the invention is only defined by the scope of the claims. Like reference numerals refer to like elements throughout the specification.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a perspective view illustrating an indoor unit of an air conditioner according to an embodiment of the present invention, and FIG. 2 is an exploded perspective view of FIG. 1. Referring to FIG.

<Configuration of indoor unit>

The indoor unit of the air conditioner according to the present embodiment includes a case 100 having a suction port 101 and a discharge port 102, an indoor heat exchanger 130 disposed inside the case 100, And an indoor air blowing fan 140 for flowing air to the air inlet 101 and the air outlet 102.

<Configuration of Case>

In this embodiment, the case 100 includes a case housing 110 fixed to a ceiling of a room and opened at a lower side thereof, and a case cover 110 covering the opened face of the case housing 110, (101) and a discharge port (102).

The cover panel 120 may be formed integrally with the case housing 110 and the upper side may be opened. The case 100 may be variously formed in accordance with the production mode, and the configuration of the case 100 does not limit the idea of the present invention.

The suction port 101 is disposed at the center of the cover panel 120 and the discharge port 102 is disposed around the suction port 101. The number of the suction ports 101 or the number of the discharge ports 102 is irrelevant to the idea of the present invention. In this embodiment, one suction port 101 is formed, and a plurality of the discharge ports 102 are arranged.

In this embodiment, the suction port 101 is formed in a rectangular shape when viewed from the bottom, and the discharge port 102 is spaced apart from the edges of the suction port 101 by a predetermined distance.

The cover panel 120 further includes a suction grill 122 covering the suction port 101. The suction grill 122 is detachably installed on the cover panel 120. [

A pre-filter 124 is disposed above the suction grill 122, and the pre-filter 124 filters air sucked into the case 100.

The discharge port 102 is formed in the form of a long slit, and a discharge vane 200 for opening and closing the discharge port 102 is disposed.

<Configuration of Indoor Heat Exchanger>

The indoor heat exchanger 130 is disposed between the suction port 101 and the discharge port 102 and the indoor heat exchanger 130 divides the interior of the case 100. The indoor heat exchanger 130 is disposed vertically in this embodiment.

The indoor heat exchanger 130 is arranged to vertically enter the air discharged from the indoor air blowing fan 140.

A drain pan 132 is installed inside the case 100 and the indoor heat exchanger 130 is mounted on the drain pan 132. The condensed water generated in the indoor heat exchanger 130 may flow into the drain pan 132 and then be stored. The drain pan 132 is provided with a drain pump (not shown) for discharging the collected condensed water to the outside.

The drain pan 132 may be formed with a sloping surface having a directionality for collecting and storing the condensed water flowing down from the indoor heat exchanger 130 to one side.

<Configuration of Indoor Fan>

The indoor ventilation fan 140 is located inside the case 100 and above the air inlet 101. The indoor air blowing fan 140 uses a centrifugal air blower that sucks air into the center and discharges air in the circumferential direction.

The indoor ventilation fan 140 includes a bell mouth 142, a fan 144, and a fan motor 146.

The bell mouth 142 is disposed above the suction grill 122 and guides the air having passed through the suction grill 122 to the fan 144.

The fan motor 146 rotates the fan 144.

<Structure of the Euro>

A space on the side of the indoor ventilation fan 140 with respect to the indoor heat exchanger 130 is defined as a suction flow path 103 and a space defined between the indoor heat exchanger 130 and the case housing 110 ) Is defined as the discharge flow path 104.

The suction passage 103 communicates with the suction port 101 and the discharge passage 104 communicates with the discharge port 103.

The air flows from the lower side of the suction passage 103 to the upper side and flows from the upper side to the lower side of the discharge passage 104.

The suction port 101 and the discharge port 102 are formed on the same side of the cover panel 120.

The suction port (101) and the discharge port (102) are arranged to face in the same direction. In this embodiment, the suction port 101 and the discharge port 102 are disposed to face the floor of the room.

When the cover panel 120 is curved, the discharge port 102 may be formed to have a slight side inclination. However, the discharge port 102 connected to the discharge path 104 is formed to face downward.

A discharge vane 200 is disposed to control the direction of the air discharged through the discharge port 102.

FIG. 3 is a first perspective view showing a discharge vane according to an embodiment of the present invention, FIG. 4 is a second perspective view showing another discharge vane according to an embodiment of the present invention, FIG. 5 is a cross- Fig. 6 is a perspective view of the opposite side of the discharge vane shown in Fig. 3, and Fig. 7 is an exploded perspective view of the cam link shown in Fig.

<Configuration of Discharge Vane>

The discharge vane 200 is installed in the discharge passage 104 and controls the flow direction of the air discharged through the discharge opening 102.

The discharge vane 200 includes a vane 210 for guiding the direction of air flow while being vertically or laterally moved and rotated, and a driving force generator 210 installed in the case 100 for driving the vane 210, A rigid link 310 rotatably connected to the vane 210 and the case 100, a motor shaft 221 of the vane motor 220, And is rotatably connected to the vane 210 and the case 100. When the motor is rotated by the rotational force of the vane motor 220, And a cam link 320 guiding the movement path of the vane 210 while changing a distance between the vane 210 and the vane 210.

The rigid link 310 and the cam link 320 may be installed in the case 100. In this embodiment, the rigid link 310 and the cam link 320 are provided in the motor case 105 disposed on the discharge flow path 104.

The motor case 105 is disposed in the air discharge direction. In this embodiment, the motor case 105 may be installed in the cover panel 120 or the case housing 110 forming the discharge passage 104. The motor case 105 may be protruded toward the discharge passage 104 of the cover panel 120 or the case housing 110. [

The motor case 105 is arranged to intersect or orthogonally intersect with the longitudinal direction of the vane 210. The motor case 105 may be disposed at one end and the other end with respect to the longitudinal direction of the vane 210. The motor case 105 may be formed in a plate shape or a shape in which one side is open.

The vane motor 220 is positioned between the motor case 105 and the case 110. The motor case 105 forms a motor installation space 107 between the motor case 105 and the case 110.

A motor installation space 107 is disposed on one side (right side in FIG. 3) of the motor case 105, and a discharge port 102 is disposed on the other side.

The vane motor 220 includes a motor shaft 221 coupled to the cam link 320. The motor shaft 221 passes through the motor case 105 and is coupled to the cam link 320.

The motor case 105 is provided with a motor shaft hole 231 through which the motor shaft 221 passes and a rigid link coupling part 232 to which the rigid link 310 is coupled.

The motor shaft hole 231 is formed in the lateral direction in this embodiment.

The rigid linkage 232 is formed in the shape of a hole in this embodiment and provides the center of rotation of the rigid link 310.

The vane 210 may be separated from the motor case 105 by a predetermined distance with respect to the longitudinal direction of the vane 210 and the vane 210 may be accommodated in the discharge port 102.

The rigid link 310 and the cam link 320 are disposed at one end and the other end of the vane 210, respectively. The vane 210 is guided to rotate by the rigid link 310 and the cam link 320. The rotation of the vane 210 creates a swing trajectory rather than a rotation in place.

The vane motor 220 may be disposed at one or both ends of the vane 210. In the present embodiment, the vane motor 220 is installed only at one side or the other side of the vane 210.

The vane motor 220 is disposed on the opposite side of the vane 210 with respect to the motor case 105. Therefore, the driving force of the vane motor 220 is provided to either the rigid link 310 or the cam link 320 through the motor case 105.

In this embodiment, the vane motor 220 uses a stepping motor.

A virtual plane formed when the rigid link 310 is rotated clockwise or counterclockwise is defined as a rotation plane. In the present embodiment, a plurality of links are rotated such that each link forms a respective rotation plane.

<Composition of Bain>

For the sake of explanation, the direction in which the air is discharged is defined as forward, and the opposite direction is defined as rearward. The ceiling side is defined as the upper side, and the floor is defined as the lower side. Also, the side where the vane motor is installed in the discharge vane is defined as one side (right side) and the other side is defined as the other side (left side).

The vane 210 includes a vane body 212 formed to extend in the lengthwise direction of the discharge port 102 and a vane body 212 protruding upward from the vane body 212. The vane body 210 includes the rigid link 310 and the cam link 320, And a coupling flange 214 to which the coupling flange 214 is coupled.

The vane body 212 may be formed as a flat surface or a gently curved surface.

The vane body 212 controls the direction of air discharged along the discharge passage 104. The discharged air hits the upper or lower surface of the vane body 212 to guide the flow direction. The flow direction of the discharged air and the longitudinal direction of the vane body 212 are orthogonal or intersecting.

The coupling flange 214 is a mounting structure for coupling the rigid link 310 and the cam link 320. The coupling flange 214 is disposed on one side and the other side of the discharge vane, respectively.

The coupling flange 214 protrudes upward from the upper surface of the vane body 212. The coupling flange 214 is preferably formed along the flow direction of the discharged air. So that the coupling flange 214 is disposed orthogonally or intersecting with the longitudinal direction of the vane body 212.

The coupling flange 214 is formed so that a direction side (front side) in which air is discharged and a side (rear side) in which air enters are high. In the present embodiment, the coupling flange 214 is formed at a side where the rigid link 310 is engaged and at a side where the cam link 320 is engaged.

The rear side end 214a of the coupling flange 214 is located further rearward beyond the rear side end 212a of the vane body 212. [ That is, the rear side end 214a of the coupling flange 214 protrudes toward the rear side of the vane body 212. [

The coupling flange 214 includes a first vane coupling portion 216 to which the other end of the rigid link 310 is rotatably coupled and a second vane coupling portion 216 to which the other side end of the cam link 320 is rotatably coupled. The engaging portion 217 is formed.

In this embodiment, the first vane coupling part 216 and the second vane coupling part 217 are formed in the form of holes passing through the coupling flange 214.

The first vane coupling portion 216 and the second vane coupling portion 217 may be configured to be axially coupled or hinged.

In the present embodiment, the rigid link 310 is positioned in front of the cam link 320.

One end of the rigid link 310 is coupled to the motor case 105. One end of the cam link 320 is also coupled to the motor case 105. That is, one end of the rigid link 310 and one end of the cam link 320 are rotatably coupled to the motor case 105.

The second vane coupling portion 217 is located further rearward beyond the rear side end 212a of the vane body 212 when viewed in plan view and the first vane coupling portion 216 is located on the rear side And is located on the vane body (212).

When viewed from the front, the first vane coupling portion 216 is located higher than the second vane coupling portion 217.

A virtual straight line B connecting the first vane coupling portion 216 and the second vane coupling portion 217 forms an angle A between the link coupling portions with respect to the vane body 212 . The inclination angle (a) of the linkage portion is a structure for effectively implementing the swing motion of the vane 210.

<Configuration of link>

The rigid link 310 is disposed on the front side of the cam link 320.

The rigid link 310 is disposed on the other side of the cam link 320. The rigid link 310 and the cam link 320 are rotated on different planes to prevent interference during rotation.

The rigid link body 310 includes a rigid link body 315 and a first rigid link shaft 311 protruding to the other side from the rigid link body 315 and rotatably engaged with the first vane engaging portion 216. [ And a second rigid link shaft 312 protruded from the rigid link body 315 to one side and rotatably coupled to the motor case 105.

In this embodiment, the rigid link body 315 is formed in a curved shape, and interference with the cam body 340 during operation can be avoided.

The first rigid link shaft 311 is disposed below the rigid link body 315 and the second rigid link shaft 312 is disposed on the upper side.

The first rigid link shaft 311 protrudes to the left where the vane 210 is located in the rigid link body 315 and the second rigid link shaft 312 protrudes to the left where the motor case 105 is located And protrudes rightward.

The first rigid link shaft 311 provides a structure in which the rigid link body 315 and the vane 210 can rotate relative to each other. In this embodiment, the first rigid link shaft 311 is integrally formed with the rigid link body 315. The first rigid link shaft 311 may be integrally formed with the vane 210 or the coupling flange 214. In this case,

The second rigid link shaft 312 provides a structure in which the rigid link body 315 and the motor case 105 can rotate relative to each other. In the present embodiment, the second rigid link shaft 312 is integrally formed with the rigid link body 315. The second rigid link shaft 312 may be integrally formed with the motor case 105, the cover panel 120, or the case 100, unlike the present embodiment.

In the present embodiment, the second rigid link shaft 312 is engaged with the rigid link coupling part 232 formed in the motor case 105. [

In operation, the rigid link 310 is formed with a resilient skin 316 to avoid interference with the cam link 320. The skin 316 is disposed on one side of the rigid link body 315.

In the present embodiment, the skin 316 is formed between the rigid link body 315 and the second rigid link shaft 312. In the present embodiment, the skin 314 is formed in a concave shape of "? &Quot; In operation, the cam link 320 may be introduced into the skin 316.

The skin 316 is positioned on the rotation plane of the cam link 320.

The cam link 320 includes a cam body 330 disposed on the case (the motor case 105 in this embodiment) and having a guide surface 335 for guiding the rotation of the vane 210 on the outside, A cam arm 340 coupled to the cam body 330 and coupled to the motor shaft 221 for rotation therewith and coupled to the cam arm 340 and rotatably coupled to the vane 210, And a guide arm 350 which moves relative to the guide surface 335 of the cam body 330 while moving relative to the guide body 340 in the longitudinal direction of the cam body 340.

The cam body 330 has a curved outer surface to facilitate movement of the guide arm 350. The guide arm 350 is moved along the outer surface of the cam body 330 in a state of being closely attached to the cam body 330.

The cam body 330 is fixed to the motor case 105.

The cam body 330 has an outer side surface with a large radius of curvature on the rear side and an outer side surface with a small radius of curvature on the front side. The guide arm 350 is moved along the lower side of the cam body 330 in this embodiment.

The cam body 330 is formed with a body insertion hole 331 through which the motor shaft 221 is inserted. The motor shaft 221 is inserted into the cam body 330 through the body insertion hole 331 and is engaged with the cam arm 340.

Below the cam body 330, a guide slot 332 through which the cam arm 340 is moved is formed. The rear side end 332b and the front side end 332a of the guide slot 332 serve as stoppers for restricting the rotation of the cam arm 340.

The cam body 330 includes a first cam body 334 and a second cam body 336.

The guide slot 332 is formed between the first cam body 334 and the second cam body 336 when they are engaged. When the first cam body 334 and the second cam body 336 are engaged with each other, one side of the cam arm 340 is positioned inside and is fitted into the body insertion hole 331.

The cam arm 340 is a part for connecting the cam body 330 and the guide arm 350. The camshaft 340 includes a camshaft body 345 and a motor shaft coupling portion 322 formed at one side of the camshaft body 345 and inserted into the body insertion hole 331 to be coupled to the motor shaft 221 And a cam arm coupling portion 342 formed on the other side of the cam arm body 345 and coupled with the guide arm 350. [

The first cam arm engaging portion 341 is protruded toward the motor shaft 221 side. In the present embodiment, the motor shaft 221 is disposed in the left-right direction, and the first cam arm engaging portion 341 is also disposed in the left-right direction. The motor shaft 221 is inserted into the first cam arm engaging portion 341 and is forcedly inserted.

The cam-arm engaging portion 342 protrudes in the longitudinal direction of the cam-arm body 345.

The cam body 345 is positioned on the rotation plane of the cam link 320 and is disposed in parallel with the rotation plane of the rigid link 310.

The guide arm 350 is moved in a state of being closely attached to the guide surface 335 in a state of being coupled to the cam arm 340.

The guide arm 350 is rotated about the first cam arm engaging portion 341.

The guide arm 350 is composed of three parts. The guide arm 350 includes a first guide arm body 351, a second guide arm body 352, and an elastic member 353.

The guide arm 350 includes a first guide arm 351 movably attached to the cam body 330 and installed to be movable relative to the cam arm 340, A second guide arm 352 coupled to the vane 210 and installed to be movable relative to the cam arm 340 and a second guide arm 352 connected to the cam arm 340 and the second guide arm 352, And an elastic member 353 for providing an elastic force to closely contact the first guide arm 351 with the cam arm 340.

The first guide arm 351 and the second guide arm 352 are combined and integrated. The elastic member 353 is disposed inside the combined first guide arm 351 and the second guide arm 352.

A slide space 354 is formed in the longitudinal direction within the first guide arm 351 and the second guide arm 352 and the elastic member 353 is positioned in the slide space 354.

The first guide arm 351 is formed with an insertion port 351a on the side where the cam arm 340 is in close contact with the cam body 330 and the opening 351b is formed on the opposite side.

And the cam arm engagement portion 342 of the cam arm 340 is inserted through the insertion opening 351a. The first guide arm 351 may be slidable along the longitudinal direction of the cam arm 340.

The second guide arm 352 is formed with an opening 352b on the side where it is engaged with the first guide arm 351. The second guide arm 352 has a guide arm engagement portion 321 for engagement with the vane 210.

The guide arm coupling portion 321 is coupled to the second vane coupling portion 217 of the vane 210. In this embodiment, the guide arm engagement portion 321 is formed in a hinged shape, and the second vane engagement portion 217 is formed in a hole shape.

The opening portion 351b of the first guide arm 351 and the opening portion 352b of the second guide arm 352 are formed in male and female shapes to be interference fit.

In the present embodiment, the elastic member 353 is formed in the form of a coil spring, and various shapes and materials may be used, unlike the present embodiment.

One side of the elastic member 353 is held in contact with the cam arm 340 and the other side thereof is held in contact with the guide arm 350. In this embodiment, one side of the elastic member 353 is coupled to the cam arm engagement portion 342, and the other side is supported in the second guide arm 352.

A support portion 353a for elastically supporting the other side of the elastic member 353 is formed in the second guide arm 352. The support portion 353a may be formed in a cylindrical shape to prevent movement of the coil spring, and may be inserted into the coil spring.

The cam arm joining portion 342 is also formed in a cylindrical shape to prevent movement of the coil spring, and may be inserted into the coil spring.

The cam arm 340 is coupled to the elastic member 353 and the guide arm 350 is closely attached to the cam body 330 by the elastic force of the elastic member 353.

<Explanation of cam link operation>

The operation of the rigid link 310 and the cam link 320 will be described in more detail with reference to Fig.

When the vane motor 220 rotates the cam arm 340 to the maximum in the clockwise direction, the discharge vane 200 forms a state as shown in FIG. 8 (a). In this embodiment, the state (a) of FIG. 8 is a state when the indoor unit is not operated.

8 (a), the discharge vane 200 maintains a state as shown in FIG. 8 (b) when the cam arm 340 is rotated counterclockwise. In this embodiment, the state shown in Fig. 8 (b) is a state when horizontal wind is provided.

8 (b), the discharge vane 200 maintains a state as shown in FIG. 8 (c) when the cam arm 340 is further rotated counterclockwise. In the present embodiment, the state shown in (c) of FIG. 8 is a state when the inclined wind is provided.

8 (c), the discharge vane 200 maintains a state as shown in FIG. 8 (d) when the cam arm 340 is rotated counterclockwise. When the vane motor 220 rotates the cam arm 340 in the maximum counterclockwise direction, the cam link 320 forms a state as shown in FIG. 8 (d). In this embodiment, the state shown in (d) of FIG. 8 is a state when vertical wind is provided.

A state in which the vane 210 is disposed substantially parallel or horizontally with respect to the floor, the ceiling, the bottom of the case, or the bottom of the cover panel is defined as a horizontal wind. When the horizontal air is blown, the discharged air flowing through the vane 210 generally flows in parallel to the floor, the ceiling, the case bottom, or the bottom of the cover panel.

The horizontal wind is discharged substantially parallel to the floor, the ceiling, the bottom of the case, or the bottom surface of the cover panel so as to flow the farthest room away from the room, instead of supplying the discharged air directly to the user. The discharged air discharged in the horizontal wind may not flow accurately in the horizontal direction because vortex or the like is generated during the flow. Thus, in the present embodiment, the term "generally horizontal" or "substantially parallel" is used, and the intended bar of the horizontal wind is intended to cause air to flow farther into the room by discharging the air in the horizontal direction . When providing the horizontal wind, the discharge air is guided through the upper side of the vane 210.

 A state in which most of the discharged air is guided through the upper side or the lower side of the vane 210 and the front end of the vane 210 is inclined downward is defined as a tilted wind.

A state in which most of the discharged air is guided through the lower side surfaces of the vane 210 and the vane 210 is installed substantially vertically toward the ground is defined as vertical wind. When the air is vertically blown, the discharge air is mainly struck against the lower side of the vane 210 and is guided vertically toward the surface.

When providing the horizontal wind, the inclined wind, or the vertical wind, the vane 210 may be positioned below the discharge port 102.

In the state of FIG. 8 (a), the indoor unit or the discharge vane 200 may be in an inactive state or in a state of not discharging air.

8 (a), the cam arm 340 is positioned at the rear side end 332b of the guide slot 332, and the rear side end 332b limits the rotation of the cam arm 340 .

8A, the guide arm 350 connected to the cam arm 340 is rotated along the guide surface 335 of the cam body 330. As shown in FIG.

8A, the vane 210 is housed in the discharge port 102. When the vane 210 is housed in the discharge port 102, the vane 210 is held by the cover 102, The same plane as the bottom surface of the panel 120 can be formed. That is, when the discharge vane 200 is not operated, the lower surface of the vane 210 does not protrude outside the cover panel 120, but forms a continuous surface with the cover panel 120.

In the state of FIG. 8 (b), the discharge vane 200 may form a horizontal wind. When the discharged air flows in a horizontal wind, the flow distance of the air can be maximized.

8A, the vane motor 220 rotates the cam arm 340 counterclockwise to form the state shown in FIG. 8B. The cam arm 340 is rotated around the motor shaft coupling portion 322.

A distance from the motor shaft coupling portion 322 to the rear side end 332b of the guide slot 322 is defined as a first guide distance L1 and the distance from the motor shaft coupling portion 322 to the guide slot 322 322 is defined as a second guide distance L2.

The distance between the guide arm engagement portion 321 and the motor shaft engagement portion 322 is variable.

8 (a), the distance between the guide arm engaging portion 321 and the motor shaft engaging portion 322 is the shortest distance. In the state shown in FIG. 8 (d) And the longest distance between the engaging portion 321 and the motor shaft engaging portion 322 is formed.

8A, when the cam arm 340 is rotated in the counterclockwise direction, the guide arm 350 is moved along the guide surface 335 in a state of being in tight contact with the guide surface 335 The distance between the guide arm engaging portion 321 and the motor shaft engaging portion 322 is gradually increased in the course of moving the guide slot 322 toward the front side end 332a.

Since the upper side of the rigid link 310 is rotatably coupled to the motor case 105 and the lower side of the rigid link 310 is rotatably coupled to the vane 210, when the cam arm 340 rotates counterclockwise, The front end of the vane 210 is rotated clockwise as shown in FIG. 8 (b).

Since the vane 210 is rotated in a state where it is configured in the cam link 320 and the rigid link 310, the vane 210 is operated in the form of a swing rather than a rotation.

8 (a) to 8 (b), the vane 210 is lowered from the upper side to the lower side, and the front end 212b of the vane 210 is rotated . That is, the vane 210 is vertically elevated and clockwise rotated simultaneously.

8A, the guide arm coupling portion 321 and the motor shaft coupling portion 322 form a virtual straight line G, and the first vane coupling portion 216 are located on the right side with respect to the straight line G as a reference.

In addition, the straight line G and the straight line B form a predetermined angle b.

The angle (c) between the straight line G and the straight line B in the state of FIG. 8 (b) is increased as compared with the case of FIG. 8 (a). In the present embodiment, the angle c is formed to be 90 degrees or less (when the clockwise direction from the straight line G to the straight line B is referred to).

In the state of FIG. 8 (b), it is advantageous that the vane 210 is positioned below the discharge port 102 when the air is discharged in the horizontal wind.

When the vane 210 is rotated at a height as shown in FIG. 8A, the amount of air guided to the vane 210 is reduced due to interference with the discharged air.

The vane 210 is lowered to the lower side of the discharge port 102 and then aligned in the horizontal direction as shown in FIG. 8B of this embodiment, so that most of the discharged air can be guided in the horizontal direction.

The vane 210 can be moved to the lower side of the discharge port 102 through the rotation of the rigid link 310 and the cam link 320 and the direction of the vane 210 can be formed horizontally. Conventionally, since the vane of the indoor unit is rotated in place, the same effect as the present embodiment can not be realized.

When the horizontal wind is formed through the rigid link 310 and the cam link 320, the vane 210 is positioned below the discharge port 102, and a larger amount of discharge air is supplied through the horizontal wind can do.

When the vane 210 is horizontally disposed and the air discharged from the discharge port 102 is formed as a horizontal wind, the vane 210 is positioned below the discharge port 102.

When the vane 210 is horizontally disposed and the air discharged from the discharge port 102 is formed as a horizontal wind, the vane 210 is positioned on the bottom surface of the case 100 (in this embodiment, And is positioned lower than the bottom surface of the cover panel 120. [0050]

The vane 210 is supported by the rigid link 310 and the cam link 320 in the state of FIG. 8 (b) forming the horizontal wind. Therefore, the air discharged from the discharge port 102 is vane 210 can be suppressed.

8 (b), the cam arm 340 is further rotated in the counterclockwise direction through the vane motor 220 to form the state shown in FIG. 8 (c).

The discharge vane 200 of FIG. 8 (c) can discharge the discharged air in the oblique direction between the vertical and horizontal directions. In the present embodiment, this is defined as an oblique wind.

The angle d between the straight line G and the straight line B in the state of FIG. 8 (c) is increased as compared with FIG. 8 (b). In the present embodiment, the angle d is greater than 90 degrees (when the clockwise direction from the straight line G to the straight line B is referred to as a reference), and is formed to be 180 degrees or less.

When the cam arm 340 is further rotated counterclockwise in the state of FIG. 8 (c), the state shown in FIG. 8 (d) can be formed.

In the state shown in FIG. 8 (d), the discharge vane 200 can form a vertical wind. A state in which the air discharged through the discharge port 102 is guided by the vane 210 and flows downward in the vertical direction is defined as a vertical wind. When the vane 210 forms a vertical wind, the vane crosses or orthogonally intersects the ceiling or the ground, and is arranged in the vertical direction.

When the vane 210 is disposed in the vertical wind, the discharge air is guided to the ground through the bottom surface of the vane 210. The upper surface of the vane 210 is preferably brought into close contact with the cover panel 120 as much as possible to minimize the flow of the discharged air.

In the present embodiment, the vertical wind is formed when the cam shaft 340 is rotated in the counterclockwise direction. In this state, the cam arm 340 is positioned at the front side end 332b of the guide slot 332. [

The vanes 210 are generally perpendicular to the ceiling or the ground.

The angle (e) between the straight line G and the straight line B in the state (d) of FIG. 8 is increased as compared with the case (c) of FIG. In the present embodiment, the angle (e) is more than 180 degrees (when the clockwise direction from the straight line G to the straight line B is referred to as a reference), and is formed to be 270 degrees or less.

8 (d), since the vane 210 is in close contact with the front side of the discharge port 102, almost all of the air discharged from the discharge port is moved downward.

8 (d), the first vane coupling part 216 is positioned below the straight line G. In this case,

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It is to be understood that the invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive.

100: Case 101: Suction port
102: discharge port 103:
104: Discharge channel 110: Case housing
120: cover panel 130: indoor heat exchanger
140: Indoor ventilation fan 200: Discharge vane
210: Vane 220: Vane motor
310: Rigid link 311: First rigid link shaft
312: second rigid link shaft 315: rigid link body
320: cam link 321: guide arm engaging portion
322: motor shaft coupling part 330: cam body
332: guide slot 333: front end
334: rear side end 335: guide surface
340: cam arm 350: guide arm
351: first guide arm body 352: second guide arm body
353: elastic member

Claims (15)

An indoor unit of an air conditioner installed on a ceiling,
The indoor unit includes a case having a suction port and a discharge port formed on a bottom surface thereof;
And a discharge vane disposed in the case and guiding a flow direction of air discharged from the discharge port,
The discharge vane,
A vane motor installed in the case and providing a driving force for adjusting the angle of the vane;
A rigid link rotatably connected to the vane and the case, respectively;
A motor for driving the vane motor, a motor for driving the vane motor, a motor for driving the motor, a motor for driving the motor, And a cam link for guiding the movement path of the vane while varying the length of the vane. The method according to claim 1,
Wherein the vane is positioned below the discharge port when the vane is rotated and discharge air discharged from the discharge port is discharged as horizontal wind. The method according to claim 1,
When the vane is rotated and the discharged air discharged from the discharge port is discharged as a horizontal wind,
Wherein the vane is spaced apart from a bottom surface of the case by a predetermined distance, and is positioned lower than a bottom surface of the case. The method according to claim 1,
When the vane is rotated and the discharged air discharged from the discharge port is discharged as vertical wind,
And a part of the vane is located inside the discharge port. The method according to claim 1,
Wherein the cam link
A cam body disposed in the case and having a guide surface for guiding the rotation of the vane outside;
A cam arm coupled to the cam body and coupled to the motor shaft and rotated;
And a guide arm which is coupled to the cam arm on an upper side so as to be relatively movable with respect to the vane and is movably coupled to a guide surface of the cam body while relatively moving in a longitudinal direction of the cam arm, ,
A motor shaft coupling portion to be coupled to the motor shaft is disposed in the cam arm,
And a guide arm engaging portion engaging with the vane in a relatively rotatable manner is disposed in the guide arm. The method of claim 5,
Wherein an elastic member is disposed between the cam arm and the guide arm, and the guide arm is brought into close contact with the guide surface of the cam body by the elastic force of the elastic member. The method of claim 6,
Wherein the elastic member is disposed inside the guide arm,
Wherein one side of the cam arm is located inside the cam body and the other side of the cam arm is located inside the guide arm. The method of claim 5,
The cam body
A body insertion hole into which the motor shaft is inserted;
And a guide slot in which the cam arm is inserted and moved. The method of claim 8,
Wherein the guide surface is formed along the guide slot. The method of claim 5,
The vane
A first vane coupling portion coupled to the rigid link so as to be rotatable relative to the rigid link;
And a second vane coupling portion that is coupled to the cam link in a relatively rotatable manner,
And the first vane coupling portion is located forward of the second vane coupling portion. The method of claim 10,
A virtual straight line (B) connecting the first vane coupling portion and the second vane coupling portion,
A virtual straight line G connecting the motor shaft coupling portion and the second vane coupling portion forms a predetermined angle,
When the discharged air discharged from the discharge port is discharged as a horizontal wind,
And the angle (c) between the straight line (B) and the straight line (G) is formed at 90 degrees or less. The method of claim 11,
And the air discharged from the discharge port is guided through the upper surface of the vane when the discharge air is formed in the horizontal wind. The method of claim 10,
A virtual straight line (B) connecting the first vane coupling portion and the second vane coupling portion,
A virtual straight line G connecting the motor shaft coupling portion and the second vane coupling portion forms a predetermined angle,
When the discharged air discharged from the discharge port is discharged as vertical wind,
And an angle (c) between the straight line (B) and the straight line (G) is formed to be greater than 180 degrees but less than 270 degrees. 14. The method of claim 13,
And the air discharged from the discharge port is guided through the lower surface of the vane when the discharge air is formed in the vertical wind. An indoor unit of an air conditioner installed on a ceiling,
The indoor unit includes a case having a suction port and a discharge port formed on a bottom surface thereof;
And a discharge vane disposed in the case and guiding a flow direction of air discharged from the discharge port,
The discharge vane,
A vane motor installed in the case and providing a driving force for adjusting the angle of the vane;
A rigid link rotatably connected to the vane and the case, respectively;
A cam body disposed in the case and having a guide surface for guiding the rotation of the vane outside;
A cam arm coupled to the cam body and coupled to the motor shaft and rotated;
A guide arm having an upper side coupled to the cam arm so as to be relatively movable, a lower side coupled with the vane so as to be relatively rotatable relative thereto, and being moved relative to the guide surface of the cam body while being relatively moved in the longitudinal direction of the cam arm;
And an elastic member disposed between the cam arm and the guide arm and providing an elastic force to the guide arm when the cam arm and the guide arm are moved relative to each other to closely contact the guide arm with the guide surface of the cam body,
A motor shaft coupling portion to be coupled to the motor shaft is disposed in the cam arm,
A guide arm engaging portion engaging with the vane so as to be relatively rotatable is disposed in the guide arm,
Wherein the elastic member is disposed inside the guide arm,
Wherein one side of the cam arm is located inside the cam body and the other side of the cam arm is located inside the guide arm.

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