KR102451312B1 - Indoor unit of air conditioner - Google Patents

Abstract

The present invention relates to an indoor unit of an air conditioner installed on a ceiling, the indoor unit comprising: a case in which an inlet and an outlet are formed on a bottom surface of the indoor unit; and a discharge vane disposed in the case and guiding the flow direction of the air discharged from the discharge port, wherein the discharge vane includes: a vane for guiding the flow direction of the air; a rigid drink link comprising a first rigid drink shaft rotatably coupled to the vane and a second rigid drink shaft rotatably coupled to the case; A first joint link comprising a first joint link shaft coupled to the case and relative rotation; a second joint link comprising a second joint link shaft coupled to the vane and relatively rotatable; a joint shaft formed on at least one of the first joint link or the second joint link, and rotatably coupled to the first joint link and the second joint link; and a vane motor installed in the case and providing a driving force to any one of the rigid link or the first joint link for adjusting the angle of the vane.
When the present invention forms a horizontal wind through the rigid drink and the joint link, the vane is positioned at the lower side of the discharge port, and through this, a greater amount of discharge air can be provided as a horizontal wind, and the rigid drink and the joint link When forming a vertical wind through the , there is an advantage that a portion of the vane is in close contact with the outlet side, and through this, a larger amount of discharge air can be provided as a vertical wind.

Description

Indoor unit of air conditioner

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

In general, an air conditioner is composed of a compressor, a condenser, an evaporator, and an expander, and supplies cold or warm air to a building or room using an air conditioning cycle.

Structurally, the air conditioner is divided into a separate type in which the compressor is disposed outdoors and an integral type in which the compressor is integrally manufactured.

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

The integral type is an indoor heat exchanger, an outdoor heat exchanger and a compressor installed in one case. The integrated air conditioner includes a window type air conditioner which is installed directly by hanging the device on a window, and a duct type air conditioner which is installed outside the room by connecting a suction duct and a discharge duct.

The separation type air conditioner is generally classified according to an installation form of the indoor unit.

An indoor unit installed vertically in the indoor space is called a stand-type air conditioner, an indoor unit installed on a wall is called a wall-mounted air conditioner, and an indoor unit installed on the ceiling is called a ceiling-type indoor unit.

Also, as a type of a separate type air conditioner, there is a system air conditioner capable of providing air-conditioned air to a plurality of spaces.

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

The plurality of indoor units provided in the system air conditioner may be any of a stand type, a wall mounted type, or a ceiling type.

In the case of a conventional ceiling-type indoor unit, one vane is installed at a discharge port, and a rotation angle of the vane is adjusted to control the flow direction of the discharged air.

However, since the conventional ceiling-type indoor unit controls the air discharge direction with only one vane, there is a limited problem in controlling the air discharge direction.

Republic of Korea Patent Registration 10-0679838 B1

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

An object of the present invention is to provide an indoor unit of an air conditioner capable of minimizing interference with discharge air through a rigid link and a joint link and realizing a vertical wind and a horizontal wind.

An object of the present invention is to provide an indoor unit of an air conditioner capable of relatively rotating a first joint link and a second joint link about a joint axis disposed in the middle of the joint link, thereby minimizing the loss of discharge air. .

The present invention provides an indoor unit of an air conditioner capable of providing a larger amount of discharged air as a horizontal wind through a vane positioned below a discharge port when a horizontal wind is formed through a rigid drink link and a joint link. there is a purpose to

The present invention provides an indoor unit of an air conditioner capable of providing a larger amount of discharged air as a vertical wind through a portion of a vane in close contact with an outlet side when a vertical wind is formed through a rigid drink link and a joint link. there is a purpose to

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

The present invention minimizes the interference with the discharge air through the rigid link and the articulated link and can implement a vertical wind and a horizontal wind.

When the present invention forms a horizontal wind, the first joint link and the second joint link are arranged in a straight line and disposed below the outlet, and when forming a vertical wind, the first joint link and the second joint link form an obtuse angle By forming a part of the vane can be located inside the outlet.

The present invention relates to an indoor unit of an air conditioner installed on a ceiling, the indoor unit comprising: a case in which an inlet and an outlet are formed on a bottom surface of the indoor unit; and a discharge vane disposed in the case and guiding the flow direction of the air discharged from the discharge port, wherein the discharge vane includes: a vane for guiding the flow direction of the air; a rigid drink link comprising a first rigid drink shaft rotatably coupled to the vane and a second rigid drink shaft rotatably coupled to the case; A first joint link comprising a first joint link shaft coupled to the case and relative rotation; a second joint link comprising a second joint link shaft coupled to the vane and relatively rotatable; a joint shaft formed on at least one of the first joint link or the second joint link, and rotatably coupled to the first joint link and the second joint link; and a vane motor installed in the case and providing a driving force to any one of the rigid link or the first joint link for adjusting the angle of the vane.

When the vanes are horizontally disposed to form air discharged from the outlet in a horizontal wind, the vane may be positioned below the outlet.

When the vanes are horizontally disposed to form the air discharged from the outlet in a horizontal wind, the vanes may be spaced apart from the bottom surface of the case by a predetermined distance, and may be located further below the bottom surface of the case.

When the vanes are horizontally arranged to form the air discharged from the outlet in a horizontal wind, the first joint link and the second joint link may be arranged in a line.

When the vanes are disposed perpendicular to the ceiling or the ground to form air discharged from the outlet in a vertical wind, a portion of the vanes may be located inside the outlet.

When the vane is disposed perpendicular to the ceiling or the ground to form the air discharged from the outlet in a vertical wind, the angle between the first rigid drink shaft, the second rigid drink shaft and the second joint link shaft is formed (C ) can be formed as an obtuse angle.

When the vane is disposed perpendicular to the ceiling or the ground to form the air discharged from the outlet in a vertical wind, the angle between the first joint link axis, the joint axis and the second joint link axis is an obtuse angle (D). can be formed with

When the vanes are disposed orthogonally to the ceiling or the ground to form the air discharged from the outlet in a vertical wind, the first joint link shaft, the second rigid link shaft and the second joint link shaft may be arranged in a line. ,

When the vane is disposed orthogonally to the ceiling or the ground to form the air discharged from the outlet in a vertical wind, the first joint link shaft, the second rigid link shaft and the second joint link shaft are arranged in a line, the ground Alternatively, it may be disposed orthogonal to the ceiling.

and a boss stopper disposed in the case and limiting a rotation angle of the rigid drink, wherein the boss stopper includes one end limiting the rotation angle of the rigid drink when the rigid drink is rotated clockwise; When the rigid link is rotated counterclockwise, it may include the other end limiting the rotation angle of the rigid link.

It may further include a boss disposed on the case, to which the second rigid link shaft is rotatably coupled, the boss is formed to protrude toward the vane, and the boss stopper may be formed on the boss.

The second rigid drink shaft may be disposed to pass through the boss, and the vane motor may be connected to the second rigid drink shaft disposed to pass through the boss to provide a driving force.

It is disposed on at least one of the first joint link or the second joint link, and may further include a joint stopper for limiting the relative rotation angle during relative rotation about the joint axis.

The joint stopper is disposed on any one of the first joint link or the second joint link, and when the second joint link is rotated counterclockwise with respect to the joint axis, it is supported on the other one and is no longer counterclockwise. a first joint stopper limiting rotation in the direction; It is disposed on at least one of the first joint link or the second joint link, and when the second joint link is rotated in the clockwise direction with respect to the joint axis, it is supported on the other one to limit further rotation in the clockwise direction. It may include a second joint stopper.

When the vanes are horizontally arranged to form the air discharged from the outlet in a horizontal wind, the first joint stopper disposed on any one of the first joint link or the second joint link is the first joint link or the first joint link. It is supported on the other of the two joint links, and the second joint link may limit further rotation in the counterclockwise direction with respect to the first joint link.

When the vane is disposed perpendicular to the ceiling or the ground to form the air discharged from the outlet in a vertical wind, the second joint stopper disposed on any one of the first joint link or the second joint link is the first It is supported on the other of the joint link or the second joint link, the second joint link may limit further rotation in the clockwise direction with respect to the first joint link.

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 being able to implement a vertical wind and a horizontal wind through the joint link and the rigid link for rotating the vane.

Second, the present invention has the advantage that, when forming a horizontal wind through the rigid drink link and the joint link, the vane is positioned below the discharge port, and through this, a larger amount of discharge air can be provided as horizontal wind.

Third, the present invention has an advantage in that when forming a vertical wind through the rigid drink and the joint link, a portion of the vane is in close contact with the discharge port side, thereby providing a larger amount of discharge air as a vertical wind.

Fourth, when the present invention forms a horizontal wind, the first joint link and the second joint link are arranged in a straight line and arranged on the lower side of the outlet, and when the vertical wind is formed, the first joint link and the second joint link are By forming an obtuse angle, there is an advantage that a part of the vane can be positioned inside the outlet.

Fifth, the present invention is an advantage that the rear end of the vane body can be closer to the outlet side more because the first joint link and the second joint link are rotated about the joint axis to form an angle (D) of 180 degrees or less. There is this.

Sixth, in the present invention, since the first joint link and the second joint link are rotated about the joint axis, the first joint link axis of the rigid drink can be raised to a height similar to the joint axis, and through this, the rear end of the vane body There is an advantage that can be closer to the discharge port side.

Seventh, the present invention has the advantage of preventing the interference of the joint link and the rigid link since the first joint link and the second joint link are rotated around the joint axis.

Eighth, in the present invention, when the discharge vane forms a vertical wind, the rigid drink is in a state supported by the boss stopper, and the joint link is in a state supported by the joint stopper. There are advantages to doing.

Ninth, according to the present invention, when the discharge vane forms a vertical wind, the rigid drink is supported by the boss stopper, and the joint link is supported by the joint stopper. There are advantages that can be

1 is a perspective view illustrating an indoor unit of an air conditioner according to an embodiment of the present invention.
FIG. 2 is a cut-away perspective view of FIG. 1 ;
3 is a first perspective view showing a discharge vane according to an embodiment of the present invention.
4 is a second perspective view from another angle showing a discharge vane according to an embodiment of the present invention.
FIG. 5 is a plan view of FIG. 4 .
Figure 6 is a perspective view of the joint link shown in Figure 3;
7 is an exploded perspective view of FIG. 6 ;
8 is an exemplary view of the operation of the joint link shown in FIG.
9 is an exemplary operation view of the discharge vane shown in FIG.

Advantages and features of the present invention and methods of achieving them will become apparent with reference to the embodiments described below in detail 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 allow the disclosure of the present invention to be complete, and common knowledge in the technical field to which the present invention pertains It is provided to fully inform those who have the scope of the invention, and the present invention is only defined by the scope of the claims. Like reference numerals refer to like elements throughout.

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

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 a cutaway perspective view of FIG. 1 .

<Configuration of indoor unit>

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

<Case configuration>

In this embodiment, the case 100 is fixed to the ceiling of the room, the lower side is opened to cover the case housing 110, the open surface of the case housing 110 is exposed to the room, the suction port 101 and a cover panel 120 having a discharge port 102 formed therein.

Unlike the present embodiment, the cover panel 120 may be formed integrally with the case housing 110 and may be formed so that the upper side thereof is opened. The case 100 may be implemented in various ways depending on the manufacturing form, and the configuration of the case 100 does not limit the spirit 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 spirit of the present invention. In this embodiment, one suction port 101 is formed, and a plurality of the discharge ports 102 are disposed.

In this embodiment, the inlet 101 is formed in a rectangular shape when viewed from the bottom, and four outlets 102 are spaced apart from each edge of the inlet 101 by a predetermined distance.

The cover panel 120 further includes a suction grill 122 that covers the suction port 101 , and the suction grill 122 is detachably installed from the cover panel 120 .

A pre-filter 124 is disposed on the upper side of the suction grill 122 , and the pre-filter 124 filters the 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 inlet 101 and the outlet 102 , and the indoor heat exchanger 130 partitions the inside of the case 100 . The indoor heat exchanger 130 is vertically disposed in this embodiment.

The indoor heat exchanger 130 is disposed so that the air discharged from the indoor blowing fan 140 enters vertically.

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 to the drain pan 132 and then be stored. A drain pump (not shown) for discharging the collected condensed water to the outside is disposed in the drain pan 132 .

The drain pan 132 may have a directional inclined surface to collect and store the condensed water flowing down from the indoor heat exchanger 130 to one side.

<Configuration of indoor blower fan>

The indoor blowing fan 140 is located inside the case 100 and is disposed above the suction port 101 . The indoor blower fan 140 is a centrifugal blower that sucks air in the center and discharges air in the circumferential direction.

The indoor blowing 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 passing through the suction grill 122 to the fan 144 .

The fan motor 146 rotates the fan 144 .

<Configuration of Euro>

For the indoor heat exchanger 130 , a space on the side of the indoor blowing fan 140 is defined as a suction passage 103 , and an outer space (indoor heat exchanger 130 and case housing 110 ) with respect to the indoor heat exchanger 130 . ) is defined as the discharge flow path 104 .

The suction flow path 103 communicates with the suction port 101 , and the discharge flow path 104 communicates with the discharge port 103 .

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 inlet 101 and the outlet 102 are formed on the same surface of the cover panel 120 .

The suction port 101 and the discharge port 102 are disposed to face 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, but the discharge port 102 connected to the discharge passage 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 .

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 a discharge vane according to an embodiment of the present invention from another angle, and FIG. 5 is FIG. is a plan view of, FIG. 6 is a perspective view of the joint link shown in FIG. 3, and FIG. 7 is an exploded perspective view of 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 port 102 .

The discharge vane 200 includes a vane 210 for guiding the flow direction of air, and a vane motor 220 installed in the case 100 and providing a driving force for angle adjustment of the vane 210, A rigid link (310, rigid link) and an articulating link (310) that rotatably connects the vane 210 and the case 100, respectively, and rotates according to the driving force of the vane motor 220 to rotate the vane 210 ( 320).

The rigid drink 310 and the joint link 320 may be installed in the case 100 , but in this embodiment, they are installed in the motor case 105 disposed on the discharge passage 104 . In this embodiment, the joint link 320 is formed longer than the rigid link 310 .

The motor case 105 is disposed in the air discharge direction. In the present embodiment, the motor case 105 may be installed in the cover panel 120 or the case housing 110 forming the discharge passage 104 . Unlike the present embodiment, the motor case 105 may be formed to protrude toward the discharge passage 104 of the cover panel 120 or the case housing 110 .

The motor case 105 is disposed to cross or orthogonal to the longitudinal direction of the vane 210 . The motor case 105 may be disposed at one end and the other end in the longitudinal direction of the vane 210 , respectively. The motor case 105 is formed in a plate shape.

The vane 210 may be spaced apart from the motor case 105 by a predetermined distance in the longitudinal direction of the vane 210 , and the vane 210 may be accommodated in the outlet 102 .

A vane motor installation part 106 to which the vane motor 220 is assembled protrudes from the outside (the vane motor side) of the motor case 105 . The vane motor 220 is fastened to the vane motor installation part 106 and fixed.

The rigid link 310 and the joint link 320 are respectively disposed at one end and the other end of the vane 210 .

The vane motor 220 may be disposed on at least one of one end or the other end of the vane 210 . In this embodiment, the vane motor 220 is installed only at one end or the other end 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 . So, the driving force of the vane motor 220 is provided to any one of the rigid link 310 and the joint link 320 through the motor case 105 .

A boss for installing a link is formed on the inner side (the vane side) of the motor case 105 . The boss 230 is formed to protrude inward (the vane side).

Any one of the rigid link 310 or the joint link 320 may be installed through the boss 230 . The installed link is rotated around the boss 230 .

In this embodiment, the rigid link 310 may be coupled to the boss 230 and rotated around the boss 230 .

The vane motor 220 provides a driving force to the link coupled to the boss 230 .

In this embodiment, the rotational force of the vane motor 220 is provided to the rigid link 310 installed through the boss 230, and the rigid link 310 rotates clockwise according to the rotation direction of the vane motor 220. Alternatively, it may be rotated counterclockwise.

In this embodiment, the vane motor 220 is a step motor is used.

The boss 230 not only provides the coupling structure of the rigid link 310 but also provides a stopper function for limiting the rotation radius of the rigid link 310 .

The boss 230 is formed as a hollow 236 with an empty inside. The rigid link 310 penetrates through the hollow 236 of the boss 230 and is disposed to penetrate the motor case 105 .

The boss 230 is formed in a cylindrical shape and protrudes toward the vane 210 .

The boss 230 has a boss stopper 232 that further protrudes toward the vane 210 . The boss stopper 232 forms a mutual engagement when the rigid drink 310 rotates, and limits the rotation of the rigid drink 310 .

The boss stopper 232 limits the rotation angle with respect to the clockwise rotation and the counterclockwise rotation of the rigid link 310 , respectively.

In this embodiment, the boss stopper 232 limits the rotation angle of the rigid link 310 to be rotatable by approximately 270 degrees.

The boss stopper 232 forms a continuous surface with the boss 230 formed in a cylindrical shape. One end 233 and the other end 234 of the boss stopper 232 mutually interfere with the rigid link 310 .

The one end 233 is in contact with the clockwise rotation of the rigid drink 310 and limits the rotation of the rigid drink 310 . The other end 234 is in contact with the counterclockwise rotation of the rigid drink 310 , and is a portion limiting the rotation of the rigid drink 310 . The positions of the one end 233 and the other end 234 may be reversed according to design.

The boss stopper 232 is positioned on the rotational plane of the rigid drink 310, and when the rigid drink 310 is rotated, the boss stopper 232 comes into contact with the one end 233 or the other end 234 to stop the rotation. do.

A virtual plane formed when the rigid link 310 is rotated in a clockwise or counterclockwise direction is defined as a rotation plane. In this embodiment, a plurality of links are rotated, and each link forms a respective unique rotational plane.

<Configuration of the vane>

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

The vane 210 has a vane body 212 formed to extend long in the longitudinal direction of the outlet 102, and protrudes upward from the vane body 212, and the rigid link 310 and the joint link 320. Includes a coupling flange 214 to which is coupled.

The vane body 212 may be formed in a gently curved surface.

The vane body 212 controls the direction of air discharged along the discharge passage 104 . The discharged air collides with the upper 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 perpendicular or intersecting.

A plurality of grooves 213 are formed on the upper surface of the vane body 212 . The groove 213 is formed in the longitudinal direction of the vane body 212 . The groove 213 is positioned between the plurality of coupling flanges 214 .

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

The coupling flange 214 is formed to protrude 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, the coupling flange 214 is disposed to be perpendicular to or crossed with respect to the longitudinal direction of the vane body 212 .

The coupling flange 214 has a low air discharge direction side (front) and a high air entry direction side (rear side). In this embodiment, the coupling flange 214 is formed with a high side to which the rigid link 310 is coupled and a low side to which the joint link 320 is coupled.

The rear side end 214a of the coupling flange 214 is positioned further rearward beyond the rear side end 212a of the vane body 212 . That is, the rear end 214a of the coupling flange 214 is formed to protrude toward the rear side of the vane body 212 .

The coupling flange 214 includes a first vane coupling part 216 to which the other end of the rigid link 310 is rotatably coupled, and a second vane to which the other end of the joint link 320 is rotatably coupled. A coupling 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 a hole passing through the coupling flange 214 .

Unlike the present embodiment, the first vane coupling part 216 and the second vane coupling part 217 may have a structure capable of axial coupling or hinge coupling. For example, the first vane coupling part 216 and the second vane coupling part 217 may be manufactured in the same shape as the boss 230 .

Meanwhile, one end of the rigid link 310 is coupled to the motor case 105 , and more specifically, coupled to the boss 230 . One end of the joint link 320 is coupled to the motor case 105 . That is, one end of the rigid link 310 and one end of the joint link 320 are rotatably coupled to the motor case 105 .

The motor case 105 has a boss to which one end of the rigid link 310 is rotatably coupled, and a joint link coupling part 237 to which one end of the joint link 320 is rotatably coupled is formed. .

The joint link coupling portion 237 is formed in the form of a hole.

The first vane coupling part 216 is located on the rear side beyond the rear end 212a of the vane body 212 when viewed in a plan view, and the second vane coupling part 217 is viewed in a plan view. When, it is located on the vane body (212).

The first vane coupling part 216 is positioned higher than the second vane coupling part 217 when viewed from the front.

Therefore, the first vane coupling part 216 and the second vane coupling part 217 form an angle A between the link coupling parts with respect to the vane body 212 . The link coupling portion inclination angle (a) is a structure for effectively implementing the turning motion of the vane (210).

<Configuration of link>

The rigid link 310 is disposed on the rear side compared to the joint link 320 .

The rigid link 310 is disposed on the other side compared to the joint link 320 . So, the rigid link 310 and the joint link 320 are rotated on different rotational planes, thereby preventing interference during rotation.

The rigid drink 310 includes a rigid drink body 315 and a first rigid link shaft 311 protruding from the rigid drink body 315 to the other side and rotatably coupled to the first vane coupling part 216 . ), a second rigid drink shaft 312 that protrudes to one side from the rigid drink body 315 and is rotatably coupled to the boss 320, and the rigid drink body 315 protrudes onto the rotational plane , and a link stopper 314 that forms a mutual engagement with the boss stopper 232 when rotating at a predetermined angle.

The first rigid drink shaft 311 provides a structure in which the rigid drink body 315 and the vane 210 can be relatively rotated. In this embodiment, the first rigid drink shaft 311 is manufactured integrally with the rigid drink body 315 . Unlike this embodiment, the first rigid link shaft 311 may be manufactured integrally with the vane 210 or the coupling flange 214 .

The second rigid drink shaft 312 provides a structure in which the rigid drink body 315 and the motor case 105 can be relatively rotated. In this embodiment, the second rigid drink shaft 312 is manufactured integrally with the rigid drink body 315 . Unlike this embodiment, the second rigid link shaft 312 may be manufactured integrally with the motor case 105 , the cover panel 120 , or the case 100 .

The link stopper 314 is disposed on the rotational plane of the rigid link 310 . When the rigid link 310 is rotated clockwise, the link stopper 314 comes into contact with one end 233 of the boss stopper 232, and the rotation is stopped. When the rigid link 310 is rotated counterclockwise, the link stopper 314 or the rigid link body 315 comes into contact with the other end 234 of the boss stopper 232, and the rotation is stopped.

In this embodiment, the link stopper 314 is formed to protrude to the opposite side of the joint link 320 with respect to the rigid drink body 315.

The joint link 320 may be bent in a joint form at a specific location.

The joint link 320 is rotatably coupled to the case 100 and a first joint link 330 rotatably coupled to the vane 210 and rotatably with the first joint link 330 . The second joint link 340 is coupled, and is formed in at least one of the first joint link 330 or the second joint link 340, the first joint link 330 and the second joint link 340 ) includes a joint stopper 350 that limits the rotation angle during relative rotation.

The rotation plane of the joint link 320 is formed differently from the rotation plane of the rigid link 310 . Since the rotation planes of the joint link 320 and the rigid link 310 are different from each other, it is possible to prevent interference during operation.

The first joint link 330 is the case 100 and the second joint link 340 and the first joint link body 335 relative to each other, and the first joint link body 335 protrudes to one side. and a first joint link shaft 331 rotatably coupled to the case 100, and a first joint link shaft formed on the first joint link body 335 and rotatably coupled with the second joint link 340 1 includes a connect link unit (336).

The first joint link body 335 is rotatably coupled to the upper side of the case 100 and the lower side is rotatably coupled to the second joint link 340 .

The rotation plane of the first joint link body 335 is arranged to be parallel to the discharge direction of the air. That is, the rotation plane of the first joint link body 335 is orthogonal to the longitudinal direction of the vane 210 .

The first joint link shaft 331 protrudes from the first joint link body 335 to one side.

The first joint link shaft 331 is coupled to the joint link coupling portion 237, and forms a center of rotation in which the first joint link body 335 can be rotated. Since the joint link coupling portion 237 is formed in the form of a hole, the first joint link shaft 331 is formed in a cylindrical structure that can be inserted into the hole.

After the first joint link shaft 331 is inserted into the joint link coupling portion 237, a hook structure is disposed so that separation is blocked. In this embodiment, the first joint link 331 includes a plurality of first link shaft body 332 and a first link hook 333 disposed at an end of the first link shaft body 332, respectively.

The first link shaft body 332 forms a part of a cylindrical shape, and the first link hook 333 has the first link shaft body 332 protruding outward in the radial direction to form a first link hook 333 . .

In this embodiment, four of the first link shaft body 332 are arranged, and these are gathered to form a cylindrical shape. Each of the first link shaft body 332 is spaced apart from each other by a predetermined interval, thereby forming a space capable of bending deformation.

The first joint link shaft 331 is elastically deformable by the material.

The first joint link shaft 331 passes through the joint link coupling portion 237 , and the first link hook 333 forms a mutual engagement with the motor case 105 .

The first joint link shaft 331 is formed with a shaft flange 338 that limits the insertion depth of the first link shaft body 332 . The shaft flange 338 is in close contact with the other side of the motor case 105 .

The first connect link portion 336 is formed to extend from the first joint link body (335). The first connect link portion 336 is formed to protrude in the longitudinal direction of the first joint link body (335).

The first connect link part 336 and the second connect link part 346 to be described later are assembled in a male and female shape. In the present embodiment, the first connect link unit 336 has a female shape and the second connect link unit 346 has a male shape. Unlike the present embodiment, the male and female shapes may be arranged oppositely.

The first connect link unit 336 and the second connect link unit 346 may be rotated relative to each other on the rotation plane of the first joint link 330 .

The first connect link unit 336 includes one side link unit body 337 and the other side link unit body 337 protruding in the longitudinal direction from one side and the other side of the first connect body 335, respectively, and the one side link unit body. It includes a joint shaft hole 339 formed in the 337 and the other link unit body 337, respectively.

A link insertion space 334 is formed between the one side link unit body 337 and the other side link unit body 337 .

The one side link unit body 337 and the other side link unit body 337 are disposed to face each other. Each joint shaft hole 339 is also disposed to face each other.

The second joint link 340 is the vane 210 and the first joint link 330 and a second joint link body 345 relative to each other, and the second joint link body 345 protrudes to the other side. and a second joint link shaft 341 rotatably coupled to the vane 210, and a second joint link shaft 341 formed on the second joint link body 345 and rotatably coupled to the first joint link 330 2 includes a connect link unit 346 .

The second joint link body 345 is formed longer than the first joint link body 335 . The second joint link body 345 is disposed in the same direction as the first joint link body 335 .

The second joint link body 345 forms a plane of rotation of the joint link with the first joint link body 335 . The rotation plane formed by the joint link 320 is parallel to the rotation plane formed by the rigid link 310 .

The second joint link shaft 341 has the same configuration as the first joint link shaft 331 . However, the second joint link shaft 341 is formed to protrude in the opposite direction to the first joint link shaft 331 .

The second joint link shaft 341 includes a second link shaft body 342 and a second link hook 343 . The second joint link shaft 341 is formed with a shaft flange 348 that limits the insertion depth of the second link shaft body 342 . The shaft flange 348 is in close contact with one side of the coupling flange 214 .

The second connect link unit 346 includes one side link unit body 347 and the other side link unit body 347 protruding from one side and the other side of the second connect body 345 in the longitudinal direction, respectively, and the one side link unit body. (347) and a joint shaft 349 formed on the other side link unit body 347, respectively, and the interspace 343 formed between the one side link unit body 347 and the other side link unit body 347.

The joint shaft 349 formed on the one side link part body 347 is formed to protrude to one side, and the joint shaft 349 formed on the other side link part body 347 is formed to protrude to the other side.

The joint shaft 349 may be formed in at least one of the first joint link 330 or the second joint link 340, and the first joint link 330 and the second joint link 340 coupled in a relative rotatable manner.

The one side link unit body 347 and the other side link unit body 347 can be bent and deformed by the elasticity of the material.

When the second connect link part 346 is inserted into the link insertion space 334 and coupled with the first connect link part 336, the one side link part body 347 and the other side link part body 347 are the It may be bent and deformed into the interspace 344 .

The joint shaft 349 of the second joint link 340 is inserted into the joint shaft hole 339 of the first joint link 330 . In such a structure, the first joint link 330 and the second joint link 340 may be rotated relative to each other.

On the other hand, the joint stopper 350 limits the relative rotation angle of the first joint link 330 and the second joint link 340 .

Since the angle between the first joint link 330 and the second joint link 340 is limited through the joint stopper 350, the vane 210 can be positioned more accurately.

In this embodiment, the joint stopper 350 is a first joint stopper 352 for limiting the clockwise rotation of the joint link 320, and a second joint for limiting the counterclockwise rotation of the joint link 320 A stopper 354 is included.

The first joint stopper 352 is disposed on the front side of at least one of the first joint link 330 or the second joint link 340 . The second joint stopper 354 is disposed on the rear side of at least one of the first joint link 330 or the second joint link 340 .

In this embodiment, the first joint stopper 352 is formed to protrude forward from the second joint link body 345 .

The second joint stopper 354 is manufactured by forming the rear side of the second joint link body 345 inclined. Unlike this embodiment, the second joint stopper 354 can also be manufactured to protrude.

The first joint stopper 352 and the second joint stopper 354 may be arranged in various positions in various shapes according to the relative rotation angle to be limited.

In this embodiment, the first joint stopper 352 may be supported on the front side outer surface 351 of the first joint link body 335 . The second joint stopper 354 may be supported on the rear side outer surface 353 of the first joint link body 335 .

8 is an operational view of the joint link shown in FIG. 7, and FIG. 9 is an operational view of the discharge vane shown in FIG.

<Explanation of joint link operation>

The operation of the joint link 320 will be described in more detail with reference to FIG. 8 .

When the vane motor 220 rotates the rigid link 310 to the maximum in the clockwise direction, the joint link 320 forms a state as shown in (a) of FIG. 8 .

When rotating the rigid link 310 counterclockwise in the state of Figure 8 (a), the joint link 320 maintains the state as shown in Figure 8 (b).

When the vane motor 220 rotates the rigid link 310 counterclockwise to the maximum, the joint link 320 forms a state as shown in (c) of FIG. 8 .

When the state of Figure 8 (a), the first joint stopper 352 is a state supported on the front side outer surface 351 of the first joint link body 335 . In this state, the second joint link 340 can no longer rotate in the counterclockwise direction.

In the state of Figure 8 (c), the second joint stopper 354 is supported on the rear side outer surface 353 of the first joint link body 335 . When the second joint link 340 is rotated clockwise about the joint axis 349 in the state of (a) of FIG. (c) of (c) is formed.

<Explanation of operation of rigid link and joint link>

The operation of the rigid link and the joint link will be described with reference to FIGS. 8 and 9 .

In the state of FIGS. 8A and 9A , the discharge vane 200 is in a non-operational state. When the indoor unit is not operated, the discharge vane 200 maintains the state as shown in FIGS. 8A and 9A , and the vane motor 220 moves the rigid link 310 clockwise to the maximum rotate At this time, the link stopper 314 is supported by one end 233 of the boss stopper 232 .

The first joint stopper 352 is in a state supported on the front side outer surface 351 of the first joint link body 335 . The joint link 320 does not form an angle between them, and maintains a straight-line state.

The rigid drink 310 is rotated about the second rigid drink shaft 312, the joint link 320 is rotated about the first joint link shaft 331.

The vane 210 is rotated in a state constrained by the rigid link 310 and the joint link 320 , and is located in the outlet 102 . A lower surface of the vane 210 forms a continuous surface with the cover panel 120 .

In the state of FIG. 9 (b), the discharge vane 200 may form a horizontal wind.

The horizontal wind is defined as a state in which the air discharged from the outlet 102 is guided by the vane 210 and flows in the horizontal direction with the ceiling or the ground. When the discharge air flows in a horizontal wind, the flow distance of the air can be maximized.

In the state of Fig. 9 (a), the vane motor 220 rotates the rigid link 310 counterclockwise to form the state of Fig. 9 (b). The joint link 320 is rotated about the first joint link shaft 331 .

When the vanes 210 are disposed to discharge the horizontal wind, the second joint link shaft 341 is located lower than the first rigid link shaft 311 .

When the air is discharged in the horizontal wind, the vane 210 is advantageously located below the discharge port 102 .

When the vane 210 is rotated at the same height as in FIG. 9A , the amount of air guided to the vane 210 is reduced due to interference with the discharge air.

As shown in (b) of FIG. 9 of this embodiment, after the vane 210 descends to the lower side of the discharge port 102, it must be aligned in the horizontal direction to guide most of the discharge air in the horizontal direction.

In this embodiment, the vane 210 can be moved to the lower side of the outlet 102 through the rotation of the rigid drink 310 and the joint link 320, and the direction of the vane 210 can also be formed horizontally. Since the vane of the conventional indoor unit has a structure that rotates in place, the same effect as the present embodiment cannot be realized.

When forming a horizontal wind through the rigid drink link 310 and the joint link 320, the vane 210 is positioned below the discharge port 102, and through this, a larger amount of discharge air is provided as a horizontal wind. can do.

When the vanes 210 are horizontally arranged to form the air discharged from the outlet 102 in a horizontal wind, the vanes 210 are positioned below the outlet 102 .

When the vanes 210 are horizontally arranged to form the air discharged from the outlet 102 in a horizontal wind, the vanes 210 are formed on the bottom surface of the case 100 (in this embodiment, the cover panel 120). is spaced apart from the bottom surface of the cover panel 120 by a predetermined distance, and is located further below the bottom surface of the cover panel 120 .

Since the vane 210 is supported by the rigid link 310 and the joint link 320 in the state of FIG. 9 (b) to form a horizontal wind, the air discharged from the outlet 102 is a vane ( 210), it is possible to suppress the vibration generated by the collision.

When the rigid link 310 is further rotated counterclockwise through the vane motor 220 in the state of FIG.

The discharge vane 200 of FIG. 9(c) may discharge discharge air in an inclined direction between vertical and horizontal. In this embodiment, this is defined as an inclined wind.

In the state of Figure 9 (c), the second rigid link shaft 312, the first rigid link shaft 311 and the second joint link shaft 341 may be arranged in a line. When the second rigid drink shaft 312, the first rigid drink shaft 311 and the second joint link shaft 341 are arranged in a line, the first joint link shaft 331, the joint shaft 349 and The second joint link shaft 341 may also be arranged in a line.

After the second rigid link shaft 312, the first rigid link shaft 311 and the second joint link shaft 341 are arranged in a line, the rigid drink 310 is operated through the vane motor 220. When further rotated counterclockwise, the first joint link 330 and the second joint link 340 through the joint link shaft 341 start to rotate relative.

In the state of Figure 9 (c), the rigid link 310 and the joint link 320 form a predetermined angle between the (B). In the present embodiment, the angle B may be formed to be greater than 0 degrees and less than or equal to 90 degrees. The angle (B) may be formed in various ways depending on the length of the rigid link and the joint link or the position of the axis of rotation.

When the rigid link 310 is further rotated counterclockwise in the state of FIG. 9(c), the state as shown in FIG. 9(d) can be formed.

When the rigid link 310 is further rotated counterclockwise in the state of FIG. 9 (c), the vane 210 is rotated clockwise.

When the state as shown in (d) of Figure 9, the discharge vane 200 may 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 intersects or is perpendicular to the ceiling or the ground, and is disposed in the vertical direction.

In this embodiment, the vertical wind is formed when the rigid link 310 is rotated to the maximum in the counterclockwise direction. In this state, the vane 210 is disposed substantially perpendicular to the ceiling or the ground.

When the state of Fig. 9 (c) is changed to the state of Fig. 9 (d), the vane 210 rotates clockwise unlike when the state of Figs. 9 (b) and 9 (c) is changed. do.

In the state (c) of FIG. 9 , since the vane 210 must be changed in a vertical direction, the vane 210 must be rotated clockwise.

In the state of Figure 9 (d), the second joint stopper 354 is supported on the rear side outer surface 353 of the first joint link body 335, and can no longer be rotated. In addition, the rigid link 310 is supported by mutual interference with the other end 234 of the boss stopper 232 , and the rigid link 310 cannot be rotated any more.

In a state in which the first joint link shaft 331, the joint shaft 349 and the second joint link shaft 341 are arranged in a line, the joint shaft 349 is further rotated counterclockwise to form a vertical wind. The state of FIG. 9 (d) is formed.

As the joint shaft 349 rotates counterclockwise, the vane 210 rotates clockwise around the second joint link shaft 341 .

In the state of FIG. 9 (d) to form a vertical wind, the second rigid drink shaft 312, the first rigid drink shaft 311 and the second joint link shaft 341 have a predetermined angle C between them. to form In this embodiment, the angle C may be formed to be greater than or equal to 90 degrees and less than 180 degrees. The in-between angle C may form an obtuse angle.

The angle D may be formed in various ways depending on the position of the second rigid drink shaft 312 , the first rigid drink shaft 311 , or the second joint link shaft 341 .

In the state of FIG. 9 (d) to form a vertical wind, the first joint link 330 and the second joint link 340 form a predetermined angle D between them. In this embodiment, the angle D may be formed to be greater than or equal to 90 degrees and less than 180 degrees. The in-between angle D may be formed as an obtuse angle.

The angle (D) may be formed in various ways according to the length of the first joint link and the second joint link or the position of the axis of rotation.

In the state of FIG. 9 (d) to form a vertical wind, the first rigid drink shaft 311 and the second joint link shaft 341 may be vertically disposed.

In the state of FIG. 9 (d) to form a vertical wind, the first rigid drink shaft 311, the second joint link shaft 341 and the first joint link shaft 331 may be arranged in a line or vertically.

In the state of FIG. 9 (d) to form a vertical wind, the rigid link 310 is in a state supported by the boss stopper 232, and the joint link 320 is in a state supported by the joint stopper 350, so the discharge It is possible to suppress the vibration generated by the air hitting the vane 210 .

In addition, when the discharge vane 200 forms a vertical wind, the rigid drink 310 is in a state supported by the boss stopper 232 , and the joint link 320 is in a state supported by the joint stopper 350 . The external force applied to the vane 210 may be distributed to the rigid drink 310 and the joint link 320 .

In the present invention, since the first joint link 330 and the second joint link 340 are rotated about the joint axis 349 to form the angle D of 180 degrees or less, the vane body 212 is There is an advantage in that the rear end 212a can be closer to the discharge port side.

The rear end 212a of the vane body 212 is raised to the height at which the motor case 105 is located, and through this, the air discharged from the outlet 102 can be more effectively guided vertically downward.

When forming a vertical wind through the rigid drink link 310 and the joint link 320, a portion of the vane 210 is in close contact with or inserted into the outlet 102 side, and through this, a larger amount of discharged air is blown into the vertical wind. can be provided as When a part of the vane 210 is not in close contact with or inserted into the outlet 102 , some air may be discharged in a direction other than the vertical wind.

In addition, it is possible to raise the first joint link shaft 311 of the rigid link 310 to a height similar to the joint shaft 349, and through this, the rear end 212a of the vane body 212 through the discharge port ( 102) can be approached to the side.

In addition, since the first joint link 330 and the second joint link 340 are rotated about the joint axis 349 , it is possible to prevent interference between the joint link 320 and the rigid link 310 . .

Although the embodiments of the present invention have been described above with reference to the accompanying drawings, the present invention is not limited to the above embodiments, but may be manufactured in various different forms, and those of ordinary skill in the art to which the present invention pertains. It will be understood by those skilled in the art that the present invention may be embodied in other specific forms without changing the technical spirit or essential features of the present invention. Therefore, it should be understood that the embodiments described above are illustrative in all respects and not restrictive.

100: case 101: intake port
102: discharge port 103: suction flow path
104: discharge flow path 110: case housing
120: cover panel 130: indoor heat exchanger
140: indoor blowing fan 200: discharge vane
210: vane 220: vane motor
230: boss 232: boss stopper
310: Rigid Drink 311: First Rigid Drink Shaft
312: second rigid drink shaft 314: link stopper
315: rigid drink body 320: joint link
330: first joint link 331: first joint link axis
340: second joint link 341: second joint link shaft
349: joint axis 350: joint stopper
352: first joint stopper 354: second joint stopper

Claims (17)

a case in which the inlet and the outlet are formed on the bottom;
a discharge vane disposed in the case and guiding a flow direction of the air discharged from the discharge port; and
It includes a vane motor for providing power to the discharge vane,
The discharge vane is
a vane disposed at the outlet;
a rigid drink having one end coupled to the vane and the other end coupled to the case; and
It is coupled to the vane and includes a joint link spaced apart from the rigid link,
The joint link is,
a first joint link coupled to the case;
a second joint link having one end coupled to the vane and the other end coupled to the first joint link; and
Containing a joint axis connecting the first joint link and the second joint link,
The vane motor provides the power to the rigid drink and the first joint link,
The rigid link includes a first surface facing the vane,
The second joint link includes a second surface facing the vane,
The first surface of the rigid link is disposed closer to the vane than the second surface of the second joint link. According to claim 1,
When the vanes are horizontally arranged, the vanes are positioned below the outlet. According to claim 1,
When the vanes are horizontally arranged, the vanes are spaced apart from the bottom surface of the case by a predetermined distance, and are positioned below the bottom surface of the case. According to claim 1,
When the vanes are horizontally arranged, the first joint link and the second joint link are arranged in a line. According to claim 1,
When the vane is disposed in the vertical direction with respect to the ceiling or the ground, a part of the vane is located inside the outlet. According to claim 1,
When the vanes are disposed in the vertical direction with respect to the ceiling or the ground, an angle between the rigid drink link and the second joint link is formed as an obtuse angle. According to claim 1,
When the vanes are disposed in the vertical direction with respect to the ceiling or the ground, an angle between the first joint link and the second joint link is formed as an obtuse angle. According to claim 1,
The case includes a boss protruding from the case in a direction toward the vane,
and the boss includes a boss stopper protruding from the boss in a direction toward the vane. 9. The method of claim 8,
The boss stopper is an indoor unit of the air conditioner overlapping at least a portion of the rigid drink in a rotational direction of the rigid drink. According to claim 1,
It is disposed in the case, further comprising a boss stopper for limiting the rotation angle of the rigid drink,
The boss stopper includes one end limiting the rotation angle of the rigid drink when the rigid drink is rotated clockwise;
and the other end limiting the rotation angle of the rigid drink when the rigid link is rotated counterclockwise. 11. The method of claim 10,
A first rigid drink shaft is formed at the one end of the rigid drink,
A second rigid drink shaft is formed at the other end of the rigid drink,
It is disposed in the case, further comprising a boss to which the second rigid link shaft is rotatably coupled,
The boss is formed to protrude toward the vane,
The boss stopper is an indoor unit of the air conditioner formed on the boss. 12. The method of claim 11,
The second rigid drink shaft is disposed through the boss, and the vane motor is connected to the second rigid drink shaft disposed through the boss to provide a driving force. According to claim 1,
The indoor unit of the air conditioner further comprising a joint stopper disposed on at least one of the first joint link and the second joint link, and limiting the relative rotation angle when the joint is rotated relative to the joint axis. 14. The method of claim 13,
The joint stopper,
It is disposed on any one of the first joint link or the second joint link, and when the second joint link is rotated counterclockwise with respect to the joint axis, it is supported on the other one and is no longer rotated counterclockwise. a first joint stopper limiting;
It is disposed on at least one of the first joint link or the second joint link, and when the second joint link is rotated in the clockwise direction with respect to the joint axis, it is supported on the other one to limit further rotation in the clockwise direction. An indoor unit of an air conditioner including a second joint stopper. 15. The method of claim 14,
When the vane is horizontally disposed, the first joint stopper disposed on any one of the first joint link or the second joint link is supported on the other one of the first joint link or the second joint link, and the second joint link 2 The indoor unit of the air conditioner restricts further rotation of the joint link in the counterclockwise direction with respect to the first joint link. 15. The method of claim 14,
When the vane is disposed in the vertical direction with respect to the ceiling or the ground, the second joint stopper disposed on any one of the first joint link or the second joint link is the other one of the first joint link or the second joint link An indoor unit of an air conditioner supported on the , and limiting further rotation of the second joint link in a clockwise direction with respect to the first joint link. According to claim 1,
The first joint link includes a first joint link body having one end rotatably coupled to the case and the other end rotatably coupled to the second joint link,
The second joint link includes a second joint link body having one end rotatably coupled to the vane, and the other end rotatably coupled to the first joint link body,
The length of the second joint link body is formed longer than the length of the first joint link body indoor unit of the air conditioner.

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