KR20210129880A - Smart wall - Google Patents

Abstract

The present invention comprises: a case arranged between a first space and a second space; an indoor fan arranged inside the case and pressurizing and flowing air inside the case; a discharge duct having a duct space formed therein, having a duct inhalation hole formed to receive air from the indoor fan, and having a first duct discharge hole for supplying the air of the duct space to the first space and a second duct discharge hole for supplying the same to the second space; a partition arranged inside the discharge duct and partitioning the duct space into a first duct space and a second duct space; a separator for opening and closing part of the dust inhalation hole; and an actuator for providing a driving force to the separator. The present invention can adjust the ratio of air flowing into the first space and the second space or can block air flowing into either through a first separator or a second separator arranged inside the discharge duct.

Description

Smart wall {Smart wall}

The present invention relates to a wall installed in a building, and more particularly, to a smart wall capable of providing air conditioning to the interior of a building.

The walls of the building are installed to demarcate the space.

The wall may be integrally constructed together when a building is constructed in the form of a load-bearing wall, or may be installed to partition a space after construction of the building.

In this way, most of the walls installed together during the construction of a building are load-bearing walls, have a concrete structure, and are called wet walls. The wet wall includes, for example, a concrete structure using cement steel frames and a structure in which walls are built by stacking bricks.

On the other hand, a wall having a structure that can be manufactured without using water is called a dry wall, and a structure using steel or light steel frame is an example.

Korean Patent Registration No. 10-1335243 describes a structure capable of installing drywall.

However, a wall including a conventional wet wall or dry wall partitions an indoor space and provides sound insulation or heat insulation, but there is a problem in that it cannot provide information related to the lives of residents or air conditioning.

Korean Patent Registration No. 10-0764264 describes a stand-type air conditioner that can be installed by being inserted into a wall.

However, even if the conventional air conditioner is installed by being inserted into the wall of the room, it is possible to provide air-conditioned air to only one space of the room.

In addition, in order to install the display indoors, there is a problem in that it must be installed on a wall or standing on the floor.

That is, when a display or an air conditioner is separately installed as in the prior art, since it occupies an indoor space, there is also a problem in that the utilization of the indoor space is reduced.

Korean Patent Registration No. 10-1335243 Korean Patent Registration No. 10-0764264

An object of the present invention is to provide a smart wall partitioning a first space and a second space, and respectively air-condition the first space and the second space through an air conditioner disposed inside the smart wall.

An object of the present invention is to provide air conditioning to two spaces partitioned by a wall through an air conditioner installed on a wall in a room.

An object of the present invention is to provide a smart wall that can control the ratio of air flowing into the first space and the second space.

An object of the present invention is to provide a smart wall that can selectively provide air-conditioned air to a first space or a second space.

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 can adjust the ratio of air flowing into the first space and the second space through a separator that opens and closes the first duct inlet or the second duct inlet.

According to the present invention, air conditioned through a separator that opens and closes the first duct inlet or the second duct inlet can be selectively provided to the first space or the second space.

The present invention, a case disposed between the first space and the second space; an indoor fan disposed inside the case and pressurizing the air inside the case to flow; A duct space is formed therein, a duct inlet for receiving air from the indoor fan is formed, and a first duct outlet for supplying air from the duct space to the first space and a second duct for supplying the second space a discharge duct formed with a discharge port; a partition disposed inside the discharge duct and dividing the duct space into a first duct space and a second duct space; a separator for opening and closing a part of the duct inlet; and an actuator that provides a driving force to the separator.

Based on the partition, the first duct outlet may be disposed on one side, and the second duct outlet may be disposed on the other side.

The first duct outlet may be disposed on one side of the duct inlet, and a second duct outlet may be disposed on one side of the duct inlet.

The partition may be disposed above the duct inlet.

The partition may be disposed between one edge and the other edge of the duct inlet.

It may further include a; it is disposed in the partition, and is rotatably assembled with the discharge duct. The rotation shaft may be located above the partition.

A lower end of the partition may be disposed above the duct inlet.

The separator may further include a rotating shaft disposed on the separator and rotatably assembled with the discharge duct.

The separator rotation shaft may be disposed below the partition.

The separator rotation shaft may be disposed at the duct inlet.

The actuator may be disposed outside the discharge duct, and the separator rotation shaft may be disposed to pass through the discharge duct.

A rotation axis of the partition and a rotation axis of the separator may be parallel to each other.

An area of the separator may be 1/2 or more of the duct inlet.

Lengths W1 of one side and the other side of the separator may be shorter than vertical lengths of the partition.

A length W2 between the lower end of the partition and the rotation shaft may be longer than a length W1 of the separator in the direction of one side and the other side.

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

The smart wall according to the present invention has one or more of the following effects.

First, the present invention has an advantage in that the flow rate of air flowing into the first space and the second space can be adjusted by rotating the separator disposed at the duct inlet of the discharge duct.

Second, in the present invention, the first duct inlet or the second duct inlet can be closed by rotating the separator disposed at the duct inlet of the discharge duct, and air flowing into the first space or the second space can be blocked through this.

Third, the present invention has the advantage that the separator can be moved to the first duct space or the second duct space by pushing the partition, and can close the first duct inlet or the second duct inlet.

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

1 is a perspective view of a building showing a smart wall according to a first embodiment of the present invention.
Figure 2 is an installation perspective view of the smart wall shown in Figure 1.
Figure 3 is an operation example of the smart wall shown in Figure 1.
4 is a schematic front view of the smart wall shown in FIG.
5 is a perspective view showing the inside of the smart wall according to the first embodiment of the present invention.
6 is a perspective view of the air conditioner shown in FIG. 5 .
FIG. 7 is a side cross-sectional view of FIG. 6 .
FIG. 8 is an exploded perspective view of FIG. 6 .
9 is an exploded perspective view of the filter shown in FIG. 8 .
FIG. 10 is a perspective view of the fan housing shown in FIG. 8 .
11 is a perspective view of the discharge duct shown in FIG.
12 is an exploded perspective view of the discharge duct, the damper, and the fan housing shown in FIG. 8 .
13 is a perspective view of the damper shown in FIG. 12 .
14 is a perspective view of the separator shown in FIG. 12 .
15 is a front view of the damper shown in FIG. 12 before operation.
FIG. 16 is an exemplary operation view of the damper shown in FIG. 12 .

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 art 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.

1 is a perspective view of a building showing a smart wall according to a first embodiment of the present invention. Figure 2 is an installation perspective view of the smart wall shown in Figure 1. Figure 3 is an operation example of the smart wall shown in Figure 1. 4 is a schematic front view of the smart wall shown in FIG.

Referring to FIG. 1 , the smart wall 100 is a non-bearing wall, and has a structure that can be removed or reinstalled.

The smart wall 100 according to the present embodiment is disposed inside the building, and may be disposed between the first space 101 and the second space 102 of the building. For example, the first space 101 may be a living room, and the second space 102 may be a room.

One side of the smart wall 100 is arranged to face the first space 101 , and the other side is arranged to face the second space 102 . The smart wall 100 may partition a first space 101 and a second space 102 .

In this embodiment, the door 103 is disposed on the side of the smart wall 100 . The smart wall 100 divides a first space 101 and a second space 102 together with the door 103 .

2 to 4 , the smart wall 100 may include a display 110 that provides information through images to the user. The display 110 is disposed to face the first space 101 . The smart wall 100 may further include a display cover 112 selectively covering the display 110 .

The display cover 112 may move in a vertical direction, and may cover a part or all of the display 110 . When the display 110 is fully exposed, a movie or broadcast can be viewed. When the display 110 is partially exposed, daily information (eg, weather, temperature, news headlines, etc.) may be provided to the user.

The display cover 112 may be hidden inside the smart wall 100 and may be located in front of the display 110 only when necessary.

In the present embodiment, the display cover 112 is disposed on the upper portion of the display 100 , and covers the entire display from the top of the display 100 while moving downward.

And the smart wall 100 is a speaker 114 is disposed toward the first space (101). The speaker 114 is disposed on the side of the display 100 . In this embodiment, the speaker 114 is disposed on the left and right sides of the display 100, respectively.

Meanwhile, referring to FIG. 3 or FIG. 4 , the smart wall 100 may have an air conditioner 200 for air conditioning therein. The air conditioner 200 may be disposed above or below the display 100 , and in the present embodiment, it is disposed below the display 100 .

5 is a perspective view showing the inside of the smart wall according to the first embodiment of the present invention.

Referring to FIG. 5 , the smart wall 100 includes a frame assembly 300 .

The frame assembly 300 may be assembled to a wall or ceiling of a building and support the wall or ceiling. The frame assembly 300 is disposed between the first space 101 and the second space 102 . The frame assembly 300 provides an installation space for the display 100 and the air conditioner 200 .

The frame assembly 300 includes an outer frame and an inner frame. The outer frame provides an exoskeleton of the smart wall 100 , and the inner frame provides an endoskeleton of the smart wall 100 .

The frame assembly 300 includes a lower frame 310 installed on the floor 121 of a building, an upper frame 320 spaced apart from the lower frame 310 and disposed on an upper side, and the lower frame 310 . and a first side frame 330 connected to one side (left side in this embodiment) of the upper frame 320 and the other side (right side in this embodiment) of the lower frame 310 and the upper frame 320 . and a second side frame 340 that is

The lower frame 310 , the upper frame 320 , the first side frame 330 , and the lower frame 310 are the outer frames. The lower frame 310, the upper frame 320, the first side frame 330, and the lower frame 310 are preferably formed of a steel material.

An installation space 390 is formed inside the frame assembly 300 . The installation space 390 may be divided into a plurality of inner frames.

The lower frame 310 is installed on the floor 121 .

The first side frame 330 is assembled to one side of the lower frame 310 and is installed perpendicularly to the lower frame 310 . The second side frame 340 is assembled to the other side of the lower frame 310 and is installed perpendicularly to the lower frame 310 .

In this embodiment, the first side frame 330 and the lower frame 310 are fastened and assembled through a fastening member, and the second side frame 340 and the lower frame 310 are also fastened and assembled through a fastening member. The first side frame 330 and the second side frame 340 are supported by the lower frame 310 .

One side of the upper frame 320 is supported by the first side frame 330 , and the other side is supported by the second side frame 340 . In this embodiment, the first side frame 330 and the upper frame 320 are fastened and assembled through a fastening member, and the second side frame 340 and the upper frame 320 are also fastened and assembled through a fastening member.

The upper frame 320 may be directly fixed to the ceiling wall 122 of the building. However, since the floor heights of the buildings are different, a gap member 350 connecting the upper frame 320 and the ceiling wall 122 is further disposed in the present embodiment.

The lower end of the gap member 350 is fastened to the upper frame 32 , and the upper end is fixed to the ceiling wall 122 .

By making the heights of the first side frame 330 and the second side frame 340 uniformly, the height of the installation space 390 can be standardized and manufactured.

When the height of the installation space 310 is different for each building in which it is installed, it is difficult to standardize the size of the display 110 or the air conditioner 200 installed in the smart wall 100 .

In this embodiment, after standardizing the size of the frame assembly 300 of the frame assembly 300, the gap member 350 is installed between the frame assembly 300 and the ceiling wall 122, and through this, the frame assembly ( The gap between 300 and the ceiling wall 122 can be filled.

A lower end of the gap member 350 is coupled to the upper frame 320 , and an upper end of the gap member 350 is coupled to the ceiling wall 122 . A plurality of the gap members 350 are arranged, and in this embodiment, two are installed on one side and the other side of the upper frame 320 .

The inner frame is disposed inside the outer frame and supports the outer frame.

The inner frame includes a transverse frame 360 disposed in the installation space 390 and disposed in a horizontal direction, and a longitudinal frame 370 disposed in the installation space 390 and disposed in a vertical direction. .

The transverse frame 360 and the longitudinal frame 370 may be coupled to each other. According to the embodiment, the transverse frame 360 is coupled to at least one of the first side frame 330 or the second side frame 340, and the longitudinal frame 370 is the lower frame 310 or the upper frame ( 320) may be coupled to at least one.

A plurality of transverse frames 360 may be disposed. A plurality of longitudinal frames 370 may also be disposed.

In this embodiment, the transverse frame 360 includes a first transverse frame 361 coupled to the first side frame 330 and the second side frame 340, and the first transverse frame 361. and a second transverse frame 362 that is spaced apart from the upper side.

In this embodiment, the longitudinal frame 370 has a lower end coupled to one side (left side) of the first transverse frame 361 and a first longitudinal frame 371 having an upper end coupled to the upper frame 320 and , a lower end coupled to the other side (right side) of the first transverse frame 361, and a second longitudinal frame 372 having an upper end coupled to the upper frame 320 .

The second transverse frame 362 is disposed between the first longitudinal frame 371 and the second longitudinal frame 372 . One end of the second longitudinal frame 362 is coupled to the first longitudinal frame 371 , and the other end is coupled to the second longitudinal frame 372 .

The first longitudinal frame 371 and the first side frame 330 are spaced apart from each other by a predetermined distance to form a first side spaced space 331 . The second longitudinal frame 372 and the second side frame 340 are spaced apart from each other by a predetermined distance to form a second side separation space 341 .

Components for the operation of the display cover 112 are disposed in at least one of the first side separation space 331 and the second side separation space 341 .

The longitudinal frame 370 includes a third longitudinal frame 373 and a fourth longitudinal frame 374 connecting the first transverse frame 361 and the second transverse frame 362 to each other. include

The third longitudinal frame 373 and the fourth longitudinal frame 374 support the second transverse frame 362 . The display 110 is installed between the third longitudinal frame 373 and the fourth longitudinal frame 374 .

A first speaker installation space 394 for installing the left speaker 114 is formed between the third longitudinal frame 373 and the first longitudinal frame 371 .

A second speaker installation space 395 for installing the right speaker 114 is formed between the fourth longitudinal frame 374 and the second longitudinal frame 372 .

And the longitudinal frame 370 further includes a fifth longitudinal frame 375 and a sixth longitudinal frame 376 connecting the second transverse frame 362 and the upper frame 320 . . The fifth longitudinal frame 375 is disposed on the left, and the sixth longitudinal frame 376 is disposed on the right.

In this embodiment, the third longitudinal frame 373 and the fifth longitudinal frame 375 are vertically arranged in a line, and the fourth longitudinal frame 374 and the sixth longitudinal frame 376 are also arranged in a line. placed vertically with

The installation space 390 is divided into a plurality by the transverse frame 360 and the longitudinal frame 370 .

For convenience of description, an installation space below the first transverse frame 361 is referred to as a first installation region 391 , and between the first transverse frame 361 and the second transverse frame 362 . The installation space of the second installation area 392 is called, and the installation space between the second lateral frame 362 and the upper frame 320 is called a third installation zone 393 .

The air conditioner 200 is disposed in the first installation area 391 , and the display 110 is disposed in the second installation area 392 .

6 is a perspective view of the air conditioner shown in FIG. 5 . FIG. 7 is a side cross-sectional view of FIG. 6 . FIG. 8 is an exploded perspective view of FIG. 6 .

The air conditioner 200 is disposed in the first installation area 391 . The air conditioner 200 is disposed above the lower frame 310 and is spaced apart from the floor 121 . The air conditioner 200 sucks in air from the spaced-apart lower part, and discharges the air to the first space 101 and the second space 102 .

In this embodiment, the air conditioner 200 includes an indoor unit 210 and an outdoor unit (not shown), and the indoor unit 210 and the outdoor unit 220 are connected through a refrigerant pipe.

Therefore, the indoor unit 210 of the air conditioner 200 is disposed in the first installation area 391 . Unlike the present embodiment, the integrated air conditioner may be installed.

And in this embodiment, an air purifier 230 for filtering indoor air is installed next to the indoor unit 210 . The air purifier 230 may be operated independently of the indoor unit 210 .

The indoor unit 210 includes a case 410 installed in the frame assembly 300, a filter 420 disposed in the case 410 and filtering air sucked into the case 410; A heat exchanger 430 disposed inside the case 410 and heat-exchanging the suctioned indoor air with a refrigerant, and the heat-exchanged air disposed in the case 410 in the first space 101 and second space ( 102); 410), and includes a drain pan 450 for temporarily storing the condensed water generated in the heat exchanger 430.

The case 410 may be disposed in the first installation area 391 and mounted on the lower frame 310 . The filter 420 is disposed below the case 410 . The filter 420 is spaced apart from the bottom 121 .

To this end, at least a portion of the lower side of the case 410 is opened, and the filter 420 is disposed in the opened portion.

In this embodiment, the case 410 has an overall shape of a rectangular parallelepiped shape, a first opening surface 411 with an open lower side, a pipe installation groove 412 with a part of the side open, and an upper side It further includes an opened second opening surface 413 .

In order to be installed inside the smart wall 100, the front and back of the case 410 is formed wider than the side.

The case 410 includes a front wall 410a, left and right sidewalls 410b and 410c, and a rear wall 410d.

The first opening surface 411 is disposed at lower ends of the front wall 410a, the left and right sidewalls 410b and 410c, and the rear wall 410d. The second opening surface 413 is disposed at upper ends of the front wall 410a, the left and right sidewalls 410b and 410c, and the rear wall 410d.

In the present embodiment, the pipe installation groove 412 is disposed on the left and right sidewalls 410b and 410c.

Since the case 410 is mounted on the lower frame 310 , the middle portion of the filter 420 is supported by the lower frame 310 . Thus, the front side of the filter 420 is exposed to the first space 101 , and the rear side is exposed to the second space 102 .

9 is an exploded perspective view of the filter shown in FIG. 8 .

8 or 9 , the filter 420 covers the opening surface 411 of the case 410 , and a part of the filter 420 may be inserted into the case 410 . In this embodiment, four corners of the case 410 extend downward to surround and support the filter 420 .

The filter 420 may be inserted into the case 410 and may be disposed to be wrapped around the front wall 410a, the left and right sidewalls 410b, 410c, and the rear wall 410d.

The filter 420 is detachably assembled to the case 410 .

Since the air of the first space 101 and the second space 102 is sucked through the filter 420, the indoor unit of the smart wall according to this embodiment can provide air cleaning for the two partitioned spaces. have.

In particular, since the filter 420 is disposed close to the floor 121, it is possible to effectively suction and filter the dust settled on the floor.

The filter 420 includes a filter housing 422 and a filter member 424 disposed in the filter housing 422 .

The lower frame 310 of the frame assembly 300 is supported on the floor 121 of the building, and the lower end 422c of the filter 420 is spaced apart from the floor 121 to form a filter separation distance 421 . do.

A plurality of holes 423 are formed in the filter housing 422 at least on the surface discharged through the first opening 411 . In the present embodiment, the filter housing 422 has an overall shape of a rectangular parallelepiped shape, a plurality of holes 423 are formed on a lower side thereof, and an upper side thereof is opened.

The filter member 424 is mounted through the opened upper surface of the filter housing 422 . The filter member 424 has a structure that can be separated from the filter housing 422 . Also, the filter housing 422 and the filter member 424 may be integrally separated from the case 410 .

The indoor air passes in the order of "the first opening surface 411 -> the hole 423 -> the filter member 424", and may flow into the case 410 . Indoor air flows from the bottom to the top.

A front end 422a of the filter housing 422 is exposed in the first space 101 , and a rear end 422b of the filter housing 422 is exposed in the second space 102 . And the lower end 422c of the filter housing 422 is spaced apart from the bottom 121 to form a filter separation distance 421 .

That is, when the indoor fan 460 is operated, the indoor air of the first space 101 and the indoor air of the second space 102 may be sucked into the filter 420, and the filter 420 may The indoor air of the first space 101 and the indoor air of the second space 102 may be filtered at the same time.

The filter 420 may be drawn forward or downward while being inserted into the first opening surface 411 . The extraction direction of the filter 420 may be selected in various ways according to design.

In the present embodiment, air is sucked through the lower surface of the filter 420 . Unlike the present embodiment, air in each of the spaces 101 and 102 may be sucked through the front or rear surface of the filter 420 .

The heat exchanger 430 is disposed inside the case 410 . In this embodiment, the heat exchanger 430 is arranged in the vertical direction, one side is arranged to face the first space 101 , and the other side is arranged to face the second space 102 .

The front and rear surfaces of the heat exchanger 430 are formed wider than the side surfaces. The heat exchanger 430 is formed to have a width in a left-right direction longer than a thickness in the front-rear direction. Since the front and rear surfaces of the heat exchanger 430 are wide, a large heat exchange area can be secured in a structure having a narrow thickness in the front and rear directions.

The heat exchanger 430 and the fan 460 are disposed to face each other, thereby minimizing the flow distance of the heat-exchanged air.

In this embodiment, the heat exchanger 430 is mounted on the drain pan 450 . The heat exchanger 430 may be a fin-tube heat exchanger or a microchannel heat exchanger.

The heat exchanger 430 is disposed above the filter 420 . In addition, the drain pan 450 is disposed between the heat exchanger 430 and the filter 420 . The drain pan 450 is disposed above the filter 420 to prevent the condensed water generated in the heat exchanger 430 from falling into the filter 420 .

The heat exchanger 430 and the indoor fan 460 are disposed in the front-rear direction. One of the heat exchanger 430 and the indoor fan 460 is disposed on the side of the first space 101 , and the other one is disposed on the side of the second space 102 .

In this embodiment, the heat exchanger 430 is disposed on the side of the first space 101 rather than the indoor fan 460 .

The indoor fan 460 includes a fan 470 , a fan motor 471 , and a fan housing 480 .

In this embodiment, the fan 470 is a centrifugal fan. Unlike the present embodiment, the fan may be a turbofan.

The fan 470 sucks air in the center of the shaft and then discharges the air in the circumferential direction. The fan housing 480 guides the air discharged from the fan 470 to the discharge duct 440 . The fan motor 471 is disposed in the fan housing 480 , is connected to the fan 470 through a motor shaft 472 , and rotates the fan 470 .

The fan housing 480 is disposed inside the case 410 . The fan housing 480 is disposed to face the heat exchanger 430 .

At least a part of the fan 470 is inserted inside the fan housing 480 . The fan motor 471 is disposed between the fan 470 and the fan housing 480 . The fan motor 471 is coupled to the fan housing 480 , and is connected to the fan 470 through a motor shaft 472 .

The heat exchanger 430 is disposed in front of the fan 470 . The suction port of the fan 470 and the heat exchanger 430 face each other.

The discharge duct 440 is disposed above the fan housing 480 . The discharge duct 440 may supply air guided through the fan housing 480 to the first space 101 and the second space 102 .

10 is a perspective view of the fan housing shown in FIG. 8 .

8 or 10, the fan housing 480 includes a fan housing body 482 having an insertion space 481 formed therein so that a fan 460 can be inserted, and the fan housing body 482. and a guide body 484 for shielding the second opening surface 413 of the case 310, and a guide body 484 for discharging air from the insertion space 481 into the discharge duct ( It includes a guide flow path 486 for guiding to 440 .

In this embodiment, the overall shape of the fan housing body 482 is formed in a rectangular parallelepiped shape. The insertion space 481 is formed inside the fan housing body 482 . In order to form the insertion space 481 , a guide wall 483 is disposed inside the fan housing body 482 . The insertion space 481 is formed inside the guide wall 483 .

In this embodiment, the insertion space 481 is formed in a circular shape when viewed from the front. The insertion space 481 has an open front and a closed back. The side surface of the insertion space 481 is closed by the guide wall 483 , and the rear surface is closed by the rear wall 482d of the fan housing body 482 .

An open insertion opening surface 481a is formed on the front side of the insertion space 481 .

The fan housing body 482 includes a front wall 482a, left and right sidewalls 482b and 482c, a rear wall 482d and a bottom wall 482e. According to the embodiment, the top wall may be additionally disposed. In this embodiment, since the guide body 484 is disposed on the upper side of the fan housing body 482, the top wall is not separately disposed.

The fan motor 471 is disposed in the installation space 481 and is coupled to the guide body 482 .

The guide wall 483 connects the front wall 482a and the rear wall 482d.

An upper portion of the guide wall 483 is opened to form a guide opening 483a , and the guide opening 483a communicates with the guide passage 486 .

In this embodiment, one end and the other end of the guide wall 483 are spaced apart to form the guide opening 483a. Unlike the present embodiment, the guide opening 483a may be formed in the form of a hole penetrating the guide wall 483 .

The guide opening 483a is located below the guide body 484 . The guide opening 483a forms an inlet of the guide passage 486 .

The guide opening 483a communicates with the insertion space 481 . The guide opening 483a is disposed above the insertion space 481 , thereby minimizing the length of the guide passage 484 .

The guide body 484 is disposed below the discharge duct 440 . The guide passage 486 guides air to the discharge duct 440 through the guide body 484 .

In this embodiment, the guide body 484 is disposed above the guide wall 483 and the installation space 481 .

In this embodiment, the guide body 484 shields the entire second opening surface 413 of the case 410 . The guide body 484 closes the second opening surface 413 , thereby preventing leakage of air inside the case 410 .

This is to allow the air inside the case 410 to flow into the guide passage 486 . When air leakage occurs due to the gap between the second opening surface 413 , the pressure of the flowing air is lowered, and the indoor fan 460 must be operated at high speed to compensate for this.

The guide body 484 may be disposed inside the case 410 and be coupled to the case 410 . In this embodiment, some of the side surfaces of the guide body 484 may be disposed to be surrounded by the front wall 410a, the left and right side walls 410b and 410c and the rear wall 410d.

The guide passage 486 is disposed on the guide body 484 , and in this embodiment, the guide passage 486 passes through the guide body 484 . Unlike the present embodiment, a separate duct structure may be installed on the side of the guide body 484 to arrange the guide passage 486 .

In this embodiment, the guide passage 486 is formed in the form of a duct passing through the guide body 484 . To this end, a front guide 486a, left and right side guides 486b, 486c, and a rear guide 486d that form the guide passage 486 are disposed inside the guide body 484 .

The suction side and the discharge side of the guide flow path 486 are opened. A suction side of the guide flow path 486 is referred to as a guide suction port 487 , and a discharge side of the guide flow path 486 is referred to as a guide discharge port 489 .

The guide suction port 487 is disposed below the guide passage 486 and communicates with the installation space 481 . The guide suction port 487 communicates with the guide opening 483a of the guide wall 483 . In this embodiment, the guide inlet 487 is disposed above the guide opening 483a.

In addition, the guide discharge port 489 is disposed above the guide passage 486 and communicates with the discharge duct 440 . In this embodiment, the guide outlet 489 is disposed below the discharge duct 440 , and the guide suction port 487 is disposed below the guide outlet 489 .

In this embodiment, the area of the guide outlet 489 is larger than the area of the guide inlet 487 is formed. This is to easily control the amount of air supplied from the discharge duct 440 to the first space 101 and the second space 102 .

The front guide 486a may be disposed obliquely in the front-rear direction, and in this embodiment, the front guide 486a is formed by bending forward. And the rear end of the front guide 486a is arranged low, the front end is arranged high.

A front end of the front guide 486a forms a guide inlet 487 , and a rear end forms the guide outlet 489 .

The rear guide 486d may be inclined in the front-rear direction. In this embodiment, the rear guide 486d is formed by bending forward. And the rear end of the rear guide 486d is arranged low, the front end is arranged high.

The front guide 486a is disposed to be inclined than the rear guide 486d. The rear guide 486d is disposed more vertically than the front guide 486a.

The front guide 486a and the rear guide 486d move the air in the installation space 481 to the middle of the case 410 in the front-rear direction. This is because the fan housing 480 is disposed on the rear side.

Since the fan housing 480 is disposed on the rear side of the fan 470 and the heat exchanger 430 is disposed in front of the fan 470 , the fan housing 480 is structurally disposed on the rear side.

Unlike the present embodiment, when the fan housing 480 is disposed in the middle of the front-rear direction of the case 410 , the thickness of the case 410 in the front-rear direction should be increased. This increases the thickness of the smart wall 100, so there is a problem of occupying a lot of indoor space.

The guide flow path 486 as in this embodiment has the advantage of moving the conditioned air to the middle of the case 410 while minimizing the thickness of the smart wall 100 .

The left and right side guides 486b and 486c connect the front guide 486a and the rear guide 486d.

11 is a perspective view of the discharge duct shown in FIG. 12 is an exploded perspective view of the discharge duct, the damper, and the fan housing shown in FIG. 8 . 13 is a partial perspective view of the fan housing shown in FIG. 8 . 14 is a perspective view of the damper shown in FIG. 12 . 15 is a front view of the damper shown in FIG. 12 before operation. FIG. 16 is an exemplary operation view of the damper shown in FIG. 12 .

7 to 8 and 11 , the discharge duct 440 receives air from the guide passage 486 , and the supplied air is supplied to the first space 101 and the second space 102 . .

The discharge duct 440 is disposed above the guide body 484 . In the present embodiment, the discharge duct 440 is disposed above the second opening surface 413 , covers the second opening surface 413 , and seals the second opening surface 413 . The discharge duct 440 is preferably formed to be wider than the area of the second opening surface 413 .

The discharge duct 440 is closely attached to the upper surface of the guide body 484 and is supported on the upper end of the case 410 .

In this embodiment, the discharge duct 440 is formed in a rectangular parallelepiped shape.

The discharge duct 440 includes a duct body 445 having a duct space 446 formed therein, and a first duct discharge port disposed in the duct body 445 and opened toward the first space 101 ( 441), a second duct outlet 442 disposed in the duct body 445 and opened toward the second space 102, and disposed in the duct body 445, the guide passage 486 and a duct inlet 443 communicating with and receiving air.

In the present embodiment, the duct body 445 includes a duct front 445a, a first duct side 445b, a second duct side 445c, a duct rigger 445d, a duct top 445e, and a duct bottom 445f. includes

The duct body 445 is formed to have a width in the left and right direction longer than the width in the front and rear direction.

In this embodiment, the first duct side 445b is a left wall, and the second duct side 445c is a right wall.

The first duct outlet 441 is formed in the duct front 445a, and the second duct outlet 442 is formed in the duct rea 445d.

The first duct outlet 441 and the second duct outlet 442 may be formed of a plurality of holes or slits, and communicate the duct space 446 with the outside.

In particular, the first duct outlet 441 communicates with the duct space 446 and the first space 101 , and the second duct outlet 442 connects the duct space 446 and the second space 102 . communicate

The duct suction port 443 is formed in the duct bottom 445f, and communicates the duct space 446 with the guide passage 486.

The first duct outlet 441 and the second duct outlet 442 are disposed to be biased toward different sides, respectively. In this embodiment, the first duct outlet 441 is disposed to be biased toward the second duct side 445c, and the second duct outlet 442 is disposed to be biased toward the first duct side 445b.

On the other hand, the duct suction port 443 is disposed in the middle left and right of the discharge duct (440). In the case of this embodiment, when viewed from the front, one side (left) of the duct inlet 443 overlaps with the second duct outlet 442 to form a second overlap length OL2, and the The other side (right side) overlaps the first duct inlet 441 to form a first overlap length OL1.

So, the air discharged from one edge 443a of the duct inlet 443 can flow directly to the second duct discharge port 442, and the air discharged from the other edge 443b is the first duct discharge port 441. ) can be directly transferred to

By forming the first overlap length OL1 and the second overlap length OL2 to be the same, the air flow rate supplied to the first space 101 and the second space 102 may be uniformly formed.

Also, a partition 501 dividing the duct space 446 into a first duct space 446a and a second duct space 446b is disposed inside the discharge duct 440 .

The partition 501 divides the inside of the discharge duct 440 to the left and right, and defines a space communicating with the first duct discharge port 441 as the first duct space 446a, and the second duct discharge port ( A space communicating with 442 is defined as a second duct space 446b.

The partition 501 is rotatably disposed in the direction of the first duct space 446a and the second duct space 446b. In this embodiment, the partition 501 may be rotated in the left and right directions. It further includes a first rotation shaft 502 and a second rotation shaft 503 for rotatably coupling the partition 501 and the discharge duct 440 .

The first rotation shaft 502 is rotatably assembled to the duct front 445a. The second rotation shaft 503 is rotatably assembled to the ducter 445d. The first rotation shaft 502 and the second rotation shaft 503 are arranged in a line in the front-rear direction.

The partition 501 may be rotated about the first rotation shaft 502 and the second rotation shaft 503 .

In this embodiment, the partition 501 is disposed above the duct inlet 443 and the guide outlet 489 .

The lower end 504 of the partition 501 may be disposed in the direction of gravity when there is no external force. The lower end 504 of the partition 501 is disposed in the middle of the duct suction port 443 , and specifically, it is preferably disposed in the middle of one edge 443a and the other edge 443b of the duct suction hole 443 .

The duct inlet 443 may be divided based on the partition 443 . Based on the partition 501 , a side of the first duct outlet 441 is defined as a first duct inlet 447 , and a side of the second duct outlet 442 is defined as a second duct inlet 448 .

In this embodiment, the first duct inlet 447 and the first duct space 446a are disposed on the right side of the partition 501, and the second duct inlet 448 and the second duct space 446b are partitioned ( 501) is placed on the left.

The area of the first duct inlet 447 and the area of the second duct inlet 448 may vary according to the rotation of the partition 501 . For example, when the partition 501 is rotated to the left, the area of the first duct inlet 447 is larger than that of the second duct inlet 448 . Conversely, when the partition 501 is rotated to the right, the area of the second duct inlet 448 is larger than that of the first duct inlet 447 .

For rotation of the partition 501, the lower end 504 of the partition 501 is preferably spaced apart from the duct bottom 445f. When the lower end 504 is in contact with the duct bottom 445f, rotation and friction noise of the partition 501 may be generated.

In this embodiment, a damper 500 for opening and closing any one of the first duct inlet 447 or the second duct inlet 448 inside the discharge duct 440 is disposed.

11 to 14 , the damper 500 may be disposed in the discharge duct 440 or the fan housing 480 . The damper 500 may open and close the duct inlet 443 or the guide outlet 489 .

The damper 500 is disposed between the first duct outlet 441 and the second duct outlet 442 . The damper 500 may provide the air supplied from the guide passage 486 to the first duct space 446a or the second duct space 446b.

In addition, the damper 500 may adjust the flow rate ratio of the air flowing to the first duct outlet 441 or the second duct outlet 442 . In addition, the damper 500 opens and closes any one of the first duct inlet 447 or the second duct inlet 448 to control the air flowing to the first duct outlet 441 or the second duct outlet 442 . can do.

The damper 500 includes a separator 510 that opens and closes the first duct inlet 447 or the second duct inlet 448 , and an actuator 530 that provides a driving force to the separator 510 .

The separator 510 may cover the first duct inlet 447 or the second duct inlet 448 , thereby closing the first duct inlet 447 or the second duct inlet 448 . The duct suction ports 447 and 448 that are not closed by the separator 510 are opened, and air can flow therein.

The separator 510 is operated by receiving a driving force from the actuator 530 .

In the present embodiment, the separator 510 is rotated about the separator rotation shafts 511 and 512 . The separator rotation shafts 511 and 512 are rotatably coupled to the discharge duct 440 .

When classification is necessary, the first separator rotation shaft 511 is referred to as a first separator rotation shaft 511, and the second separator rotation shaft 512 is disposed in the second space side with respect to the separator 510 as a reference.

The actuator 530 is coupled to any one of the separator rotation shafts 511 and 512 . The separator rotation shafts 511 and 512 may be disposed at the same height as the duct suction port 443 .

The separator rotation shafts 511 and 512 are disposed close to the partition 501 . The separator rotation shafts 511 and 512 are disposed between one edge 443a and the other edge 443b of the duct suction port 443 . The separator rotation shafts 511 and 512 may be disposed in the duct suction port 443 .

The separator rotation shafts 511 and 512 are disposed opposite to the rotation shafts 502 and 503 with respect to the partition 501 . The separator rotation shafts 511 and 512 are disposed on the lower end 504 side of the partition 501 .

The separator rotation shafts 511 and 512 and the rotation shafts 502 and 503 are arranged in parallel. The separator rotation shafts 511 and 512 may be disposed below the rotation shafts 502 and 503 .

In the present embodiment, the separator 510 is disposed below the lower end 504 . In the present embodiment, when the separator 510 is horizontally disposed, the first duct inlet 447 or the second duct inlet 448 may be closed.

In this embodiment, the area of the separator 510 is 1/2 or more of the duct inlet 443 , and the first duct inlet 447 or the second duct inlet 448 may be closed.

In this embodiment, a direction from the first space to the second space is referred to as a front-back direction, and a direction from one side of the discharge duct 440 to the other side is referred to as a left-right direction.

The length L in the front-rear direction of the separator 510 may be the same as or slightly smaller than the length in the front-rear direction of the first duct inlet 447 or the second duct inlet 448 .

The left-right length W1 of the separator 510 is smaller than the vertical length W2 of the partition 501 . In particular, the length W1 in the left and right direction of the separator 510 is preferably formed to be smaller than the length from the rotation shafts 502 and 503 to the lower end 504 .

The separator 510 can be rotated by pushing the partition 501, and through this, the first duct inlet 447 to the second duct inlet 448 or the second duct inlet 448 is rotated. 1 may be rotated by the duct inlet 447 .

In this embodiment, the actuator 530 is a step motor is used. Unlike the present embodiment, an external force may be directly applied to the separator 510 using a hydraulic cylinder structure.

In this embodiment, the actuator 530 is disposed outside the discharge duct 440 and is coupled to the first rotation shaft 511 .

A portion of the separator 510 to which the separator rotation shafts 511 and 512 are coupled is referred to as an inner side 513 , and the opposite side thereof is referred to as an outer side 514 .

The outer side 514 of the separator 510 is rotated around the separator rotation shafts 511 and 512 . The outer side 514 may be in contact with one edge 443a or the other edge 443b of the duct suction port 443 .

In this embodiment, the separator 510 is disposed above the guide discharge port 489 and rotates inside the discharge duct 440 . That is, the separator 510 is rotated in the left and right directions above the guide outlet 489 .

Since the separator 510 rotates only inside the discharge duct 440 , the vertical thickness of the guide body 484 can be minimized, and there is an advantage of utilizing the duct space 486 .

When the separator 510 is arranged horizontally, the first duct inlet 447 or the second duct inlet 448 is closed, and when the separator 510 is arranged inclined upwardly rather than horizontally, the first duct The inlet 447 and the second duct inlet 448 are opened.

The discharge flow rate of air may be adjusted according to the inclined opening angle of the separator 510 .

For example, when the separator 510 is disposed to be inclined in a state in which it is disposed in the first duct space 446a, more air may flow into the second duct space 446b.

Conversely, when the separator 510 is inclined in a state in which it is disposed in the second duct space 446b, more air may flow into the first duct space 446a.

Unlike the present embodiment, the separator 510 may be disposed at the guide discharge port 489 . For example, the separator 510 may be disposed in the guide duct 484 and may open and close the first guide outlet 489a or the second guide outlet 489b through rotation.

In this embodiment, the separator 510 opens either the first duct inlet 447 or the second duct inlet 448 while rotating from the lower side to the upper side.

Hereinafter, the flow of air according to the operation of the indoor unit according to the present embodiment will be described.

In this embodiment, the filter 420 is supported by the lower frame 310 and spaced apart from the floor 121, and the air in the first space 101 and the second space 102 is simultaneously discharged through the filter 420. can be inhaled.

The lower frame 310 is further formed with a support portion 312 to minimize contact with the filter 420 . The filter housing 422 is supported by the support 312 .

The front side of the support part 312 communicates with the first space 101 , and the rear side of the support part 312 communicates with the second space 102 .

When the fan 470 is operated, the air in the first space 101 is sucked into the inside of the case 410 through the front side of the filter 420, and the air in the second space 102 is It is sucked into the inside of the case 410 through the rear side of the filter 420 .

The air in the first space 101 and the second space 102 is filtered while passing through the filter housing 422 and the filter member 424 .

The filtered air flows into the space between the heat exchanger 430 and the front wall 410a and exchanges heat with the heat exchanger 430 while passing through the heat exchanger.

Through the heat exchange between the heat exchanger 430 and the filtered air, it is possible to provide dehumidification, cooling, or heating to the flowing air.

The filtered air passing through the heat exchanger 430 is defined as air conditioning air.

The air conditioning air flows into the fan housing 480 after being pressurized by the fan 470 . The fan housing 480 guides the air conditioning air pressurized by the fan 470 to the guide passage 486 . The air conditioning air supplied to the guide passage 486 flows through the guide body 484 to the discharge duct 440 .

The air conditioning air flows into the duct space 446 through the duct inlet 443 .

The air flows into the discharge duct 440 while flowing from the lower side to the upper side as a whole, and the change of the flow direction of the air is minimized. When the air flow direction change angle is large, air resistance is increased and the load of the fan 470 is also increased.

In this embodiment, since the air flows from the lower side to the upper side and then is discharged in the horizontal direction, it is possible to minimize the flow direction change angle of the air. In particular, the air resistance and the load of the fan 470 can be minimized by excluding the structure in which the air is turned 180 degrees.

In this embodiment, the flow rate of air provided to the first space 101 or the second space 102 through the separator 510 may be adjusted.

In addition, any one of the first duct inlet 447 or the second duct inlet 448 may be closed through the separator 510 , and through this, either the first space 101 or the second space 102 . Only one can supply conditioning air.

15, specifically, the separator 510 may close the second duct inlet 448, and the air conditioning air supplied from the guide flow path 486 is a first duct inlet 447 and a first duct outlet ( It is discharged into the first space 101 through 441 .

Meanwhile, a process in which the separator 510 is moved from the second duct space 446b to the first duct space 446a will be described with reference to FIG. 16 .

When the separator 510 is positioned in the second duct space 446b, the actuator 530 may be operated to rotate the separator 510 clockwise.

When the horizontally arranged separator 510 is rotated beyond the vertical direction, the outside 514 is pushed to the partition 501 , and the partition 501 is pushed and rotated by the pushing force of the separator 510 .

Thereafter, when the separator 510 is further rotated, it may be moved to the first duct space 446a through the partition 501 . After the separator 510 is rotated into the first duct space 446a, the partition 501 may be vertically disposed again by its own weight.

In addition, when the outside 504 of the separator 510 supports the partition 501 , it may be maintained in an inclined state. In this case, the ratio of the air flow rate of the air conditioning air to the first duct space 446a and the second duct space 446b may be adjusted.

In the above, preferred embodiments of the present invention have been illustrated and described, but the present invention is not limited to the specific embodiments described above, and in the technical field to which the present invention pertains without departing from the gist of the present invention as claimed in the claims. Various modifications may be made by those of ordinary skill in the art, and these modifications will not be individually understood from the technical spirit or perspective of the present invention.

100: smart wall 110: display
200: air conditioner 210: indoor unit
300: frame assembly 410: case
420: filter 430: heat exchanger
440: discharge duct 450: drain pan
460: indoor fan 470: fan
480: fan housing 500: damper
510: separator 530: actuator

Claims (15)

a case disposed between the first space and the second space;
an indoor fan disposed inside the case and pressurizing the air inside the case to flow;
A duct space is formed therein, a duct inlet for receiving air from the indoor fan is formed, and a first duct outlet for supplying air from the duct space to the first space and a second duct for supplying the second space a discharge duct formed with a discharge port;
a partition disposed inside the discharge duct and dividing the duct space into a first duct space and a second duct space;
a separator for opening and closing a part of the duct inlet; and
A smart wall comprising; an actuator that provides a driving force to the separator. The method according to claim 1,
A smart wall in which the first duct outlet is disposed on one side based on the partition, and the second duct outlet is disposed on the other side. The method according to claim 1,
A smart wall in which the first duct outlet is disposed on one side of the duct inlet, and a second duct outlet is disposed on one side of the duct inlet. The method according to claim 1,
A smart wall in which the partition is disposed on the upper side of the duct inlet. The method according to claim 1,
A smart wall in which the partition is disposed between the edge of one side and the edge of the other side of the duct inlet. The method according to claim 1,
A rotation shaft disposed on the partition and rotatably assembled with the discharge duct; further comprising, the rotation shaft is located above the partition. 7. The method of claim 6,
The lower end of the partition is a smart wall disposed above the duct inlet. The method according to claim 1,
The smart wall further comprising a; a separator rotation shaft disposed on the separator and rotatably assembled with the discharge duct, wherein the actuator provides a rotational force to the separator rotation shaft. 9. The method of claim 8,
The separator rotation shaft is a smart wall disposed below the partition. 9. The method of claim 8,
The separator rotation shaft is a smart wall disposed at the duct inlet. 9. The method of claim 8,
The actuator is disposed outside the discharge duct, and the separator rotation shaft is disposed to pass through the discharge duct. 9. The method of claim 8,
A rotation shaft disposed in the partition and rotatably assembled with the discharge duct; further comprising,
A smart wall in which the axis of rotation of the partition and the axis of rotation of the separator are parallel to each other. The method according to claim 1,
The area of the separator is 1/2 or more of the duct inlet smart wall. The method according to claim 1,
The length (W1) of the one side and the other side of the separator is formed shorter than the vertical length of the partition smart wall. The method according to claim 1,
A rotation shaft disposed in the partition and rotatably assembled with the discharge duct; further comprising,
A smart wall in which a length (W2) between the lower end of the partition and a rotation axis is longer than a length (W1) in one direction and the other side of the separator.

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