KR101611197B1 - Multi-ventilating system and controlling method thereof - Google Patents

Abstract

The present invention relates to a multi-efficiency ventilation system and a control method thereof, and more particularly, to a piping system connected to rooms of a building. An air supply and exhaust unit connected to the piping system for supplying outside air to the rooms through the piping system or discharging air from the rooms to the outside; An electric damper unit provided at a pipe end of a piping system located in each room of the building, the electric damper unit controlling the amount of air supplied and discharged to and from the respective rooms; A human body detection system connected to the rooms of the building to detect presence or absence of a person in the room; A control unit for controlling the feed / discharge unit and the electric damper unit according to a detection signal of the human body detection system; And a person presence notification unit for informing the landlord's portable terminal of the presence of a person in the room of the building when the person is detected by the human body detection system. According to the present invention, it is possible not only to effectively ventilate an interior of a building but also to reduce power consumption by stopping operation when a person goes out without turning off the power supply of the ventilation system. It not only reduces the power consumption to ventilate the building but also prevents theft inside the building.

Description

[0001] MULTI-VENTILATING SYSTEM AND CONTROLLING METHOD THEREOF [0002]

The present invention relates to a multi-high efficiency ventilation system and a control method thereof.

Generally, if a person is in a room for a long period of time in a room where the interior of the building is not well ventilated from outside, it is necessary to ventilate the room because the room air can not be kept comfortable due to pollution and CO2 increase.

Opening windows to ventilate can cause not only contaminants but also internal heat losses. To solve this problem, various types of ventilation systems (also called ventilators) are installed in buildings.

Korean Unexamined Patent Publication No. 2007-0054228 (published on May 28, 2007) (hereinafter referred to as Prior Art 1) discloses a ventilator having an indoor ventilation function for 24 hours. However, since the prior art 1 ventilates the room for 24 hours regardless of whether there is a person in the room, there is a disadvantage in that a large amount of power is consumed.

Korean Unexamined Patent Publication No. 2003-0063856 (published on 2003. 07. 31.) discloses a method for measuring the concentration of carbon dioxide (CO2) in a room, And an automatic ventilation method using the same. However, the prior art 2 measures the concentration of carbon dioxide in the room regardless of whether or not there is a person in the room, so that the room is ventilated. Therefore, the ventilator operates even when the person is outdoors There is a drawback that power is increased.

An object of the present invention is not only to efficiently ventilate an interior of a building but also to reduce power consumption by stopping operation when a person goes out without turning off the power supply of the ventilation system.

Another object of the present invention is to reduce power consumption for ventilating the interior of a building and also to prevent theft of the building.

To achieve the object of the present invention, a piping system connected to the rooms of a building; An air supply and exhaust unit connected to the piping system for supplying outside air to the rooms through the piping system or discharging air from the rooms to the outside; An electric damper unit provided at a pipe end of a piping system located in each room of the building, the electric damper unit controlling the amount of air supplied and discharged to and from the respective rooms; A human body detection system connected to the rooms of the building to detect presence or absence of a person in the room; A control unit for controlling the feed / discharge unit and the electric damper unit according to a detection signal of the human body detection system; And a person presence notification unit for informing the landlord's terminal of the presence of a person in the room of the building when the person is detected by the human body detection system.

Wherein the piping system includes an air supply line connected to the rooms of the building to supply outside air to the rooms, and an exhaust line connected to the rooms of the building to discharge air from the room to the outside, And an air supply branch pipe branched from the air supply main pipe and communicating with each room of the building, wherein the exhaust line is divided into an exhaust main pipe and an exhaust main pipe branched from the exhaust main pipe, It is desirable to include pivot branches.

Preferably, the electric damper unit includes electric damper units installed at a tube end of a piping system located in each room of the building, and a connecting wire connecting the electric damper units to the control unit.

The human body detection system preferably includes human body detection sensors provided in each room of the building for sensing a person and a connection line connecting the human body detection sensors and the control unit.

It is preferable that the human body detection sensor is provided in an electric damper unit located in a room.

The connection line of the human body detection system is preferably provided along the piping system.

Further, in order to achieve the object of the present invention, Opening an electric damper of an exhaust line of an exhaust line of the piping system by opening an electric damper of an exhaust line of a piping system in a region where a person is detected when a person is detected in a room of the building; The air flow generating unit of the air supply unit and the air supply flow generating unit of the air supply unit are respectively operated to discharge the room air of the building through the exhaust line and the exhaust flow path to the outside of the building through the air supply line and the air supply flow path, Into a room; And informing a resident of the building room of the presence of a person in the room.

It is preferable that the inflow air and the exhaust air pass through the heat exchange module of the water supply and exhaust unit so that the inflow air flowing into the room of the building and the discharge air discharged out of the room of the building are exchanged with each other during the summer and winter.

In the present invention, since the air in the room where the person is present is kept clean and the room (s) of the person without building is ventilated, Power and usage costs.

In addition, when no one is present in the room (s) of the building, it is sensed that there is no person inside the building, so that the room of the building is not ventilated, so that if a person living in the building goes out without turning off the ventilation system, Thereby preventing the ventilation system from operating and reducing the power consumption of the ventilation system. In addition, when a resident of a building goes out of the building and there is no one inside the building, when a thief breaks into the building, he informs the landlord (residents) So that a theft accident can be prevented.

FIG. 1 is a plan view showing a multi-high efficiency ventilation system according to an embodiment of the present invention,
FIG. 2 is a plan sectional view showing an embodiment of a water supply and exhaust unit constituting an embodiment of a multi-high efficiency ventilation system according to the present invention,
3 is a front sectional view showing a supply and exhaust flow path control unit constituting an embodiment of the multi-high efficiency ventilation system according to the present invention,
4 is a front sectional view showing an embodiment of an electric damper constituting an embodiment of a multi-high efficiency ventilation system according to the present invention,
FIG. 5 is a perspective view explaining an embodiment of an electric damper constituting an embodiment of the multi-high efficiency ventilation system according to the present invention,
6 is a flowchart showing an embodiment of a method for controlling a multi-high efficiency ventilation system according to the present invention.

Best Mode for Carrying Out the Invention Hereinafter, embodiments of a multi-high efficiency ventilation system and a control method thereof according to the present invention will be described with reference to the accompanying drawings.

FIG. 1 is a plan view showing a multi-high efficiency ventilation system according to an embodiment of the present invention.

1, an embodiment of a multi-high efficiency ventilation system according to the present invention includes a piping system 100, a water supply and exhaust unit 200, an electric damper unit 300, a human body detection system 400, Unit 500, and a person presence notification unit 600. [

The piping system 100 is provided in the building. The piping system 100 guides the flow of air so that the air outside the building flows into each room of the building or the air of each room is discharged to the outside of the building.

In the piping system 100, for example, the piping system 100 includes a supply line 110 connected to the rooms of the building and supplied with external air to the rooms, respectively, and an exhaust line 110 connected to the rooms of the building, Line 120. < / RTI > The air supply line 110 includes an air supply main pipe 111 installed in the ceiling of the rooms of the building and a supply air distribution pipe 112 branched from the air supply main pipe 111 and communicating with each room of the building. The exhaust line 120 includes an exhaust main pipe 121 installed in the ceiling of the rooms of the building and an exhaust branch pipe 122 branched from the exhaust main pipe 121 to communicate with each room of the building.

A plurality of auxiliary branch pipes (not shown) may be connected to the supply and discharge branch pipes 112 and 122, respectively.

The air supply and exhaust unit 200 is connected to the piping system 100. The air supply and exhaust unit 200 supplies outside air to the rooms of the building through the piping system 100 or discharges air from the rooms to the outside. 2, the air supply and exhaust unit 200 includes a main body case 210, a first air supply connection pipe SP1 and a first air supply connection pipe DP1, A second air supply connection pipe SP2 and a second exhaust connection pipe DP2, a heat exchange module 220, an exhaust flow control unit 230, an air supply flow control unit 240, an exhaust flow generation unit 250, And a flow generating unit 260.

The main body case 210 has a first partition 211, a heat exchange module 220 and a second partition 212 arranged in a row in the longitudinal direction of the inside of a case of a hexahedron. The first partition 211, The interior of the case is partitioned into two passages by the module 220 and the second partition 212. One passageway is defined as an exhaust passage F1 through which the room air escapes to the outside, And is referred to as an incoming air supply passage F2. The heat exchange module 220 has a hexagonal shape (as viewed in a plan view) having a predetermined thickness and is provided with a passage through which hot air flows so that hot air passing through the exhaust passage F1 and cold air passing through the air supply passage F2 are heat- And a plurality of unit heat exchange modules formed so as to cross the passages through which the cold air flows. A first exhaust connection pipe DP1 is provided on one side of the main body case 210 to communicate with the exhaust flow path F1 and a second exhaust connection pipe DP2 is provided on one side surface of the main body case 210 so as to be positioned next to the first exhaust connection pipe DP1 And a first air supply connection pipe SP1 is provided so as to communicate with the air supply flow path F2. A second exhaust connection pipe DP2 is provided on the other side of the main body case 210 so as to communicate with the exhaust flow path F1 on the other side of the main body case 210 The second air supply connection pipe SP2 is provided on the other side surface of the main body case 210 so as to communicate with the air supply flow path F2. The first exhaust connection pipe DP1 is connected to the exhaust main pipe 121 of the exhaust line 120 of the piping system 100 and the first air supply connection pipe SP1 is connected to the air supply line 110 of the piping system 100 The main supply pipe 111 is connected to the supply main pipe 111. The second exhaust connection pipe DP2 and the second air supply connection pipe SP2 are exposed outside the building.

3, the exhaust flow control unit 230 includes a rotation shaft 231 rotatably coupled to one corner of the heat exchange module 220 and a plate valve 232 coupled to the rotation shaft 231 And an exhaust driving unit 233 mounted on the outside of the main body case 210 so as to be connected to the rotating shaft 231 to rotate the rotating shaft 231 so as to adjust the exhaust flow path F1 do. When the plate valve 232 is positioned vertically (hereinafter referred to as a first position) with respect to the inner surface of the body case 210, the indoor air flows only through the heat exchange module 220 and the plate valve 232 communicates with the heat exchange module 220 The indoor air flows through the space between the side surface of the heat exchange module 220 and the inner surface of the main body case 210 without passing through the heat exchange module 220 . When the plate valve 232 is located between the first position and the second position (hereinafter, referred to as a third position), a part of the indoor air flows through the heat exchange module 220 and the remaining part of the indoor air flows through the heat exchange module 220 And flows between the side surface and the inner surface of the body case 210.

The air supply flow control unit 240 includes a rotation shaft 241 rotatably coupled to one corner of the heat exchange module 220 as in the configuration of the exhaust flow control unit 230, A plate type valve 242 and an air supply driving unit which is mounted on the outside of the body case 210 so as to be connected to the rotation axis 241 and rotates the rotation axis 241 so as to adjust the air supply flow path F2 243). When the plate valve 242 is positioned vertically (hereinafter referred to as a first position) to the inner surface of the body case 210, outdoor air flows only through the heat exchange module 220 and the plate valve 242 is connected to the heat exchange module (Hereinafter, referred to as a second position), the outdoor air passes through the space between the side surface of the heat exchange module 220 and the inner surface of the main body case 210 without passing through the heat exchange module 220 . When the plate valve 242 is positioned between the first position and the second position (hereinafter, referred to as the third position), a part of the outdoor air flows through the heat exchange module 220 and the other part flows through the heat exchange module 220 And flows between the side surface and the inner surface of the body case 210.

The exhaust flow generating unit 250 is provided in the second exhaust connection pipe DP2 to generate an air flow. The exhaust flow generating unit 250 preferably includes an outer rotor type VDD motor (not shown) and a fan (not shown) provided in an outer rotor of the outer rotor type VDD motor. The air supply flow generation unit 260 is provided in the first air supply connection pipe SP1 to generate a flow of air. The air supply flow generation unit 260 preferably includes an outer rotor type VDD motor (not shown) and a fan (not shown) provided in the outer rotor of the outer rotor type VDD motor. When the capacity of the VDD motor of the exhaust flow generating unit 250 is larger than the capacity of the VDD motor of the air flow generating unit 260 and the fan of the exhaust flow generating unit 250 is the size of the fan of the air flow generating unit 260 . It is preferable that the filter unit 270 is mounted on the second supply pipe SP2.

The electric damper unit 300 includes electric dampers D provided at the ends of pipes (branch pipes and auxiliary branch pipes) located in respective rooms of the piping system 100, electric dampers D and control units 500 are connected to each other via a connecting wire W. When the electric damper D provided at each end of the oil supply branch pipes 112 of the air supply line 110 is closed, the air escapes into the oil supply branch pipe 112 The air damper D is opened and the air is discharged through the air supply distribution pipe 112. The flow rate of the air is determined according to the degree of opening of the electric damper D. When the electric damper D provided at each end of the branch pipes 122 is closed, the air can not escape to the branch pipe 122. When the electric damper D is opened, .

It is preferable that the electric damper D provided in the air supply line 110 and the electric damper D provided in the exhaust line 120 have the same configuration.

4 and 5, one end of the electric damper D is connected to a branch pipe 112 (or an auxiliary branch pipe), and the other end of the electric damper D is formed in a ceiling A diffuser casing (310) coupled to a rim of the through hole and having an air passage therein; A fixed base member 320 provided inside the air passage of the diffuser casing 310; A plurality of opening and closing plates 330 provided in the air passage of the diffuser casing 320 to open and close the air passage according to the rotation; A diffuser cone (340) supported by the fixed base member (320) to diffuse air flowing through the air passage and rotate the opening / closing plates (330) in accordance with the rotation; And a cone drive unit 350 provided in the fixed base member 320 and rotating the diffuser cone 340.

The diffuser casing 310 includes a tube portion 311 having an air passage F therein and an expansion portion 312 extending from one end of the tube portion 311. The tube portion 311 is connected to the branch tube 112. The fixed base member 320 includes a first base plate portion 321 extending in a fan shape on one side of the inner circumferential surface of the air passage F of the diffuser casing 310 and a second base plate portion 321 extending in the other direction of the inner circumferential surface of the air passage F of the diffuser casing 310 A second base plate portion 322 extending in a fan shape and a cylindrical portion 323 located in the air passage F and connected to the first and second base plate portions 321 and 322, respectively. It is preferable that the open / close boards 330 are two. It is preferable that the opening and closing plates 330 are sequentially rotated in accordance with the rotation of the diffuser cone 340. The first and second open / close boards 330A and 330B are connected to the air passage F (F) together with the fixed base member 320, ) Direction. One of the first open / close board 330A is positioned to be in contact with the fixed base member 320 and one of the second open / close board 330B is positioned in contact with the other of the first open / close board 330A. The first opening and closing plate 330A includes a disc portion 3 having an insertion hole H1 formed therein and a first and a second plate portions 1 each extending in a fan shape on both outer peripheral surfaces of the disc portion 3, (2). The second opening / closing plate 330B includes a disc portion 13 having an engaging hole H2 therein, and first and second plate portions 11 and 12 formed on the outer circumferential surfaces of the disc portion 13, 12). The first opening and closing plate 330A is interlocked with the second opening and closing plate 330B and the second opening and closing plate 330B is interlocked with the diffuser cone 340 to sequentially rotate the first and second opening and closing plates 330A, . In order to interlock the first and second open / close boards 330A and 330B, the first and second open / close boards 330A and 330B and the fixed base member 320 are provided with a rod-like latching protrusion A . The diffuser cone 340 includes a cone-shaped cone 341, a coupling portion 342 extending to a predetermined length at the stem portion of the cone portion 341 and coupled to the coupling hole H2 of the second opening / closing plate 330B, A supporting portion 343 extending to a length set in the engaging portion 342 and inserted into the insertion hole H1 of the first opening and closing plate 330A and a shaft coupling hole 344 formed at a depth set at the end surface of the supporting portion 343 ). The human body detection sensor 410 constituting the human body detection system 400 is mounted on the diffuser cone 340. It is preferable that the human body detection sensor 410 is provided on a lower surface of the cone portion 341 of the diffuser cone 340. The cone drive unit 350 includes a rotation motor. The rotating motor is mounted on the upper surface of the cylindrical portion 230 of the fixed base member 200 and the motor shaft 351 of the rotating motor is inserted into the cylindrical portion 323 of the fixed base member 320, And is coupled to the coupling hole 344. The cone driving unit 350 is connected to the connecting wire W.

The cone driving unit 350 rotates the second opening and closing plate 330B while the diffuser cone 340 rotates in a forward direction according to the forward rotation and the first opening and closing plate 330A is rotated by the rotation of the second opening and closing plate 330B It rotates with interlocking. As the cone drive unit 350 rotates in the reverse direction, the diffuser cone 340 rotates in the reverse direction to rotate the second opening / closing plate 330B in the reverse direction, and the second opening / closing plate 330B is rotated in the reverse direction, (330A) is interlocked and rotated in the reverse direction. When the first and second opening and closing plates 330A and 330B are rotated in the forward or reverse direction and the fixing base member 320 and the first and second opening and closing plates 330A and 330B are minimized The air passage F of the diffuser casing 310 is completely closed and the air passage F is closed with the fixed base member 320 and the first and second opening / closing plates 330A and 330B being overlapped with each other. The flow rate of the air is adjusted as the size of the flow path is determined according to the degree of overlap between the fixed base member 320 and the first and second opening / closing plates 330A and 330B.

The human body detection system 400 detects presence or absence of a person in the rooms of the building. The human body detection system 400 includes human body detection sensors 410 provided in each room of the building for sensing a person and a connection line 420 connecting the human body detection sensors 410 and the control unit 500 do. It is preferable that the human body detection sensor 410 is provided on the lower surface of the diffuser cone 340 of the electric damper D of the oil pressure branch pipe 112 located in the room. Since the human body detection sensor 410 is provided on the lower surface of the diffuser cone 340, human body detection of the human body detection sensor 410 is accurately performed and wiring of the connection line 420 is simplified. The connection line 420 is preferably provided along the supply line 110 of the piping system.

The control unit 500 controls the feed / discharge unit 200 and the electric damper unit 300 according to the detection signal of the human body detection system 400. A connection line 420 of the human body detection system 400 is connected to the control unit 500. The exhaust drive unit 233 and the air supply drive unit 243, the exhaust flow generation unit 250, the air supply flow generation unit 260 and the electric dampers D of the air supply and exhaust unit 200 are connected to the control unit Lt; / RTI >

The person presence notification unit 600 informs the landlord's portable terminal 410 of the presence of a person in the building room when the person detection system 400 detects the person. The person presence notification unit 600 includes a wireless transmitter (not shown) provided in the control unit 500 and a receiver provided in the landlord's portable terminal 410.

6 is a flowchart showing an embodiment of a method for controlling a multi-high efficiency ventilation system according to the present invention.

As shown in FIG. 6, an embodiment of a method for controlling a multi-high efficiency ventilation system according to the present invention includes a step S1 of detecting whether a person is located in a room of a building, (S2) of opening the electric damper (D) of the air supply line (110) of the piping system (100) of the pipeline system (100) and opening the electric damper (D) of the air supply line It proceeds.

After the electric damper D of the air supply line 110 and the electric damper D of the air discharge line 120 are opened and the exhaust flow generation unit 250 and the air flow generation unit 260 of the air supply and exhaust unit 200 are opened, The air in the room where the person is sensed is discharged through the exhaust line 120 and the exhaust passage F1 to the outside of the building and the outside air is discharged through the air supply line 110 and the air supply passage F2, The step S3 is carried out. At this time, the supply line electric damper D and the exhaust line electric damper D of the building room where the person is detected are opened and the supply line electric damper D and the exhaust line electric damper D) is preferably in a closed state. Since the air supply damper D and the exhaust line electric damper D of the building room where the person is detected are open, only the building room where the person is detected is ventilated.

A person is detected in the room of the building and ventilation of the room in which the person is detected is performed, and at the same time, step S4 is performed in which the occupant of the building (the landlord) is notified that there is a person in the room of the building.

In the summer and winter, the inflow air and the exhaust air pass through the heat exchange module 220 of the exhaust unit 200 so that the inflow air flowing into the room where the person is sensed and the discharge air discharged from the building are exchanged with each other .

Hereinafter, the operation and effects of the multi-high efficiency ventilation system and the control method thereof according to the present invention will be described.

First, when no person is detected for a predetermined time in the room of the building in the human body detection system 400, the electric damper D of the electric damper unit 300 is closed and the air flow generation unit 260 of the air supply and exhaust unit 200 And the exhaust flow generating unit 250 are not operated. In other words, do not ventilate the room air because there is no person in the room of the building.

When the human body detection system 400 detects that a person is located in the room of the building, only the air of the room where the person is sensed is ventilated. The operation of ventilating the air in the room where the person is detected is performed by opening the electric damper D of the air supply line 120 of the room where the person is located and the electric damper D of the air supply line 110, The electric damper D of the line 120 and the electric damper D of the exhaust line 110 are closed. The exhaust flow generation unit 250 and the air flow generation unit 260 of the air supply and exhaust unit 200 are respectively operated to discharge the room air in the room where the person is sensed to the outside, And the room is ventilated by the inflow (supply). Such an operation is performed under the control of the control unit 500.

More specifically, the operation of ventilating the sensed room is performed by operating the exhaust driving unit 233 and the air supply driving unit 243 respectively to place the plate valves 232 and 242 in the third position, The flow generation unit 250 and the air supply flow generation unit 260 are operated respectively.

(Exhausting force) is generated by the operation of the exhaust flow generating unit 250 so that the air in the room where the person is located passes through the exhaust line 110 of the piping system 100 and the first exhaust connection pipe DP1 A part of the room air flowing into the exhaust passage F1 of the main body case 210 and flowing into the exhaust passage F1 of the main body case 210 passes through the second exhaust connection pipe DP2 via the heat exchange module 220 The rest of the room air flowing into the exhaust flow path F1 of the main body case 210 flows between the side surface of the heat exchange module 220 and the inner surface of the main body case 210, (DP2). The flow of air is generated by the operation of the air flow generating unit 260 so that outdoor air outside the building flows into the air supply passage F2 of the main body case 210 through the second air supply connection pipe SP2 . A part of the outdoor air flowing into the air supply passage F2 of the main body case 210 flows into the air supply line 120 of the piping system 100 through the first air supply connection pipe SP1 via the heat exchange module 220 The outdoor air flowing into the air supply line 120 is supplied (supplied) to the room where the person is located through the air supply line 120. When the outdoor air passes through the heat exchange module 220, heat exchange with the indoor air is performed, and the outdoor air is supplied to the room of the building in a heated state. In addition, the indoor air transfers heat to the outside air in the heat exchange module 220, and is discharged out of the building in a cooled state. This will purify the indoor air of the building while minimizing the heat loss of the room of the building.

On the other hand, the position of the plate-shaped valve 232 on the exhaust flow path and the position of the plate-shaped valve 242 on the air supply flow path can be set according to the conditions of the outside air outside the building. That is, in the winter or summer, the plate-shaped valves 232 and 242 are located at the first and third positions so that the inflow air flowing into the room and the discharged air discharged out of the building are heat exchanged with each other.

In addition, when it is detected that a person is located in the room of the building in the human body detection system 400, only the air of the room where the person is sensed is ventilated by the control unit 500, and at the same time, The mobile terminal 610 of the resident (landlord) who is the master informs that there is a person in the room of the building.

In the present invention, the air in a room where a person is present is kept clean and the room (s) of a building without a person is not ventilated. Therefore, .

In addition, when no one is present in the room (s) of the building, it is sensed that there is no person inside the building, so that the room of the building is not ventilated, so that if a person living in the building goes out without turning off the ventilation system, Thereby preventing the ventilation system from operating and reducing the power consumption of the ventilation system. In addition, if the occupant of a building goes out of the building and there is no one inside the building, if a thief breaks inside the building, he informs the landlord that the person is inside the building. So that theft can be prevented.

100; A piping system 200; Class, exhaust unit
300; An electric damper unit 400; Human body detection system
500; A control unit 600; Human presence notification unit

Claims (8)

A piping system connected to the rooms of the building;
An air supply and exhaust unit connected to the piping system for supplying outside air to the rooms through the piping system or discharging air from the rooms to the outside;
An electric damper unit provided at a pipe end of a piping system located in each room of the building, the electric damper unit controlling the amount of air supplied and discharged to and from the respective rooms;
A human body detection system for detecting presence or absence of a person in the rooms of the building;
A control unit for controlling the feed / discharge unit and the electric damper unit according to a detection signal of the human body detection system; And
And a person existence notifying unit for notifying a landlord's portable terminal of the presence of a person in a room of the building when the person is detected by the human body detecting system ,
Wherein the electric damper unit includes electric damper units installed at a tube end of a piping system located in each room of the building and a connecting wire connecting the electric damper units to the control unit,
Wherein the electric damper includes a diffuser casing having one end connected to a pipe end of the piping system and the other end connected to a rim of a through hole formed in a ceiling and having an air passage therein; A fixed base member provided inside the air passage of the diffuser casing; A plurality of open / close plates provided inside the air passage of the diffuser casing for opening / closing the air passage according to rotation; A diffuser cone supported by the stationary base member and diffusing air flowing through the air passage, the diffuser cone including a conical cone portion for rotating the opening and closing plates along with rotation; And a cone driving unit provided on the fixed base member and rotating the diffuser cone,
Wherein the human body detection system includes human body detection sensors provided in respective rooms of a building for sensing a person and a connection line for connecting the human body detection sensors and the control unit,
Wherein the human body detection sensor is mounted on a bottom surface of a cone of a diffuser cone of the electric damper. The air conditioner according to claim 1, wherein the piping system includes an air supply line connected to the rooms of the building and supplied with external air into the rooms, and an exhaust line connected to the rooms of the building, The line includes an air supply main pipe and air supply and distribution pipes branched from the air supply main pipe and communicating with each room of the building. The air supply line is divided into an exhaust main pipe and an exhaust main pipe, A multi-high efficiency ventilation system comprising vented ducts communicating with each room. delete delete delete delete delete delete

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