KR101365949B1 - Ventilating system for controlling smoke in fire situation and method thereof - Google Patents

Abstract

The present invention relates to a flue gas regeneration fire retardant ventilation system and a control method thereof, the present invention comprises a piping system connected to the rooms of the building; A detection system connected to the rooms of the building and detecting flame and smoke; A supply / exhaust unit connected to the piping system and configured to supply external air to the rooms or discharge the air of the rooms to the outside through the piping system; An electric damper unit provided at a pipe end of a piping system located in each room of the building, the electric damper unit adjusting a quantity of exhaust gas flowing into and out of each room; A control unit for controlling the supply / exhaust unit and the electric damper unit according to the detection signal of the detection system, and releasing the lock of the front door of the building; And an alarm unit for giving an alarm to the building management room according to the signal of the detection system. According to the present invention, the heat loss of the room is minimized when the room is ventilated, and the smoke is quickly removed in the event of a fire in the building.

Description

FUTILATING SYSTEM FOR CONTROLLING SMOKE IN FIRE SITUATION AND METHOD THEREOF

The present invention relates to a flue gas regeneration fire retardant ventilation system and a control method thereof.

In general, if the indoors of a building is not well ventilated with the outside, if a person is active for a long time indoors, the indoor air cannot be kept comfortable due to pollution of the indoor air and increased CO2.

Opening the windows and venting not only introduce contaminants but also cause internal heat loss, and the devices that solve these problems are electrothermal and sensible heat exchangers.

Such a ventilation device is required to minimize the escape of the heat of the interior when the indoor air is discharged to the outside and the outdoor air is filtered and introduced into the interior. In addition, the heat transfer and sensible heat exchanger is equipped with a function to secure a time for people in the building to exit the building by quickly exhausting the smoke to the outside in the early direction in the event of fire in the building.

Particularly, when a person living with inconvenient behavior dwells inside the building, the smoke is discharged quickly in the induced direction at the time of fire and at the same time, the front door is opened and closed so that the assistant can move out of the building. Time can be saved to reduce casualties.

It is an object of the present invention to minimize the heat loss of the room when the interior of the building to ventilate, and to provide a flue gas and re-enactment fire ventilation system and control method for quickly removing the smoke in the induced direction in the event of a fire in the building. .

In order to achieve the object of the present invention, a piping system connected to the rooms of the building; A detection system connected to the rooms of the building and detecting flame and smoke; A supply / exhaust unit connected to the piping system and configured to supply external air to the rooms or discharge the air of the rooms to the outside through the piping system; An electric damper unit provided at a pipe end of a piping system located in each room of the building, the electric damper unit adjusting a quantity of exhaust gas flowing into and out of each room; A control unit for controlling the supply / exhaust unit and the electric damper unit according to the detection signal of the detection system, and releasing the lock of the front door of the building; And an alarm unit configured to provide an alarm to the building management room according to a signal of the detection system.

The piping system includes an air supply line connected to the rooms of the building and supplied with outside air to the rooms, and an exhaust line connected to the rooms of the building, and the air of the room is discharged to the outside. And an air supply branch pipe branched to the air supply main pipe and connected to each room of the building, wherein the exhaust line is branched to the air main pipe and the air main pipe to communicate with each room of the building. It is desirable to include mood tubes.

The piping system includes an air supply line connected to the rooms of the building and supplied with outside air to the rooms, and an exhaust line connected to the rooms of the building, and the air of the room is discharged to the outside. And air supply branch pipes branched according to the number of rooms of the building, and a plurality of air supply auxiliary pipe pipes connected to the air supply branch pipe to communicate with the room of the building. And an exhaust branch pipe branched according to the number of rooms of the building, and a plurality of exhaust auxiliary branch pipes connected to the exhaust branch pipe to communicate with the room of the building. Preferably, the number is larger than the number of the air supply auxiliary branch pipes.

Preferably, the electric damper unit includes an electric damper installed at a pipe end of a pipe system located in each room of the building, and a connection wire connecting the electric dampers to the control unit.

The detection system preferably includes sensors provided in each room of the building to detect flame and smoke, and a connection line connecting the sensors and the control unit.

The supply and exhaust unit includes a main body case having an exhaust passage and an air supply passage; A first air supply connection pipe and a first exhaust connection pipe which are provided at one side of the main body case and are in communication with the seal and the internal and external air flow paths, and are connected to the piping system; A second air supply connection pipe and a second exhaust connection pipe provided on the other side of the main body case so as to communicate with the indoor and outdoor air flow paths, respectively; A heat exchange module provided at a boundary between the exhaust passage and the air supply passage so as to share the indoor and outdoor air passages, and exchanging hot air through the exhaust passage and cold air through the supply passage; An exhaust passage adjusting unit provided in the exhaust passage to adjust a flow of air flowing in the exhaust passage; An air supply passage adjusting unit provided in the air supply passage and controlling the flow of air flowing in the air supply passage; An exhaust flow generating unit provided in the second exhaust connection pipe to generate an air flow; It is preferable to include an air supply flow generating unit provided in the first air supply connection pipe for generating a flow of air.

The supply and exhaust flow generating unit preferably includes a fan provided in the outer rotor type BLD motor and the outer rotor of the outer rotor type BLD motor.

In addition, to achieve the object of the present invention, the step of detecting smoke or flame in the room; Closing the electric damper of the air supply line of the piping system in the smoke or flame detection zone and opening only the electric damper of the exhaust line of the piping system in the smoke or flame detection zone; Blocking the flow path of the heat exchange module of the exhaust flow path and opening the exhaust flow path; Operating the exhaust flow generating unit to discharge indoor air out of the building through the exhaust line and the exhaust passage; Unlocking the front door of the building; And a sounding alarm in the guard room is provided.

The present invention minimizes the heat loss in the room since the indoor air and the outdoor air are exchanged with each other in the heat exchange module when the indoor air of the building is purified in a normal state and the outdoor air introduced into the room is heated. This not only reduces the heating costs of the building, but also saves energy.

The present invention is provided with an electric damper at each end of the exhaust line and the air supply line of the piping system only open the electric damper of the exhaust line of the room where the fire occurred when the fire occurs and the other electric dampers to exhaust the smoke in a closed state all the fire The smoke of the generated room is quickly exhausted. In the event of a fire, the exhaust path of the main body case blocks the flow path of the heat exchange module and exhausts the smoke through the inner surface of the main body case and the side of the heat exchange module, so the smoke is quickly exhausted to the outside of the building.

As a result, the smoke of a fired room is quickly exhausted out of the building, so that people in the building as well as those in the fired room can exit the room with minimal exposure to smoke. You will have time.

The present invention releases the locked state of the front door when a fire occurs and gives an alarm signal to the guard room so that the guards or firefighters can quickly enter the interior of the building to rescue people who are inconvenient in movement.

1 is a plan view showing that an embodiment of the exhaust and re-enactment fire fighting ventilation system according to the present invention is provided in a building,
Figure 2 is a plan view showing another embodiment of the exhaust line and the air supply line constituting the exhaust and regeneration fire fighting ventilation system according to the present invention,
Figure 3 is a front cross-sectional view showing an embodiment of the electric damper constituting the exhaust and regeneration fire fighting ventilation system according to the present invention,
Figure 4 is a cross-sectional view showing an embodiment of the supply, exhaust unit constituting the exhaust and regeneration fire fighting ventilation system according to the present invention,
Figure 5 is a front sectional view showing a supply, exhaust flow path control unit constituting the exhaust and regeneration fire fighting ventilation system according to the present invention,
Figure 6 is a flow chart illustrating an embodiment of a control method of the exhaust and re-enactment fire fighting ventilation system according to the present invention.

Hereinafter, with reference to the accompanying drawings, an embodiment of the flue gas and reenactment fire fighting ventilation system and the control method according to the present invention will be described.

1 is a plan view showing that an embodiment of the exhaust and re-enactment fire fighting ventilation system according to the present invention is provided in a building.

As shown in Figure 1, one embodiment of the exhaust and re-enactment fire ventilation system according to the present invention is a piping system 100, detection system 200, supply, exhaust unit 300, electric damper unit, control unit ( 400), an alarm unit 500 is included.

The piping system 100 is provided in the building. The piping system 100 communicates each room provided in the building with the outside of the building to guide the flow of air so that the air outside the building is introduced into each room of the building or the air of each room is discharged out of the building.

The plumbing system 100 includes an air supply line 110 connected to the rooms of the building to supply external air to the rooms, and an exhaust line 120 connected to the rooms of the building to discharge the air of the room to the outside. do. The air supply line 110 is supplied to the air supply main pipe 111 installed in the ceiling of the rooms of the building and the air supply branch pipes 112 branched to each of the air supply main pipe 111 to communicate with each room of the building. Include. The exhaust line 120 is an exhaust main pipe 121 is installed in the ceiling of the rooms of the building and the exhaust branch pipes 122 branched to each of the exhaust main pipe 121 to communicate with each room of the building. Include.

At each end of the air supply branch pipe 112 of the air supply line 110 is provided with an electric damper (D) for adjusting the flow rate of the air flowing air to the air supply branch pipe (112). When the electric damper (D) is closed, the air does not escape to the air supply branch pipe 112, and when the electric damper (D) is opened, air is drawn out through the air supply branch pipe (112). In addition, the flow rate of air is determined according to the opening degree of the electric damper D.

As another embodiment of the air supply line 110 and the exhaust line 120, as shown in Figure 2, another embodiment of the air supply line 110 is the air supply branch pipe 112 to the air supply main pipe 111 ) Is connected, and a plurality of air supply auxiliary branch pipes 113 are connected to the air supply branch pipe 112, and the electric power damper D is provided at each of the air supply auxiliary branch pipes 113. The flow rate of air is determined according to the opening degree of the electric damper (D). According to another embodiment of the exhaust branch pipe 120, an exhaust branch pipe 122 is connected to the exhaust main pipe 121, and a plurality of exhaust auxiliary branch pipes 123 are connected to the exhaust branch pipe 122. The exhaust auxiliary branch pipes 123 are provided with electric dampers D, respectively. The flow rate of air is determined according to the opening degree of the electric damper (D).

It is preferable that the number of the exhaust auxiliary branch pipes 123 is larger than the number of the air supply auxiliary branch pipes 113. The electric damper D provided in the air supply line 110 and the electric damper D provided in the exhaust line 120 preferably have the same configuration.

As an example of the electric damper (D), as shown in Figure 3, the electric damper (D) is connected to the branch pipe (or auxiliary branch pipe) one side and the other end of the through hole formed in the ceiling An outer casing 130 to be coupled, a diffuser tube 140 coupled to the inside of the outer casing 130, a fixing member 150 coupled to the inside of the diffuser tube 140, and the diffuser tube 140. ) Is located inside the diffuser cone 160 to open and close the diffuser tube 140, the rotary motor 170 coupled to the diffuser cone 160, and connected to the motor shaft of the rotary motor 170 And a lead screw 180 screwed to the fixing member 150, and guide bars 190 connected to the diffuser tube 140 and inserted into the fixing member 150. . As the lead screw 180 rotates according to the forward and reverse rotation of the rotary motor 170, the diffuser cone 160 reciprocates linearly. The diffuser tube 140 is opened and closed according to the linear reciprocating motion of the diffuser cone 160. The wire 171 connected to the rotary motor 170 is connected to the control unit 400. The electric damper (D) is a publicly disclosed technology, and a detailed description thereof will be omitted.

The electric damper unit includes electric dampers (D) provided at ends of pipes (branch pipes and auxiliary branch pipes) located in each room of the piping system 100, and the wires of the electric dampers (D). It is connected to each connected to the control unit 400 includes a connection wire (not shown).

The detection system 200 is connected to the rooms of the building to detect the flame and smoke. The detection system 200 is provided in each room of the building to detect the flame and smoke 210 and the connection line 220 for connecting the sensor 210 and the control unit 400 Include.

The supply and exhaust unit 300 is connected to the piping system 100. The supply and exhaust unit 300 supplies the outside air to the rooms of the building through the piping system 100 or discharges the air of the rooms to the outside. As an example of the air supply and exhaust unit 300, as shown in FIG. 4, the air supply and exhaust unit 300 includes a main body case 310, a first air supply connection pipe SP1, and a first exhaust connection pipe ( DP1), the second air supply connection pipe (SP2) and the second exhaust connection pipe (DP2), the heat exchange module 320, the exhaust flow path control unit 330, the air supply flow path control unit 340, exhaust flow generating unit 350 , Air supply flow generating unit (360).

The main body case 310 is formed by arranging the first partition 311, the heat exchange module 320, and the second partition 312 in a line in the longitudinal direction of the inner case of the hexahedron, and the first partition 311. The inside of the case is divided into two passages by the heat exchange module 320 and the second partition 312. One passage is referred to as an exhaust passage F1 through which indoor air escapes to the outside, and the other passage refers to outdoor air. It is called an air supply flow path (F2) flowing into the room. The heat exchange module 320 has a hexagonal shape (viewed from the plane) having a predetermined thickness, and the hot air flows so that hot air passing through the exhaust flow path F1 and cold air passing through the air supply flow path F2 exchange with each other. A plurality of unit heat exchange modules are formed in which passages and passages through which cold air flows cross each other are stacked.

The main body case 310 is provided on one side of the main body case 310 so as to be in communication with the exhaust flow path F1, and is located next to the first exhaust connection pipe DP1. The first air supply connecting pipe (SP1) is provided on one side of the in communication with the air supply passage (F2). The second exhaust connection pipe DP2 is provided on the other side of the main body case 310 (a side opposite to the side on which the first exhaust connection pipe is provided) so as to communicate with the exhaust flow path F1. The second air supply connection pipe SP2 is provided on the other side of the main body case 310 so as to be located next to the exhaust connection pipe DP2 so as to communicate with the air supply passage 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 piping system 100. It is connected to the air supply main pipe 111 of the air supply line (110).

The second exhaust connection pipe DP2 and the second air supply connection pipe SP2 are exposed outside the building.

As illustrated in FIG. 5, the exhaust passage adjusting unit 330 includes a rotary shaft 331 coupled to one corner of the heat exchange module 320 so as to be rotatable, and a plate type coupled to the rotary shaft 331. An exhaust valve mounted to the outside of the main body case 310 so as to be connected to the valve 332 and the rotation shaft 331 to rotate the rotation shaft 331 angularly so that the plate valve 332 adjusts the exhaust flow path F1. It includes a drive unit 333. When the plate valve 332 is positioned perpendicular to the inner surface of the body case 310 (hereinafter, referred to as a first position), indoor air flows only through the heat exchange module 320, and the plate valve 332 is a heat exchange module. When positioned in contact with the inflow side of the 320 (hereinafter referred to as a second position), the indoor air is not connected to the side of the heat exchange module 320 and the inner surface of the body case 310 without passing through the heat exchange module 320. Flow through. In addition, when the plate-shaped valve 332 is located between the first position and the second position, a part of the indoor air flows through the heat exchange module 320 and the rest of the inside of the body case 310 and the side of the heat exchange module 320. It will flow through the sides.

The air supply flow path control unit 340, as in the configuration of the exhaust flow path control unit 330, the rotary shaft 341 is rotatably coupled to one corner portion of the heat exchange module 320, the rotary shaft 341 A plate-shaped valve 342 coupled to the rotary shaft 341 and mounted to the outside of the main body case 310 to be connected to the rotary shaft 341 so that the plate-shaped valve 342 adjusts the air supply flow path F2. Air supply drive unit 343 for rotating each angle is included. When the plate valve 342 is positioned perpendicular to the inner surface of the main body case 310 (hereinafter, referred to as a first position), outdoor air flows only through the heat exchange module 320, and the plate valve 342 exchanges heat. Positioned so as to contact the inlet side of the module 320 (hereinafter referred to as a second position), outdoor air does not pass through the heat exchange module 320 but between the side of the heat exchange module 320 and the inner surface of the body case 310. Will flow through. In addition, when the plate-shaped valve 342 is located between the first position and the second position, a part of the outdoor air flows through the heat exchange module 320 and the other part of the side surface of the heat exchange module 320 and the inside of the body case 310. It will flow through the sides.

The exhaust flow generating unit 350 is provided in the second exhaust connection pipe DP2 to generate air flow. The exhaust flow generating unit 350 preferably includes an outer rotor type BLD motor (not shown) and a fan (not shown) provided in the outer rotor of the outer rotor type BLD motor.

The air supply flow generating unit 360 is provided in the first air supply connecting pipe (SP1) to generate the flow of air. The air supply flow generating unit 360 preferably includes an outer rotor type Bieldi motor (not shown), and a fan (not shown) provided in the outer rotor of the outer rotor type Bieldi motor.

It is preferable that the capacity of the non-ELD motor of the exhaust flow generating unit 350 is greater than that of the non-ELD motor of the air supply flow generating unit 360 and the fan of the exhaust flow generating unit is larger than the size of the fan of the air supply flow generating unit. .

It is preferable that the filter unit 370 is mounted on the second air supply connecting pipe SP2.

The control unit 400 controls the supply / exhaust unit 300 according to the detection signal of the detection system 200 and releases the lock of the front door of the building. The connection line 220 of the sensing system 200 is connected to the control unit 400. In addition, the exhaust driving unit 333 and the air supply driving unit 343 of the air supply and exhaust unit 300, the exhaust flow generating unit 350, the air supply flow generating unit 360, the electric damper (D), respectively It is connected to the control unit 400. In addition, a locking unit (L) for locking or releasing the front door of the building is connected to the control unit (400).

The alarm unit 500 gives an alarm to the building management room (guard room) according to the signal of the detection system 200. The alarm unit 500 includes an alarm line and a connection line connecting the alarm unit and the control unit 400.

Figure 6 is a flow chart illustrating an embodiment of a control method of the flue and replay fire fighting ventilation system according to the present invention.

As shown in Figure 6, one embodiment of the control method of the exhaust and re-enactment fire fighting ventilation system according to the present invention comprises the steps of detecting smoke or flame in the room; Closing the electric damper (D) of the air supply line (120) of the piping system (100) and opening the electric damper (D) of the exhaust line (110); Blocking the flow path of the heat exchange module 320 of the exhaust flow path F1 and opening the exhaust flow path F1; Operating the exhaust flow generating unit 350 to discharge the indoor (room) air out of the building through the exhaust line 110 and the exhaust flow path F1; Unlocking the front door of the building; And ringing an alarm in the guard room.

Hereinafter, the operation and effects on the flue gas regeneration fire retardant fire ventilation system and the control method according to the present invention will be described.

First, if the smoke or heat is not detected in the room of the building in the detection system 20, the normal operation is made. That is, when ventilating a room or rooms of a building, the electric damper D of the air supply line 120 and the electric damper D of the exhaust line 110 located in the room are opened and the exhaust driving unit 333 and the air supply are opened. The drive units 343 are operated respectively to place the plate valves 332 and 342 in the third position. Then, the exhaust flow generating unit 350 and the air supply flow generating unit 360 are operated. Such operation is performed by the control of the control unit 400.

The flow (exhaust force) is generated by the operation of the exhaust flow generating unit 350 so that the air in the room of the building passes through the exhaust line 110 and the first exhaust connection pipe DP1 of the piping system 100. Part of the indoor air introduced into the exhaust passage F1 of the 310 and introduced into the exhaust passage F1 of the body case 310 is exhausted out of the building through the second exhaust connection pipe DP2 via the heat exchange module 320. At the same time, the remainder of the indoor air introduced into the exhaust flow path F1 of the main body case 310 flows between the side surface of the heat exchange module 320 and the inner side surface of the main body case 310 to open the second exhaust connection pipe DP2. Through the building is exhausted.

The flow (air supply force) is generated by the operation of the air supply flow generating unit 360 so that outdoor air outside the building flows into the air supply flow path F2 of the main body case 310 through the second air supply connection pipe SP2. A part of outdoor air introduced into the air supply passage F2 of the main body case 310 is introduced into the air supply line 120 of the piping system 100 through the first air supply connection pipe SP1 through the heat exchange module 320. The outdoor air introduced into the air supply line 120 is supplied to the room of the building through the air supply line 120. When the outdoor air passes through the heat exchange module 320, heat is exchanged with the indoor air, and the outdoor air is supplied to the room of the building while the outside air is heated. In addition, the indoor air is transferred to the outside air in the heat exchange module to be exhausted out of the building in a cooled state. As a result, the indoor air of the building is purified while minimizing heat loss of the building's room.

On the other hand, if a fire occurs in any room of the building is detected by the detection system 200 to send a signal to the control unit 400. When the fire occurrence signal is received from the control unit 400, the electric damper D of the air supply line 120 of the piping system 100 is closed, and the sensing system 200 among the electric dampers D of the exhaust line 110 is closed. Detected at, only the electric damper (D) of the room in which the fire is opened, the other dampers (D) are closed, the exhaust drive unit 333 is operated to position the plate-shaped valve 332 in the second position. Then, the operation of the air supply flow generating unit 360 is stopped and the exhaust flow generating unit 350 is operated. At the same time release the lock state of the front door to give a signal to the alarm unit 500 of the guard room to operate the alarm unit 500. This operation is operated by the control unit 400.

The air in the building of the building where the fire is generated by the operation of the exhaust flow generating unit 350 and the fire is generated is accompanied by the smoke and the exhaust line 110 and the first exhaust connection pipe DP1 of the piping system 100. The indoor air and the smoke introduced into the exhaust flow path F1 of the main body case 310 and introduced into the exhaust flow path F1 of the main body case 310 do not pass through the heat exchange module 320. It flows between the side surface and the inner surface of the body case 310 and is exhausted out of the building through the second exhaust connecting pipe DP2.

When the indoor air of the building is purified in a normal state, the indoor air and the outdoor air are exchanged with each other in the heat exchange module 320 so that the outdoor air introduced into the room is heated, thereby minimizing indoor heat loss. . This not only reduces the heating costs of the building, but also saves energy.

The present invention is provided with an electric damper (D) at each end of the exhaust line 110 and the air supply line 120 of the piping system 100, the electric damper (D) of the exhaust line 110 of the room where the fire occurs in the event of a fire Only open and the other electric dampers (D) to exhaust the smoke in a closed state to quickly exhaust the smoke in the fire room. In addition, in the event of a fire, the flow path of the heat exchange module 320 is blocked in the exhaust passage of the main body case 310, and the smoke is exhausted through the inner surface of the main body case 310 and the side surface of the heat exchange module 320, so that the smoke is quickly outside the building. Is exhausted.

As a result, the smoke of a fired room is quickly exhausted out of the building, so that people in the building as well as those in the fired room can exit the room with minimal exposure to smoke. You will have time.

The present invention releases the locked state of the front door when a fire occurs and gives an alarm signal to the guard room so that the guards or firefighters can quickly enter the interior of the building to rescue people who are inconvenient in movement.

100; Piping system 200; Detection system
300; Supply and exhaust unit 400; The control unit
500; Alarm unit

Claims (8)

A piping system connected to the rooms of the building;
A detection system connected to the rooms of the building and detecting flame and smoke;
A supply / exhaust unit connected to the piping system and configured to supply external air to the rooms or discharge the air of the rooms to the outside through the piping system;
An electric damper unit provided at a pipe end of a piping system located in each room of the building, the electric damper unit adjusting an amount of supply / exhaust flow into and out of each room;
A control unit for controlling the supply / exhaust unit and the electric damper unit according to the detection signal of the detection system, and releasing the lock of the front door of the building; And
And an alarm unit for giving an alarm to the building management room according to the signal of the detection system. According to claim 1, The piping system includes an air supply line connected to the rooms of the building and the outside air is supplied to the rooms, and an exhaust line connected to the rooms of the building and the air of the room is discharged to the outside,
The air supply line includes air supply main pipes and air supply branch pipes branched to the air supply main pipes to communicate with each room of the building, and the exhaust line is branched to the main air exhaust pipe and the main air exhaust pipe, respectively. A flue and replay fire ventilation system comprising exhaust branch pipes communicating with each room of the building. According to claim 1, The piping system includes an air supply line connected to the rooms of the building and the outside air is supplied to the rooms, and an exhaust line connected to the rooms of the building and the air of the room is discharged to the outside,
The air supply line includes an air supply main pipe, air supply branch pipes branched according to the number of rooms of the building, and a plurality of air supply auxiliary branch pipes connected to the air supply branch pipe and communicate with the room of the building. The line includes an exhaust main pipe, exhaust branch pipes branched according to the number of rooms in the building, and a plurality of exhaust auxiliary branch pipes connected to the exhaust branch pipe to communicate with the room of the building, and exhaust of each room. A flue gas and replay fire ventilation system, characterized in that the number of auxiliary branch pipes is greater than the number of auxiliary air branch pipes. The fire and smoke retardant fire fighting apparatus according to claim 1, wherein the electric damper unit includes an electric damper installed at an end of a pipe of a piping system located in each room of the building, and a connection wire connecting the electric dampers to the control unit. Ventilation system. According to claim 1, wherein the detection system is provided in each room of the building and the fire and smoke retardant fire ventilation system including a sensor for detecting flame and smoke, and a connection line connecting the sensors and the control unit. According to claim 1, The air supply and exhaust unit and the main body case is provided with an exhaust passage and the air supply passage; A first air supply connection pipe and a first exhaust connection pipe which are provided at one side of the main body case and are in communication with the seal and the internal and external air flow paths, and are connected to the piping system; A second air supply connection pipe and a second exhaust connection pipe provided on the other side of the main body case so as to communicate with the indoor and outdoor air flow paths, respectively; A heat exchange module provided at a boundary between the exhaust passage and the air supply passage so as to share the indoor and outdoor air passages, and exchanging hot air through the exhaust passage and cold air through the supply passage; An exhaust passage adjusting unit provided in the exhaust passage to adjust a flow of air flowing in the exhaust passage; An air supply passage adjusting unit provided in the air supply passage and controlling the flow of air flowing in the air supply passage; An exhaust flow generating unit provided in the second exhaust connection pipe to generate an air flow; A flue gas regeneration and fire retardant ventilation system comprising an air supply flow generating unit is provided in the first air supply connection pipe for generating a flow of air. According to claim 6, The supply and exhaust flow generating unit, respectively, the outer rotor type Bieldi motor and the outer rotor type Bieldi motor, the outer rotor of the outer rotor type Bieldi motor, the exhaust and regeneration fire fighting ventilation system, characterized in that . Detecting smoke or flame in the interior of the building;
Closing the electric damper of the air supply line of the piping system in the smoke or flame detection zone and opening only the electric damper of the exhaust line of the piping system in the smoke or flame detection zone;
Blocking the flow path of the heat exchange module of the exhaust flow path and opening the exhaust flow path;
Operating an exhaust flow generating unit to discharge the indoor air out of the building through an exhaust line and an exhaust passage;
Unlocking the front door of the building; And
Fire alarm and replay fire alarm system comprising a; ringing an alarm in the guard room provided in the building.

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