KR101381911B1 - Smoke control system between floors - Google Patents

Abstract

The present invention relates to an inter-floor smoke control system that controls an amount of exhaust gas within a predetermined range such that differential pressures of insides and outsides of all smoke discharge barriers disposed in a fire occurrence floor can be maintained below a predetermined maximum differential pressure (for example, 80 Pa) at which a predetermined minimum opening force (for example, 110 N) determined as a value by which a normal person can open the smoke discharge barriers by using a differential pressure between a fire occurrence floor and a non-fire occurrence floor of a building, and controls an amount of supplied air within a predetermined range such that pressures of a direct upper floor and a direct lower floor of the fire occurrence floor can be maintained above a pressure of the fire occurrence floor and below pressures of annexes of the direction upper floor and the direct lower floor by using the differential pressure between the fire occurrence floor and the non-fire occurrence floor of a building. According to the present invention, a fatal accident due to suffocation and burns as a person on the fire occurrence floor cannot open the smoke discharge barrier can be prevented, air flows from the annexes of the direction upper floor and the direct lower floor can be smoothly maintained, and the smoke on the fire occurrence floor can be prevented from being spread to the direct upper floor and the direct lower floor. [Reference numerals] (AA,BB,CC,DD,EE,FF,GG) Controller

Description

Smoke control system between floors

The present invention relates to a smoke control system, and more particularly to a sandwich pressure type interlayer smoke control system using a differential pressure between the fire generating layer and the non-fire generating layer of the building.

Sandwich pressurization is an inter-floor ventilation system equipped with an air supply and an exhaust device for each floor of a building to exhaust the fire generating layer of the building and exhaust smoke to the outside, and to supply the upper and lower layers of the fire generating layer to the air supply. By forming the pressure to a positive pressure higher than the pressure of the fire generating layer, it is a smoke control system that prevents the smoke of the fire generating layer from diffusing to the upper and lower layers.

For reference, the design criteria for this sandwich pressurized interlayer ventilation system are based on the National Fire Protection Association (NFPA) barriers and differential pressure control standards 92A 2009 (NFPA 92A Standard for Smoke-Control Systems Utilizing Barriers and See chapter 5.5 of Pressure Differences 2009 Edition.

In the sandwich pressurization system of the sandwich pressurization method as described above, when the exhaust device of the fire generating layer of the building operates to discharge the smoke to the outside, if the exhaust volume of the fire generating layer increases, the pressure of the fire generating layer is operated. It is formed at a lower negative pressure than the pressure of the upper layer and the lower layer.

At this time, when the difference between the amount of air supply flowing into the evacuation stairs of the fire generating layer or the auxiliary room through the emergency elevator through the ventilation control line of the building and the amount of exhaust of the fire generating layer increases, the evacuation path of the fire generating layer is proportional to the difference. As the pressure difference in the inner part of any one or more of the at least one flame retardant barriers placed on the floor becomes excessively large, a person in the fire-generating layer may not be able to open the flame barrier and die due to asphyxiation, burns, etc. Can be.

The ancillary room refers to a ventilation area between the fire generating floor and the evacuation stairs of the building or a ventilation area between the fire generating floor and the emergency lift, and the above-described flame barrier is an entrance door (or a fire door) between the auxiliary room and the fire generating floor. Or doors (or fire doors) between the interior and the interior of the fire-generating floor, and those who are in the fire-generating floor are connected via an evacuation path through the door between the interior and the interior of the fire-generating floor. Open the entrance door to the attached room and go to the evacuation stairs or emergency lift via this room.

As described above, the conventional sandwich pressurization system for sandwich pressurization may be caused by an accident in which a person in the fire generating layer may not open the flame barrier and die due to suffocation or burn. There is a need for a new technology that maintains the differential pressure of all the flame-retardant barriers placed on the fire-generating layer in a safe range so that the person on the fire-generating layer can easily open the flame-retardant barrier.

NFPA 92A Standard for Smoke-Control Systems Utilizing Barriers and Pressure Differences (2009 Edition)

The present invention is to solve the conventional problems as described above, the object of the present invention is to use the pressure difference between the fire generating layer and the non-fire generating layer of the building using the differential pressure of the inner blanket of all the flame-retardant barriers arranged in the fire generating layer Control the displacement to a predetermined range so as to keep below a predetermined maximum differential pressure (e.g. 80 Pa) that can be maintained below a predetermined minimum opening force (e.g. 110 N) at a value that an average person can open the flame barrier. By using the pressure difference between the fire generating layer and the non-fire generating layer of the building, the pressures of the upper and lower layers of the fire generating layer are higher than the pressure of the fire generating layer and the pressures of the respective auxiliary rooms of the upper and lower layers. It is to provide an interlayer dehumidification system that controls the air supply amount to a predetermined range so as to keep it low.

It is another object of the present invention that a fire generating layer of a building is disposed on the fire generating layer according to a result of comparing the pressure difference between the fire generating layer and two or more fire non-generating layers above or below with a predetermined exhaust pressure difference. Displacement pressure to maintain the inner pressure differential pressure of all flame barriers below a predetermined maximum differential pressure (eg 80 Pa) that can be maintained below a predetermined minimum opening force (eg 110 N) at a value that an average person can open the flame barrier. And control the pressure difference between the fire-generating layer and the layer directly below the fire-generating layer and the fire-generating layer, the layer directly above the fire-generating layer and the non-fire-generating layer except the layer below the fire-generating layer. According to the result of comparison with the reference air pressure difference, the pressures of the upper and lower layers of the fire generating layer are higher than the pressure of the fire generating layer and the respective parts of the upper and lower layers are To provide an inter-layer smoke control system for controlling a feeding amount in a predetermined range so as to keep lower than the pressure in the chamber.

Another object of the present invention is to compare the differential pressure of the inner space of the flame retardant barrier that requires the maximum opening force in the event of a fire among the at least one flame retardant barrier disposed on the fire generating floor of the building to a reference exhaust pressure for a predetermined exhaust. Thus, a predetermined maximum differential pressure (eg The exhaust volume is controlled in a predetermined range so as to maintain the pressure of 80 Pa) or less, and the upper layer of the fire generating layer is configured according to the result of comparing the pressure difference between the fire generating layer and the upper layer of the fire generating layer with a predetermined standard differential pressure for supplying air. The air supply amount is controlled to a predetermined range so that the pressure of the upper layer is higher than the pressure of the fire generating layer and lower than the pressure of the auxiliary chamber of the upper layer, The lower layer of the layer is higher than the pressure of the fire generating layer and the pressure of the lower layer of the fire generating layer is higher than that of the fire generating layer according to the result of comparing the pressure difference between the fire generating layer and the lower layer of the fire generating layer with the predetermined standard differential pressure for supplying air. It is to provide an interlayer dehumidification system that controls the air supply to a predetermined range so as to be kept lower than the pressure in the annex.

In order to achieve the object of the present invention as described above, a first embodiment of the interlayer ventilation system according to the present invention, an exhaust blower for discharging the bet to the outside in each floor through an exhaust line installed in each floor of the building; An exhaust damper installed at each floor exhaust line to adjust an exhaust volume of the corresponding floor; An exhaust damper driver installed at each floor to control an opening degree of the exhaust damper of the corresponding floor; An air supply blower for supplying air to each floor through an air supply line installed at each floor of the building; An air supply damper installed in each floor air supply line to control the air supply of the floor; An air supply damper driving unit installed at each floor to control an opening degree of the air supply damper of the corresponding floor; If the floor is a fire-generating layer, and the floor is a fire-generating layer, the fire-generating layer and the fire An interlayer pressure guiding tube for sensing pressure in the generating layer; And installed in each floor, and if the floor is a fire generating layer, the pressure difference between the fire generating layer detected by the exhaust pressure difference sensor connected to the pair of interlayer pressure pipes and the fire non-generating layer two or more separated from above or below. By controlling the opening degree of the exhaust damper by controlling the opening of the exhaust damper according to the result of comparing with the reference differential pressure for exhaust, the ordinary person can open the differential pressure of the inner barrier of all the flameproof barriers arranged in the fire generating layer. And a controller for controlling the displacement to a predetermined range so as to maintain a predetermined maximum differential pressure (for example, 80 Pa) that can be maintained at or below a predetermined minimum opening force (for example, 110N).

In the first embodiment of the interlayer ventilation system according to the present invention, the controller is installed for each floor, and if the floor is a floor directly above the fire generating layer is detected by the air supply pressure sensor connected to the pair of interlayer pressure pipes. The air supply damper driving unit according to the result of comparing the pressure difference between the fire immediately above the other fire non-fire generating layer, that is, the fire non-fire generating layer and the other fire non-fire generating layer except the lower layer of the fire generating layer with the predetermined standard differential pressure for air supply. And controlling the opening degree of the air supply damper to control the air supply amount in a predetermined range so as to maintain the pressure of the upper layer of the fire generating layer higher than the pressure of the fire generating layer and lower than the pressure of the accessory chamber of the upper layer. .

In the first embodiment of the interlayer ventilation system according to the present invention, the controller is installed for each floor, and if the floor is a floor directly below the fire generating layer is detected by the air supply pressure sensor connected to the pair of interlayer pressure pipes. According to the result of comparing the pressure difference between the fire floor and other fire non-fire floors, that is, the fire-fired floor and other fire-free fire floors except the immediate floor of the fire-fired floor and the standard fire pressure difference. By controlling the opening degree of the air supply damper by driving the air supply damper drive unit to control the air supply amount in a predetermined range to maintain the pressure of the lower layer of the fire generating layer higher than the pressure of the fire generating layer and lower than the pressure of the auxiliary chamber of the lower layer. It is characterized by.

In the first embodiment of the interlayer ventilation system according to the present invention, the controller installed on the upper or lower floor of the fire generating layer is characterized in that it operates by receiving the output signal of the controller installed in the fire generating layer.

In order to achieve the object of the present invention as described above, a second embodiment of the interlayer ventilation system according to the present invention, an exhaust blower for discharging the bet to the outside in each floor through an exhaust line installed in each floor of the building; An exhaust damper installed at each floor exhaust line to adjust an exhaust volume of the corresponding floor; An exhaust damper driver installed at each floor to control an opening degree of the exhaust damper of the corresponding floor; An air supply blower for supplying air to each floor through an air supply line installed at each floor of the building; An air supply damper installed in each floor air supply line to control the air supply of the floor; An air supply damper driving unit installed at each floor to control an opening degree of the air supply damper of the corresponding floor; A pair of barriers between the at least one fume barrier placed on each floor of the building, installed inside the enclosure of the reference flame barrier that requires the maximum opening force in case of fire, to sense the pressure in the enclosure of the reference flame barrier. Pressure pipe; It is installed on each floor except the top floor of the building, and if the floor is a fire-generating floor, it operates in pairs with other first inter-layer pressure pipes installed on the upper floor of the fire-generating floor to control the pressure between the fire-generating floor and the upper floor. Sensing a first interlayer guiding tube; It is installed on each floor except the lowest floor of the building, and if the floor is a fire-generating floor, it operates in pairs with another second interlayer pressure pipe installed on the lower floor of the fire-generating floor, thereby reducing the pressure between the fire-generating floor and the lower floor. Sensing a second interlayer guiding tube; And installed on each floor, and if the floor is a fire-generating layer, the pressure difference between the inner and outer walls of the reference fume barrier detected by the exhaust pressure difference sensor connected to the pair of barrier pressure guide tubes is compared with a predetermined exhaust pressure difference. Therefore, by controlling the opening degree of the exhaust damper by driving the exhaust damper drive unit, a predetermined minimum opening force (e.g., a predetermined opening force) is set to a value at which an ordinary person can open the flameproof barrier by controlling the opening degree of the exhaust damper. And a controller that controls the displacement in a predetermined range to maintain the predetermined maximum differential pressure (eg, 80 Pa) or less, which can be maintained at or below 110 N).

In a second embodiment of the interlayer ventilation system according to the present invention, the controller is installed floor by floor, and if the floor is the upper floor of the fire generating floor, the fire generating floor is directly connected to the pair of first interlayer pressure pipes. By controlling the opening degree of the air supply damper by driving the air supply damper driving unit according to a result of comparing the pressure difference between the fire generating layer detected by the air supply differential pressure sensor installed in the upper layer and the upper layer of the fire generating layer with the reference differential pressure for the defined air supply. It is characterized in that the air supply amount is controlled in a predetermined range so as to maintain the pressure of the upper layer of the fire generating layer higher than the pressure of the fire generating layer and lower than the pressure of the accessory chamber of the upper layer.

In the second embodiment of the interlayer ventilation system according to the present invention, the controller installed on the upper floor of the fire generating layer is characterized in that it operates by receiving the output signal of the controller installed in the fire generating layer.

In a second embodiment of the interlayer ventilation system according to the present invention, the controller is provided for each floor, and if the floor is directly below the fire generating layer, the controller is installed in the fire generating layer connected with the pair of second interlayer pressure pipes. Fire generation layer by controlling the opening degree of the air supply damper by driving the air supply damper driving unit according to a result of comparing the pressure difference between the fire generating layer sensed by the air supply differential pressure sensor and the lower layer of the fire generating layer with a reference air pressure differential for a predetermined air supply. It is characterized in that the air supply amount is controlled to a predetermined range so as to maintain the pressure of the lower layer of the lower than the pressure of the fire generating layer and lower than the pressure of the auxiliary chamber of the lower layer.

In the second embodiment of the interlayer ventilation system according to the present invention, the controller installed directly below the fire generating layer is provided by the air supply pressure sensor connected to the pair of second interlayer pressure pipes from the controller installed in the fire generating layer. It is characterized in that the operation is received by receiving the pressure difference between the fire generating layer and the layer directly below the fire generating layer.

According to the present invention, a predetermined pressure can be maintained within a predetermined minimum opening force (e.g., 110 N) at a value at which an ordinary person can open the flame barrier in accordance with the inner pressure of all the flame barriers arranged in the fire generating floor of the building. By controlling the displacement to be within a predetermined range so as to maintain the maximum differential pressure (for example, 80 Pa) or less, it is possible to prevent an accident in which a person in the fire generating layer cannot open a flame barrier and die due to asphyxiation, burns, or the like.

According to the present invention, if the air supply amount is controlled in a predetermined range to maintain the respective pressures of the upper and lower layers of the fire generating layer higher than the pressure of the fire generating layer and lower than the pressures of the respective auxiliary rooms of the upper and lower layers. The air supply flow is maintained intact from each of the upper and lower floors of the upper and lower floors, and the smoke of the fire generating layer can be prevented from spreading to the upper and lower floors.

1 is a first embodiment showing the configuration of an interlayer ventilation system according to the present invention;
2 is an embodiment showing the controller of FIG.
Figure 3 is a second embodiment showing the configuration of the interlayer ventilation system according to the present invention.
4 shows an embodiment of the controller of FIG.

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

Referring to FIG. 1, the interlayer ventilation system 200 according to the first embodiment of the present invention is installed separately from the building ventilation system 100 that is already installed in a building.

The building ventilation system 100 operates the blower 110 when a fire breaks out of the building to supply outside air to the blowing line 111 of the building, and is installed in the floor-specific accessory room 112 of the building and the blowing line 111 and The air supply operation of the blower 110 is controlled to supply external air of an air supply amount (eg, a leakage amount and a replenishment amount) to maintain a flameproof wind speed of a predetermined standard through the air supply damper 113 connected.

The exhaust blower 210 of the interlayer ventilation system 200 discharges the bet to the outside from each floor through an exhaust line 211 installed in each floor of the building.

An exhaust damper 220 of the interlayer ventilation system 200 is installed in each floor exhaust line 211 to adjust the displacement of the floor.

The exhaust damper driver 230 of the interlayer ventilation system 200 is installed for each floor to control the opening degree of the exhaust damper 220 of the corresponding floor.

The opening degree (eg, the maximum opening or closing angle or the minimum opening and closing angle) of the exhaust damper 220 may be determined in advance to maintain the following maximum differential pressure (eg, 80 Pa) through a preliminary test or calculation.

The air supply blower 240 of the interlayer ventilation system 200 supplies outdoor air to each floor through an air supply line 241 installed at each floor of the building.

The air supply damper 250 of the interlayer ventilation system 200 is installed in the floor air supply line 241 to adjust the air supply of the floor.

The air supply damper driver 260 of the interlayer ventilation system 200 is installed for each floor to control the opening degree of the air supply damper 250 of the corresponding floor.

The opening degree (eg, the maximum opening angle or the minimum opening angle) of the air supply damper 250 is determined by preliminary test or calculation to determine the pressure difference between the fire generating layer and the upper layer and the fire generating layer and the lower layer within a predetermined differential pressure range. Can be determined in advance.

The interlayer pressure pipe 270 of the interlayer ventilation system 200 is installed for each floor, and if the floor is a fire generating layer, another interlayer installed at a fire non-occurring floor two or more away from or above the fire generating layer. It operates in pairs with the pressure guiding pipe 270 to sense the pressure of the fire generating layer and the non-fire generating layer.
For reference, in FIG. 1, the first floor (1F) to the seventh floor (7F) of the building are installed for each floor, and if the floor is a fire generating floor, two or more fire-free floors spaced up or down from the fire generating floor. It illustrates an interlayer pressure pipe 270 for detecting the pressure of the fire generating layer and the non-fire generating layer by operating in pairs with other interlayer pressure pipes 270 installed in the building. In particular, the first floor of the building (1F) From the seventh floor (7F), the interlayer pressure pipe (270) installed on the seventh floor (7F), which is the uppermost floor, operates in pairs with the interlayer pressure pipe (270) installed on the fourth floor (4F) separated by three down, An embodiment in which the interlayer pressure pipes 270 provided on the first floor 1F operate in pairs with the interlayer pressure pipes 270 provided on the three floors 3F separated by two upwards is shown.

The controller 280 of the interlayer ventilation system 200 is installed for each floor, and if the floor is a fire generating floor, a fire occurrence detected by the exhaust pressure difference sensor 281 connected to the pair of interlayer pressure pipes 270. By controlling the opening degree of the exhaust damper 220 by driving the exhaust damper driver 230 according to a result of comparing the pressure difference between the floor and the fire non-occurring layer which is two or more above or below with a predetermined exhaust reference differential pressure. A predetermined maximum differential pressure that can maintain the inner pressure differential pressure of all the flame-retardant barriers 300 disposed in the fire generating layer below a predetermined minimum opening force (e.g., 110 N) to a value at which an ordinary person can open the flame-retardant barrier ( For example, the displacement is controlled in a predetermined range so as to be maintained at 80 Pa or less.

The minimum opening force varies depending on the person (eg, child, female, elderly, etc.) who open the flame barrier, but in the embodiment according to the present invention, it is preferable to maintain the minimum opening force in the range of 50N to 133N. In the range of 50N to 133N, 50N is the minimum value set for children or the elderly, and 133N is the maximum recommended in the 2009 edition of the Smoke Control System Standard 92A 2009 using the barrier and differential pressure of the National Fire Protection Association (NFPA). It is a standard.

The maximum differential pressure varies depending on the stack effect of the building and the influence of the wind, whether or not the sprinkler is installed, the height of the door serving as a flame retardant barrier, the width and the friction of the door closer, but in the embodiment of the present invention 12.5Pa ~ 100Pa It is desirable to maintain the maximum differential pressure in the range. In the range of 12.5 Pa to 100 Pa, 12.5 Pa is a value recommended by the National Fire Protection Association (NFPA) barrier and differential pressure control system 92A 2009 edition, and 100Pa is the applicant (or inventor). In order to expect the effects of the present invention described above with reference to preliminary tests and calculation data considering the stack effect and wind effect of the building, whether or not the sprinkler is installed, the height of the door serving as a smoke barrier, the width and the friction of the door closer. It is a fixed value.

The controller 280 is a fire non-occurrence layer different from the immediate upper layer sensed by the air supply pressure sensor 282 connected to the pair of interlayer pressure pipes 270 when the corresponding layer is the upper layer of the fire generating layer. The air supply damper driving unit 260 is driven according to a result of comparing the pressure difference between the fire generating layer and another fire non-generating layer except the upper layer of the fire generating layer and the lower layer of the fire generating layer with the predetermined standard differential pressure for supplying air. By controlling the opening degree of the air supply damper 250, the air supply amount is controlled in a predetermined range so as to maintain the pressure of the upper layer of the fire generating layer higher than the pressure of the fire generating layer and lower than the pressure of the accessory chamber 112 of the upper layer.

If the floor is a floor directly below the fire generating floor, the controller 280 is a non-fire floor that is different from the floor directly below that detected by the air supply pressure sensor 282 connected to the pair of interlayer pressure pipes 270. The air supply damper driving unit 260 is driven according to a result of comparing the pressure difference between the fire generating layer and another fire non-generating layer except the upper layer of the fire generating layer and the lower layer of the fire generating layer with the predetermined standard differential pressure for supplying air. By controlling the opening degree of the air supply damper 250, the air supply amount is controlled in a predetermined range so as to maintain the pressure of the lower layer of the fire generating layer higher than the pressure of the fire generating layer and lower than the pressure of the auxiliary chamber 112 of the lower layer.

The controller 280 operates by receiving an output signal of the controller 280 installed in the fire generating floor if the floor is directly above or below the fire generating floor.

2, the controller 280 includes the exhaust differential pressure sensor 281 and the air supply differential pressure sensor 282.

The exhaust differential pressure sensor 281 and the air supply differential pressure sensor 282 share a fire generating layer and a fire non-generating layer separated two or more from above or below the fire generating layer by sharing the pair of interlayer pressure pipes 270. To detect the differential pressure.

2 illustrates an embodiment in which the exhaust pressure differential sensor 281 and the air supply differential pressure sensor 282 share the pair of interlayer pressure pipes 270, but the exhaust pressure difference sensor 281 and the air supply differential pressure are required as needed. The sensor 282 may use a pair of interlayer guiding tubes 270 corresponding to each.

The interlayer ventilation system 200 according to the first embodiment of the present invention configured as described above operates as follows.

In FIG. 1, an entrance door (or fire door) between an accessory room 112 and a fire generating floor for each floor of a building is illustrated as a flame retardant barrier 300. In the first embodiment of the present invention, the flame retardant barrier 300 is a fire occurrence. It is assumed that the maximum opening force is required.

For example, when a fire occurs on the fifth floor 5F of a building, a fire detection signal of a fire detector (not shown) or a fire detection system (not shown) that is already installed in the building may be used to control the fire generating floor 5F. 280, and the controller 280 operates accordingly.

At this time, the exhaust pressure difference sensor 281 included in the controller 280 installed in the fire generating layer 5F is above or below the fire generating layer 5F detected by the pair of interlayer pressure pipes 270. The differential pressure with the fire non-occurring layer (eg, 2F of FIG. 1) separated by two or more furnaces, and the controller 280 compares the currently detected differential pressure with a predetermined exhaust reference differential pressure. The opening of the exhaust damper 220 is controlled by driving the driver 230.

As such, when the opening degree of the exhaust damper 220 is controlled, the minimum opening predetermined by the value of the inner pressure of all the flame-retardant barriers 300 disposed on the fire generating layer 5F is set to a value at which an ordinary person can open the flame-retardant barrier. The displacement can be controlled to a predetermined range so as to be kept below a predetermined maximum differential pressure (eg, 80 Pa) that can be kept below a force (eg, 110 N).

Therefore, it is possible to prevent an accident in which a person in the fire generating layer 5F fails to open the flame barrier 300 and dies due to suffocation, burns, or the like.

On the other hand, the controller 280 installed in the fire generating layer 5F receives the fire detection signal and at the same time the upper layer 6F of the fire generating layer 5F through the N + 1 output terminal and the N-1 output terminal. And outputs the output signal to the lower floor 4F, and accordingly, the controller 280 installed on the upper floor 6F of the fire generating layer 5F receives the output signal through the N-1 input terminal and operates. In addition, the controller 280 installed on the lower floor 4F of the fire generating layer 5F operates by receiving the output signal through an N + 1 input terminal.

At this time, the air supply differential pressure sensor 282 included in the controller 280 installed in the upper layer 6F of the fire generating layer 5F is the upper layer (S) detected by the pair of interlayer pressure pipes 270 ( 6F) and other non-fire-generating layers, i.e., other non-fire-generating layers except for the fire-generating layer 5F and the fire-generating layer 5F, the upper layer 6F and the fire-generating layer 5F, the lower layer 4F. For example, the differential pressure with 3F of FIG. 1 is sensed, and the controller 280 installed in the upper layer 6F is configured to compare the currently detected differential pressure with a predetermined reference differential pressure for air supply damper driving unit 260. ) To control the opening degree of the air supply damper 250.

As such, when the opening degree of the air supply damper 250 installed in the upper layer 6F is controlled, the pressure of the upper layer 6F of the fire generating layer 5F is higher than the pressure of the fire generating layer 5F and the upper layer 6F. The air supply amount can be controlled to a predetermined range so as to be lower than the pressure of the auxiliary chamber 112 of the).

In addition, at this time, the air supply differential pressure sensor 282 included in the controller 280 installed in the lower layer 4F of the fire generating layer 5F is a corresponding upper layer sensed by the pair of interlayer pressure pipes 270. Other fire non-occurring layers other than 4F, that is, the fire generating layer 5F and other fire non-generating layers except the upper layer 6F of the fire generating layer 5F and the lower layer 4F of the fire generating layer 5F. For example, the differential pressure with respect to 1F of FIG. 1 is sensed, and the controller 280 installed in the lower layer 4F is configured to compare the currently detected differential pressure with a predetermined reference differential pressure for supply air, and thus the air supply damper driver ( The opening degree of the air supply damper 250 is controlled by driving 260.

As such, when the opening degree of the air supply damper 250 installed in the lower layer 4F is controlled, the pressure of the upper layer 4F of the fire generating layer 5F is higher than the pressure of the fire generating layer 5F and the lower layer 4F. The air supply amount can be controlled to a predetermined range so as to be lower than the pressure of the auxiliary chamber 112 of the).

Therefore, the air supply flow is maintained intact from each of the accessory chambers 112 of the upper layer 6F and the lower layer 4F, respectively, to the upper layer 6F and the lower layer 4F. Can be prevented from spreading to the upper layer 6F and the lower layer 4F.

Referring to FIG. 3, the floor defrosting system 200a according to the second embodiment of the present invention is installed separately from the building dedusting system 100 that is already installed in a building.

The building ventilation system 100 operates the blower 110 when a fire breaks out of the building to supply outside air to the blowing line 111 of the building, and is installed in the floor-specific accessory room 112 of the building and the blowing line 111 and The air supply operation of the blower 110 is controlled to supply external air of an air supply amount (eg, a leakage amount and a replenishment amount) to maintain a flameproof wind speed of a predetermined standard through the air supply damper 113 connected.

The exhaust blower 210a of the interlayer ventilation system 200a discharges the bet to the outside from each floor through an exhaust line 211a installed at each floor of the building.

An exhaust damper 220a of the interlayer ventilation system 200a is installed in each floor exhaust line 211a to adjust the displacement of the floor.

The exhaust damper driver 230a of the interlayer ventilation system 200a is installed for each floor to control the opening degree of the exhaust damper 220a of the corresponding floor.

The opening degree (eg, maximum opening or closing angle or minimum opening and closing angle) of the exhaust damper 220a may be determined in advance to maintain the following maximum differential pressure (eg, 80 Pa) through a preliminary test or calculation.

The air supply blower 240a of the interlayer ventilation system 200a supplies outdoor air to each floor through an air supply line 241a installed at each floor of the building.

The air supply damper 250a of the interlayer ventilation system 200a is installed in the floor air supply line 241a to adjust the air supply of the floor.

The air supply damper driver 260a of the interlayer ventilation system 200a is installed for each floor to control the opening degree of the air supply damper 250a of the corresponding floor.

The opening degree of the air supply damper 250a (eg, the maximum opening angle or the minimum opening angle) is determined by preliminary test or calculation to determine the pressure difference between the fire generating layer and the upper layer and the fire generating layer and the lower layer within a predetermined differential pressure range. Can be determined in advance.

The pair of inter-barrier pressure ducts 270a of the interlayer ventilation system 200a is a reference flame retardant that requires the maximum opening force in the event of a fire among at least one of the at least one flame retardant barriers 300,300a disposed on each floor of the building. It is installed in the inner bag of the barrier 300a to sense the pressure of the inner bag of the reference flame-retardant barrier 300a.

The first interlayer pressure pipe 270b of the interlayer ventilation system 200a is installed for each floor except for the top floor of the building, and if the floor is a fire generating floor, another first interlayer diagram installed on the upper floor of the fire generating floor. It operates in pairs with the pressure pipe 270b to sense the pressure of the fire generating layer and the upper layer.

The second interlayer pressure duct 270c of the interlayer smoke control system 200a is installed for each floor except the lowest floor of the building, and if the floor is a fire generating layer, another second interlayer diagram installed in the lower floor of the fire generating layer. It operates in pairs with the pressure pipe 270c to sense the pressure of the fire generating layer and the lower layer.

The controller 280a of the interlayer ventilation system 200a is installed for each floor, and if the floor is a fire-generating layer, the controller sensed by the exhaust pressure difference sensor 281a connected to the pair of inter-barrier pressure pipes 270a. According to the result of comparing the differential pressure of the inner space of the reference flame barrier 300a with a predetermined reference differential pressure for exhaust, the exhaust damper driver 230a is driven to control the opening degree of the exhaust damper 220a so as to control all openings in the fire generating layer. Below the pre-determined maximum differential pressure (e.g. 80 Pa) that can maintain the differential pressure inside the flame retardant barrier (300, 300a) below a predetermined minimum opening force (e.g. 110 N) at a value that an average person can open the flame retardant barrier. The displacement is controlled in a defined range to maintain.

The minimum opening force varies depending on the person (eg, child, female, elderly, etc.) who open the flame barrier, but in the embodiment according to the present invention, it is preferable to maintain the minimum opening force in the range of 50N to 133N. In the range of 50N to 133N, 50N is the minimum value set for children or the elderly, and 133N is the maximum recommended in the 2009 edition of the Smoke Control System Standard 92A 2009 using the barrier and differential pressure of the National Fire Protection Association (NFPA). It is a standard.

The maximum differential pressure varies depending on the stack effect of the building and the influence of the wind, whether or not the sprinkler is installed, the height of the door serving as a flame retardant barrier, the width and the friction of the door closer, but in the embodiment of the present invention 12.5Pa ~ 100Pa It is desirable to maintain the maximum differential pressure in the range. In the range of 12.5 Pa to 100 Pa, 12.5 Pa is a value recommended by the National Fire Protection Association (NFPA) barrier and differential pressure control system 92A 2009 edition, and 100Pa is the applicant (or inventor). In order to expect the effects of the present invention described above with reference to preliminary tests and calculation data considering the stack effect and wind effect of the building, whether or not the sprinkler is installed, the height of the door serving as a smoke barrier, the width and the friction of the door closer. It is a fixed value.

The controller 280a is provided for each floor, and if the corresponding floor is the upper floor of the fire generating layer, the air supply differential pressure sensor 282a installed on the upper floor of the fire generating layer connected to the pair of first interlayer pressure pipes 270b. By controlling the opening degree of the air supply damper 250a by driving the air supply damper driver 260a according to a result of comparing the pressure difference between the fire generating layer detected by the fire layer and the immediate upper layer of the fire generating layer with a predetermined air supply reference differential pressure. The air supply amount is controlled to a predetermined range so that the pressure of the upper layer of the fire generating layer is higher than the pressure of the fire generating layer and lower than the pressure of the accessory chamber 112 of the upper layer.

The controller 280a operates by receiving an output signal of the controller 280a installed in the fire generating layer if the floor is directly above the fire generating layer.

The controller 280a is installed for each floor and is sensed by the air supply pressure sensor 282a installed in the fire generating layer connected to the pair of second interlayer pressure pipes 270c when the floor is directly below the fire generating layer. The fire generating layer is driven by controlling the opening degree of the air supply damper 250a by driving the air supply damper driver 260a according to a result of comparing the pressure difference between the fire generating layer and the lower layer of the fire generating layer with a predetermined standard pressure difference for supplying air. The air supply amount is controlled to a predetermined range so as to maintain the pressure of the lower layer of the lower than the pressure of the fire generating layer and lower than the pressure of the auxiliary chamber 112 of the lower layer.

The controller 280a is detected by the air supply pressure sensor 282a connected to the pair of second interlayer pressure pipes 270c from the controller 280a installed in the fire generating layer when the floor is directly below the fire generating layer. It operates by receiving the differential pressure between the fire generating layer and the lower layer of the fire generating layer.

Referring to FIG. 4, the controller 280a includes the exhaust differential pressure sensor 281a and the air supply differential pressure sensor 282a.

The exhaust pressure difference sensor 281a is a pair of at least one of the at least one flame-retardant barrier 300, 300a disposed on each floor of the building installed in the inner space of the reference flame-retardant barrier 300a that requires the maximum opening force in the event of a fire. The differential pressure between the inner barrier of the reference flame-retardant barrier 300a is sensed by using the barrier barrier pressure pipe 270a.

The air supply differential pressure sensor 282a senses the differential pressure between the fire generating layer and the ground layer by using a pair of first interlayer pressure pipes 270b installed on the fire generating layer of the building and the upper floor of the fire generating layer, respectively.

The air supply differential pressure sensor 282a senses the differential pressure between the fire generating layer and the lower floor by using a pair of second interlayer pressure pipes 270c installed on the fire generating layer of the building and the lower floor of the corresponding fire generating layer, respectively. .

The interlayer ventilation system 200a according to the second embodiment of the present invention configured as described above operates as follows.

In FIG. 3, an entrance door (or fire door) between an auxiliary room 112 and a fire generating floor of each floor of a building or an interior door (or fire door) between an interior and an inside of a fire generating floor is illustrated as a flame retardant barrier 300 and 300a. Of these, the door (or fire door) between the interior of the fire generating layer and the interior is illustrated as a reference flame barrier 300a that requires the maximum opening force in the event of a fire.

For example, when a fire occurs on the fifth floor 5F of a building, a fire detection signal of a fire detector (not shown) or a fire detection system (not shown) that is already installed in the building may be used to control the fire generating floor 5F. 280a, the controller 280a operates accordingly.

At this time, the exhaust pressure difference sensor 281a included in the controller 280a installed in the fire generating layer 5F is an inner space of the reference flame retardant barrier 300a detected by the pair of barrier pressure pipes 270a. Sensing the differential pressure, and the controller 280a drives the exhaust damper driver 230a according to a result of comparing the differential pressure of the inner space of the reference flame retardant barrier 300a with a predetermined exhaust reference differential pressure. The opening degree of the exhaust damper 220a is controlled.

As such, when the opening degree of the exhaust damper 220a is controlled, a minimum predetermined pressure is set to a value that allows an ordinary person to open the flame barrier by setting the pressure difference between the inner flames of all the flame barriers 300 and 300a disposed in the fire generating layer 5F. The displacement can be controlled to a predetermined range so as to maintain below a predetermined maximum differential pressure (for example, 80 Pa) that can be kept below an opening force (for example, 110 N).

Therefore, it is possible to prevent an accident in which a person in the fire generating layer 5F cannot open the flame barriers 300 and 300a and die due to suffocation, burns, and the like.

On the other hand, the controller 280a installed in the fire generating layer 5F receives the fire detection signal and transmits an output signal through the N + 1 output terminal to the upper layer 6F of the fire generating layer 5F. And a fire occurrence detected by the air supply pressure sensor 282a connected to the pair of second interlayer pressure pipes 270c through an N-1 output terminal to the lower layer 4F of the fire generating layer 5F. The differential pressure between the floor 5F and the fire generating layer 5F and the lower layer 4F is transmitted, so that the controller 280a installed in the upper layer 6F of the fire generating layer 5F is inputted with N-1. The output signal is input through the terminal to operate, and the controller 280a installed on the lower floor 4F of the fire generating layer 5F operates by receiving the differential pressure through an N + 1 input terminal.

At this time, the air supply differential pressure sensor 282a included in the controller 280a installed on the upper layer 6F of the fire generating layer 5F generates a fire detected by the pair of first interlayer pressure pipes 270b. The differential pressure between the floor 5F and the fire generating layer 5F of the upper layer 6F is sensed, and the controller 280a installed on the fire layer 5F on the upper layer 6F of the fire generating layer 5F detects the differential pressure and the current detected pressure. The opening degree of the air supply damper 250a is controlled by driving the air supply damper driver 260a according to a result of comparing a predetermined air supply reference differential pressure.

In this way, when the opening degree of the air supply damper 250a provided in the upper layer 6F of the fire generating layer 5F is controlled, the pressure of the upper layer 6F of the fire generating layer 5F is reduced to that of the fire generating layer 5F. The air supply amount can be controlled to a predetermined range so as to be higher than the pressure and lower than the pressure of the auxiliary chamber 112 of the upper layer 6F.

In addition, at this time, the controller 280a installed in the lower layer 4F of the fire generating layer 5F may include an air supply differential pressure sensor installed in the fire generating layer 5F connected to the pair of second interlayer pressure pipes 270c. The air supply damper driving unit 260a is driven according to a result of comparing the pressure difference between the fire generating layer 5F sensed by 282a and the lower layer 4F of the fire generating layer 5F with a predetermined supply differential pressure difference. The opening degree of the air supply damper 250a is controlled.

As such, when the opening degree of the air supply damper 250a provided in the lower layer 4F of the fire generating layer 5F is controlled, the pressure of the lower layer 4F of the fire generating layer 5F is reduced to that of the fire generating layer 5F. The air supply amount can be controlled in a predetermined range so as to be higher than the pressure and lower than the pressure of the auxiliary chamber 112 of the lower layer 4F.

Therefore, the air supply flow is maintained intact from each of the accessory chambers 112 of the upper layer 6F and the lower layer 4F, respectively, to the upper layer 6F and the lower layer 4F. Can be prevented from spreading to the upper layer 6F and the lower layer 4F.

The above-described layered ventilation system according to the present invention is not limited to the above-described embodiments, and those skilled in the art to which the present invention pertains without departing from the gist of the present invention claimed in the following claims. The technical spirit is to the extent that various changes can be made.

100: building ventilation system 110: blower
111: blowing line 112: attached room
113: air supply damper 200,200a: interlayer ventilation system
210, 210a: exhaust fan 211, 211a: exhaust line
220,220a: exhaust damper 230,230a: exhaust damper drive unit
241,241a: Air supply line 240,240a: Air supply blower
250, 250a: Air supply damper 260, 260a: Air supply damper drive unit
270: interlayer pressure pipe 270a: barrier between pressure pipe
270b: first interlayer pressure pipe 270c: second interlayer pressure pipe
280,280a: Controller 281,281a: Exhaust differential pressure sensor
282,282a: Air supply differential pressure sensor 300,300a: Flame retardant barrier

Claims (10)

An exhaust blower 210 for discharging the bet to the outside through the exhaust line 211 installed in each floor of the building;
An exhaust damper 220 installed in each floor exhaust line 211 to adjust an exhaust volume of the corresponding floor;
An exhaust damper driver 230 installed at each floor to control an opening degree of the exhaust damper 220 of the corresponding floor;
An air supply fan 240 for supplying outside air to each floor through an air supply line 241 installed at each floor of the building;
An air supply damper 250 installed in each floor air supply line 241 to adjust the air supply of the floor;
An air supply damper driver 260 installed on each floor to control an opening degree of the air supply damper 250 of the corresponding floor;
If the floor is installed, and the floor is a fire-generating layer, the fire-generating layer is operated in pairs with other interlayer pressure guiding pipes 270 installed on the non-fire-generating layer two or more away from the fire generating layer. Interlayer pressure pipe 270 for detecting the pressure of the fire and non-fired layer; And
If the floor is installed by floor, and the floor is a fire generating layer, two or more fires generated above or below the fire generating layer detected by the exhaust pressure difference sensor 281 connected to the pair of interlayer pressure pipes 270 are not generated. According to the result of comparing the differential pressure with the floor to the predetermined reference differential pressure for exhaust, the exhaust damper driver 230 is driven to control the opening degree of the exhaust damper 220, so that all of the flame-retardant barriers 300 disposed on the fire generating layer are controlled. A controller 280 for controlling the displacement to a predetermined range so as to maintain the differential pressure of the inner pack below a predetermined maximum differential pressure that can be maintained below a predetermined minimum opening force at a value at which an ordinary person can open the flameproof barrier;
An interlayer ventilation system, characterized in that consisting of. The method of claim 1, wherein the controller 280 is
If the floor is installed on the floor, and the floor is the upper floor of the fire generating layer, the fire non-occurring layer different from the upper floor detected by the air supply pressure sensor 282 connected to the pair of interlayer pressure pipes 270, that is, the fire The air supply damper driving unit 260 is driven according to a result of comparing the differential pressure between the generating layer and the fire non-generating layer except the upper layer of the fire generating layer and the non-fire generating layer except the lower layer of the fire generating layer. By controlling the opening degree of the damper 250, the air supply amount is controlled in a predetermined range so as to maintain the pressure of the upper layer of the fire generating layer higher than the pressure of the fire generating layer and lower than the pressure of the auxiliary chamber 112 of the upper layer. Interlayer ventilation system. The method of claim 1, wherein the controller 280 is
If the floor is installed by floor, and the floor is a floor directly below the fire generating floor, the fire floor other than the floor directly detected by the air supply pressure sensor 282 connected to the pair of interlayer pressure pipes 270, that is, the fire The air supply damper driving unit 260 is driven according to a result of comparing the differential pressure between the generating layer and the fire non-generating layer except the upper layer of the fire generating layer and the non-fire generating layer except the lower layer of the fire generating layer. By controlling the opening degree of the damper 250, the air supply amount is controlled in a predetermined range so as to maintain the pressure of the lower layer of the fire generating layer higher than the pressure of the fire generating layer and lower than the pressure of the auxiliary chamber 112 of the lower layer. Interlayer ventilation system. 4. The controller of claim 2 or 3, wherein the controller 280
Interlayer ventilation system, characterized in that to operate by receiving the output signal of the controller 280 installed in the fire generating floor. An exhaust blower 210a for discharging the bet to the outside through the exhaust line 211a installed in each floor of the building;
An exhaust damper 220a installed in each floor exhaust line 211a to adjust an exhaust volume of the corresponding floor;
An exhaust damper driver 230a installed at each floor to control an opening degree of the exhaust damper 220a of the corresponding floor;
An air supply blower 240a for supplying outside air to each floor through an air supply line 241a installed at each floor of the building;
An air supply damper 250a installed in each floor air supply line 241a to control the air supply of the floor;
An air supply damper driver 260a installed on each floor to control an opening degree of the air supply damper 250a of the corresponding floor;
Among the at least one flame retardant barrier 300,300a disposed on each floor of the building, it is installed in the inner flank of the reference flame retardant barrier 300a that requires the maximum opening force in the event of a fire, A pair of barrier barrier pressure vessels 270a for sensing pressure;
Installed on each floor except the top floor of the building, and if the floor is a fire-generating floor, it operates in pairs with another first interlayer pressure pipe 270b installed on the upper floor of the fire-generating floor, and the fire-generating floor and the upper floor. A first interlayer pressure pipe 270b for detecting a pressure of the first interlayer pressure pipe 270b;
Installed on each floor except the lowest floor of the building, and if the floor is a fire-generating floor, it operates in pairs with another second inter-layer pressure pipe 270c installed on the lower floor of the fire-generating floor to operate the fire-producing floor and the lower floor. A second interlayer pressure pipe 270c for detecting a pressure of the second interlayer pressure pipe 270c; And
If the floor is installed in each floor and the floor is a fire-generating floor, the exhaust pressure of the inner space of the reference flame-retardant barrier 300a detected by the exhaust pressure difference sensor 281a connected to the pair of barrier pressure pipes 270a is exhausted. By controlling the opening degree of the exhaust damper 220a by driving the exhaust damper driver 230a according to the result compared with the reference differential pressure, the inner pressure of all the flame-retardant barriers 300 and 300a arranged in the fire generating layer is normal. A controller 280a for controlling the displacement to a predetermined range so as to keep the flame retardant barrier below a predetermined maximum differential pressure which can be maintained at a value below a predetermined minimum opening force;
An interlayer ventilation system, characterized in that consisting of. The method of claim 1 or 5, wherein the controller (280, 280a)
The minimum opening force is 110N or less, and the maximum differential pressure is 80Pa or less to control the displacement amount to a predetermined range, characterized in that. The method of claim 5, wherein the controller (280a)
Fire is detected by the air supply differential pressure sensor 282a installed on each floor and installed on the upper floor of the fire generating layer connected to the pair of first interlayer pressure pipes 270b when the floor is directly above the fire generating layer. The air supply damper driver 260a is driven to control the opening degree of the air supply damper 250a according to a result of comparing the pressure difference between the floor and the upper layer of the fire generating layer with a predetermined standard pressure difference for supplying air, thereby controlling the opening degree of the air supply damper 250a. The air supply amount is controlled in a predetermined range so as to maintain the pressure of the fire generating layer higher than the pressure of the fire generating layer and lower than the pressure of the upper chamber 112 of the upper layer. 8. The method of claim 7, wherein the controller 280a
An interlayer ventilation system characterized in that it operates by receiving the output signal of the controller (280a) installed in the fire generating floor. The method of claim 5, wherein the controller (280a)
The fire generating layer and the fire detected by the air supply differential pressure sensor 282a installed in the fire generating layer connected to the pair of second interlayer pressure pipes 270c if the corresponding floor is installed below the fire generating layer. According to a result of comparing the differential pressure with the lower layer of the generation layer to the predetermined reference differential pressure for supplying air, the air supply damper driving unit 260a is driven to control the opening degree of the air supply damper 250a to control the pressure of the lower layer of the fire generating layer. And an air supply amount is controlled within a predetermined range so as to maintain a pressure higher than a pressure of a fire generating layer and lower than a pressure of an auxiliary chamber 112 of the lower floor. 10. The controller of claim 9, wherein the controller 280a
The differential pressure between the fire generating layer detected by the air supply differential pressure sensor 282a connected to the pair of second interlayer pressure pipes 270c and the lower layer of the fire generating layer is transmitted from the controller 280a installed in the fire generating layer. Receiving floor system, characterized in that the operation.

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