KR102089216B1 - Building against fire with flame-retardant and heat-shielded room - Google Patents

Abstract

According to the present invention, a building comprises: a double firewall (100, 200) arranged to separate an evacuation space (10) and an indoor fire space and including a first firewall (100) adjacent to the evacuation space (10) and a second firewall (300) adjacent to the indoor fire space; a first fire door (200) pivotally installed to block a first door hole formed in the first firewall (100) and opening toward the evacuation space (10); a second fire door (400) pivotally installed to block a second door hole formed in the second firewall (300) and opening toward the indoor fire space; an intermediate enclosed space (90) formed between the first firewall (100) on which the first fire door (200) is closed and the second firewall (300) on which the second fire door (400) is closed; a gas supply unit (500) supplying gas to each of the intermediate enclosed space (90) and the evacuation space (10) to increase the pressure of the intermediate enclosed space (90) and the pressure of the evacuation space (10); a cooling water supply unit (600) cooling at least the first fire door (200) with cooling water; a fire detection unit (71) detecting a fire in the indoor fire space; a fire door detection unit (72) detecting closing of the first fire door (200) after opening thereof; and a control unit (73) operating the gas supply unit (500) and the cooling water supply unit (600) when the fire detection unit (71) detects a fire, and the fire door detection unit (72) detects closing of the first fire door (200) after opening thereof. Therefore, the building can protect people from smoke, flames, and high heat when a fire occurs.

Description

Building against fire with flame-retardant and heat-shielded room

The present invention relates to a fire-preparing building, and more particularly, to a fire-preparing building having a heat shield and a flame-retardant space.

When a fire occurs in a building, flames, smoke, and toxic gases spread rapidly enough that people living in the building do not have time to evacuate outside. According to statistics, after about 6 minutes of fire, the oxygen concentration decreases to 15% and in the case of carbon monoxide, which is a risk of suffocation, it increases to 7600 ppm. These levels are not only rapid breathing, increased pulse rate and dizziness, but also a very dangerous situation that can lead to death after 15 minutes or more. Carbon monoxide moves to other upper floors in a short time through stairs as well as a fire space.

In particular, in high-rise buildings such as apartment houses, it is difficult for people located above the fire to escape from the building through a corridor or emergency stairs. Accordingly, evacuation equipment is being developed one after another. The descending ladder for evacuation routes is a type in which the ladder automatically opens when the lid is opened. After installation, a large number of evacuation equipment installed on the window frame can be descended by pulling on the safety line after boarding. There is also a fire evacuation device that opens to open the door and creates an evacuation space.

However, these evacuation mechanisms have a disadvantage in that they are complicated in use and have poor accessibility in case of an emergency fire and focus on vertical evacuation. Vertical evacuation has limited access to behaviorally limited people with disabilities. For this reason, high-rise buildings are provided with evacuation spaces on the same floor where people can evacuate in the event of a fire. However, most evacuation spaces have limitations in blocking flames, and there are still limitations in protecting people from smoke and high heat. In order to protect people from smoke and toxic gases flowing into the evacuation space, a technique is used to inject air into the evacuation space to increase the pressure in the evacuation space and thereby prevent smoke from the fire space from entering the evacuation space. . However, there is a limit to rapidly increasing the pressure in the evacuation space. In particular, the evacuation space should be arranged in an area in contact with the outside air, and thus, an increase in pressure in the evacuation space through the inflow of external air may not be effective. In addition, due to deformation due to high heat, the fire door may not be able to withstand the fire, and the wall or the floor in the evacuation space is thermally connected to the floor or the wall of the fire space, and thus a situation in which the high temperature cannot be withdrawn occurs.

Therefore, there is a need for a structure having a heat shield and a flame-proof evacuation space that can protect a person from smoke, flame, and high heat in a fire.

The problem to be solved by the present invention is to provide a building having a heat shield and a flameproof evacuation space that can protect a person from smoke, flame and high heat in the event of a fire.

The building according to one aspect of the present invention is arranged to divide the space between the evacuation space 10 and the indoor fire space, the first firewall 100 adjacent to the evacuation space 10 and the second adjacent to the indoor fire space Double firewall (100, 200) consisting of a firewall (300); A first fire door 200 which is rotatably installed to block the first door hole formed in the first firewall 100 and opens toward the evacuation space 10; A second fire door 400 which is rotatably installed to block the second door hole formed in the second firewall 300 and opens toward the indoor fire space; An intermediate enclosed space 90 formed between the first firewall 100 in which the first fire door 200 is closed and the second firewall 300 in which the second fire door 400 is closed; A gas supply unit 500 supplying gas to each of the intermediate enclosed space 90 and the evacuation space 10 to increase the pressure of the intermediate enclosed space 90 and the pressure of the evacuated space 10; A cooling water supply unit 600 provided to cool at least the first fire door 200 with cooling water; A fire detector 71 for detecting the fire in the indoor fire space; A fire door detection unit 72 that detects the opening and closing of the first fire door 200; And when the fire detection unit 71 detects a fire and the fire door detection unit 72 detects the opening and closing of the first fire door 200, activates the gas supply unit 500 and supplies the cooling water. It includes a control unit 73 for operating the unit 600, the evacuation space 10, the first window 80 communicating with the evacuation space 10, and the second window 90 communicating with the indoor fire space The first outer wall 30, the second outer wall 40 orthogonal to the first outer wall 30, the inner wall 50 orthogonal to the second outer wall 40, and the double firewall 100 , 300), the upper and lower portions of the evacuation space 10 are blocked by the ceiling wall 70 and the bottom wall 60, and the first surface is external to the first outer wall 30. The flame propagation prevention wall 32 that blocks between the window 80 and the second window 82 is elongated in the vertical direction, and the gas supply unit 500 is a top The main gas supply nozzle 518 installed between the first firewall 100 and the second firewall 300 and installed in the interior wall 50 into the intermediate enclosed space 90 and the interior wall 50 Alternatively, the main gas connected between the gas supply source 501 and the main gas supply nozzle 518 and an auxiliary gas supply nozzle 528 introduced into the evacuation space 10 while being installed in the first firewall 100. It includes a supply line 510 and an auxiliary gas supply line 520 branched from the main gas supply line 510 and connected to the auxiliary gas supply nozzle 528, wherein the main gas supply line 510 and the Gas flow control valves 503 and 504 are installed in each of the auxiliary gas supply lines 520.

According to an embodiment, the cooling water supply unit 600 includes a cooling water supply line 610 connected to a water supply line 8, a cooler 601 for cooling cooling water flowing through the cooling water supply line 610, and the It is buried in the bottom wall 60 and passes through the cooler 601 to flow cooling water cooled to a certain temperature or less, and is connected to the bottom pipe line 612 through a bottom connector 603. The firewall piping line 614 embedded in the first firewall 100 and the uppermost piping line of the firewall piping line 614 are connected to the top of the door hole in which the first fire door 200 is closed. The first fire door 200 includes a plurality of coolant injection pipes 616 for spraying coolant to the top, and the bottom connector 603 is connected to the firewall piping line 614 on the first firewall ( 100) and the bottom wall (60) Located.

According to one embodiment, the evacuation platform 34 further connected to the flame propagation barrier 32 and horizontally extended to below the first window 80 is further included, and the evacuation platform 34 includes evacuation An opening is formed, an opening and closing cover 36 is installed to cover the opening for evacuation, and the cooling water supply unit 600 includes a cooling water supply line 610 connected to a water supply line 8 and the cooling water supply line ( 610) a cooler 601 for cooling the cooling water flowing through the coolant, which is buried in the bottom wall 60 of the evacuation space 10, and passes through the cooler 601 to cool water cooled to a predetermined temperature or less. A bottom piping line 614 having a bottom connector 603a, a second bottom connector 603b, and a third bottom connector 603c at a boundary between the bottom wall 60 and the first firewall 100; The first firewall 100 is embedded in the first floor connector 603a, the second floor connector 603b, and the third floor cover The first firewall piping line 614a, the second firewall piping line 614b, and the third firewall piping line 614c connected to the connector 603c include the first firewall piping line 614a. 1 A plurality of first coolant injection pipes 616a for spraying coolant to the top of the fire door 200 are connected, and the second firewall pipe line 614b injects coolant to one side of the first fire door 200 A plurality of second cooling water injection pipes 616b are connected, and the third firewall piping line 614c includes a plurality of third cooling water injection pipes 616c that inject cooling water to the other side of the first fire door 200 Are connected.

According to the present invention, in the event of a fire, there is provided a structure having a heat shield and a flame evacuation space that can protect a person from smoke, flame and high heat.

The various working effects and advantages of the present invention will be better understood from the following description of the examples.

1 is a perspective cross-sectional perspective view showing one of several floors of a fire-preparing building having a heat- and flame-retardant evacuation space according to an embodiment of the present invention,
FIG. 2 is an enlarged view of a virtual line rectangle “A” of FIG. 1,
FIG. 3 is a plan cross-sectional view showing the evacuation space shown in FIG. 2, which is a diagram showing a floor piping line pattern indicated by an imaginary line and an air supply unit and a cooling water supply unit together;
FIG. 4 is a front view showing the main firewall and the main fire door, and is a diagram showing the cooling water piping line embedded in the bottom of the evacuation space and the cooling water piping line embedded in the main firewall and spraying water to the top of the main fire door in dotted lines. ,
5 is a block diagram for explaining a system for making the evacuation space shown in FIG. 1 into a flameproof and heat shielding space
6 is a view for explaining another embodiment of the present invention,
7 is a view for explaining another embodiment of the present invention,
8 is a view for explaining another embodiment of the present invention.

Note that for all embodiments disclosed herein, any structure, material, step, or feature may constitute other embodiments along with any structure, material, step, or other feature of other embodiments that are part of the present invention. do. Note that the detailed description and related drawings do not limit or define the protection scope of the present invention. The protection scope of the present invention is defined by the claims.

1 is a perspective cross-sectional perspective view showing one of several layers of a fire-preparing building having a heat- and flame-retardant evacuation space according to an embodiment of the present invention, and FIG. 2 is an enlarged imaginary square "A" of FIG. FIG. 3 is a plan cross-sectional view showing the evacuation space shown in FIG. 2, and is a diagram showing a floor piping line pattern indicated by a virtual line and an air supply unit and a cooling water supply unit together, and FIG. 4 is a main As a front view showing the firewall and the main fire door, it is a diagram showing the cooling water piping line buried in the bottom of the evacuation space and the cooling water piping line embedded in the main firewall and spraying water to the top of the main fire door. 1 is a configuration diagram for explaining a system for making the evacuation space shown in FIG.

1 to 5, the building includes layers of a general four-bay structure including a first bedroom 1, a kitchen and living room 2, a second bedroom 3, a third bedroom 4, and the like. It consists of an ordinary apartment structure. Note that this structure is only an example.

According to this embodiment, a balcony space 20 and an evacuation space 10, which are indoor non-evacuation spaces, are arranged between the first exterior wall 30 and the first bedroom 1 in which windows facing directly to the outside air are formed. . A balcony door 21 is installed between the first bedroom 1 and the balcony space 20.

 In addition, the balcony space 20 is disposed to be adjacent to the evacuation space 10 with a double firewall including the first firewall 100 and the second firewall 300 parallel to each other. The evacuation space 10 includes a first outer wall 30 in a lateral direction, a second outer wall 40 orthogonal to the first outer wall 30, and orthogonal to the second outer wall 40. And the inner wall 50 facing the first bedroom 1 and surrounded by the double firewalls 100 and 300, and the upper and lower portions are blocked by a ceiling wall 70 and a floor wall 60. The first outer wall 30, the second outer wall 40, the inner wall 50, the double firewall (100, 200), the ceiling wall 70 and the bottom wall 60 are flames in case of fire It is formed of a material that can withstand.

In this embodiment, the first outer wall 30 is a first window 80 communicating with the evacuation space 10 and a balcony space 20 which is an indoor space (or fire space) adjacent to the evacuation space. 2 A window 82 is formed. In the event of a fire, the flame spreads from bottom to top. In the above process, the flame and smoke from the second window 82 can be propagated to the evacuation space 10 through the first window 80. In this embodiment, the outer surface of the first outer wall 30 is prevented from propagating such flame and smoke to the evacuation space 10 through the second window 82 and the first window 80. In addition, the flame propagation prevention wall 32 that blocks between the first window 80 and the second window 82 is elongated in the vertical direction.

The first firewall 100 is formed with a rectangular first door hole, and the first fire door 200 is rotatably installed by a first hinge to open and close the first door hole. A second rectangular door hole is formed in the second firewall 300, and a second fire door 400 is rotatably installed by a second hinge to open and close the second door hole. The first fire door 200 is disposed in contact with the evacuation space 10 and is configured to open toward the evacuation space 10. In addition, the second fire door 400 is configured to open toward the direction opposite to the direction in which the first fire door 200 is opened, that is, toward the balcony space 20. Therefore, when the second fire door 400 is opened, it may not be disturbed by the first fire door 200 or the first firewall 100. At this time, the second fire door 400 is configured to automatically close, for example, by a damper or a spring when the handle is released after opening. This prevents the evacuator from closing the second fire door 400 in the absence of a situation.

When the first fire door 200 is closed, an airtight structure is formed between the edge of the first fire door 200 and the first firewall 100 to reduce the gap between them. In addition, when the second fire door 400 is closed, a closed structure is formed between the edge of the second fire door 400 and the second firewall 300 to reduce the gap between them.

Between the first firewall 100 in which the first fire door 200 is closed and the second firewall 300 in which the second fire door 400 is closed, an intermediate enclosed space 90 in which the front, rear, left, and right are blocked is formed. do. According to this embodiment, the building includes a gas supply unit 500 that supplies gas into the intermediate enclosed space 90 to increase the pressure in the intermediate enclosed space 90. By the gas supply into the intermediate enclosed space 90 by the gas supply unit 500, the pressure in the intermediate enclosed space 90 increases, and accordingly, the pressure from the relatively low fire space. It is possible to suppress the introduction of smoke or toxic gas into the high intermediate closed space 90 side. Additionally, the gas supply unit 500 may supply gas into the evacuation space 10 to increase the pressure in the evacuation space 10. At this time, it is preferable that the gas to be supplied is air.

In this embodiment, the gas supply unit 500 is installed in the interior wall 50 between the first firewall 100 and the second firewall 300, the main gas introduced into the intermediate enclosed space 90 It includes a supply nozzle 518 and an auxiliary gas supply nozzle 528 introduced into the evacuation space 10 while being installed in the interior wall 50 or the first firewall 100.

In addition, the gas supply unit 500 includes a gas supply source 501, a main gas supply line 510 connecting between the gas supply source 501 and the main gas supply nozzle 518, and the main gas supply line And an auxiliary gas supply line 520 branched from 510 and connected to the auxiliary gas supply nozzle 528. A valve element that selectively opens and closes at least one of the main gas supply line 510 and the auxiliary gas supply line 520 at a point where the auxiliary gas supply line 520 branches from the main gas supply line 510. 502) may be installed. Gas flow control valves 503 and 504 are respectively installed in each of the main gas supply line 510 and the auxiliary gas supply line 520.

If the intermediate airtight space 90 is excessively large, it takes a long time to increase the pressure in the airtight space 90 despite the gas supply by the gas supply unit 500, so the evacuation space 10 volume It is preferable that it is made smaller than about 1/3 of. In addition, the interval between the first firewall 100 and the second firewall 300 of the intermediate enclosed space 90 does not exceed 5 times the thickness of the first firewall 100 or the second firewall 300 It is desirable to make it as small as possible.

On the other hand, the building according to the present embodiment is a cooling water supply unit for cooling the bottom wall 60 of the evacuation space 10 and the first firewall 100 in order to inject cooling water to the first fire door 200 ( 600). The cooling water supply unit 600 includes a cooling water supply line 610 connected to a water supply line 8, a cooler 601 for further cooling the cooling water flowing through the cooling water supply line 610, and the evacuation space 10. The floor piping line 612 is buried in a predetermined pattern on the bottom wall 60 of the cooling water flowing through the cooler 601 to a predetermined temperature or less, and the floor piping line 612 through the floor connector 603 ) And the first firewall 100 is buried in a predetermined pattern of the firewall piping line 614 and the uppermost piping line of the firewall piping line 614 is connected to the first fire door 200 and the closed door hole of the door hole. It is formed to be connected to the upper portion of the first fire door 200 includes a plurality of coolant injection pipes 616 for spraying coolant to the top.

On the other hand, the bottom connector 603, as well shown in Figure 4, the surface connected to the firewall piping line 614 is located at the boundary between the first firewall 100 and the bottom wall 60 It is desirable to do. This makes it possible to easily connect the firewall piping line 614 to the bottom wall connector 603 when installing the first firewall 100 on the bottom wall 60.

Referring back to FIGS. 1 to 5, in the event of a fire, heat transferred to the bottom wall 60 of the evacuation space 10 by heat conduction may cause serious burns to the soles of the evacuees evacuated to the evacuation space 10. , According to the present embodiment, since the cooling water flows through the bottom pipe line 612 to cool the bottom wall 60, excessive temperature rise of the bottom wall 60 can be prevented. In addition, since the coolant passes through the firewall piping line 614, the temperature of the first firewall 100 is lowered, so that radiant heat from the first firewall 100 can be reduced. 10) to help withstand.

Cooling water sprayed to the top of the first fire door 200 through the plurality of coolant injection pipes 616 suppresses deformation due to heat of the first fire door 200, while the first fire door 200 and the agent 1 By forming a water film that closes the gap between the firewalls 100, it also contributes to suppressing smoke or toxic gases from entering the evacuation space 10.

In this embodiment, the first fire door 200 positioned relatively closer to the evacuator is cooled by using cooling water, but the same or similar configuration may be applied to cool the second fire door 400 with cooling water, if necessary. Note that you can.

5, the building according to the present embodiment is a fire detection unit 71 installed at an arbitrary location in the building, and a fire door detection unit 72 that detects closing after opening of the first fire door 200 ), When the fire detection unit 71 detects a fire, and when the fire door detection unit 72 detects the opening and closing of the first fire door 200, activates the gas supply unit 500 and It includes a control unit 73 for operating the cooling water supply unit 600. The control unit 73 drives a gas supply source, such as a blower fan or a compressor, for operation of the gas supply unit 500, and simultaneously extends into an intermediate enclosed space 90 (see FIGS. 2 and 3). Gas flow control valves 503 and 504 installed in the gas supply line 510 (see FIG. 4) and the auxiliary gas supply line 510 (see FIG. 4) extending into the evacuation space 10 (see FIGS. 2 and 3). 4). In addition, the control unit 73 is connected to the control unit 1000 installed in the guard room or the fire station by wired or wireless communication, and when the fire is detected by the fire detection unit 71 and the fire detection unit 71 When both the fire detection and the detection by the fire door detection unit 72 are present, these states may be provided to the control unit 1000 with different signals.

In addition, the control unit 73 opens the on-off valve 611 installed in the cooling water supply line 610 for the operation of the cooling water supply unit 600. In addition, a temperature sensor may be further provided to measure the temperature of the water flowing through the cooling water supply line 610 or to be supplied to the cooling water supply line 610, wherein the controller 73 has a temperature of the water equal to or higher than a reference temperature. In this case, by operating the cooler 601, the coolant temperature supplied through the coolant supply line 610 may be lowered below a reference temperature.

In this embodiment, the elements used for control, such as the control unit 73, the fire detection unit 71, and the fire door detection unit 72, may be damaged by the fire and may not function properly, but the elements are normally only in the early stage of the fire. As it may be operated, it is not a problem in performing the above-described control.

6 is a view for explaining another embodiment of the present invention.

Referring to FIG. 6, the building according to the present embodiment has a first window 80 connected to an evacuation space 10 on the first outer wall 30 and a balcony space 20 which is a fire space adjacent to the evacuation space 10. And a second window 82 is formed. In addition, to prevent flame and smoke from propagating to the evacuation space 10 through the second window 82 and the first window 80, the first surface of the first outer wall 30 is prevented. The flame propagation prevention wall 32 that blocks between the window 80 and the second window 82 is elongated in the vertical direction.

In the present embodiment, the building further includes a platform 34 for evacuation horizontally extending below the first window 80 while being connected to the flame prevention wall 32. An evacuation opening is formed in the evacuation platform 34, and a retractable cover 36 is installed to cover the evacuation opening. In addition, one end of an expandable ladder is fixed to the inner surface of the evacuation opening. Therefore, evacuees can use the ladder to evacuate to an evacuation platform (not shown) provided on the lower floor (not shown).

The rest of the configuration is substantially the same as the previous embodiment, so further description is omitted.

7 is a view for explaining another embodiment of the present invention.

Referring to FIG. 7, the floor piping line 612 includes a first floor connector 603a, a second floor connector 603b, and a third floor connector 603c with the bottom wall 60 and the first firewall 100. Shall be provided at the boundary of. In addition, the first firewall pipe line 614a, the second firewall pipe line 614b, and the third firewall pipe line 614c are embedded in the first firewall 100. In addition, a plurality of first coolant spray pipes 616a for spraying coolant to the top of the first fire door 200 are connected to the first firewall pipe line 614a, and the second firewall pipe line 614b includes a first 1 A plurality of second cooling water injection pipes 616b for spraying cooling water to one side of the fire door 200 are connected, and the third firewall piping line 614c sprays cooling water to the other side of the first fire door 200 A number of the third coolant injection pipe (616c) is connected. The cooling water sprayed from the first cooling water spray pipes 616a forms a water film in a gap between the top of the first fire door 200 and the first firewall 100, and the second cooling water spray pipes 616b The cooling water sprayed from the field forms a water film in the gap between one side of the first fire door 200 and the first firewall 100, and the cooling water sprayed from the third cooling water spray pipes 616c 1 A water film is formed in a gap between the other side of the fire door 200 and the first firewall 100. The gap between the bottom of the first fire door 200 and the bottom wall 60 is closed by a water film by cooling water dropped on the bottom wall 60.

The rest of the configuration is substantially the same as the previous embodiments, so further description is omitted.

8 is a view for explaining another embodiment of the present invention.

As shown in FIG. 8, the building according to the present embodiment includes a fire detection unit 71 installed at an arbitrary location in the building, and a fire door detection unit 72 that detects the opening and closing of the first fire door 200. Wow, when the fire detection unit 71 detects a fire, and when the fire door detection unit 72 detects the opening and closing of the first fire door 20, the gas supply unit 500 is operated and the It includes a control unit 73 for operating the cooling water supply unit 600. The control unit 73 opens the on-off valve 611 installed in the cooling water supply line 610 for the operation of the cooling water supply unit 600. In addition, a temperature sensor may be further provided to measure the temperature of the water flowing through the cooling water supply line 610 or to be supplied to the cooling water supply line 610, wherein the controller 73 has a temperature of the water equal to or higher than a reference temperature. In this case, by operating the cooler 601, the coolant temperature supplied through the coolant supply line 610 may be lowered below a reference temperature.

According to this embodiment, the cooling water supply line 610 is branched into a first cooling line 610a and a second cooling line 610b, and the first cooling line 610a is a bottom wall 600 and a first It is configured to inject coolant to the top of the first fire door 200 through the firewall 100 through the end coolant spray tubes 616A. In addition, the second cooling line 610b injects cooling water to the top of the first fire door 200 through the cooling water injection pipes 616B at the end without passing through the bottom wall. The second cooling line 616 sprays cooling water to the first fire door 200 while minimizing the contact area with the first firewall without going through the bottom wall. Depending on the environment or the progress of the fire, if one or both of the first cooling line 610A and the second cooling line 610B are properly used, the evacuation space is more effectively protected from flame, smoke and heat generated during a fire. can do.

The rest of the configuration is substantially the same as the previous embodiments, so further description is omitted.

10: evacuation space 100: first firewall
200: first fire door 300: second firewall
400: second fire door 90: middle closed space
500: gas supply unit 600: cooling water supply unit
71: fire detection unit 72: fire door detection unit
73: control

Claims (3)

Each floor of the plurality of floors includes a balcony space 20 and an evacuation space 10 adjacent to the balcony space 20, wherein the balcony space 20 and the evacuation space 10 are windows facing the outside air directly. They are disposed between the first outer wall 30 and the first bedroom 1 in which they are formed, a balcony door 21 is installed between the first bedroom 1 and the balcony space 20 and the first outer wall In (30), in the high-rise building having a first window (80) communicating with the evacuation space (10) and a second window (82) communicating with the balcony space (20),
The first firewall 100 adjacent to the evacuation space 10 and the second firewall 300 adjacent to the balcony space 20 are arranged to separate the evacuation space 10 and the balcony space 20. Double firewall consisting of (100, 200);
A first fire door 200 which is rotatably installed to close the first door hole formed in the first firewall 100 and always opens toward the evacuation space 10;
The second door is formed to be rotatable so as to close the second door hole formed in the second firewall 300, and always opens toward the balcony space 20. After opening, the second is automatically closed even if a person is not closed by a damper or spring. Fire door 400;
An intermediate enclosed space 90 formed between the first firewall 100 in which the first fire door 200 is closed and the second firewall 300 in which the second fire door 400 is closed;
A gas supply unit 500 supplying gas to each of the intermediate enclosed space 90 and the evacuation space 10 to increase the pressure of the intermediate enclosed space 90 and the pressure of the evacuated space 10;
A cooling water supply unit 600 provided to cool at least the first fire door 200 with cooling water;
A fire detection unit 71 for detecting a fire in the indoor space through the balcony space 20;
A fire door detection unit 72 that detects the opening and closing of the first fire door 200; And
When the fire detection unit 71 detects a fire, and when the fire door detection unit 72 detects the opening and closing of the first fire door 200, the gas supply unit 500 is operated and the cooling water It includes a control unit 73 for operating the supply unit 600,
The evacuation space 10 includes a second outer wall 40 orthogonal to the first outer wall 30, an inner wall 50 orthogonal to the second outer wall 40, and the double firewalls 100 and 300. Surrounded by,
The upper and lower portions of the evacuation space 10 are blocked by the ceiling wall 70 and the bottom wall 60,
On the outer surface of the first outer wall 30, a flame propagation prevention wall 32 that blocks between the first window 80 and the second window 82 is elongated in the vertical direction.
The gas supply unit 500,
A main gas supply nozzle 518 installed between the first firewall 100 and the second firewall 300 into the interior wall 50 and introduced into the intermediate enclosed space 90;
An auxiliary gas supply nozzle 528 introduced into the evacuation space 10 while being installed on the interior wall 50 or the first firewall 100,
A main gas supply line 510 connecting between the gas supply source 501 and the main gas supply nozzle 518,
And an auxiliary gas supply line 520 branched from the main gas supply line 510 and connected to the auxiliary gas supply nozzle 528,
And gas flow control valves 503 and 504 installed in the main gas supply line 510 and the auxiliary gas supply line 520, respectively.
The cooling water supply unit 600,
A cooling water supply line 610 connected to the water supply line 8,
Cooler 601 for cooling the cooling water flowing in the cooling water supply line 610,
A bottom piping line 612 which is embedded in the bottom wall 60 and flows through the cooler 601 to cool water cooled below a certain temperature;
A firewall piping line 614 connected to the floor piping line 612 through a floor connector 603 and embedded in the first firewall 100;
A plurality of cooling water components that are connected to the uppermost piping line of the firewall piping line 614 and formed so as to extend to the upper portion of the closed door hole of the first fire door 200. Includes officers 616,
The floor connector 603 is a building characterized in that the surface connected to the firewall pipe line 614 is located at the boundary between the first firewall 100 and the floor wall (60). delete Each floor of the plurality of floors includes a balcony space 20 and an evacuation space 10 adjacent to the balcony space, wherein the balcony space 20 and the evacuation space 10 are formed with windows that directly face outside air. 1 is disposed between the outer wall 30 and the first bedroom 1, a balcony door 21 is installed between the bedroom 1 and the balcony space 20, and the first outer wall 30 has the In the high-rise building having a first window (80) communicating with the evacuation space (10) and a second window (82) communicating with the balcony space (20),
The first firewall 100 adjacent to the evacuation space 10 and the second firewall 300 adjacent to the balcony space 20 are arranged to separate the evacuation space 10 and the balcony space 20. Double firewall consisting of (100, 200);
A first fire door 200 which is rotatably installed to close the first door hole formed in the first firewall 100 and always opens toward the evacuation space 10;
The second door is formed to be rotatable so as to close the second door hole formed in the second firewall 300, and always opens toward the balcony space 20. After opening, the second is automatically closed even if a person is not closed by a damper or spring. Fire door 400;
An intermediate enclosed space 90 formed between the first firewall 100 in which the first fire door 200 is closed and the second firewall 300 in which the second fire door 400 is closed;
A gas supply unit 500 supplying gas to each of the intermediate enclosed space 90 and the evacuation space 10 to increase the pressure of the intermediate enclosed space 90 and the pressure of the evacuated space 10;
A cooling water supply unit 600 provided to cool at least the first fire door 200 with cooling water;
A fire detection unit 71 for detecting a fire in the indoor space through the balcony space 20;
A fire door detection unit 72 that detects the opening and closing of the first fire door 200; And
When the fire detection unit 71 detects a fire, and when the fire door detection unit 72 detects the opening and closing of the first fire door 200, the gas supply unit 500 is operated and the cooling water It includes a control unit 73 for operating the supply unit 600,
The evacuation space 10 includes a second outer wall 40 orthogonal to the first outer wall 30, an inner wall 50 orthogonal to the second outer wall 40, and the double firewalls 100 and 300. Surrounded by,
The upper and lower portions of the evacuation space 10 are blocked by the ceiling wall 70 and the bottom wall 60,
A flame propagation prevention wall 32 blocking the first window 80 and the second window 82 is formed on the outer surface of the first outer wall 30 in the vertical direction,
The evacuation platform 34 is horizontally extended to below the first window 80 while being connected to the flame prevention wall 32,
The gas supply unit 500,
A main gas supply nozzle 518 installed between the first firewall 100 and the second firewall 300 into the interior wall 50 and introduced into the intermediate enclosed space 90;
An auxiliary gas supply nozzle 528 introduced into the evacuation space 10 while being installed on the interior wall 50 or the first firewall 100,
A main gas supply line 510 connecting between the gas supply source 501 and the main gas supply nozzle 518,
And an auxiliary gas supply line 520 branched from the main gas supply line 510 and connected to the auxiliary gas supply nozzle 528,
And gas flow control valves 503 and 504 installed in the main gas supply line 510 and the auxiliary gas supply line 520, respectively.
An evacuation opening is formed in the evacuation platform 34, and a retractable cover 36 is installed to cover the evacuation opening,
The cooling water supply unit 600 includes a cooling water supply line 610 connected to a water supply line 8, a cooler 601 for cooling the cooling water flowing through the cooling water supply line 610, and an evacuation space 10. Cooling water that is buried in the bottom wall 60 and cooled to a predetermined temperature or less after passing through the cooler 601 flows, the first bottom connector 603a, the second bottom connector 603b, and the third bottom connector 603c A floor piping line 614 provided at a boundary between the bottom wall 60 and the first firewall 100, a first floor connector 603a buried in the first firewall 100, and a second floor A first firewall piping line 614a, a second firewall piping line 614b and a third firewall piping line 614c connected to the connector 603b and the third floor connector 603c, wherein the first firewall piping A plurality of first coolant injection pipes 616a for spraying coolant to the top of the first fire door 200 are connected to the line 614a. In addition, a plurality of second coolant injection pipes 616b for spraying coolant to one side of the first fire door 200 are connected to the second firewall pipe line 614b, and the third firewall pipe line 614c In the building, characterized in that a plurality of third cooling water injection pipe (616c) for spraying cooling water to the other side of the first fire door (200) is connected.

Images