KR20220018789A - Damper to prevent overpressure and negative pressure in the protection area - Google Patents

Abstract

The present invention relates to a damper installed on an air circulation duct or a side wall of a fire extinguishing gas discharge area to prevent overpressure and negative pressure caused by the expansion of gas pressure therein. More specifically, an artesian damper includes: a square frame comprising a vertical frame and a horizontal frame so as to be installable on an air blowing duct or a side wall of a building forming a protection area; a plurality of main wings installed on a vertical line to be opened and closed by internal pressure between upper and lower brackets in the square frame; and sub wings installed on the plurality of main wings, which are installed between the upper and lower brackets, respectively to introduce air from the outside when negative pressure is produced within the protection area. The artesian damper of the present invention can automatically control overpressure and negative pressure in the protection area through its simple composition.

Description

Damper to prevent overpressure and negative pressure in the protection area

The present invention relates to a damper installed on a side wall or an air circulation duct of a fire extinguishing gas discharge area to prevent internal overpressure and negative pressure (negative pressure), and more particularly, a fire protection area by fire extinguishing gas radiated to the protection area in case of fire. When overpressure occurs due to excessive air pressure in the protection area, the air in the protection area is discharged to the outside to protect people and facilities. It is related to the overpressure and negative pressure prevention damper of the protection area to prevent negative pressure by allowing the air of the protection area to automatically flow into the protection area.

In the case of a fire, it is common to extinguish a fire by spraying water or foam with an extinguishing agent, but when extinguishing a fire by spraying water, expensive equipment or facilities are lost. Fire is extinguished by spraying extinguishing gas.

In other words, facilities that use extinguishing gas include places with dense electrical facilities such as electrical rooms, substations, power generation rooms, and power storage rooms, document storage rooms, libraries, computer rooms, communication facilities, etc. In places where expensive assets such as museums are stored or exhibited, or places where flammable liquids or dangerous substances are stored, gas-based fire extinguishing facilities are provided to extinguish fires in case of fire.

At this time, the gas used in the fire extinguishing facility is installed in a high-pressure container that stores inert gas such as carbon dioxide, nitrogen, argon, and liquefied extinguishing gas such as Halon and halogen compounds. It is open to extinguish the fire in the protected area.

Gas-based fire extinguishing equipment is equipped with means to block the inflow of outside air, such as a fire shutter or automatic closing device, which blocks the inflow of outside air into the protection area in case of a fire, and extinguishes the fire by spraying fire extinguishing gas into the protection area.

The extinguishing gas of gas-based fire extinguishing equipment increases the specific gravity of inert gas in the air and lowers the oxygen concentration in the air to extinguish the fire by suffocation, and the extinguishing gas of halogen compounds cools the surroundings to extinguish the fire.

At this time, if a fire occurs in a communication facility, etc. and fire extinguishing gas is sprayed, the fire is extinguished by gas. have.

In addition, in the electrical room, substation room, power generation room, power storage room, document storage room, library, computer room, communication facility, museum, painting room, etc., the negative pressure in the room is caused by the pressure difference due to the instantaneous cooling action when some halogenated chemicals are emitted. As this occurs, a negative pressure blocking damper must be installed for the purpose of introducing external air, but there is a problem in that a damper that can be shared between the supply air damper and the negative pressure prevention damper is not provided.

Looking at the prior art in this field, as shown in FIG.

In the pressure damper of a gas-based fire extinguishing system having a plurality of opening and closing blades for opening and closing the inner space of a rectangular frame, rectangular moving holes are formed in pairs to face each other on the left and right side panels of the rectangular frame, and each opening and closing blade is assembled horizontally and rotatably on the inside of the left and right side panels of the rectangular frame, and is rotatably assembled and fixed on the outside of the left and right side panels of the rectangular frame, so that the A plurality of connecting members that transmit operating force in both directions and an overpressure operation/restoration in which each connecting member is commonly assembled so that it can rotate by forming a plurality of eccentric holes that are installed upright on the outside of the left and right side panels of the rectangular frame By providing a bidirectional damper for gas-based fire-fighting equipment equipped with a support member, each opening/closing blade moves horizontally or self-rotates at the same time by overpressure or negative pressure in the protection area to automatically open the inner space of the square frame and release the overpressure or negative pressure A configuration has been disclosed so that the inner space of the square frame can be automatically closed without power by automatically returning by the self-weight of each opening/closing blade or the overpressure operation/restoration support member.

In the prior art of FIG. 1, when a certain level of negative pressure generated on the front surface of the square frame 10 is applied to the opening and closing blades 20 when negative pressure is generated, each opening and closing blade uses each blade support shaft as an operating axis to be individually and freely. When the opening and closing blades 20 are opened and the negative pressure is released by the opening, each opening and closing blade that can be rotated freely by each blade support shaft is quickly and automatically returned by its own weight, so that each opening and closing blade 20 can be closed, so that the liquid fire extinguishing agent Even if negative pressure is generated due to instantaneous temperature drop in the protection area due to the release of a large amount of liquid extinguishing agent in the early stage of extinguishing from a gas-based fire extinguishing facility that emits It can be seen that it is possible to achieve an instantaneous pressure equilibrium within the protection area.

The prior art of FIG. 1 relates to a bidirectional pressure damper of a gas-based fire extinguishing system, and the opening and closing blades 20 are installed inside the rectangular frame 10, and the opening and closing blades are the front blades 21 and the rear blades 22. The front and rear wings are configured to be opened and closed around the wing support shaft installed in the moving hole.

That is, in the prior art of FIG. 1, a plurality of rear wings 22 are installed in close contact with the wing support shaft 23 in a vertical line, and the front wings are installed on the front side, but the upper bent portion 21a of the front wings is the rear wing ( 22) It is caught on the wing support shaft of the central part, and the lower bent part 21b of the front wing is installed to be located between the upper part of the rear wing and the wing support shaft located in the lower part through the point where the rear wing and the rear wing correspond.

Since the upper bent part 21a of the front wing is connected to the wing support shaft 23, when fire extinguishing gas is sprayed in a room that is a protection area, even if internal pressure is initially generated, the internal pressure is in contact with the entire front wing. Since the area of the front wing is formed larger than the contact area of the rear wing, the front wing pushes the lower part of the wing support shaft of the rear wing, and the upper part of the rear wing is caught by the closing stopper and is not opened. When high pressure is generated in the wing, the eccentric pressure is generated at the moment when the wing support shaft moves along the moving hole by the pressurization of the rear wing and the front wing according to the internal pressure, and the opening and closing wing is opened to discharge the internal overpressure to the outside. Also, when negative pressure (negative pressure) is generated in the room, when the external pressure presses the rear wing, the rear wing is pushed around the wing support shaft of the inner front wing. However, fire disaster prevention facilities including overpressure dampers do not operate frequently, but are prepared for a fire that occurs once every few years or decades. The configuration in which the wing support shaft is moved along the moving hole by the joint-shaped actuating bar connected to the first body, the second body, and the bent part by As the wing support shaft cannot move along the moving hole, the damper under pressure cannot open and close, so there is a problem in that the facilities inside the room are destroyed.

In other words, if dust and foreign matter accumulates on the connection part of the shaft over a long period of time, foreign substances such as dust remain on the rotating shaft of the joint-type actuating bar and rust occurs. If the movement fails, the opening and closing blades cannot be opened, so even if there is no fire damage, there is a problem in that the internal facilities are destroyed or lost due to the internal pressure of the extinguishing gas.

Republic of Korea Patent Publication No. 10-1423989

The present invention is to solve the above problems, and the present invention is a place where electrical facilities such as an electric room, a substation room, a power generation room, and a power storage room that use extinguishing gas in case of a fire are dense, or a document storage room that cannot be recovered when wet with water , libraries, computer rooms, communication facilities, etc., and by installing auxiliary wings on the main wings of overpressure dampers (pressure dampers) installed in museums that store or exhibit valuable cultural assets and treasures, they are formed to open and close in the opposite direction to the opening and closing direction of the main wings. When internal pressure is generated by spraying fire extinguishing gas, the main wing and auxiliary wing are automatically opened when combined to lower the internal pressure of the disaster prevention area. The purpose of this is to keep the pressure inside the protection area from being negative pressure by allowing outside air to flow in.

The present invention is a means for achieving the above object, and a rectangular frame consisting of a vertical frame and a horizontal frame so as to be installed on the side wall or the ventilation duct of a building forming a protection area,

a plurality of main wings installed in a vertical line to enable opening and closing by internal pressure between the inner upper and lower brackets of the square frame;

It is characterized in that it is formed as a damper under pressure including: an auxiliary wing that is installed on a plurality of main wings installed between the upper and lower brackets, respectively, so that external air can flow when a negative pressure is generated in the protection area.

In the vertical frames on both sides of the square frame, the main blades, which are opened and closed by the internal pressure of the protection zone, are not opened more than a certain angle, and when opened, the guide shafts installed in the main blade shaft holes on both sides of the main blade are guided through the first guide holes in the vertical frames on both sides. It is characterized in that it is formed.

Bearing shafts are coupled to both sides of the second guide hole integrally formed on the bottom surface of the main wing shaft hole, and bearings are fitted to the bearing shafts on both sides and are respectively connected and fixed to shaft holes formed in the vertical panel.

The auxiliary wing is installed in the space of the main wing, connected to the auxiliary wing moving shaft and the auxiliary wing moving shaft hole fitted into the second guide hole on the side of the space, and integrally formed on the bottom surface of the auxiliary wing moving shaft hole in the shaft fitting groove The auxiliary wing shaft is fitted, and both ends of the auxiliary wing shaft are connected to the auxiliary wing shaft hole of the main wing.

The main wing and the auxiliary blade have a locking groove formed on the outer upper surface of the main wing shaft hole, and a locking protrusion is formed at the lower end of the main wing to fit into the locking groove, so that a plurality of main wings are installed in close contact with each other in a vertical line in a square frame. .

The main wing installed in the square frame is coupled to the main wing engaging groove located at the uppermost end and the upper bracket lower clamping portion, and the main wing lower engaging projection is coupled to the lower bracket upper engaging portion.

The auxiliary wing is characterized in that the lower end of the auxiliary wing is inserted into the lower step groove of the space of the main wing, and the auxiliary wing and the male wing are combined.

In the present invention as described above, when overpressure occurs due to the expansion of the air pressure in the protection area by the extinguishing gas emitted to the protection area in case of a fire, the overpressure gas in the protection area is discharged to the outside to protect the facilities, and the external air pressure It is designed to provide an overpressure and negative pressure prevention damper in the protection area to prevent negative pressure by automatically allowing outside air to flow into the protection area when the gas pressure in the protection area is lower and negative pressure is generated in the protection area.

The present invention relates to a place where electrical facilities such as an electrical room, a substation room, a power generation room, and a power storage room that use extinguishing gas in case of a fire are dense, or a document storage room, library, computer room, communication facility, etc. Auxiliary wings are installed on the main wings of the overpressure dampers (pressure dampers) installed in museums that store or exhibit. It has the effect of preventing damage to walls, etc. due to fire extinguishing gas,

In addition, the auxiliary wing installed on the main wing is opened to effectively block the negative pressure generated in the room by the cooling of the halogen compound drug emitted to the protection area, and external air flows into the protection area to reduce the negative pressure (negative pressure). has the effect of preventing

1 is a side view showing an open state of a wing showing a conventional bidirectional pressure-bearing damper.
Figure 2 is a perspective view showing a damper to be pressured to prevent overpressure and negative pressure of the present invention.
3 is a front view showing a damper to be pressured to prevent overpressure and negative pressure of the present invention.
Figure 4 is a partially separated perspective view showing the connection configuration of the vertical frame and the main wing of the damper to be pressed according to the present invention.
Figure 5 is a partial excerpted perspective view showing the connection configuration of the main wing and the auxiliary wing of the damper to be pressed according to the present invention.
Figure 6 is a coupling sectional view showing a state in which the main wing is installed in a vertical line inside the damper to be pressured of the present invention.
7 is a coupling cross-sectional view showing the main wing installed inside the damper to be pressed and the auxiliary wing installed in the space of the present invention.
8 is an exemplary view showing a state in which the main wing is opened when overpressure occurs in the pressure damper installed in the protection area as an embodiment according to the present invention.
9 is an exemplary view showing a state in which an auxiliary wing installed on the main wing is opened when a negative pressure is generated in the protection area as an embodiment according to the present invention, and external air is introduced.
10 is an exemplary view showing a state in which one main wing and an auxiliary wing are installed inside the damper to be pressed as another embodiment of the present invention.

The present invention makes it possible to extinguish a fire using gaseous extinguishing gas without using water when a fire occurs, and places where electrical facilities such as electrical rooms, substation rooms, power generation rooms, and storage rooms where water damage is a concern are dense, or water It relates to overpressure dampers (pressure dampers) installed in document storage rooms, libraries, computer rooms, communication facilities, etc., which cannot be recovered when wet with moisture, and museums that store or exhibit valuable cultural assets and treasures (hereinafter referred to as "protection areas").

Therefore, when a certain gas pressure is exceeded in the protection area by the extinguishing gas emitted to the protection area in case of a fire, the air in the protection area is discharged to the outside through the pressure damper to protect people and facilities. When negative pressure is generated in the protection area due to the low air pressure in the area, the external air is automatically introduced into the protection area through the pressure damper to prevent negative pressure.

Hereinafter, an embodiment will be described in detail based on the accompanying drawings of the present invention.

Figure 2 is a perspective view showing the damper to be overpressure and negative pressure prevention of the present invention, Figure 3 is a front view showing the damper to be pressured to prevent overpressure and negative pressure of the present invention, on the side wall of a building forming a protection area or a ventilation duct As for the damper to be installed, the horizontal frames 111 and 112 and the vertical frames 113 and 114 are combined to form a square frame 110 .

A plurality of main wings 200 are installed on a vertical line to enable opening and closing by internal pressure inside the rectangular frame 110 constituting the body of the damper to be pressured 100, and the main wings 200 are opened by negative pressure. The auxiliary wing 300 is installed.

The square frame 110 has an upper bracket 115 and a lower bracket 116 installed in the upper and lower parts of the interior, but a plurality of main wings 200 are disposed between the upper bracket 115 and the lower bracket 116 on a vertical line. Install them at a predetermined interval so that they can be installed.

In addition, a space 220 is formed in the main wing 200 installed between the upper bracket 115 and the lower bracket 116 , and the auxiliary wing 300 is installed, and the auxiliary wing 300 is the main wing. (200) is installed to open in the opposite direction to the opening direction.

The main wing 200 and the auxiliary wing 300 installed in this way are overpressured by the extinguishing gas in the protection area after extinguishing the fire with the gas pressure emitted during a fire. ), and the main wing 200 of the damper to be pressured 100 is opened to the outside by the pressure to release air, so that the pressure inside the protection area room is maintained in an appropriate state.

In addition, when negative pressure is applied inside the protection zone room, the auxiliary wing 300 installed in the space 220 of the main wing 200 is opened by external air pressure so that external air flows into the protection zone to maintain the initial pressure. do.

4 is a partially excerpted perspective view showing the connection configuration of the vertical frame and the main wing of the damper under pressure according to the present invention. As an example, in the main wing 200 of the present invention, a tubular main wing shaft hole 210 is formed at the upper end, and a second guide hole 211 is integrally formed at the bottom thereof.

Auxiliary wing shaft holes 212 are formed in the lower surface of the second guide hole 211 so that both ends of the auxiliary wing rotating shaft 330 are fitted.

A main wing 200 is formed at the bottom of the auxiliary wing shaft hole 212 , and a space 220 in which the auxiliary wing 300 is installed is formed in the central portion of the main wing 200 .

The main wing 200 has a locking groove 214 formed on the upper end of the outer surface of the main wing shaft hole 210, and the locking part 117 formed at the lower end of the upper bracket 115 or the main wing 200 located on the upper part of the lower locking stone The group 213 is formed to be fitted.

In addition, a stepped groove 221 is formed at the lower end of the space 220 of the main wing 200 so that the lower end of the auxiliary wing 300 installed in the space 220 is fitted.

The auxiliary wing 300 of the damper to be pressured 100 is installed in the space 220 of the main wing 200, and the auxiliary wing 300 is installed to open and close in the opposite direction to the opening and closing direction of the male wing 200.

Auxiliary blade moving shaft holes 311 are formed in the upper end of the auxiliary wing 200 , and auxiliary wing moving shafts 312 are fitted on both sides to fit into the second guide hole 211 of the main wing 200 .

The auxiliary wing 300 has a shaft fitting hole 313 integrally formed on the bottom surface of the auxiliary wing moving shaft hole 311, so that the auxiliary wing rotating shaft 330 is fitted, so that both ends are the main wing 200, space part 220, upper both sides It is fixed to the auxiliary wing shaft hole 212 formed in.

6 is a coupling cross-sectional view showing a state in which the main blade is installed in a vertical line inside the damper under pressure of the present invention, and FIG. 7 is a coupling showing the main blade installed inside the damper under pressure and the auxiliary damper installed in the main wing space of the present invention. It is a cross section.

The damper 100 of the present invention is connected and installed so that a plurality of main wings 200 are in close contact with each other on a vertical line inside the rectangular frame 110 .

The main wing 200 is installed between the upper and lower horizontal frames 111 and 112 as shown in FIG. 6, and the upper bracket 115 is welded to the inner bottom surface of the upper horizontal frame 111, and the lower frame 112. A lower bracket 116 is welded to the inside.

The main wing 200 is installed to correspond to the engaging groove 214 formed on the outer upper surface of the main wing shaft hole 210 in the lower engaging portion 117 of the upper bracket 115, the main wing of the main wing 200 The guide shaft 215 fitted on both sides of the shaft hole 210 is fitted into the first guide hole 120 formed in the vertical frames 113 and 114 .

At this time, the bearing shaft 217 is fixed to both ends of the main blade shaft hole 210 of the main blade 200 , and the bearing 216 is installed on the bearing shaft 217 , so that the shaft hole 121 of the vertical frames 113 and 114 is installed. ) is fixed to

In addition, as for the auxiliary wing 300 installed in the space 220 of the main wing 200, one end of the auxiliary wing moving shaft 312 is fitted into the upper auxiliary wing moving shaft hole 311 and fixed, and the other end is the main wing 200. It is inserted into the second guide hole 211 of the auxiliary wing 300 is installed to move when opening and closing.

At this time, the auxiliary wing 300 is rotated about the auxiliary wing rotating shaft 330 fitted in the shaft fitting hole 313 when opening and closing, and both ends of the auxiliary wing rotating shaft 330 are the space portion 220 of the main wing 200 upper It is fitted and fixed in the auxiliary wing shaft holes 212 formed on both sides.

The damper under pressure 100 of the present invention as described above is normally installed as shown in FIGS. 6 and 7 to maintain the closed state of the damper under pressure 100 .

The damper 100 of the present invention is normally a main wing 200, an upper bracket 115 and a lower bracket 116, a main wing 200 and a main wing 200, a main wing 200 and an auxiliary wing ( 300) maintains a close bonding state.

8 is an exemplary view showing a state in which the main wing is opened when the pressure damper installed in the protection area is overpressured as an embodiment according to the present invention, and FIG. 9 is an embodiment according to the present invention, an auxiliary installed on the main wing 200 It is an exemplary view showing a state in which the wing 300 is opened when a negative pressure is generated in the protection zone and external air is introduced.

In the present invention, when a fire occurs in the protection area, fire is extinguished using the extinguishing gas. In this case, even if the fire is extinguished, the protection area is in a state of overpressure by the heat from the fire and the extinguishing gas sprayed during extinguishing.

At this time, when more than the previous pressure occurs, the main wing 200 of the damper to be pressured 100 is pressurized by the pressure in the protection zone, so that the main wing 200 is the bearing shaft 217 and the vertical frames 113 and 114. It is rotated around the bearing 216 installed in the shaft hole 121 and opened while the guide shaft 215 fitted in the main wing shaft hole 210 at the top of the main wing 200 is moved along the first guide hole 211 and the main The wing 200 is opened as shown in FIG.

At this time, when the pressure in the protection zone is lowered by the opening of the main wing 200, the main wing 200 is returned to its original position by its own weight to close the damper to be pressured (100).

In addition, the present invention provides an electrical room, a substation room, a power generation room, a power storage room, a document storage room, a library, a computer room, a communication facility, a museum, a painting room, etc. (negative pressure) is generated, but also when the main wing 200 returns in the process of relieving the overpressure inside the room after extinguishing with the extinguishing gas, and the exhaust pump operates for a certain period of time with the damper under pressure 100 closed A negative pressure is generated inside the room. As such, when negative pressure is generated inside the room, the auxiliary wings 300 designed to open and close in the opposite direction to the main wings 200 are opened as shown in FIG. Let it be one pressure.

Specifically, when a negative pressure (negative pressure) is generated in the protection zone, the internal room pressure is weaker than the external pressure, so that the auxiliary wing 300 is pushed inward by the external air pressure and the space 220 is opened. .

At this time, when the auxiliary wing 300 is opened by external air pressure, the auxiliary wing 300 is opened around the auxiliary wing rotating shaft 330 fitted in the shaft fitting hole 313 , and the auxiliary wing moving shaft groove 311 is fitted and installed on both sides. The auxiliary wing moving shaft 312 moves to one side within the second guide groove 211 formed in the main wing 300 so that the auxiliary wing 300 opens the main wing 200 and the space 220 as shown in FIG. Allow outside air to flow in.

As described above, when the auxiliary wing 300 is opened and external air is introduced, the air pressure in the protection zone room in a negative pressure state becomes equal to the external air pressure and the initialization is maintained.

As such, in the damper 100 of the present invention, when overpressure is applied to the room of the protection zone, the main wing 200 is opened to discharge the air inside, and when negative pressure is applied to the room of the protection zone, the auxiliary wing 300 is It is opened and the outside air flows into the inside, so that the internal and external pressure is uniform, and the initialization before the fire is performed.

In addition, the main wing 200 and the auxiliary wing 300 of the present invention are automatically closed by their own weight when the pressure is lowered after opening. The main wing 200 or the auxiliary wing 300 is automatically operated by the pressure formed in the room.

10 is an exemplary view showing a state in which one main wing and an auxiliary wing are installed inside the damper under pressure as another embodiment of the present invention. Even if only one auxiliary wing 300 is installed, it is possible to eliminate overpressure and negative pressure.

In the present invention described above, as shown in FIGS. 2 to 9, the number of blades installed inside the damper 100 is not set to three, but one or two main blades depending on the volume area of the fire protection zone. Dogs, 3, 4, etc. can be selectively used, and the operation of the main wing 200 and the auxiliary wing 300 is the same as described above.

The present invention as described above is useful in places where electrical facilities such as electric rooms, substation rooms, power generation rooms, and power storage rooms that use extinguishing gas in case of fire are dense, or document storage rooms, libraries, computer rooms, communication facilities, etc. that cannot be recovered when wet with water, valuable Auxiliary wings are installed on the main wings of the overpressure dampers (pressure dampers) installed in museums that store or exhibit cultural assets and treasures. At the same time, the auxiliary wing is opened to effectively block the negative pressure generated in the room by the pressure difference of the cooling action when the drug is released from the protection area, and external air flows into the protection area to prevent negative pressure. has the effect of making it happen.

Therefore, the damper under pressure of the present invention can automatically adjust the overpressure and negative pressure of the protection zone with a simple configuration.

100: pressure damper 110; square frame
111, 112: horizontal frame 113, 114: vertical frame
115: upper bracket 116: lower bracket
117, 117': locking part 120: first guide hole
121: shaft 200: main wing
210: main wing shaft hole 211: second guide hole
212: auxiliary wing shaft hole 213: jamming projection
214: locking groove 215: guide shaft
216: bearing 217: bearing shaft
220: space 221: step groove
300: auxiliary wing
310: auxiliary blade shaft 311: auxiliary blade moving shaft hole
312: auxiliary wing moving shaft 313: shaft fitting groove
330: auxiliary wing rotation axis

Claims (7)

A rectangular frame 110 consisting of horizontal frames 111 and 112 and vertical frames 113 and 114 so as to be installed on the side walls or ventilation ducts of buildings forming a protection zone,
a plurality of main wings 200 installed in a vertical line to enable opening and closing by internal pressure between the inner upper bracket 115 and the lower bracket 116 of the square frame 110;
Auxiliary blades 300 that are respectively installed on the main wings 200 that are installed between the upper bracket 115 and the lower bracket 116 so that external air can be introduced when a negative pressure occurs in the protection area: Containing Overpressure and negative pressure prevention damper of the protection area, characterized in that formed of the pressure damper (100). The method of claim 1,
The main wing 200, which is opened and closed by the internal pressure of the protection zone, is not opened at a predetermined angle or more in the square frame 110 of the damper to be pressured 100, and the main wing shaft hole 210 on both sides of the main wing 200 when opened. The overpressure and negative pressure prevention damper of the protection area, characterized in that the first guide holes 120 are formed in the vertical frames 113 and 114 on both sides to guide the guide shaft 215 installed in the . The method of claim 1,
A bearing shaft 217 is coupled to both sides of the second guide hole 211 integrally formed on the bottom surface of the main wing shaft hole 210, and a bearing 216 is fitted to the both sides of the bearing shaft 217 to fit a vertical panel 113 ( Overpressure and negative pressure prevention damper of the protection area, characterized in that each connected and fixed to the shaft hole 121 formed in 114). The method of claim 1,
The auxiliary wing 300 is installed in the space 220 of the main wing 200, the auxiliary wing moving shaft 312 and the auxiliary wing moving shaft fitted into the second guide hole 211 on the side of the space 220 Connected to the hole 311, the auxiliary wing shaft 310 is fitted into the shaft fitting groove 313 integrally formed on the bottom surface of the auxiliary wing moving shaft hole 311, and the auxiliary wing shaft 310 both ends are the main wing ( 200) of the auxiliary wing shaft hole 212 of the protection zone, characterized in that connected to the overpressure and negative pressure damper. The method of claim 1,
The main wing 200 and the auxiliary wing 300 have a locking groove 214 formed on the outer upper surface of the main wing shaft hole 210, and a locking protrusion ( 213) is formed and a plurality of main wings 200 are installed in close contact with each other in a vertical line in the rectangular frame 110. Overpressure and negative pressure prevention damper of the protection zone, characterized in that. The method of claim 1,
The main wing 200 installed in the square frame 110 is coupled with the engaging groove 214 of the main wing 200 located at the uppermost end and the lower engaging part 117 of the upper bracket 115, and the main wing ( 200) of the lower engaging projection 213 of the lower bracket 116, the upper end engaging portion 117', the protection zone, characterized in that the combined overpressure and negative pressure damper. The method of claim 1,
The auxiliary wing 300 is characterized in that the lower end of the auxiliary wing 300 is inserted into the space 220 of the main wing 200, and the lower stepped groove 221 is coupled to the auxiliary wing 300 and the mail wing 200. Damper to prevent overpressure and negative pressure in the protected area.

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