KR20180119838A - Thermal deformation prevention device of the fire door - Google Patents

Abstract

The present invention relates to an apparatus for preventing a firewall from being deformed due to heat. More specifically, the present invention is made to improve reliability of a product, especially, to pass a fire resistance performance test by blocking flames from being spouted toward the outside as the firewall is deformed by higher heat inside when a fire occurs. According to the present invention, the apparatus includes a firewall body (100) which has the shape of a door in a hollow structure, and is coupled to a door frame (200) by a hinge (300) such that the door frame (200) is open or closed. An inner part of the firewall body (100) is filled with an insulating material (150) in the state that an enhancement member (700) is fixedly attached to an inside of the frame member (110). The apparatus includes: a sleeve (500) fixed to an inner upper position of the door frame (200) and having a receiving space (510) in the state that a lower portion of the sleeve (500) is open; a melting member (520) filled in the sleeve (500) to be maintained in a solid state at a normal temperature and melted to leak to the outside of the sleeve (500) when higher heat is transmitted by the fire; a locking pin (530) received inside the sleeve (500) at the normal temperature in the state that the locking pin (530) is surrounded by the melting member (520) and dropped down when the melting member (520) is melted or separated by the fire; and a fixing pocket (540) mounted at a drop position of the locking pin (530) in the firewall body (100) such that a portion of a lower end of the locking pin (530) is fitted into the fixing pocket (540), supported, and locked between sleeves (500).

Description

TECHNICAL FIELD [0001] The present invention relates to a thermal deformation prevention device for a fire door,

More particularly, the present invention relates to an apparatus for preventing thermal deformation of a fire door, and more particularly, it relates to an apparatus for preventing thermal deformation of a fire door, It was invented to be able to pass.

Generally, fire doors made of iron plates are installed in the front of apartments, homes, offices, etc. in order to prevent the transmission of flames in the event of a fire.

1, a door frame 200 of a size that covers the exterior of the fire door main body 100 is fixed to a building and a hinge 300 is installed between the door frame 200 and one side of the fire door main body 100 .

A gasket member 400 may be provided at a contact portion between the door frame 200 and the fire door main body 100 for noise prevention, insulation, and buffering during opening and closing.

In addition, a gap is formed between the fire door main body 100 and the door frame 200 to facilitate opening and closing, and this gap may be blocked by a gasket 600 having a blade shape of a "T" cross section (FIG. 2)

Therefore, the gap between the fire door main body 100 and the door frame 200 is sealed by the gasket 600 and the gasket member 400 to block the gas from entering the room when the fire occurs, and the fire door main body 100 It is possible to prevent noise generated by colliding with the door frame 200 when the door frame 200 is closed, as well as to block the outside air and the inside air, thereby achieving an indoor heat insulation effect.

The reinforcement member 700 is fixed to the inner circumference of the fire door main body 100 mainly by welding or screws, and the insulator 150 is filled inside.

The heat insulating material 150 is formed of a binder of a synthetic resin type, and is adhered and fixed using an iron plate and an inorganic component bond.

Korea Patent Registration No. 10-0766199 (Registered on October 04, 2007) Korea Utility Model Registration No. 20-305989 (Registered February 18, 2003)

In the conventional fire door having the above-described construction, a heat insulating material is filled in the inside for the purpose of heat insulation, and the outside is entirely made of a metal plate material.

In the fire door main body 100 having such a structure, when the sealed room temperature becomes high in the event of a fire, the binder of the heat insulating material 150, which is firstly thermally deformed in the vertical direction and the left and right direction, is burnt, The torsion occurs at the portion where the strength is weakened at the same time as the expansion due to the pressure (Fig. 3).

The torsion phenomenon is particularly severe in the main body 100 of the fire door at the corner opposite to the hinge 300 than the portion where the hinge 300 is connected to the door frame 200.

At this time, since the inner side of the fire door main body 100 is in contact with the gasket member 400, a gap is formed between the door frames 200, and the flame is leaked to the outside together with the noxious gas, .

In order to solve these problems, it is stipulated that the fire safety gate does not deform or break even at a high temperature of more than 1000 degrees.

An object of the present invention is to provide a fire door capable of preventing the leakage of noxious gases and flames due to deformation due to high temperature caused by a fire, thereby improving the safety and reliability of the product.

Another object of the present invention is to provide a fire door which is suitable for safety regulations and can satisfy fire resistance performance.

In order to achieve the above object, according to the present invention, a hinge (300) is openably and closably connected to a door frame frame (200) in a hollow door shape, and a reinforcing member (700) In the fire door main body 100 in which the heat insulating material 150 is filled into the inside of the fire door main body 100 in a state where the heat insulating material 150 is fixedly attached,

A sleeve 500 fixed to the inside of the upper portion of the frame frame 200 and having a receiving space 510 formed in a lowered state,

A molten member 520 which is filled in the sleeve 500 and remains in a solid state at room temperature but is melted when the high temperature is transmitted by fire and flows out to the outside of the sleeve 500,

A locking pin 530 accommodated in the sleeve 500 at a normal temperature in a state of being wrapped around the molten member 520 and dropped by the load when the molten member 520 is melted and separated due to fire,

And a fixing pocket 540 which is installed at the dropping position of the locking pin 530 in the main body 100 of the fire door and which is supported by a part of the lower end of the locking pin 530 to be caught between the sleeves 500 .

Here, the molten member 520 includes a polyurethane resin or lead that melts at 100 degrees or more.

In addition, the sleeve 500 is formed in such a manner that the center of the sleeve 500 is convex to the outside, thereby preventing the molten member 520, which is filled in the accommodation space 510, from being separated or flowed at room temperature.

According to the present invention, when a high temperature is transmitted in a fire or fire resistance test, the molten member wrapping the locking pin is melted due to the high temperature, and the locking pin is dropped by the load to be caught between the fixing pocket and the sleeve to prevent the twist of the fire door do.

Therefore, a gap is formed between the fire door and the frame frame due to the twist, so that it is possible to prevent the flame and the harmful gas from leaking to the outside.

In addition, it conforms to the product safety regulations and can pass the fire resistance test, thereby improving the reliability and merchantability of the product.

1 is a front view of an installation state of a conventional fire door.
2 is an enlarged sectional view taken along the line AA in Fig.
3 is a cross-sectional view illustrating a state where the present invention is twisted due to high temperature;
4 is an enlarged cross-sectional view showing a state in which the present invention is installed normally.
5 is a cross-sectional view of a state in which the locking pin is locked and locked between a fire door and a frame frame by a fire.
6 is an enlarged cross-sectional view of the main part of Fig. 5;

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

4 to 6 show a structure of a device for preventing thermal deformation of a fire door to which the present invention is applied.

The fire door main body 100 has a hollow space therein, and the periphery thereof is closed by the frame member 110 while keeping the distance between the inner member and the outer member so as to have a total door shape.

The interior space of the fire door main body 100 is filled with the heat insulating material 150 in a state where the reinforcement member 700 is installed inside the frame member 110 to reinforce the strength.

The heat insulating material 150 is filled with a resin material having a good thermal insulation effect and is fixedly attached to the inner space of the fire door main body 100 in a state in which the mutually connected state is maintained by a synthetic resin binder.

The door framing frame 200 is fixed to the building and surrounds the exterior of the fireproofing door body 100. A hinge 300 is connected to one side of the door frame frame 100 for opening and closing the door.

The door frame frame 200 is provided with a gas-impermeable gasket member 400 for forming a concave groove portion to insulate between the fire door main bodies 100 and to provide airtightness and sound insulation.

A gap of about 3-5 mm is formed between the frame frame 200 and the fire door main body 100 for smooth opening and closing. Thus, a gasket 600 having a "T" So that the wing portion can block a gap formed between the fire door main body 100 and the door frame 200 to facilitate opening and closing.

Accordingly, the wings can prevent the door frames 200 and the fire door main body 100 from being connected to each other by metal, thereby achieving a dew condensation preventing effect. As a result, the indoor air and the outdoor air are completely blocked, It is possible.

Meanwhile, when a high temperature is transmitted by a fire, the locking pin 530 installed on the door frame 200 falls down due to the melting of the molten member 520, and the locking pin 530 is maintained in a locked state between the fire door main bodies 100 Thereby suppressing the torsion of the fire door.

The locking pin 530 is surrounded by a molten member 520 which is filled in the receiving space 510 of the sleeve 500 with a round or square bar made of a ferrous metal having excellent strength.

The sleeve 500 is rigidly fixed to the frame frame 200 by welding, and is made of a ferrous metal material. The receiving space 510 is downwardly inserted to accommodate the molten member 520 therein And is molded into a cap shape.

 A fixed pocket 540 is installed vertically downward in the fire door main body 100 at a position corresponding to the installation position of the sleeve 500.

The locking pockets 540 are formed in a state in which the locking pins 530 are inserted into the locking pockets 530 in a state in which the locking pockets 540 are top-shielded with a strong iron-based metal having high strength. However, it is preferable that a separate fixed pocket 540 is molded as shown in FIG. 6, and then fixed firmly by welding along the joint.

At this time, the fixed pocket 540 forms the warp guide portion 541 so that the locking pocket 530 can be received inside even if the position of the locking pin 530 does not coincide with the entrance portion.

Meanwhile, the molten material 520 which is melted and discharged to the outside of the sleeve 500 is filled in the inner housing space 510 of the sleeve 500 while maintaining a solid state at room temperature, when the high temperature is transmitted by the fire .

When the molten member 520 is heated to a high temperature to be filled with the locking pin 530 at the center of the accommodation space 510 and then cooled to room temperature, the locking pin 530 is moved to the molten member 520 The mounting state is maintained without being detached from the surrounding state.

When the shape of the sleeve 500 is formed to be convex to the outside, it is possible to prevent the solid molten member 520, which is filled in the accommodation space 510, from slipping off and moving away from each other at room temperature, The stability is improved.

Here, the molten member 520 includes a polyurethane resin or lead (Pb) that is solid at normal temperature and melts at a high temperature of 100 degrees or more.

The present invention maintains the distance from the inner side surface to such an extent that it does not come into contact with the door frame 200 when the fire door main body 100 is normally opened or closed (Fig. 4). Fig.

When a high temperature around 1000 degrees Celsius is transmitted to the indoor side by a fire or fire resistance test in a normal use state, the melted member 520 melts and is melted and discharged through the lower part of the accommodating space 510.

Then, the locking pin 530 falls down due to its own weight as soon as the molten member 520 which has been fixed is melted and discharged, and is accommodated in the fixing pocket 540 (Fig. 5). (Fig. 5)

Since the inclined guide portion 541 is formed at the entrance of the fixed pocket 540 even if the fire door main body 100 is partially twisted due to heat, the falling position of the locking pin 530 and the inclined guide portion 541 of the fixed pocket 540 Even if the centers are not coincident with each other, can be guided to be accommodated inside.

The upper end portion of the locking pin 530 is partially inserted into the sleeve 500 while the lower portion of the locking pin 530 is received in the fixing pocket 540. Therefore, the fire door main body 100 and the door frame 200 are locked with the locking pin 530, (Fig. 5 and Fig. 6). As a result, it is possible to prevent the expansion and twisting of the fire door main body 100 from being caused by the transmission of high heat after the fire door main body 100 is stretched due to thermal deformation.

When the torsion of the fire door main body 100 is prevented as described above, a gap is not generated between the door frame frames 200, and in particular, as a result that the gasket member 400 keeps a close contact state with the inner side surface of the fire door main body 100 This can help to prevent the indoor flames and harmful gases from leaking to the outside.

It is preferable that the locking pins 530 dropped by the melting of the molten member 520 are disposed at a predetermined interval between the upper surface of the fire door main body 100 and the door frame 200.

According to the present invention, it is possible to safely keep from a dangerous situation in which a fire range is spread.

In addition, fire resistance performance test can be passed.

The present invention is applied to a technique for preventing thermal deformation of an entrance fire door of an office or an apartment. Particularly, it is applied to a device for preventing thermal deformation that prevents the flame from leaking due to deformation and torsion of a fire door at a high temperature during a fire or fire resistance test.

100 - fire door main body 110 - frame member
111 - Screw hole 150 - Insulation
200 - Door Frames 300 - Hinges
400 - Gasket member 500 - Sleeve
510 - receiving space 520 - melt member
530 - Locking pin 540 - Locking pocket

Claims (3)

And a reinforcing member 700 fixed to the inside of the frame member 110 so that the reinforcing member 700 is fixed to the inside of the fire door main body 100 in a state in which the reinforcing member 700 is fixedly attached to the frame frame 200 by a hinge 300, In the main body 100 of the fire door where the heat insulating material 150 is filled,
A sleeve 500 fixed to the inside of the upper portion of the frame frame 200 and having a receiving space 510 formed in a lowered state,
A molten member 520 which is filled in the sleeve 500 and remains in a solid state at room temperature but is melted when the high temperature is transmitted by fire and flows out to the outside of the sleeve 500,
A locking pin 530 accommodated in the sleeve 500 at a normal temperature in a state of being wrapped around the molten member 520 and dropped by the load when the molten member 520 is melted and separated due to fire,
And a fixing pocket 540 which is installed at the dropping position of the locking pin 530 in the main body 100 of the fire door and which is supported by a part of the lower end of the locking pin 530 to be caught between the sleeves 500 Wherein the fire prevention door is provided with an opening for preventing thermal deformation of the fire door.
The apparatus of claim 1, wherein the molten member (520) comprises polyurethane resin or lead that melts at 100 degrees or more.
The sleeve (500) according to claim 1, wherein the sleeve (500) is shaped to be convex outward to prevent the molten member (520) filled in the accommodation space (510)
Wherein an inclined guide portion (541) is formed at an entrance of the stationary pocket (540).

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