KR20120116249A - Fireproof door and manufacturing method thereof - Google Patents

Abstract

PURPOSE: A fire door and a manufacturing method thereof are provided to simplify the process of manufacturing the fire door, and to offset the problem generated when intermediate goods are burned. CONSTITUTION: A method for manufacturing a fire door comprises following steps. A reinforcement frame(30) is formed on the space(21) in a back plate(20). A noncombustible shield plate(50) with a cushion is installed to form a noncombustible wall. Liquid filler is charted in the shield plate. The liquid filler is made of 60wt% of granules, 20wt% of water, and 20wt% of non-combustible adhesive. A front plate(10) is covered on the back plate, and the load of 30 ton is applied for five to ten minutes. The liquid filler is heated at 90~110°C, and the front plate is attached to the back plate. The edge coupling piece(11) of the front plate is connected to the coupled piece(22) of the edge of the back plate. [Reference numerals] (AA) Filler

Description

Fire door and its manufacturing method {FIREPROOF DOOR AND MANUFACTURING METHOD THEREOF}

TECHNICAL FIELD The present invention relates to a fire door and a method of manufacturing the same, which can minimize the strain due to fire, become more structurally robust, and are excellent in heat insulation and sound insulation.

In general, a metal fire door is constructed of a reinforcement frame around the inner surface of the front plate, and then a honeycomb-shaped intermediate material (usually 'honeycomb') with an adhesive applied to the entire inner surface of the front plate corresponding to the inside of the reinforced frame. The front and back plates and the intermediate material are bonded to each other by adhesive bonding, and then the joining pieces formed around the edges of the front plates are attached to the joined pieces formed on the edges of the back plates. It is completed by bending.

The use of such fire doors as doors to houses, apartments, offices, etc. can reduce the risk of loss of life and property by preventing the movement and spread of high-temperature flames and toxic gases (hereinafter referred to as 'flames') in the event of a fire. In order to achieve the above purpose, the front or rear of the fire door should not be deformed, even if exposed to a high temperature fire for a long time.

However, the fire doors up to now have high thermal conductivity between the front plate and the rear plate, and when high heat is applied to one side, the heat is rapidly transferred to the other side, and the conduction phenomenon causes the deformation of the front and rear plates, causing the movement of the flame / Caused diffusion. In other words, the flame is moved / diffused by air (oxygen), and the movement / diffusion is mostly performed through the gap between the fire door and the door frame. Therefore, if all or one of the front and rear plates of the fire door is deformed, the gap between the fire door and the door frame is widened to promote the movement / diffusion of the flame.

Prior arts for solving such problems include Korean Patent Registration No. 0966241, Utility Model Registration No. 0363578, Publication No. 2005-0116339 (hereinafter referred to as 'prior art 1') proposed by the applicant and inventor of the present application, and There is a patent registration No. 0982752 (hereinafter referred to as 'prior art 2').

Prior art 1 is to post a separate non-combustible airtight member between the fire door and the door frame or to make the bond between the door frame and the fire door to be firm in case of fire so that even if the fire door is deformed, the movement / spread of the flame is prevented.

However, in the prior art 1, when the fire door is exposed to high heat for a long time and thermal conduction is continuously performed, or when one side melts or melts, the function is lost. The room was insufficient.

Next, prior art 2 is a clay mineral made of aluminum-magnesium and iron hydroxide silicate on the core of the intermediate material placed between the front and rear plates of the fire door, and vermiculite powder widely used as heat-resistant material and soundproofing material or light weight. It is a building material mixed with concrete aggregate, asbestos, cement, etc. for concrete, and is filled with a filler of pearlite powder which is effective in fire, insulation, sound absorption, etc. , Soundproof, fireproof. However, vermiculite or pearlite in the prior art 2 has heat resistance, but the heat conduction blocking effect is extremely insignificant, and it is not possible to overcome the fire door deformation due to heat conduction in fire and the movement / diffusion of fire due to the deformation. Therefore, the prior art 2 may exert an effect such as heat insulation, but the closed end due to heat conduction has a problem that cannot be solved.

On the other hand, since the prior arts 1 and 2 together include the intermediate material of paper, the thermal conduction effect is maximized due to the combustion of the intermediate material in the fire, and the front and rear plates of the fire door are separated or separated due to the combustion of the intermediate material. Resulted. In particular, in the case of the prior art 2, when the intermediate material is combusted, the solidified filler is filled into the core of the intermediate material and separated into a plurality of hexagonal pillars (core type), as well as free flow after separation. Tilting due to free flow) contributed to the deformation of the fire door.

The present invention has been invented to solve the problems appearing in the conventional fire door, including the prior art 1,2, the main object of the present invention to block the thermal conductivity between the front and rear plates of the fire door to perform the function of the fire door completely in the fire It's about making it happen.

The secondary purpose is to remove the paper intermediate material between the front and rear plates of the fire door to offset the problems caused by the combustion of the intermediate material in the event of fire, and further, to simplify the manufacture of the fire door to achieve the above objectives to ensure the ease of manufacture.

In the fire door according to the present invention, the front and rear plates are coupled to each other by bending the coupling pieces around the edge of the front plate to the to-be-joined pieces of the edge of the rear plate, and the conventional fire doors have a reinforcement frame formed around the front and rear plates. In the above, the non-combustible membrane plate is partitioned inside the reinforcing frame forming an outer space between the front and rear plates, and the plate and the front plate by placing a plate containing the non-combustible grains of extremely low thermal conductivity in the space between the membrane plate It is characterized in that the back plate is bonded.

The manufacturing method for obtaining the above fire door, the conventional step of building a reinforcing frame around the inner surface of the back plate of the fire door; Installing a nonflammable barrier plate having a cushion inside the reinforcing frame; Filling a liquid filler in which the non-combustible particles (hereinafter referred to as 'non-conductive granules'), water, and liquid non-combustible adhesive are mixed at a predetermined ratio inside the membrane plate; Covering the front plate with the front plate and applying a constant load and temperature for a predetermined time so that the filler is cured while the filler and the front and rear plates are adhesively fixed; After the step is characterized in that it comprises a conventional step of bending the edge engaging piece of the front plate to the back plate border.

In the present invention, since a plate made of non-conductive granules is placed between the front and rear plates of the fire door, thermal conduction is not substantially conducted between the front and rear plates during the fire, so that even if one side of the fire door is exposed to high temperatures for a long time, the front and rear surfaces of the fire door are exposed. It is effective to block the movement / diffusion of flames due to the deformation of the plate, and even if the front plate or the back plate melts due to high heat, the mating surface is still strong and the position of the plate is not changed due to the strong mating surface (that is, fire door Since the shape is maintained as it is), it is possible to obtain a fire door that can completely block the movement / diffusion of the flame despite the melting of the front and rear plates.

On the other hand, in the present invention, since the filler, which is the raw material of the plate, mainly composed of non-conductive granules, is liquid, the filling of the filler is easy when the fire door is manufactured, so that the plate can be easily formed, and the solidification of the filler (plate) is combined with the front plate. When applying a certain load, temperature, and time, it is effective to make the solidification work more convenient. Furthermore, since the filler itself contains adhesive, the front and back plates and the board can be bonded during the solidification process of the filler without any additional work. There is a possible effect, and this effect also has the effect of simplifying the manufacture of fire doors that can achieve the purpose of fire protection perfectly.

In addition, since the present invention does not use a paper material different from the conventional fire door, it is possible to prevent the deformation of the fire door due to the combustion of the intermediate material in case of fire, and also because there is no core like the intermediate material in the plate, the effect of insulation and sound insulation is conventional. It is effective to obtain a fire door that is superior to a fire door.

1 is a cross-sectional view of the fire door of the present invention
Figure 2 is an illustration of a manufacturing method of the present invention.

When described in detail with reference to the accompanying drawings a preferred embodiment of the present invention. However, in the description of the present invention, the detailed description of the known technology and the conventional technology registered in advance may obscure the gist of the present invention and replace it with an omission or a simple name.

The present invention is formed by the appearance of a fire door (rectangular shape) by forming a space 21 therein and the back plate 20 is formed in the rim to be joined 22; A reinforcing frame (30) constructed on the space wall of the back plate; It is based on the conventional fire door made of the front plate 10 is covered with an upper portion of the back plate 20 and the coupling piece 11 around the edge is bent and coupled to the engagement piece 22 of the back plate 20.

Fire door according to the present invention is reinforced by partitioning the non-combustible barrier plate 50 having a cushion, such as glass fiber inside the reinforcing frame 30 forming the outer space between the front and rear plates 10, 20 of the conventional fire door. While removing the boundary gap between the reinforcing frame 30 and the diaphragm 50 while allowing a rectangular wall surface to be constructed inside the frame 30, a plate material 40 having non-conductive grains as a main component is formed in the rectangular diaphragm wall surface. By placing the plate 40 and the front and rear plates 10, 20 are bonded. In the above, the nonflammable barrier plate is not necessarily glass fiber because it is satisfied that there is a slight cushion together with the nonflammable function.

The fire door of the above configuration has a non-combustible barrier plate 50 inside the reinforcing frame 30, the non-conductive plate member 40 is configured inside the barrier plate 50, so that the front plate 10 or the back plate 20 Even if a high heat is applied to the heat shield, the heat can be prevented from being conducted to the other side. Also, the contents of the fire door (plate and membrane) are all non-combustible, so that combustion by high heat is prevented, so that the fire door loses form or rigidity. You can get over it. In addition, since the barrier plate 50 is made of a cushioned material so that the boundary gap between the barrier plate 50 and the reinforcing frame 30 can be removed, even if the rear plate 20 is melted, the toxic gas passes through the gap. This will prevent leakage in the opposite direction of the fire.

Fire door manufacturing method according to the invention, the conventional step of building a reinforcing frame 30 around the space 21 of the back plate 20 formed in the form of a fire door by using a press, such as a steel plate of a predetermined thickness;

Installing a non-combustible barrier plate (50) having a cushion inside the reinforcing frame (30) to implement a rectangular non-combustible wall surface;

Filling a liquid filler containing 60% by weight of non-conductive granules, 20% by weight of water, and 20% by weight of liquid incombustible adhesive inside the membrane plate 50;

Cover the front plate 10 on the back plate 20 and pressurize the load of 30 tons for 5 to 10 minutes, by applying heat of 90 ~ 110 ℃ to the front, back plate 10, 20 so that the filling solidifies While the front and back plates 10 and 20 are adhesively fixed;

After the step is to include a conventional step of bending the edge engaging piece 11 of the front plate 10 to the engaging piece 22 of the edge of the back plate 20.

In the method of manufacturing a fire door, the filling is filled in the space 21 of the rear plate 20, and then pressurized and heated to solidify the filler immediately into a plate shape, and to bond the front and rear plates 10 and 20 in the solidification process. Also, since the filling is made of 60% by weight of non-conductive granules, 20% by weight of water and 20% by weight of liquid incombustible adhesive, the product is a liquid having a certain viscosity (thick state), so that there is no fear of loss or leakage during filling. In addition, charging can also be facilitated.

Meanwhile, when the membrane plate 50 is constructed higher than the space of the rear plate 20 and the filler is filled in the membrane plate 50, the membrane plate 50 and the filler material are constructed as high as the cover plate 10 is pressurized. Because of this compression, the diaphragm 50 can more fully eliminate the gap between the diaphragm 50 and the reinforcement frame 30, and the filling material has a non-conductive grain particle density of the plate 40 when the filler is solidified. It can be increased to maximize the heat conduction effect. Here, the membrane plate 50 can be compressed because there is some degree of cushioning as noted.

When the present invention is completed as described above, the total weight of the fire door may be increased due to the plate of the filling, but the total weight of the fire door is unchanged since the plate may reduce the thickness of the front and rear plates and the reinforcement frame. I will be able to maintain. In addition, the non-conductive grains presented in the present invention may be any conventional materials having non-conductive functions, and thus are not specified in the present invention.

Although the present invention has been described in the above embodiments, those skilled in the art will be able to make various modifications and changes without departing from the spirit and scope described in the embodiments of the present invention.

10: front panel 11: joining piece
20: rear panel 21: space
22: to be joined 30: reinforcement frame
40: plate 50: membrane plate

Claims (4)

The front and rear plates 10 and 20 are coupled to each other by bending the coupling pieces 11 around the edges of the front plate 10 to the coupled pieces 22 of the edge of the rear plate 20. In the conventional fire doors so that the reinforcement frame 30 is configured around the (10) and (20),
The nonflammable barrier plate 50 is partitioned inside the reinforcing frame 30 forming an outer space between the front and rear plates 10 and 20, and thermal conductivity is extremely high in the space 21 between the membrane plates 50. A fire door comprising a plate (40) mainly composed of incombustible granules of non-combustible material, and the plate and the front and rear panels are bonded to each other.
A conventional step of constructing a reinforcement frame around an inner surface of the backplate of the fire door;
Installing a nonflammable barrier plate having a cushion inside the reinforcing frame;
Filling a liquid filler in which the non-combustible particles, water, and the liquid non-combustible adhesive are mixed at a predetermined ratio inside the membrane plate;
Covering the front plate with the front plate and applying a constant load and temperature for a predetermined time so that the filler is cured while the filler and the front and rear plates are adhesively fixed;
Fireproof door manufacturing method characterized in that it comprises a conventional step of bending the edge engaging piece of the front plate to the back plate border after the step.
The method of claim 2,
60 wt% of non-conductive granules with liquid filling; 20 wt% water; Fireproof door manufacturing method characterized in that 20% by weight of the liquid non-flammable adhesive.
The fire door according to claim 2, wherein the front plate is pressurized at a load of 30 tons for about 5 to 10 minutes, and heat is applied at 90 to 110 ° C. to the front and rear plates to solidify the filling.

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