KR102076448B1 - The fireproof door with excellent fire resistance and manufacturing method of the same - Google Patents

Abstract

Provided are a fire door having excellent fire resistance comprising: a door frame member; a door member mounted on the inside of the door frame member; and a hinge member connecting the door frame member and the door member, and a manufacturing method of the fire door. The door member includes: a door main body including plate-shaped front and rear frames positioned parallel to each other and inner frames forming side surfaces by being coupled to the ends of the front and rear frames; a door filler filled in the door main body to block heat transfer; and a front condensation preventing part positioned on one side or more of the front frame and a rear condensation preventing part positioned on one side or more of the rear frame. The front condensation preventing part and the rear condensation preventing part each have a condensation gasket absorbing moisture generated by condensation. Therefore, fire resistance can be improved by filling the door filler in the door main body.

Description

Fireproof door with excellent fire resistance and manufacturing method of the same}

The present invention relates to a fire door having excellent fire resistance and a method for manufacturing the same, and a condensation prevention part provided at the front or rear of the fire door to easily remove moisture generated by condensation on the surface of the fire door, and to a fire door having excellent fire resistance and a method of manufacturing the same. .

Fire doors are structures, such as entrance doors or emergency doors, installed at the entrances of houses, apartments, factories, offices, and prefabricated buildings to prevent the spread of flames and smoke behind them in the event of a fire. A fire door consists of a frame installed through a wall and a hinged door like a normal door, but it must be resistant to conditions such as combustion, melting, cracking, pyrolysis, explosion or deterioration even when exposed to fire. In addition, it should be provided with resistance to warpage so as to remain coupled to the door frame during exposure to strong heat to prevent the expansion of the damage range caused by fire.

In general, the fire door has a rubber packing between the indoor and outdoor frame members to adopt a method of blocking the outdoor temperature from entering the room. Conventional fire doors as described above can block the influence of the outdoor temperature to the interior through the rubber packing, but due to the temperature difference between the outdoor and indoor, condensation may occur in the fire door itself. That is, the fire doors and the frame are in contact with both the outdoor and the indoor. Therefore, if the temperature difference between the indoor and outdoor is severe, such as in winter, condensation may occur in the fire door and the frame contacting the indoor due to the temperature difference. have.

Water generated by condensation on the surface of the rubber packing may cause corrosion, and as a result, the rubber packing may be frequently damaged, thereby causing replacement and maintenance of the rubber packing, which is difficult to manufacture. Of course, maintenance costs may rise.

Korea Patent Registration No. 10-1892482 (Registration Date: 2018. 08. 22.) Korean Patent Publication No. 10-2019-0054322 (published: 2019. 05. 22.)

The technical problem to be achieved by the present invention, by bending the front frame and the rear frame in parallel to each other, by connecting and coupling them to the inner frame can be easily produced the door body, the door filler to block heat transfer to the space inside the door body An object of the present invention is to provide a fire door having excellent fire resistance and a method for manufacturing the same, which can be filled to improve fire resistance.

In addition, another technical problem to be achieved by the present invention is to provide a fire protection door excellent in fire resistance and a method of manufacturing the same to form a condensation prevention portion provided with a dew condensation gasket on the fire door to improve the removal rate of water generated by condensation. There is this.

Furthermore, another technical problem to be achieved by the present invention is to form a portion of the condensation gasket to expose the condensation gasket and moisture easily, and to form a condensation movement hole in the inner frame to move the moisture generated in the door body condensation An object of the present invention is to provide a fire door having excellent fire resistance and a method for manufacturing the same, which can be introduced into a condensation gasket through a ball.

The object of the present invention is not limited to the above-mentioned object, and other objects not mentioned will be clearly understood by those skilled in the art from the following description.

In order to solve the above problems, the present invention is a door door member, a door member seated on the inside of the door frame member and a fire door comprising a hinge member connecting the door frame member and the door member, the door member is positioned in parallel with each other A door body including a plate-shaped front frame and a rear frame, and an inner frame forming a side surface in combination with ends of the front frame and the rear frame; A door filler that is filled in the door body to block heat transfer; And a front condensation prevention unit positioned on at least one side of the front frame and a rear condensation prevention unit located on at least one side of the rear frame. The front condensation prevention unit and the rear condensation prevention unit include moisture generated by condensation. It is possible to provide a fire door having excellent fire resistance, comprising a condensation gasket for absorbing.

The condensation gasket may be interposed between the coupling region of the front frame and the inner frame or interposed between the coupling region of the rear frame and the inner frame.

The front condensation preventing part is provided with an end portion of the front frame bent inwardly in a 'c' shape, and one end of the inner frame is bent outward so as to be spaced in parallel to the inside of the bent piece of the front frame. The condensation gasket may be positioned in a space spaced between the bent piece of the front frame and one end of the inner frame.

The condensation gasket may be partially exposed to the outside of the door body to surround the bent end of the front frame and to contact the outer surface of the inner frame.

The front condensation prevention unit may include a front insulation pad in an inner space formed by bending the front frame, and a bent end of the inner frame may be located between the condensation gasket and the front insulation pad.

The back dew condensation prevention part is provided with an end of the rear frame bent in a 'c' shape inwardly of the door member, and the condensation gasket between the side protruding surface of the back frame due to the bending and the other end of the inner frame. Is interposed, one end surface of the condensation gasket may be exposed to the outside side by side with the outer surface of the rear frame.

The back dew condensation prevention part includes an end portion of the inner frame contacting the rear frame to surround the outer side of the bent surface of the rear frame, and is perpendicular to the condensation gasket between the bent piece of the rear frame and the end of the inner frame. The rear insulation pad can be located.

The inner frame has a condensation moving hole at a position corresponding to the side protruding surface of the rear frame, and moisture generated on the outer surface of the inner frame may move to the condensation gasket through the condensation moving hole.

In addition, in order to solve the above problems, the present invention comprises the steps of preparing a front frame and the rear frame of the plate; Forming a side by combining an inner frame with an end of the front frame and a rear frame to form a side, and filling a door filler to block heat transfer inside the door body to form a door member; Coupling the door frame member to the doorway; And manufacturing a fire door by connecting the door member by using a hinge member to be seated inside the door frame member, wherein the door member includes a front condensation preventing unit on at least one side of the front frame and the rear frame. Forming a rear condensation prevention unit, respectively, the front condensation prevention unit and the back condensation prevention unit may provide a method of manufacturing a fire-retardant excellent fire door characterized in that it comprises a condensation gasket for absorbing moisture generated by the condensation phenomenon.

The condensation gasket may be formed between the front frame and the inner frame, or may be formed by being coupled between the rear frame and the inner frame.

Forming the front condensation preventing portion, the end of the front frame is bent inwardly in the 'c' shape of the door member, bent one end of the inner frame in contact with the front frame is spaced inside the bent piece of the front frame And be positioned to be parallel to each other, and the condensation gasket may be seated in a space spaced between the bent piece of the front frame and one end of the inner frame.

The condensation gasket may be partially exposed to the outside of the door body to surround the bent end portion of the front frame and to contact the outer surface of the inner frame.

Forming the front condensation preventing unit may form a front insulation pad in an inner space in which the front frame is bent, and an end portion of the inner frame may be positioned between the condensation gasket and the front insulation pad.

Forming the rear condensation preventing portion is formed by bending the end of the rear frame in the 'c' shape inwardly of the door member, between the side protruding surface of the rear frame due to the bending and the other end of the inner frame The condensation gasket may be formed, but one end surface of the condensation gasket may be formed to be exposed to the outside in parallel with the outer surface of the rear frame.

Forming the rear condensation preventing portion, the end of the inner frame in contact with the rear frame wraps around the outer side of the bent surface of the rear frame, the back of the vertically perpendicular to the condensation gasket between the bent piece of the rear frame and the end of the inner frame An insulation pad can be formed.

The inner frame has a condensation moving hole formed at a position corresponding to the side protruding surface of the rear frame, and moisture generated on the outer surface of the inner frame may move to the condensation gasket through the condensation moving hole.

Fireproof door and a method of manufacturing the excellent fire resistance according to an embodiment of the present invention can be easily produced by the door frame by bending the front frame and the rear frame in parallel to each other and connecting them to the inner frame, the space inside the door body There is an advantage to improve the fire resistance by filling the door filler to block heat transfer.

In addition, by forming a condensation prevention gasket with a condensation gasket on the fire door, it is possible to improve the removal rate of water generated by condensation phenomenon, furthermore, it is formed so that a portion of the condensation gasket is exposed, it is possible to easily contact the condensation gasket and moisture, By forming a condensation moving hole in the inner frame, moisture generated in the door body can be introduced into the condensation gasket through the condensation moving hole.

1 is an exploded perspective view showing a coupling relationship of a fire door excellent in fire resistance according to an embodiment of the present invention,
2 is a cross-sectional view of a fire door excellent in fire resistance according to an embodiment of the present invention;
3 is a partially enlarged view illustrating a region A of FIG. 2;
4 is a partially enlarged view illustrating a region B of FIG. 2;
FIG. 5 is a partially enlarged view illustrating region C of FIG. 2.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. The embodiments described below are provided as examples to fully convey the spirit of the present invention to those skilled in the art. Accordingly, the invention is not limited to the embodiments described below and may be embodied in other forms. In the drawings, lengths, thicknesses, and the like of layers and regions may be exaggerated for convenience. Like numbers refer to like elements throughout the specification.

1 is an exploded perspective view showing a coupling relationship of a fire door excellent in fire resistance according to an embodiment of the present invention, Figure 2 is a cross-sectional view of the fire door excellent in fire resistance according to an embodiment of the present invention, Figure 3 is a portion showing a region of FIG. 4 is a partially enlarged view showing region B of FIG. 2 and FIG. 5 is a partially enlarged view showing region C of FIG.

1 to 5, the fire door excellent in fire resistance according to an embodiment of the present invention is the door frame member 10, the door member 20 and the door frame member 10 which is seated inside the door frame member 10 And a hinge member 30 connecting the door member 20 with the door member 20.

The door frame member 10 may be formed of a door frame body 110 having a rectangular frame shape attached to an inner circumferential surface of the doorway, and a door frame filler 130 which is filled in the inside to block heat transfer. One or more surfaces of the door frame body 110 may be provided with a flame-retardant gasket (not shown) of a material that does not burn, and the door member 20 is compressed to form a space that is sealed to the outside based on the fire door Can be.

The hinge member 30 is preferably adopted as a hinge structure of a general fire door.

  The door member 20 is coupled to the ends of the front frame 231 and the rear frame 233 and the front frame 231 and the rear frame 233 of the plate-shaped parallel to each other to form a side ( A door body 230 including 235 and a door filler 210 filled in the door body 230 to block heat transfer may be formed. Accordingly, the front frame 231 and the rear frame 233 are located in parallel with each other, and the door body 230 is easily connected by connecting and coupling the sides of the front frame 231 and the rear frame 233 to the inner frame 235. It is possible to manufacture, and to improve the fire resistance by filling the door filler 210 to block heat transfer in the space inside the door body 230.

The door member 20 may include a front condensation prevention part (B) located on at least one side of the front frame 231 and a rear condensation prevention part (C) located on at least one side of the rear frame 233. The front condensation preventing unit (B) and the back condensation preventing unit (C) may include a condensation gasket 240 for absorbing moisture generated by condensation. Therefore, by forming the front condensation prevention part (B) in front of the fire door, and additionally forming the rear condensation prevention part (C) in the rear of the fire door, the condensation phenomenon occurring in the fire door is blocked twice to reduce the incidence of condensation. You can. That is, by forming a plurality of condensation preventing portion, it is possible to prevent the fire door to corrode due to the generated moisture.

The condensation gasket 240 may be interposed between the coupling region of the front frame 231 and the inner frame 235 or interposed between the coupling region of the rear frame 233 and the inner frame 235. The condensation gasket 240 is preferably made of a material such as a sponge or foam material having excellent water absorption, and preferably made of a material having flame retardancy or nonflammability to improve fire resistance.

For example, in detail, the front condensation preventing part B is provided with an end portion of the front frame 231 bent in a 'c' shape inwardly of the door member 20, and of the inner frame 235. One end 235b may be bent outward and spaced apart in parallel to the inside of the bent piece 231b of the front frame. The condensation gasket 242 may be seated in a space spaced between the bent piece 231b of the front frame and one end 235b of the inner frame. That is, one end of the front frame 231 and the inner frame 235 is bent to form parallel to each other, it is possible to easily seat the dew condensation gasket 242 in a space spaced at a predetermined interval therebetween.

The condensation gasket 242 may be partially exposed to the outside of the door body 230 to surround the end of the bent piece 231b of the front frame 231 and to contact the outer surface of the inner frame 235. That is, the water (W) generated due to condensation on the outer surface of the inner frame 235 wraps around the end of the bent piece 231b of the front frame 231 to be absorbed by contact with the condensation gasket 242 and is exposed to the outside. By forming the front gasket exposed portion 242a, moisture (W) generated due to condensation may easily contact the condensation gasket 242. At this time, the evaporation space 231a formed between the condensation gasket 242 and the bent front frame may help natural evaporation of moisture absorbed by the condensation gasket 242.

Further, the front frame 231 is provided with a front insulation pad 252 in the inner space formed by bending, the bending of the inner frame 235 between the condensation gasket 242 and the front insulation pad 252 End 235b may be located. In this case, the front insulation pad fixing part 235-1 may be formed by bending a part of the inner frame 235 to fix the position of the front insulation pad 252. Therefore, by forming the front insulation pad 252 and the front insulation pad fixing portion 235-1 to block heat transfer to the inside of the front condensation prevention portion B, it can help to minimize the thermal conductivity of the outdoor and indoor. .

In addition, as another example, the rear condensation prevention part C is provided by bending the end of the rear frame 233 inwardly into the 'c' shape of the door member 20, and the side of the rear frame due to the bending. A condensation gasket 244 may be interposed between the protruding surface 233a and the other end of the inner frame 235. In addition, one end surface 244a of the condensation gasket may be exposed to the outside in parallel with the outer surface of the rear frame 233. That is, the ends of the rear frame 233 and the inner frame 235 may be bent to form parallel to each other, and the condensation gasket 244 may be easily seated after spaced at a predetermined interval therebetween. Through one side end surface 244a of the condensation gasket exposed to, it is possible to easily absorb the moisture generated in the outer surface of the rear frame.

The back dew condensation prevention part (C) includes an end portion of the inner frame 235 contacting the rear frame 233 wrapped around the outer side of the bent surface of the rear frame, and the bending piece 233c of the rear frame. The rear insulation pad 254 may be vertically disposed between the condensation gasket 244 and the end portion 235c of the inner frame. That is, unlike the front condensation preventing part (B), the inner frame 235 is bent to have a condensation gasket inserting portion (235-2), and the condensation gasket 244 between the protruding surface 233a of the rear frame. The rear insulation pad 254 may be located between the bent end 235c of the inner frame and the bent piece 233c of the rear frame.

The inner frame 235 has a condensation moving hole 235h at a position corresponding to the protruding surface 233a of the rear frame 233, so that water (W) generated on the outer surface of the inner frame is condensation moving hole. The condensation gasket 244 may be moved through 235h. That is, the condensation movement hole 235h having the outer and inner sides of the inner frame 235 is formed in the inner frame 235 so that moisture generated in the inner frame 235 can move to the condensation gasket 244. Moisture (W) generated from the outer surface of the inner frame 235 may be introduced into the condensation movement hole (235h), the moisture generated by the condensation phenomenon due to the condensation gasket (244) in contact with the condensation movement hole (235h) W) can be easily removed.

Insulation pads 250 such as the front insulation pad 252 and the rear insulation pad 254 may be made of a ceramic insulation material.

For example, the ceramic heat insulating material may be uniformly formed by drying a paste prepared by mixing 1 to 5 parts by weight of hollow beads, 10 to 20 parts by weight of glass fibers, and 5 to 10 parts by weight of an inorganic binder to 100 parts by weight of molten silica powder. By press molding.

The fused silica powder has an average particle of 10 to 50 µm, and the BET surface area preferably has 0.01 m 2 / g to 0.5 m 2 / g. In addition, the hollow beads may be inorganic fine particles having a size of 1 to 40㎛, preferably the inorganic fine particles may be hollow silica, at least one selected from the group consisting of borosilicate glass, silicate ceramics and aluminosilicates. have. When the content of the hollow bead is less than 1 part by weight based on 100 parts by weight of the molten silica powder, the thermal insulation effect may be insufficient. When the content of the hollow beads exceeds 5 parts by weight, the thermal insulation effect may be insignificant depending on the weight and the strength of the composition may be reduced. Therefore, the hollow beads are preferably included 1 to 5 parts by weight based on 100 parts by weight of molten silica.

Glass fibers may have an average diameter of about 3 μm to about 6 μm for ease of manufacture. The glass fiber may be used for the core material of the general vacuum insulation, it is preferable that the glass fiber is standardized to be easy to produce without pollution.

The inorganic binder may be aluminum hydroxide, and when the inorganic binder is less than 5 parts by weight, the strength of the ceramic insulating material may be weakened. When the inorganic binder is more than 10 parts by weight, the thermal conductivity may increase, so the inorganic binder may be 100 parts by weight of molten silica. 5-10 weight part with respect to a part is preferable.

Solids of the paste may be mixed in a proportion of 70 to 80% by weight. If it is lower than 70% by weight, the viscosity of the paste itself is low, so the loss amount may be increased during transfer to the press molding machine. Therefore, it may be difficult to secure a uniform size of the ceramic insulation material after press molding. It is preferable that the paste solids have the above range because the composition may not be uniformly mixed and the heat insulating properties and strength may be reduced.

In order to minimize the resilience of the glass fiber after removing the binder for a ceramic insulating material including the glass fiber compressed by about 60% or more may be applied a constant press pressure. If the press pressure is less than 2.0kg / cm ² , the glass fibers may not be arranged vertically with respect to the thickness direction, and if the pressure exceeds 2.4kg / cm ² , the physical properties of the glass fibers may be reduced due to excessive compression, so that the press molding Is preferably carried out by applying a pressure of about 2.0 kg / cm ² to about 2.4 kg / cm ² . In addition, when the drying temperature is less than 250 ° C, the paste may not be sufficiently dried. If the drying temperature exceeds 300 ° C, the physical properties of the ceramic insulation material may be lowered. Can be carried out at a temperature. Further, the heat treatment may be performed by applying a press pressure of about 2.0kg / cm ² to about 2.4kg / cm ² .

In the method of manufacturing a fire door having excellent fire resistance according to an embodiment of the present invention, first, a plate-shaped front frame 231 and a rear frame 232 are prepared, and then, the inner frame 235 is the front frame 231 and The door body 230 may be prepared by forming a side surface in combination with an end of the rear frame 232.

In addition, the door member 20 may be formed by filling the door filler 210 that blocks heat transfer inside the door body 230. Therefore, the front frame 231 and the rear frame 233 are located in parallel with each other, by connecting and coupling them to the inner frame 235 can be easily produced the door body 230, which blocks heat transfer to the space inside the door body By filling the door filler 210 may be improved fire resistance.

At this time, the door member 20 may form a front condensation prevention part (B) located on one side or more of the front frame 231 and a rear condensation prevention part (C) located on one side or more of the rear frame 233. The front condensation prevention part (B) and the back condensation prevention part (C) may include a condensation gasket 240 for absorbing moisture generated by condensation. Therefore, by forming the front condensation prevention part (B) in front of the fire door, and additionally forming the rear condensation prevention part (C) in the rear of the fire door, the condensation phenomenon occurring in the fire door is doubled to reduce the incidence of condensation. You can. That is, by forming a plurality of condensation preventing portion, it is possible to prevent corrosion of the fire door due to moisture generated by the condensation phenomenon.

The condensation gasket 240 may be formed between the front frame 231 and the inner frame 235 or may be formed by being coupled between the rear frame 233 and the inner frame 235.

For example, forming the front condensation preventing part (B), the end portion of the front frame 231 is bent in the 'c' shape inwardly of the door member 20, the inner frame 235 of One end 235b is bent outward and spaced apart and parallel to the inside of the bent piece 231b of the front frame, and then spaced between the bent piece 231b of the front frame and one end 235b of the inner frame. The condensation gasket 242 may be formed in a closed space. That is, one end of the front frame 231 and the inner frame 235 may be bent to form parallel to each other, spaced apart at predetermined intervals therebetween, and then the condensation gasket 242 may be easily seated.

The condensation gasket 242 may be partially exposed to the outside of the door body 230 to surround the end of the bent piece 231b of the front frame 231 and to contact the outer surface of the inner frame 235. That is, the water (W) generated due to condensation on the outer surface of the inner frame 235 wraps around the end of the bent piece 231b of the front frame 231 to be absorbed by contact with the condensation gasket 242 and is exposed to the outside. By forming the front gasket exposed portion 242a, moisture (W) generated by condensation may easily contact the condensation gasket 242. At this time, an evaporation space 231a may be formed between the condensation gasket 242 and the bent front frame, thereby helping to naturally evaporate moisture absorbed by the condensation gasket 242.

Furthermore, the front insulation pad 252 is formed in the inner space formed by bending the front frame 231, and the inner frame 235 is bent between the condensation gasket 242 and the front insulation pad 252. End 235b may be located. In this case, the front insulation pad fixing part 235-1 may be formed by bending a part of the inner frame 235 to fix the position of the front insulation pad 252. Therefore, by forming the front insulation pad 252 and the front insulation pad fixing portion 235-1 to block heat transfer inside the front condensation prevention portion (B), it can help to minimize the thermal conductivity of the outdoor and indoor. have.

As another example, forming the rear condensation preventing part C may include bending the rear frame 233 inward toward the door member 20 in a 'c' shape, and protruding surface 233a of the rear frame due to the bending. ) And a condensation gasket 244 may be formed between the other end of the inner frame 235. In addition, one side end 244a of the condensation gasket may be formed to be exposed to the outside in parallel with the outer surface of the rear frame 233. That is, the ends of the rear frame 233 and the inner frame 235 may be bent to form parallel to each other, and the condensation gasket 244 may be easily seated after spaced at a predetermined interval therebetween.

The back condensation prevention part (C) includes an end portion of the inner frame 235 contacting the rear frame 233 to surround the outer side of the bent surface of the rear frame, and the bent piece 233c of the rear frame. A rear insulation pad 254 may be formed vertically with the condensation gasket 244 between the end portions 235c of the inner frame. That is, unlike the front condensation preventing part B, the inner frame 235 is bent to form a condensation gasket insertion part 235-2, and the condensation gasket 244 is formed between the protruding surface 233a of the rear frame. The rear insulation pad 254 may be formed between the bent end 235c of the inner frame and the bent piece 233c of the rear frame.

The inner frame 235 forms a condensation moving hole 235h at a position corresponding to the protruding surface 233a of the rear frame 233, so that water (W) generated on the outer surface of the inner frame is a condensation moving hole. The condensation gasket 244 may be moved through 235h. That is, by forming the condensation movement hole 235h in which the outside and the inside of the inner frame 235 are perforated so that moisture generated in the inner frame 235 can move to the condensation gasket 244, Moisture (W) generated from the outer surface of the inner frame 235 may be introduced into the condensation movement hole (235h), the moisture generated by the condensation phenomenon due to the condensation gasket (244) in contact with the condensation movement hole (235h) W) can be easily removed.

Since the door frame member 10 can be coupled to the doorway. The door frame member 10 may be formed of a door frame body 110 having a rectangular frame shape attached to an inner circumferential surface of the doorway, and a door frame filler 130 which is filled in the inside to block heat transfer. A flame retardant gasket (not shown) may be formed on one surface of the door frame body 110 so that the door member 20 may be compressed to form a space in which the inside is sealed against the outside based on the fire door. .

Finally, a fire door may be manufactured by connecting the door member 20 using the hinge member 30 to be seated inside the door frame member 10.

Hereinafter, a fire door having excellent fire resistance and a method of manufacturing the same according to the present invention will be described through the following experimental examples.

Experimental Example

The door body was all made of steel, and the front frame and the rear frame were made of steel having a thickness of 0.8T, and the inner frame was made of steel having a thickness of 1.2T. Mineral wool 120K was used as the door filler. In addition, the condensation gasket was formed by using a flame-retardant foam material in the front condensation prevention unit and the rear condensation prevention unit, and the insulation pad was formed on the four sides of the door using a ceramic insulation material.

The door frame body was formed of 1.6T steel, and 100K mineral wool was used as the door frame filler. In addition, a flame-retardant rubber gasket was formed where the door frame body and the door member contact.

Fire protection performance of the fire doors completed by the above method was tested by the test methods of KSF2268-1 and KSF2846, the thermal insulation was tested by the method of KSF2278, and the airtightness was tested by the method of KSF2292. In addition, the degree of condensation prevention was measured by the test method according to 'Design Criteria for Preventing Condensation in Apartment Housing'. The test conditions were to maintain the condensation state on the surface of the fire door after installing the fire door according to the embodiment of the present invention between a constant temperature chamber having an air temperature of 25 ° C. and a relative humidity of 50% and a zone II having a temperature of -15 ° C. for 1 hour. Observed.

result

The fire protection performance of the fire door according to the embodiment of the present invention was tested by the test method of KSF2268-1, KSF2846, the average rise temperature of the front part of the fire door is 87.2 ℃, the average rise temperature of the rear part is 135.5 ℃ heat shielding (KSF2268- In the experiment 1), it showed excellent performance compared to the performance standard, and in the flame test (KSF2268-1 experiment) which was experimented for 60 minutes, there was no crack gauge and flame generation performance. In addition, a pressure difference of air leakage in a condition under 25Pa exhibited the front portion 0.18min · m ^3, 0.9 excellent performance based on a result of the back 0.14min · m ³ tea ductility (KSF2846).

In the airtightness of the fire door according to the embodiment of the present invention, the experimental results according to KSF2292, the air flow rate of 0.86m ³ / (h · m ³ ) with respect to the pressure difference 10Pa was measured to show the first class airtightness, As a result of the experiment according to KSF2292, it exhibited excellent thermal insulation of 1.185 W / (m ³ · K).

In addition, in the prevention of condensation of the fire door according to an embodiment of the present invention, as a result of the test according to the 'design criteria for preventing condensation of the apartment house', the temperature difference ratio (TDR) is shown as a ratio of 0.30 that the condensation prevention effect is good. Although the temperature difference between the constant temperature chamber and the low temperature chamber (region II) was 40 ° C., almost no condensation occurred on the entire surface of the door member, and a slight blur appeared only in the lower part of the door member.

Although described above with reference to a preferred embodiment of the present invention, those skilled in the art will be variously modified and changed within the scope of the invention without departing from the spirit and scope of the invention described in the claims below I can understand that you can.

10; Door frame member
20; Door member
30; Hinge member
210; Door Filler
230; Door body
231; Front frame
233; Rear frame
235; Inner frame
240; Condensation Gasket
250; Insulation pad

Claims (16)

In the fire door comprising a door frame member, a door member seated inside the door frame member and a hinge member connecting the door frame member and the door member,
The door member,
A door body including a plate-shaped front frame and a rear frame positioned in parallel with each other, and an inner frame which is coupled to an end of the front frame and the rear frame to form a side surface;
A door filler that is filled in the door body to block heat transfer; And
And a front condensation prevention part located on at least one side of the front frame and a rear condensation prevention part on at least one side of the rear frame.
The front condensation prevention unit and the back condensation prevention unit is provided with a condensation gasket to absorb moisture generated by the condensation phenomenon,
The condensation prevention part of the rear surface is provided with an end of the rear frame is bent in the 'c' shape inwardly of the door member, the condensation gasket between the side protruding surface of the rear frame due to the bending and the other end of the inner frame Is interposed, one end surface of the condensation gasket is exposed to the outside alongside the outer surface of the rear frame,
The inner frame has a condensation moving hole at a position corresponding to the side protruding surface of the rear frame, and moisture generated on the outer surface of the inner frame moves to the condensation gasket through the condensation moving hole. Excellent fire door.
The method of claim 1,
The condensation gasket is interposed between the coupling region of the front frame and the inner frame, or the fire door with excellent fire resistance, characterized in that interposed between the coupling region of the rear frame and the inner frame.
The method of claim 1,
The front condensation preventing part is provided with an end portion of the front frame bent inwardly in a 'c' shape, and one end of the inner frame is bent outward so as to be spaced apart in parallel to the inside of the bent piece of the front frame. The fire door is excellent in fire resistance, characterized in that the condensation gasket is seated in a space spaced between the bent piece of the front frame and one end of the inner frame.
The method of claim 3, wherein
The condensation gasket surrounds the end of the bent piece of the front frame and has a high fire resistance door, characterized in that partially exposed to the outside of the door body to contact the outer surface of the inner frame.
The method of claim 3, wherein
The front condensation prevention unit is provided with a front insulation pad in the inner space formed by the front frame is bent, the excellent flame resistance, characterized in that the bent end of the inner frame is located between the condensation gasket and the front insulation pad. Fire doors.
delete The method of claim 1,
The back dew condensation prevention part includes an end portion of the inner frame contacting the rear frame to surround the outer side of the bent surface of the rear frame, and is perpendicular to the condensation gasket between the bent piece of the rear frame and the end of the inner frame. Fire door with excellent fire resistance, characterized in that the rear thermal insulation pad is located.
delete Preparing a front frame and a rear frame of the plate shape;
Forming a side by combining an inner frame with an end of the front frame and a rear frame to form a side, and filling a door filler to block heat transfer inside the door body to form a door member;
Coupling the door frame member to the doorway; And
Manufacturing a fire door by connecting the door member with a hinge member to be seated inside the door frame member;
The door member has a front condensation prevention unit and a rear condensation prevention unit respectively formed on at least one side of the front frame and the rear frame, and the front condensation prevention unit and the back condensation prevention unit absorb moisture generated by condensation. Including;
Forming the rear condensation preventing portion is formed by bending the end of the rear frame in the 'c' shape inwardly of the door member, between the side protruding surface of the rear frame due to the bending and the other end of the inner frame The condensation gasket is formed, but one end surface of the condensation gasket is formed to be exposed to the outside in parallel with the outer surface of the rear frame.
The inner frame has a condensation moving hole formed at a position corresponding to the side protruding surface of the rear frame, and moisture generated on the outer surface of the inner frame moves to the condensation gasket through the condensation moving hole. Method of manufacturing fire doors.
The method of claim 9,
The condensation gasket is formed between the front frame and the inner frame, or formed between the rear frame and the inner frame is coupled to form a fire door with excellent fire resistance, characterized in that.
The method of claim 9,
Forming the front condensation preventing portion, the end of the front frame is bent inwardly in the 'c' shape of the door member, bent one end of the inner frame in contact with the front frame is spaced inside the bent piece of the front frame And positioned in parallel to each other, wherein the condensation gasket is seated in a space spaced between the bent piece of the front frame and one end of the inner frame.
The method of claim 11,
The condensation gasket surrounds the end of the bent piece of the front frame and partially exposed to the outside of the door body so as to contact the outer surface of the inner frame.
The method of claim 11,
Forming the front condensation preventing portion, the front frame is formed in the front space is formed in the front insulation pad, the end of the inner frame is located between the condensation gasket and the front insulation pad, Excellent method of manufacturing fire doors.
delete The method of claim 9,
Forming the rear condensation preventing portion, the end of the inner frame in contact with the rear frame wraps around the outer side of the bent surface of the rear frame, the back of the vertically perpendicular to the condensation gasket between the bent piece of the rear frame and the end of the inner frame Method for producing a fire door excellent in fire resistance, characterized in that the insulating pad is formed. delete

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