KR20220087817A - Fire-proof structure - Google Patents

Abstract

The fire resistant structure of the present invention has heat insulation performance and fire resistance performance, and can reduce the use of formwork during building construction. a fireproof plate 115 comprising a cover layer 110 formed on the outer surface of the 105; a first coupling member 150 for coupling the fire resistant plate 115 assembled in the horizontal direction to each other; and a second coupling member 175 for coupling the fire resistant plate members 115 assembled in the vertical direction to each other.

Description

Fire resistant structure {FIRE-PROOF STRUCTURE}

The present invention relates to the field of construction technology, and more particularly, to a fire-resistant structure that protects a building from fire and the like and has improved thermal insulation performance.

Patent Invention 001 is to provide a lightweight inorganic foam fireproof board for curtain walls that can improve the fire resistance of existing aluminum curtain wall systems and improve the vulnerability of high-rise buildings due to fire, etc. In the following, selected from the group consisting of an admixture selected from fly ash, silicate powder or mixtures thereof, sludge selected from waste glass powder, glass abrasive sludge or mixtures thereof, silica fume, fine blast furnace slag powder, or mixtures thereof 1st powder mixed with 1 type; After preparing a second powder by adding any one inorganic foaming agent selected from the group consisting of graphite, iron oxide, and sodium silicate to the first powder, mixed water in which sodium silicate and water are mixed with the second powder provides a technique for preparing a foam by mixing 1 to 50 parts by weight based on 100 parts by weight of the second powder, evaporating moisture and organic matter contained in the prepared foam, and then calcining at 700 to 780 ° C.

Patent Invention 002 relates to a fire resistant board, and relates to a fire resistant board with improved fire resistance that can be applied to a fire resistant design and to tunnels and underground spaces. The fire resistant board includes a first aggregate using a shell containing a lime component, a second aggregate containing a silicon component, and a binder for binding the first aggregate and the second aggregate. Here, it further includes an admixture for mixing the first aggregate and the second aggregate, and the admixture is a water reducing agent, providing a technique of using polycarboxylate.

Patent Invention 003 discloses 1 to 3 wt% of a phosphorus-based flame retardant containing a carboxylic acid derivative; 15 to 20 wt% of the first metal oxide; 48 to 65 wt% of a second metal oxide containing silicon dioxide; 10 to 20 wt% of an aluminum hydroxide silicate mineral having a layered structure; And it relates to a water-soluble inorganic foaming fireproofing agent consisting of a residual amount of water, and a fireproofing board using the same. More specifically, the water-soluble inorganic foaming fire retardant of the present invention provides a technique of containing an aluminum hydroxide silicate mineral having a layered structure with high foamability in a water-soluble flame retardant composition using water as a solvent.

Patent Invention 004 discloses a fire resistant board made of polycrystalline alumina fiber, wherein the fire board made of polycrystalline alumina fiber is a plate-shaped first formed by connecting a plurality of first bands of a length material formed of polycrystalline alumina fiber in the width direction. plate; A second band formed by connecting and bonding a plurality of second bands of a length material formed of polycrystalline alumina fibers in the width direction and stacked in a state in which the second band is disposed to cross the first band above or below the first plate plate; It provides a technique consisting of a heat-resistant adhesive layer applied and bonded between the first plate and the second plate.

KR 10-1372517 B1 (Registration date March 03, 2014) KR 10-1558747 B1 (published on October 01, 2015) KR 10-0610059 B1 (Registration Date August 01, 2006) KR 10-2019-0095990 A (published on August 19, 2019)

The present invention has thermal insulation and fire-resistance performance, reduces the use of formwork during building construction, installs screws on the surface, allows direct painting, enables cutting with woodworking knives, taki construction, tile construction, and wallpaper construction It aims to provide a possible fire resistant structure.

In addition, the present invention can reduce the construction cost during construction, shorten the construction period, do not require installation and dismantling of the formwork, and provide a fire resistant structure excellent in fire resistance, sound insulation, heat insulation, and condensation prevention. will be.

The fire resistant structure of the present invention is a fire resistant plate material comprising a heat insulating layer 100 , a fire resistant layer 105 formed on both surfaces of the heat insulating layer 100 , and a cover layer 110 formed on an outer surface of the fire resistant layer 105 . (115).

The fire resistant structure of the present invention may further include a first coupling member 150 for coupling the fire resistant plate members 115 assembled in a horizontal direction to each other.

The fire resistant structure of the present invention may further include a second coupling member 175 for coupling the fire resistant plate members 115 assembled in the vertical direction to each other.

In the fire resistant structure of the present invention, the heat insulating layer 100 may include at least two first and second layers 200 and 205 having different heat insulating properties.

The manufacturing method of the fire resistant structure of the present invention comprises the steps of forming a heat insulating layer 100 of a set thickness; forming a fire resistant layer (105) of a set thickness on both sides of the heat insulating layer (100); and attaching a cover layer 110 having a set thickness to the outer surface of the fire resistant layer 105 .

In the present invention, it is possible to reduce the use of a formwork during construction of a building while having thermal insulation performance and fire resistance performance.

In addition, in the present invention, screw wood can be constructed on the surface, direct painting treatment is possible, cutting with a woodworking knife is possible, and taki construction, tile construction, and wallpaper construction are possible.

In addition, in the present invention, the total construction cost can be reduced, the construction period can be shortened, the installation and dismantling of the form is not required, and it is excellent in fire resistance, sound insulation, heat insulation, and condensation prevention.

The effects of the present invention mentioned above are not limited only to the description, and may include all effects predicted from the specification and drawings.

1 is a schematic cross-sectional view of a fire resistant structure according to the present invention.
2 is a partial perspective view of a fire resistant plate according to the present invention.
3 is a cross-sectional view of a fire resistant plate according to the present invention.
4 is a combined front view of a fire resistant plate according to the present invention.
5 is a perspective view of a coupling part of a fireproof plate according to the present invention.
6 is a partial plan view of a fire resistant plate according to the present invention.
7 is a partial plan view of a fire resistant plate according to the present invention.
8 is a combined front view of a fire resistant plate according to the present invention.
9 shows a method of manufacturing a heat insulating layer in a fire resistant board according to the present invention.
10 shows a method of manufacturing a protective layer according to the present invention.
11 shows a method for manufacturing a ring-resistant plate material according to the present invention.
12 is a flowchart illustrating a method for manufacturing a heat insulating layer according to the present invention.
13 is a partial plan view of a fire resistant plate according to the present invention.
14 is a schematic plan view of a fire resistant structure according to the present invention.

Hereinafter, the most preferred embodiment of the present invention will be described in detail in order to explain in detail enough that a person of ordinary skill in the art can easily carry out the present invention.

Reference numbers provided in the above examples are not limited to the numbers provided, and may be applied to other examples. An equivalent object corresponds to an object exhibiting the same purpose and effect as the configuration presented in this embodiment.

(Example 1-1) The present invention relates to a fire resistant structure, and the heat insulating layer 100, the fire resistant layer 105 formed on both surfaces of the heat insulating layer 100, and the fire resistant layer 105 formed on the outer surface a fireproof plate 115 composed of a cover layer 110; may include

Recently, research on building products that can simultaneously implement both thermal insulation performance and fire resistance performance is being conducted, and research on thermal insulation fire-resistance structures capable of replacing a separate formwork is also being conducted.

In the present invention, a heat insulating layer is formed in the center, a fire resistant layer having excellent fire resistance is formed on both surfaces thereof, and a protective cover layer is formed on the outer surface thereof.

As described above, the heat insulating layer is configured for thermal insulation performance, the fire resistant layer is configured for fire resistance performance, and the cover layer provides overall robustness, and allows painting of the surface during construction, taki construction, tile construction, and Wallpaper can be installed. In addition, the cover layer has excellent mechanical bending performance to enable formwork construction.

(Example 1-2) The present invention relates to a fire resistant structure, and in Example 1-1, the heat insulating layer 100 may include phenolic foam.

(Example 1-3) The present invention relates to a fire resistant structure, and in Example 1-2, the fire resistant layer 105 may include glass wool and/or mineral wool.

In the present invention, the heat insulating layer is made of phenolic foam, and the phenolic foam is foam-hardened by mixing a phenolic resin, a curing agent, and a foaming agent.

In addition, in the present invention, the fire resistant layer may be composed of glass wool or mineral wool, and the glass wool is made by extracting low-melting glass, which contains a lot of soda into fibers, and has excellent electrical properties because it has heat resistance and high tensile strength. has

In addition, mineral wool is made by extracting fibers from a mineral (silicic acid), and glass wool or mineral wool is excellent in sound absorption, sound insulation, and heat insulation, and can be used as a non-combustible material in particular.

(Embodiment 1-4) The present invention relates to a fire resistant structure, and in Embodiment 1-2, the cover layer 110 may be made of a gypsum board.

(Embodiment 1-5) The present invention relates to a fire resistant structure, and in Embodiment 1-2, the cover layer 110 may be made of a metal plate.

In the present invention, the cover layer is composed of gypsum board, and this cover layer has heat resistance, heat insulation, and set strength, and at the same time, screw construction is possible, direct painting treatment is possible, woodworking knife cutting is possible, Construction, tile construction, and wallpaper construction are possible. In addition, in the present invention, the cover layer may be composed of a metal plate material. Such a cover layer may have heat resistance and set strength at the same time, have high durability and strength, and may have a smooth surface.

(Embodiment 1-6) The present invention relates to a fire resistant structure, and in Embodiment 1-2, a thermal barrier air layer 120 may be formed inside the heat insulating layer 100 .

(Example 1-7) The present invention relates to a fire resistant structure, and in Example 1-2, a metal heat reflecting layer 135 may be formed on the outer surface of the fire resistant plate 115 .

In the present invention (refer to FIG. 6), a thermal barrier air layer is formed on the heat insulating layer of the fire resistant plate, and this heat insulating air layer can increase the heat insulating performance, reduce the weight of the fire resistant plate, and reduce the production cost.

In addition (refer to FIG. 13), a heat reflective layer is further formed on the outer surface of the protective layer, and the heat reflective layer can improve the fire resistance and heat resistance of the fire resistant plate by reflecting light or heat generated during a fire.

Additionally, in the present invention (refer to FIG. 1), the fireproof plate is disposed on the outside and the inside, respectively, with the concrete interposed therebetween, and extension ends 235 and 240 connecting them are formed, and these are at the fixed end 245. is fixed by

(Example 1-8) The present invention relates to a fire resistant structure, and in Example 1-2, the fire resistant plate 115 is assembled with each other, and the assembly protrusion 116 and the assembly groove 117 are formed on this assembly surface. ) can be formed.

In the present invention (refer to FIG. 8), an assembly box is formed on one side of the fireproof plate, and an assembly projection is formed on the other side. By the first engagement of the assembly groove and the assembly protrusion, several fireproof boards can realize a single solid planar structure.

(Example 2-1) The present invention relates to a fire resistant structure, and in Example 1-1, a first coupling member 150 for coupling the fire resistant plate members 115 coupled in a horizontal direction to each other; may further include.

In the present invention (refer to FIGS. 2 and 3), for convenience of explanation, the vertical direction, the horizontal direction, and the width direction are set. The fire resistant plate is formed with a heat insulating layer in the center of the width direction, a fire resistant layer is formed on both surfaces thereof, and a protective layer is formed on each of the outer surfaces thereof.

Here, the fireproof plate material may be assembled with each other in the vertical direction and horizontal direction, and when assembling in the left and right directions, a first coupling member is used therebetween.

(Embodiment 2-2) The present invention relates to a fire resistant structure, and in Example 2-1, in the fire resistant plate 115, the cover layer 110 includes a protrusion ( 140) may be included.

(Embodiment 2-3) The present invention relates to a fire resistant structure, and in Example 2-1, in a state in which the fire resistant plate materials 115 are coupled to each other in the horizontal direction, the first coupling member 150 is It may be disposed in the coupling space 145 formed by the protrusion 140 .

In the present invention (refer to FIG. 2), protrusions are formed on the left and right side surfaces of the fireproof plate. This protrusion is a portion in which the protective layer protrudes a set distance from the side surface. A space is formed inside the protruding portion, and the first coupling member may be fastened to the space. In addition, the shape of the first coupling member may be adjusted by adjusting the length of the protrusion, and the first coupling member may include a heat insulating material or a flame retardant material.

(Example 2-4) The present invention relates to a fire resistant structure, and in Example 2-3, the outer surface of the first coupling member 150 and the heat insulating layer 100, the fire resistant layer 105, and / Alternatively, the cover layer 110 may be fixed with an adhesive.

(Embodiment 2-5) The present invention relates to a fire resistant structure, and in Embodiment 2-3, the first coupling member 150 may have a rectangular shape.

In the present invention, an adhesive is applied to the outer surface of the first coupling member, and the first coupling member can be inserted vertically along the coupling space to fix the fireproof plate to each other. In addition, the first coupling member may be made of a hollow pipe made of a metal material, and may have a square pipe structure, as shown in (a) of FIG. 3 .

(Example 2-6) The present invention relates to a fire resistant structure, and in Example 2-3, a coupling groove 155 is formed on the side surface of the heat insulating layer 100, and the first coupling member 150 A coupling protrusion 160 to be inserted into the coupling groove 155 may be formed therein.

In the present invention (refer to (b) of FIG. 3), coupling protrusions are formed on both side surfaces of the first coupling member, and coupling grooves are formed on the side surfaces of the heat insulating layer of the fireproof plate. Through the engagement of the coupling protrusion and the coupling groove, the fire resistant plate material can be firmly assembled to each other.

In the present embodiment, the protrusion is formed in the coupling member and the groove is formed in the heat insulating layer. On the contrary, the groove is formed in the coupling member and the protrusion is formed in the heat insulating layer.

(Embodiment 2-7) The present invention relates to a fire resistant structure, and in Embodiment 2-3, the first coupling member 150 may have a hollow pipe structure.

(Example 2-8) The present invention relates to a fire resistant structure, and in Example 2-3, the first coupling member 150 is an extension member 165 formed by extending a set distance from both sides in the width direction. ; and a support member 170 formed at an end of the extension member 165 and supported on the outer surface of the cover layer 110 .

In the present invention (refer to FIG. 3(c)), an extension member is formed on both sides of the width direction of the first coupling member, and a support member is further formed at an end of the extension member. This support member is supported on the outer surface of the protective layer to firmly hold the fireproof plate material.

In addition, the first coupling member may have a square pipe structure, and the extension member and the support member may have a “T” shape.

(Example 3-1) The present invention relates to a fire resistant structure, and in Example 1-1, a second coupling member 175 for coupling the fire resistant plate members 115 coupled in the vertical direction to each other is further included. can do.

In the present invention (refer to FIG. 4), the fire resistant boards can be assembled with each other in the vertical direction and horizontal direction, and when assembling in the vertical direction, a second coupling member is used between them. Such a second coupling member can be used as a coupling means of the fireproof plate and at the same time improve the rigidity of the fireproof wall.

(Example 3-2) The present invention relates to a fire resistant structure, and in Example 3-1, the second coupling member 175 includes a first coupling pin 180 inserted into the upper fire resistant plate 115a. ); It may include a second coupling pin 185 inserted into the lower fire resistant plate material 115b and connected to the first coupling pin 180 .

(Example 3-3) The present invention is an invention for a fire resistant structure, and in Example 3-2, including a plate-shaped coupling plate 197 interposed between the upper and lower fire resistant board members 115a and 115b, The first and second coupling pins 180 and 185 may be formed to extend from the coupling plate 197 .

In the present invention (refer to FIGS. 4 and 5), the first coupling pin of the second coupling member is inserted into the upper fire resistant plate, and the second coupling pin is inserted into the lower fire resistant board. In addition, a first coupling pin is formed on one surface of the coupling plate, and a second coupling pin is formed on the other surface of the coupling plate. The coupling plate may be interposed between the upper and lower fire resistant boards, and the first and second coupling pins may be inserted into the heat insulating layer.

(Example 3-4) The present invention relates to a fire resistant structure, and in Example 3-2, the first and second coupling pins 180 and 185 are provided on the upper and lower fire resistant plates 115a and 115b. Press-fitted first and second coupling holes 190 and 195 may be formed, respectively.

(Example 3-5) The present invention relates to a fire resistant structure, and in Example 3-4, the first and second coupling holes 190 and 195 may be formed in the heat insulating layer 100 .

In the present invention (see FIG. 6 ), first and second coupling holes into which the first and second coupling pins are inserted are formed in the heat insulating layer of the fire resistant plate, and the coupling pins may have a structure in which the coupling pins are press-fitted into the coupling holes. In some cases, the coupling hole is not formed, and the coupling pin may dig into the phenolic foam.

(Example 4-1) The present invention relates to a fire resistant structure, and in Example 1-1, the heat insulating layer 100 includes at least two first and second layers 200 and 205 having different heat insulating properties. ) may be included.

In the present invention (see FIG. 7 ), the heat insulating layer may be formed of one layer, but in a modified embodiment it may be formed of at least two layers. By having these different characteristics, design specifications can be variously modified. For example, strength may be improved through different characteristics, and heat resistance may also be improved.

(Example 4-2) The present invention is an invention for a fire resistant structure, and in Example 4-1, the metal thin film 232 formed between and/or on the outer surface of the first and second layers 200 and 205 is may include more.

(Example 4-3) The present invention relates to a fire resistant structure, and in Example 4-2, the first and second layers 200 and 205 may be formed to have different densities.

In the present invention, a metal thin film may be interposed between the first and second layers. Such a metal thin film may also be formed on the outer surface of the first and second layers, and such a metal thin film may strengthen the overall structure and improve heat resistance or chemical resistance. For example, it can prevent the penetration of chemicals.

These two first and second layers may be made of different materials. However, the material may be the same, but may be formed to have different densities, and heat resistance and chemical resistance may be improved through this structure. For example, the part close to the surface is formed hard and dense, and the inside is relatively sloppy and sloppy, so that the rigidity can be improved and the weight can be reduced.

(Embodiment 4-4) The present invention relates to a fire resistant structure, and in Embodiment 4-2, a non-uniform thermal insulation boundary layer 210 may be formed between the first and second layers 200 and 205. .

In the present invention (see FIG. 12 ), the heat insulating layer is formed by bonding the first member and the second member to form the first and second layers, and the first and second members have first and second waves formed on opposite surfaces, respectively, They have different shapes. Therefore, when joined, a non-uniform insulating boundary layer is formed, and this insulating boundary layer forms an irregular air barrier layer, thereby effectively blocking the flow of heat.

(Example 5-1) The present invention relates to a method for manufacturing a fire resistant structure, comprising: forming a heat insulating layer 100 of a set thickness; forming a fire resistant layer (105) of a set thickness on both sides of the heat insulating layer (100); and attaching a cover layer 110 having a set thickness to the outer surface of the fire resistant layer 105 ; may include

In the present invention (see FIG. 11), a heat insulating layer is formed to a set thickness, a fire resistant layer is formed on both sides thereof, and a protective layer is attached to an outer surface thereof. As described above, the heat insulating layer is configured for thermal insulation performance, the fire resistant layer is configured for fire resistance performance, and the cover layer provides overall robustness, and allows painting of the surface during construction, taki construction, tile construction, and Wallpaper can be installed. In addition, the cover layer has excellent mechanical bending performance to enable formwork construction.

(Example 5-2) The present invention relates to a method for manufacturing a fire resistant structure, and in Example 5-1, the heat insulating layer 100 may be made of phenolic foam.

(Example 5-3) The present invention relates to a method for manufacturing a fire resistant structure. In Example 5-1, the fire resistant layer 105 may be made of glass wool and/or mineral wool.

(Example 5-4) The present invention relates to a method for manufacturing a fire resistant structure, and in Example 5-1, the cover layer 110 may be made of a gypsum board.

(Example 5-5) The present invention relates to a method for manufacturing a fire resistant structure, and in Example 5-1, the cover layer 110 may be made of a metal plate.

In the present invention, the heat insulating layer is made of phenolic foam, and the phenolic foam is foam-hardened by mixing a phenolic resin, a curing agent, and a foaming agent.

In addition, in the present invention, the fire resistant layer may be composed of glass wool or mineral wool, and the glass wool is made by extracting low-melting glass, which contains a lot of soda into fibers, and has excellent electrical properties because it has heat resistance and high tensile strength. has

In addition, mineral wool is made by extracting fibers from a mineral (silicic acid), and glass wool or mineral wool is excellent in sound absorption, sound insulation, and heat insulation, and can be used as a non-combustible material in particular.

In the present invention, the cover layer is composed of gypsum board, and this cover layer has heat resistance, heat insulation, and set strength, and at the same time, screw construction is possible, direct painting treatment is possible, woodworking knife cutting is possible, Construction, tile construction, and wallpaper construction are possible.

In addition, in the present invention, the cover layer may be composed of a metal plate material. Such a cover layer may have heat resistance and set strength at the same time, have high durability and strength, and may have a smooth surface.

(Example 5-6) The present invention relates to a method for manufacturing a fire resistant structure. In Example 5-4, in the gypsum board, a fiber and/or a thermosetting resin is included in the gypsum, and the fiber is glass wool and / or mineral wool.

In the present invention, fibers and thermosetting resin are included in order to increase the rigidity of the gypsum board, and these fibers are composed of glass wool or mineral wool, so that fire resistance and heat insulation properties can be further improved. In addition, the thermosetting resin can improve the overall strength when the gypsum paper is solidified by heating.

(Example 5-7) The present invention relates to a method for manufacturing a fire resistant structure, and in Example 5-2, the phenolic foam comprises: stirring a mixture to which a foaming agent, a foam stabilizer, and an inorganic material are added; mixing the stirred mixture with phenol; adding a curing agent to the mixture in which the pulmonol is mixed; And it may be prepared including the step of foam molding the mixture in which the curing agent is added.

In the present invention (see Fig. 9), in order to produce phenol foam, a foaming agent, a foam stabilizer, and an inorganic material are mixed, a phenol resin is mixed therein, a curing agent is added, foam molding is performed, and the phenol foam is made by coagulation and cutting. can get The foaming agent makes fine air bubble particles, the foam stabilizer performs the function of maintaining the shape of the foam, and the inorganic material is a bonding means and can improve the flame resistance.

(Example 5-8) The present invention relates to a method for manufacturing a fire resistant structure. In Example 5-4, the gypsum board is mixed with gypsum, an adhesive, a curing agent, a foaming agent, a fiber, and water in a predetermined ratio. to form a slurry; supplying a bottom film on the moving belt; supplying the mixed slurry on the bottom film; attaching a surface film on the slurry; and curing and cutting.

(Example 5-9) The present invention relates to a method for manufacturing a fire resistant structure, and in Examples 5-8, the bottom film and/or the surface film may be a metal thin film.

In the present invention (see FIG. 10), a slurry is first made to form a gypsum board. The slurry is made by water, gypsum, adhesive, hardener, foaming agent, fiber, and the like. Adhesives and hardeners can improve strength, fibers can improve rigidity, and foaming agents can reduce weight and improve fire resistance. In addition, a floor film and a surface film are applied to form a gypsum board, and paper may be used for these films.

In addition, the bottom film or the surface film may be composed of a metal thin film, which may be formed only on the outer surface of the gypsum board, and reflects heat in case of fire to improve heat resistance and fire resistance at the same time.

(Example 5-10) The present invention relates to a method for manufacturing a fire resistant structure, and in Example 5-1, the heat insulating layer 100 includes a first member ( 225) and the second member 230 on which the second wave 220 is formed on the surface facing the first wave 215 are pressed together to form the first and second layers 200 and 205. In the process in which the first and second members 200 and 205 are compressed, the first and second waves 215 and 220 may form a non-uniform insulating boundary layer 210 .

(Example 5-11) The present invention relates to a method for manufacturing a fire resistant structure. In Example 5-1, the heat insulating layer 100 includes a first member 225 having a first density and a second density. It may be made of the first and second layers 200 and 205 by pressing the second member 230 having

In the present invention (see FIG. 12 ), the first member and the second member may have different shapes, materials, and/or densities. As shown, first and second waves are formed on the surfaces facing each other, respectively. and pressurize them to form a non-uniform adiabatic boundary layer. The non-uniform thermal insulation boundary layer can improve thermal insulation performance by forming a non-uniform fine air layer.

(Example 5-12) The present invention relates to a method for manufacturing a fire resistant structure. In Example 5-1, the heat insulating layer 100 includes the first member 225 and the second member with a metal thin film therebetween. The first and second layers 200 and 205 made by pressing the members 230 to each other may be included.

In the present invention (see FIGS. 7 and 12 ), the heat insulating layer may be formed of at least two layers. A metal thin film may be interposed between the first and second layers. Such a metal thin film can strengthen the overall structure, and can improve heat resistance or chemical resistance. For example, it can prevent the penetration of chemicals.

(Example 6-1) The present invention relates to a fire resistant structure, and in Example 2-1, the fire resistant boards are arranged at a set interval in the width direction to form a cement pouring space (115d) and an outer fire resistant plate 115c, and a 1-1 coupling member 150a coupled between the inner fire resistant board 115d and a 1-2 coupling member coupled between the outer fire resistant board 115c ( 150b) may include a fixed end 245 for fixing the first and second extension ends 235 and 240 respectively extending into the cement pouring space to each other.

(Example 6-2) The present invention is an invention for a fire resistant structure, and in Example 6-1, the first-1-1 coupling member 150a and the 1-2 coupling member 150b have a space for placing cement. an extension member 165 extending outwardly; and a support member 170 formed at an end of the extension member 165 and supported on the outer surface of the cover layer 110 , respectively.

In the present invention (refer to FIG. 14 ), it includes an inner fire resistant plate disposed on the inside of a building and an outer fire resistant plate disposed on the outside, which are disposed at a set interval from each other. Concrete is poured between them and filled.

As shown, the inner fireproof plate material and the outer fireproof plate material are assembled by the inner fireproof plate member 1-1, and the outer fireproof plate material is assembled by the 1-2 coupling member. The first and second extension ends are respectively extended on the inner surfaces of the 1-1 coupling member and the 1-2 coupling member, and the fixed ends are fixed thereto. Here, the fixed end may include a bolt and nut structure.

In addition, an extension member is further formed on the outer surfaces of the 1-1 coupling member and the 1-2 coupling member, respectively, and a support member is formed at an end of the extension member, and the support member supports the outer surface of the cover layer. .

100: heat insulating layer 105: fire resistant layer
110: cover layer 145: bonding space
120: heat barrier layer 125: assembly projection
130: assembly groove 135: heat reflective layer
116: assembly projection 117: assembly groove
115: fireproof plate 115a: upper fireproof plate
115b: lower fire resistant plate 115c: outer fire resistant plate
115d: inner fire resistant plate 150: first coupling member
150a: 1-1 coupling member 150b: 1-2 coupling member
155: coupling groove 140: protrusion
160: coupling protrusion 165: extension member
170: support member 175: second coupling member
180: first coupling pin 185: second coupling pin
190: first coupling hole 195: second coupling hole
C: cement 197: bonding plate
200: first floor 205: second floor
210: adiabatic boundary layer 215: first wave
220: second wave 225: first member
230: second member 232: metal thin film
235: first extension 240: second extension
245: fixed end

Claims (5)

a fire resistant plate 115 comprising a heat insulating layer 100, a fire resistant layer 105 formed on both surfaces of the heat insulating layer 100, and a cover layer 110 formed on an outer surface of the fire resistant layer 105;
A fire resistant structure comprising a.
The method according to claim 1,
a first coupling member 150 for coupling the fire resistant plate 115 assembled in the horizontal direction to each other;
A fire resistant structure further comprising a.
The method according to claim 1,
a second coupling member 175 for coupling the fire resistant plate 115 assembled in the vertical direction to each other;
A fire resistant structure further comprising a.
The method according to claim 1,
The heat insulating layer 100,
at least two first and second layers 200 and 205 having different thermal insulation properties;
A fire resistant structure comprising a.
forming a heat insulating layer 100 of a set thickness;
forming a fire resistant layer (105) of a set thickness on both sides of the heat insulating layer (100); and
attaching a cover layer 110 having a set thickness to the outer surface of the fire resistant layer 105;
A method of manufacturing a fire resistant structure comprising a.

Images