KR101995447B1 - Composite exterior structure for construction with integral flat inorganic layer - Google Patents

Abstract

The present invention relates to a prefabricated composite exterior structure for a building whose inorganic flat layer achieves high integrity by using a thin layer of aluminum and a glass fiber mesh layer. In the prefabricated composite exterior structure for a building, an inorganic flat layer coats the surface of an incombustible insulation panel composed of at least one among a mineral fiber obtained by fusing alkaline igneous rocks, a fiber obtained by fusing low melting temperature glass, a fiber obtained by melting calcium silicate-based ore at high temperature, Cerakwool, foam concrete obtained by curing silica and lime at high pressure and high temperature, aerogel, ceramic, and a vacuum insulator. An incombustible reinforcing layer composed of a thin layer of aluminum and a glass fiber mesh layer is disposed between the surface of the incombustible insulation panel and the inorganic flat layer to maximize integrity between heterogeneous materials. To improve incombustibility and insulation performance, the prefabricated composite exterior structure mainly includes a condensation water discharge line (10), adhesive mortar (20), an incombustible insulation panel (100), an inorganic flat layer (120), incombustible reinforcing layer (160), and a fixing unit (200).

Description

TECHNICAL FIELD [0001] The present invention relates to a composite external structure for a building, in which an inorganic flat layer is highly integrated using an aluminum foil layer and a glass fiber net layer,

More particularly, the present invention relates to an inorganic composite fiber structure in which an inorganic flat fiber layer and an inorganic flat fiber layer are integrally formed using an aluminum foil layer and a glass fiber net layer, At least one layer selected from the group consisting of a fiber, a fiber obtained by melting a calcium silicate-based ore at a high temperature, a ceramic fiber cured at a high temperature and a high pressure by using cerach wool, silica sand and lime as raw materials, airgel, ceramic and vacuum insulation An inorganic flat layer is coated on the surface of the flameless insulating panel and an unburned reinforcing layer composed of an aluminum thin plate layer and a glass fiber net layer is disposed between the inorganic flat layers on the surface of the flameless heat insulating panel to maximize the integration between the foreign materials, By using an aluminum sheet layer and a glass fiber net layer to improve the heat insulation performance, The present invention relates to an assembled composite outer structure for building having a high rigidity.

Generally, natural stone such as marble or granite processed in a rectangular plate shape is applied as a finishing material for constructing inner and outer walls of a building such as a high-rise building. However, in recent years, Is widely used as an exterior wall finishing material. However, in the case of the insulation material, the wet insulation method using the adhesive mortar usually causes the external force including the typhoon and the earthquake to be easily removed when the adhesive is applied. Especially, the EPS insulation material is very vulnerable to fire, Not only does it pose a risk to the environment, it also causes a large amount of gas accompanied by harmful substances to be released during combustion, resulting in a large-scale casualty damage.

Accordingly, in the conventionally disclosed registration room No. 20-0417640, in a soundproofing, insulation, toxic material prevention, and moisture proofing material for building interior and exterior use as a finishing material by being installed on the inside, outside, roof, ceiling, floor, The base material is adhered to a lower surface of a sheet layer made of any one of a veneer film paper, a paper coating material and a woven fiber material, a veneer film gauze, a pulp paper coating material, and a woven fiber material, (Polyester Spunbonded Fabric) layer which is excellent in sound absorption property and a polyester spunbonded fabric layer which is excellent in heat insulating property and sound absorption property in various colors. A non-flammable aluminum metal foil plate layer for preventing winds, bacteria, and the like, and an aluminum metal foil material layer, (HDPE-Polypropylene) film layer, which is excellent in moisture resistance and moisture resistance, and a polypropylene film layer, which are excellent in heat insulation, sound absorption, chemical resistance, adhesion to other materials, (Polyester Spunbonded Fabric) layer, which has been formed with a certain thickness, has been pre-registered in the building.

However, the above-mentioned conventional techniques have a disadvantage in that deformation and heat insulation due to absorption of moisture are lowered and a disadvantage that bacterial bacteria and fungi can parasitize. However, in order to use them as a building exterior material, , A typhoon, an earthquake, or a drop-off phenomenon frequently occurs due to a decrease in adhesion of adhesive mortar. In particular, a sheet layer, a polyester spunbonded fabric layer, an aluminum metal foil plate layer, (HDPE-Polypropylene) film layer was easily adhered and fixed, so that when exposed to high temperature, each layer was easily fallen off, causing secondary accident caused by falling objects, and besides, the interfacial fire spread of the building was not blocked at all.

Accordingly, the present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a method for producing a glass fiber, which comprises melting inorganic fused basic rock, glass melting low melting point glass, And an inorganic flat layer is coated on the surface of a fireproof insulation panel comprising at least one layer of foamed concrete, aerogels, ceramics and vacuum insulation material which is cured at a high temperature and a high pressure with a lime as a raw material, An aluminum flat plate layer and a glass fiber net layer are disposed between the layers to maximize the integration between the different materials and the aluminum flat plate layer and the glass fiber net layer to improve fire resistance and heat insulating performance, And an object of the present invention is to provide a composite external structure for construction having high integrity.

In order to achieve the above object, the present invention is characterized in that an inorganic fiber which is installed on the building outer wall 1 by means of the fixture 200 and the adhesive mortar 20 and fuses the basic igneous rock, Comprising at least one layer selected from the group consisting of foamed fibers obtained by melting calcium silicate-based ores at high temperature, ceragallo wool, silica sand and lime as raw materials and cured at high temperature and high pressure, at least one layer of airgel, ceramic, Panel 100; The flame-resistant heat insulating panel 100 includes an inorganic flat layer 120 coated on a surface thereof; A fireproof reinforcement layer 160 disposed between the fireproof thermal insulation panel 100 and the inorganic flat layer 120 and composed of the aluminum thin plate layer 140 and the glass fiber net layer 160; And a dewatering water discharge line 10 provided between the building outer wall 1 and the fireproof insulation panel 100. The aluminum thin plate layer 140 of the fireproof reinforcement layer 160 is provided with a horizontal incision A line 142 is formed to form upper and lower cutout areas 142a and 142b and a lower cutout area 142a of the other lateral cutout line 142 is formed in the outer lateral direction of the aluminum foil layer 140 A glass fiber net layer 160 and an inorganic flat layer 120 are fixed and fixed to the upper surface of the upward phage holder 144 and the other one The upper cutout region 142a of the lateral incision line 142 is bent downward in the direction of the inner side to form a downward gripping holder 146 penetrating downwardly while the downward gripping holder 146 has a lower face, ) And fixed in position .

The flameproof panel 100 is formed with a protruding portion 120 at a pressing position corresponding to the fixture 200 and the protruding portion 120 is compressed by the pressing force at the time of fastening the fixture 200 to form a high density heat insulating layer 140 And the depth of insertion of the fixture 200 is limited by the high-density insulation layer 140 so that the surface of the fixture 200 is maintained to maintain the outer surface and flatness of the incombustible thermal insulation panel 100.

The dewatering water discharge line 10 includes a plurality of U-shaped branches (not shown) that are installed at an oblique angle to the building outer wall 1 and collect dew condensed water on the inner wall of the building outer wall 1 and the inner wall of the fire- And a drain pipe 14 connected to the lower side end of the U-shaped branch pipe 12 for discharging the condensed water collected therein. The drain pipe 14 has a valve 16, A fire extinguishing agent tank 19 is opened and closed by a control unit including a fire detection sensor. When a fire is detected by the control unit, the fire extinguishing agent tank 18 is turned off, (19) is opened to spray fire extinguishing agent between the building outer wall (1) and the fireproof thermal insulating panel (100).

The flameproof panel 100 is independently restrained in a joint section 300 formed by a combination of a straight type joint 320 and a cross type joint 340. The straight type joint 320 includes two flame- A gap maintaining bar 322 inserted in between the gap maintaining bar 322 and U-shaped ribs 322a formed in a straight line so as to be spaced apart from each other and spaced apart from each other, The cross-shaped joint 340 is inserted between the corner areas of the four flame-retardant heat insulating panels 100 facing each other, and is provided with a U-shaped groove A gap retaining bar 342 in which the upper end 342a is formed by a cross and a finishing piece 344 extending perpendicularly from the gap retaining bar 342 and restricting the outer side surface of the fireproof material 100, (322a) and (344a) are opened to the outside of the building, After the heat insulating panel 100 is installed, a smoothing material 360 including 40 to 50 parts by weight of an expansive additive based on 100 parts by weight of cement is filled.

When at least two of the flame-retardant insulating panels 100 are overlapped, the side overlapping boundary line of the flame-retardant insulating panel 100 is finished by the flame-retardant heat insulating tape 180, Is characterized in that it is finished by a hot expansion tape (190) coated with an inorganic combustible saturation layer (400).

1 to 30 parts by weight of a capsule containing an aluminum metal oxide whose moisture content is controlled and at least one inert inflatable powder of sodium silicate, calcium carbonate or silicate, sodium silicate, calcium carbonate 20 to 70 parts by weight of a binder composed of at least one member selected from the group consisting of aluminum hydroxide, magnesium hydroxide, copper hydroxide, calcium carbonate, boric acid, phosphoric acid salt and phosphorus flame retardant, and 0.01 to 3 parts by weight of a stabilized foam auxiliary material And the inorganic combustible saturated layer 400 is characterized in that the capsule is expanded by a high temperature when a fire occurs.

In addition, an inorganic combustible saturated layer 400 is applied to the outer circumferential surface of the fire-extinguishing heat insulating panel 100, and the inorganic combustible saturated layer 400 is formed of an aluminum metal oxide having a controlled moisture content and at least one of sodium silicate, calcium carbonate, 1 to 30 parts by weight of a capsule containing at least one inert expandable powder, 20 to 70 parts by weight of a binder composed of at least one of sodium silicate, calcium carbonate and silicate, aluminum hydroxide, magnesium hydroxide, copper hydroxide, calcium carbonate, boric acid And 0.01 to 3 parts by weight of a stabilized foam auxiliary material composed of at least one of phosphoric acid, phosphoric acid and phosphorus flame retardant. The inorganic combustible saturated layer 400 is characterized in that the capsule is expanded by a high temperature when a fire occurs.

The fixture 200 includes a plate-shaped head portion 220 pressed against the outer side surface of the fireproof thermal insulation panel 100, a shaft pin portion 240 fixed to the building outer wall 1 to support the plate- Like head portion 220 is formed on the outer side of the plate-shaped head portion 220 and a plurality of extension bands 224 are formed in the edge portion of the plate- Shaped recess 226 is formed between the plate-shaped head part 220 and the fixed firebox 200 so that the fireproof panel 100 is formed in the same shape as the depressed ditch 226 when fastened, .

The plate-shaped head part 220 is separated from the shaft pin part 240 so as to have a fastening hole 228 formed at the center thereof. An inner circumferential surface of the fastening hole 228 is formed with a flange plate 228a. The stop protrusion 242 is formed at a position corresponding to the flange 228a while the stop protrusion 242 has a slope 244 formed on one side of the stop protrusion 242, And the wedge-shaped protrusion is formed as a serrated protrusion.

In addition, an insulative washer 260 coated with an inorganic combustible saturation layer 400 is provided on the inner side of the plate-shaped head part 220, and the inorganic combustible saturated layer 400 of the heat insulating washer 260, And are compressed and fixed to each other while expanding to the high temperature together with the inorganic combustible saturation layer (400) on the outer peripheral surface of the casing (100).

The fixture 200 includes a plate-shaped head portion 220 having a fastening hole 228 formed at the center thereof while being pressed against the outer side surface of the fireproof thermal insulating panel 100, and a shaft pin portion 240 and the shaft pin portion 240 and the other end extends in an expanded size with respect to the thickness of the flameproof panel 100 and is inserted into the fastening hole 228 of the plate- And a finishing cap 290 coupled to the fastening hole 228 of the plate-shaped head 220 in a state of being fitted in the heat insulating mesh tube 280.

Between the fireproof panel 100 at the position corresponding to the upper or lower portion of the window 2 formed in the building outer wall 1 or at the position corresponding to the upper or lower portion of the building or the border line of each building layer, The fire-fighting line 500 formed by the fire-fighting and heat insulating block 520 is constructed.

The fire extinguishing agent pack 540 includes 50 to 100 parts by weight of carbon dioxide based on 100 parts by weight of the extinguishing agent. The fire extinguishing agent pack 540 blows out the fire extinguishing agent due to the expanding force of carbon dioxide .

According to the above-mentioned constitution and operation, the present invention provides a method for producing a high-temperature and high-strength steel sheet, which comprises the steps of preparing an inorganic fiber by melting a basic igneous rock, a fiber melting a glass having a low melting point, An inorganic flat layer is coated on the surface of a fire-retardant insulating panel comprising at least one layer of foamed concrete, aerogels, ceramics and vacuum insulation material cured at high pressure, and an aluminum thin plate layer And a fiberglass netting layer are disposed on the surface of the base material to maximize the integration between the heterogeneous materials and improve the fireproof and heat insulation performance.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a general view showing a composite composite exterior structure for construction having a high degree of integrity of an inorganic flat layer using an aluminum thin plate layer and a glass fiber net layer according to an embodiment of the present invention. FIG.
FIG. 2 is a view entirely showing a construction state using an assembled composite external structure for construction in which an inorganic flat layer is highly integrated using an aluminum thin plate layer and a glass fiber net layer according to an embodiment of the present invention.
3 is a view showing a fireproof reinforcement layer of an assembled composite outer structure having a high degree of integrity with an inorganic flat layer using an aluminum foil layer and a glass fiber net layer according to an embodiment of the present invention.
4 is a view showing the embossed protrusion of a composite composite outer structure for construction having a high level of integrity of the inorganic flat layer using an aluminum foil layer and a glass fiber net layer according to an embodiment of the present invention.
5 is a view showing a dewatering water discharge line of an assembled composite external structure for building having a high level of integrity of an inorganic flat layer using an aluminum foil layer and a glass fiber net layer according to an embodiment of the present invention.
FIG. 6 is a view showing a joint section of an assembled composite outer structure for construction in which the inorganic flat layer is highly integrated using an aluminum thin plate layer and a glass fiber net layer according to an embodiment of the present invention. FIG.
FIG. 7 is a view showing a fireproof thermal insulation tape of a composite external structure for a building having a high level of integrity of an inorganic flat layer using an aluminum thin plate layer and a glass fiber net layer according to an embodiment of the present invention. FIG.
8 is a view showing an inorganic combustible saturated layer of an assembled composite outer structure having a high integrity of an inorganic flat layer using an aluminum thin plate layer and a glass fiber net layer according to an embodiment of the present invention.
FIG. 9 is a view showing a fixture of a composite external structure for a building having a high degree of integrity with an inorganic flat layer using an aluminum thin plate layer and a glass fiber net layer according to an embodiment of the present invention.
10 is a view showing a modified example of a fastener of a composite external structure for a building having a high level of integrity of an inorganic flat layer using an aluminum thin plate layer and a glass fiber net layer according to an embodiment of the present invention.
FIG. 11 is a view showing another modification of the fastener of a composite external structure for construction, in which the inorganic flat layer is highly integrated with the aluminum thin plate layer and the glass fiber net layer according to the embodiment of the present invention. FIG.
FIG. 12 is a view showing a heat insulating washer of a composite external structure for a building having a high degree of integrity with an inorganic flat layer using an aluminum thin plate layer and a glass fiber net layer according to an embodiment of the present invention. FIG.
13 to 14 are diagrams showing a fire line of an assembled composite outer structure for construction in which the inorganic flat layer is highly integrated using an aluminum thin plate layer and a glass fiber net layer according to an embodiment of the present invention.

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

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic view showing a composite composite outer structure for construction having a high degree of integration with an inorganic flat layer using an aluminum thin plate layer and a glass fiber net layer according to an embodiment of the present invention.

The present invention relates to a compositious composite exterior structure for construction in which an inorganic flat layer is highly integrated using an aluminum foil layer and a glass fiber net layer. The inorganic composite fiber is composed of inorganic fibers in which basic igneous rock is melted, fibers in which low melting point glass is melted, A fireproof panel comprising at least one layer of foamed concrete, aerogels, ceramics, and vacuum insulation material, which is made of fibers obtained by melting calcium ores at high temperature, ceragallo, silica sand and lime as raw materials at high temperature and high pressure, An inorganic flat layer is coated on the surface, and a non-burning reinforcement layer composed of an aluminum thin plate layer and a glass fiber net layer is disposed between the inorganic flat layers on the surface of the fire retardant insulating panel to maximize the integration between the two different materials. A dewatering water discharge line 10, an adhesive mortar 20, a fire-proof thermal insulating panel 100, an inorganic flat layer 120, Including gangcheung 160, a fastener 200 comprises a main component.

The fire-proof heat insulating panel 100 according to the present invention comprises inorganic fibers fused with basic igneous rock, fibers fused with glass having a low melting point, fibers obtained by melting calcium silicate ores at high temperature, And at least one layer of foamed concrete, aerogels, ceramics, and vacuum insulation material, which is made of lacquer, silica sand and lime as raw materials and cured at high temperature and high pressure.

Herein, the inorganic fiber in which the basic igneous rock is melted is a chemical fiber obtained by melting volcanic rock ore, and the fiber obtained by melting the calcium silicate ore at high temperature is a nail ring, and the calcium silicate ore is melted at a high temperature, It is an artificial mineral fiber insulation material of inorganic fiber which is made by using the rotational force, and Cerach wool is a synthetic fiber made of mineral and has high fire resistance property.

In this case, the thickness of the fire-extinguishing panel 100 is 20 to 150 mm, the insulation is about 0.02 to 0.05 W / mK, the fire resistance to withstand about 800 ° C, and the noxious gas and flame spread in the fire, It is harmless to human body.

The inorganic flat layer 120 is coated on the surface of the flame-retardant insulating panel 100 or after the inorganic flat layer 120 is coated on the exterior wall 1 of the building. The inorganic flat layer 120 is a mixture containing at least one ore powder of silica, limestone, and volcanic rock, and protects the surface of the fire-resistant heat insulating panel 100 from fire heat in a fire.

3, a fireproof reinforcement layer 160 composed of an aluminum thin plate layer 140 and a glass fiber net layer 160 is formed between the fireproof insulation panel 100 and the inorganic flat layer 120. The horizontal cut line 142 is formed at a plurality of locations in the aluminum thin plate layer 140 of the fireproof reinforcement layer 160 and the lower cutout area 142b of the upper cutout area 142a and the upper cutout area 142b of the horizontal cutout line 142 142a are formed by upwardly grasping holders 144 that are folded in an upward direction in the outer lateral direction of the aluminum thin plate layer 140 so as to pass through the upper side of the upper flat plate holder 140. The glass fiber net layer 160 and the inorganic flat layer 120) is caught and fixed. Further, the upper incision region 142a of the other lateral incision line 142 is bent downward in the direction of the inner side to form a downward phage holder 146 penetrating downward. The downward phage holder 146 has a lower surface, And held on the panel 100 to be fixed in position.

The inorganic flat layer 120 is fixed to the upper surface of the upper phage holder 144 of the aluminum thin plate layer 140 in a state that the inorganic flat layer 120 is fused to the glass fiber net layer 160 and the inorganic flat layer 120 is fixed to the upper phage holder The lower holding holder 146 of the aluminum foil layer 140 is caught by the fire-resistant heat insulating panel 100 and is prevented from flowing in the weight direction. As a result, The integratedness between the flameless thermal insulating panel 100 and the inorganic flat layer 120 is improved and the heat insulating property is improved. Further, the glass fiber net layer 160 reinforces the durability due to warping between the inorganic flat layer 120 and the inorganic flat layer 120, so that the glass fiber net layer 160 is prevented from being deformed by an external force after being applied to the building outer wall 1.

In addition, the flameproof panel 100 is formed with the embossed protrusion 120 at the pressing position corresponding to the fixture 200. 4, the protrusion 120 is compressed by the pressing force when the fixture 200 is tightened to form the high-density insulation layer 140, and the depth of insertion of the fixture 200 is restricted by the high-density insulation layer 140, So that the surface of the flameproof panel 100 is maintained to have an outer surface and a flatness.

The dewatering water discharge line 10 according to the present invention is installed between the building outer wall 1 and the fireproof insulation panel 100. The dewatering water discharge line 10 quickly discharges the dew condensation water generated between the building outer wall 1 and the fireproof insulation panel 100 after the fireproof insulation panel 100 is installed so that the fireproof insulation panel 100, Reproduction and contamination including deformation and fungi are prevented.

5, the dew condensation water discharge line 10 includes a plurality of U-shapes (not shown) which are installed at the building outer wall 1 at an oblique angle and collect dew condensed water on the inner wall of the building outer wall 1 and the inner wall of the fire- And a drain pipe (14) connected to the lower side end of the U-shaped branch pipe (12) and discharging the collected condensed water. At this time, the U-shaped branch pipes 12 are installed at symmetrical positions with respect to the drain pipe 14 at an inclined angle, and condensation water flowing down the building outer wall 1 and the fire-proof and heat insulating panel 100 flows through a plurality of U- And is moved to the drain pipe 14 side and discharged quickly.

Since the U-shaped branch pipe 12 is dispersedly disposed on the building outer wall 1 to support the fire-retardant heat insulating panel 100, the distance between the inner side of the fireproof thermal insulating panel 100 and the building outer wall 1 is uniform maintain.

The U-shaped branch pipe 12 is disposed between the adhesive mortars 20 arranged in a point-adhesive manner, that is, on the upper side of the adhesive mortar 20 as shown in FIG. 2, and the movement of condensation water is blocked toward the adhesive mortar 20 side , And the deterioration of the adhesion strength of the adhesive mortar (20) due to exposure to dew condensation is prevented.

A valve 16 and an extinguishing agent inlet 18 are formed at the end of the water discharge pipe 14. An extinguishing agent tank 19 is connected to the extinguishing agent inlet opening 18 to open and close by a control unit including a subject sensor, When the control unit detects a fire, the valve 16 is turned off and the extinguishing agent tank 19 is opened to spray the extinguishing agent between the building outer wall 1 and the fire-extinguishing panel 100. At this time, the valve 16 is installed at the end of the drain pipe 14, and the extinguishing agent inlet 18 is provided at the end of the valve.

When the valve 16 is turned off and the extinguishing agent tank 19 is opened, the extinguishing agent injected through the extinguishing agent inlet port 18 flows backward along the drainage pipe 14, The mixture is dispersed and injected into the area L between the building outer wall 1 and the fireproof insulation panel 100 so that the fire extinguishing agent is quickly extinguished even if a flame flows into the space between the building outer wall 1 and the fireproof insulation panel 100 during a fire.

In addition, the adhesive mortar 20 according to the present invention is provided for adhering and fixing the fire-extinguishing and insulating panel 100 to the building outer wall 1. As shown in FIG. 2, the adhesive mortar 20 is disposed in a point-contact manner on the building outer wall 1 so that the fireproof panel 100 is attached to and supported by the joint partition 300, Since it has a double fixed structure that is fixed in place, it is prevented from being detached due to a typhoon, an external force due to an earthquake, and a decrease in adhesive force.

6, the flame-retardant thermal insulation panel 100 is independently constrained in the joint section 300, which is a combination of the straight joint 320 and the cross-shaped joint 340. At this time, the straight type joint 320 includes a gap maintaining bar 322 inserted between the two flameless thermal insulating panels 100 opposed to each other and having the U-shaped trough 322a formed in a straight line so as to support the respective side surfaces thereof, And a finishing plate 324 which extends at right angles to both sides of the bar 322 and restrains an outer side surface of the fireproof heat insulating panel 100.

The cruciform joint 340 is inserted between the corner areas of the four flameproof heat insulation panels 100 facing each other and has a gap maintaining bar 342 in which the U-shaped trough 342a is formed in a cross shape so as to support the respective side surfaces thereof And a finishing piece 344 extending perpendicularly from the gap retaining bar 342 and restricting the outer side surface of the incombustible heat insulating material 100.

At this time, a fastening hole is formed in the U-shaped trough 322a of the straight type joint 320 and the cross-shaped joint 340, and the fastener is inserted through the fastening hole to be fastened to the outer wall 1 of the building.

The U-shaped troughs 322a and 344a are opened to the outside of the building so that after the fireproof thermal insulation panel 100 is installed, a smooth material 360 (including 360 to 50% of expansive additive) . In addition to the fact that the U-shaped bones 322a and 344a are closed by the smoothing material 360, the cement-based expanding agent expands in the cement hardening process due to the formation of Ettingite and the expansion action of the lime, (342), the fire-extinguishing panel 100 independently accommodated in the joint section 300 is firmly restrained, and the heat bridging phenomenon between the fire-extinguishing heat insulating panels 100 is tightly blocked to improve the heat insulating performance.

7, at least two of the fire-proof and heat insulating panels 100 are overlapped with each other, the side overlapping boundary lines of the fire-proof and heat insulating panel 100 are finished by the fireproof heat insulating tape 180, The boundary line is finished by the hot expansion tape 190 to which the inorganic combustible saturation layer 400 is applied.

The inorganic combustible saturated layer 400 may include 1 to 30 parts by weight of a capsule containing an aluminum metal oxide whose moisture content is controlled and at least one inert inflatable powder of sodium silicate, calcium carbonate, and silicate, sodium silicate, calcium carbonate 20 to 70 parts by weight of a binder composed of at least one member selected from the group consisting of aluminum hydroxide, magnesium hydroxide, copper hydroxide, calcium carbonate, boric acid, phosphoric acid salt and phosphorus flame retardant, and 0.01 to 3 parts by weight of a stabilized foam auxiliary material And the inorganic combustible saturation layer (400) is provided to expand the capsule by a high temperature when a fire occurs.

14, the inorganic combustible saturation layer 400 is installed at a position corresponding to the upper or lower portion of the window 2 formed on the building outer wall 1, or a position corresponding to the upper or lower portion, or a position corresponding to each building boundary line of the building . As shown in FIG. 14 (b), when the fire occurs, the inorganic combustible saturated layer 400 is expanded due to the high temperature, and the opening of the window 2 is reduced, so that the upward movement of the flame, smoke and heat is blocked, In addition, while ensuring emergency evacuation time, the damage caused by asphyxiation is minimized.

In FIG. 8, an inorganic combustible saturated layer 400 is applied to the outer circumferential surface of the fire-extinguishing panel 100. Wherein the inorganic combustible saturated layer 400 comprises 1 to 30 parts by weight of a capsule containing an aluminum metal oxide whose moisture content is controlled and at least one inert expandable powder of sodium silicate, calcium carbonate and silicate, sodium silicate, calcium carbonate, And 0.01 to 3 parts by weight of a stabilized foam auxiliary material composed of at least one kind selected from aluminum hydroxide, magnesium hydroxide, copper hydroxide, calcium carbonate, boric acid, phosphate and phosphorus flame retardant, , And the inorganic combustible saturation layer (400) is provided to expand the capsule by a high temperature when a fire occurs.

Further, the fixture 200 according to the present invention is provided so as to be fastened at a position where the corner portions of at least two fireproof thermal insulation panels 100 are in contact with each other. The fixture 200 includes a plate type head part 220 pressed against the outer side surface of the fireproof insulation panel 100 and a shaft pin part 240 fixed to the building outer wall 1 to support the plate type head part 220 Like head portion 220 is formed on the outer side of the plate-shaped head portion 220 to increase the adhesive strength with the inorganic combustible saturation layer 400. The edge portion of the plate-shaped head portion 220 is provided with a plurality of extension bands 224 are formed in an arcuate shape, a depression groove portion 226 is formed between the extension band 224 and the plate-like head portion 220. 9, the extension band 224 is formed in an arcuate shape so that both ends thereof are connected to the plate-shaped head portion 220, and the intermediate region is spaced apart from the plate-shaped head portion 220 to form the depressed groove portion 226.

Accordingly, when the fixture 200 is fastened, the fireproof insulation panel 100 is molded and protruded in the same shape as the depressed trench 226, and is engaged and fixed in the shape of an oblique angle, so that a fixing force is further exerted in the plane direction of the fireproof insulation panel 100 Flow is prevented.

10A, the plate-shaped head part 220 is separated from the shaft pin part 240 and has a fastening hole 228 formed at the center thereof. A flange plate 228a is formed on the inner circumferential surface of the fastening hole 228, The shaft pin portion 240 is fitted into the coupling hole 228 of the plate-shaped head portion 220 to form a stop projection 242 at a position corresponding to the flange portion 228a. Shaped projection having an inclined surface 244. [

10 (b), the plate-type head part 220 is separated from the shaft pin part 240 so that a coupling hole 228 is formed at the center, a key groove 228b is formed on the inner peripheral surface of the coupling hole 228, And a plurality of stop projections 242 are formed at positions corresponding to the key grooves 228b while being fitted into the fastening holes 228 of the plate type head part 220. The plate type head part 220 When the plate-shaped head portion 220 is rotated with the fastening holes 228 of the fastening holes 228 interposed therebetween, the fastening holes 228 are fastened to the stop protrusions 242 and fixed in position.

And the plate-like head portion 220 is fixed by a one-touching method in which the plate-like head portion 220 is pressed or fitted with the fastening hole 228 sandwiched between the shaft pin portions 240. The fastening position of the plate- 242 so as to provide a versatility in which the fire-retardant insulating panel 100 of various thicknesses is fixed.

12, an insulating washer 260 is provided on the inside or outside of the plate-type head part 220 or an insulating washer (not shown) coated on the inside or outside of the plate type head part 220 with an inorganic combustible saturated layer 400 260 are provided. 12 (a) shows a state in which the heat insulating washer 260 coated with the inorganic combustible saturated layer 400 is disposed on the inner side surface of the plate type head part 220, and FIG. 12 (b) 12 (c) shows a state in which the heat insulating washer 260 is installed on the outer side of the plate-type head part 220, and FIG. 12 (d) And a heat insulating washer 260 having a smaller diameter than the diameter of the plate-shaped head 220 is installed on the inner side of the plate-shaped head 220 and the fire- Thereby improving airtightness and heat insulation.

Wherein the inorganic combustible saturated layer 400 comprises 1 to 30 parts by weight of a capsule containing an aluminum metal oxide whose moisture content is controlled and at least one inert expandable powder of sodium silicate, calcium carbonate and silicate, sodium silicate, calcium carbonate, And 0.01 to 3 parts by weight of a stabilized foam auxiliary material composed of at least one kind selected from aluminum hydroxide, magnesium hydroxide, copper hydroxide, calcium carbonate, boric acid, phosphate and phosphorus flame retardant, , And the inorganic combustible saturation layer (400) is provided to expand the capsule by a high temperature when a fire occurs.

The inorganic combustible saturating layer 400 of the insulating washer 260 is expanded to a high temperature together with the inorganic combustible saturated layer 400 coated on the outer circumferential surface of the fire-extinguishing panel 100, It is maintained firmly.

11, the fixture 200 includes a plate-shaped head portion 220 having a fastening hole 228 formed at the center thereof while being pressed against the outer side surface of the fireproof thermal insulating panel 100, The other end of the hollow portion is connected to the pin portion 240 and the shaft pin portion 240 and the other end of the hollow portion extends in the expanded size with respect to the thickness of the fireproof thermal insulating panel 100 to be inserted into the fastening hole 228 of the plate- And a finishing cap 290 coupled to the fastening holes 228 of the plate-shaped head portion 220 in a state of being fitted in the heat insulating mesh tube 280. As the plate-like head part 220 is supported by the heat insulating mesh tube 280, the heat flow through the fixture 200 is prevented and the heat insulating function is improved. In addition, due to the flexibility of the heat insulating mesh tube 280, 100), it is possible to control the fine position.

13, between the fireproof insulation panel 100 at the position corresponding to the upper or lower portion, the upper or lower portion of the window 2 formed in the building outer wall 1, or at the position corresponding to each building boundary line of the building, A fire line 500 is formed which is formed of a fireproof insulation block 520 including an inorganic combustible saturation layer 400. The fire-proof and heat insulating block 520 protrudes outward from the fire-extinguishing and insulating panel 100 to form the fire-fighting line 500, As the capsule is expanded, the opening of the window (2) is reduced, the upper movement of the flame, smoke and heat is blocked to prevent the spread of the flame, and the advantage of minimizing the damage of the large- have.

In addition, a fire extinguishing agent pack 540 containing 50 to 100 parts by weight of carbon dioxide on the basis of 100 parts by weight of the extinguishing agent is installed in the fire line 500. At this time, the extinguishing agent is provided in liquid or powder form. Thus, when the fire extinguishing agent pack 540 is exposed to a high temperature during a fire, the fire extinguishing agent is blown out by the carbon dioxide expanding force, and the fire extinguishing agent is prevented from spreading the fire, thereby securing the emergency evacuation time.

1: building exterior wall 10: condensation water discharge line
12: U-shaped pipe 14: Water pipe
16: Valve 18: Extinguishing agent inlet
19: Extinguishing agent tank 20: Adhesive mortar
100: fire-proof insulating panel 120: inorganic flat layer
140: lamina layer 142: incision line
144: Upward phage holder 146: Downward phage holder
160: fireproof reinforcement layer 180: fireproof insulation tape
190: high temperature expansion tape 200: fastener
220: head part 240: shaft pin part
260: insulating washer 280: insulating mesh tube
290: Finishing cap 300: Joint block
320: Straight joint 340: Inserter joint
360: smoothening material 400: inorganic combustible saturated layer
500: Fire wire 520: Fireproof insulation block
540: Extinguishing Agent Pack

Claims (13)

Inorganic fibers fused with basic igneous rock, fibers fused with glass having a low melting point, fibers obtained by melting calcium silicate ores at high temperature, A fireproof panel 100 comprising at least one layer of foamed concrete, aerogels, ceramics, and vacuum insulation material cured at high temperature and high pressure using ceragallo, silica sand and lime as raw materials;
The flame-resistant heat insulating panel 100 includes an inorganic flat layer 120 coated on a surface thereof;
A fireproof reinforcement layer 160 disposed between the fireproof thermal insulation panel 100 and the inorganic flat layer 120 and composed of the aluminum thin plate layer 140 and the glass fiber net layer 160;
And a condensation water discharge line (10) installed between the building outer wall (1) and the fireproof insulation panel (100)
A horizontal cut line 142 is formed at a plurality of locations in the aluminum thin plate layer 140 of the fireproof reinforcement layer 160 to form upper and lower cut regions 142a and 142b,
The lower cutout region 142a of one of the other lateral incision lines 142 is formed with an upward phage holder 144 that is bent in a direction of the outer lateral side of the aluminum sheet layer 140 so as to pass upward, The glass fiber net layer 160 and the inorganic flat layer 120 are fixed on the upper surface of the light guide plate 144,
The upper incision region 142a of the other lateral incision line 142 is bent downward in the direction of the inner side to form a downward phage holder 146 penetrating downward and the downward phage holder 146 has a lower face, And is held and fixed in position by the heat insulating panel 100,
The fireproof panel 100 is independently constrained within a joint section 300 formed by a combination of a straight joint 320 and a cross joint 340 and the straight joint 320 includes two fireproof panels 100 And a U-shaped trough 322a is formed in a straight line so as to support the side surfaces of the U-shaped trough 322a, And a finishing plate 324 for restricting the outer side surfaces of the flameproof panel 100. The cruciform joint 340 is inserted between the corner areas of the four flameproof panels 100 facing each other to form U- And a finishing piece 344 extending perpendicularly from the gap retaining bar 342 and restricting the outer side surface of the fireproof thermal insulating material 100. The U-shaped rib 322a ) 344a is open to the outside of the building, And a smooth material (360) including 40 to 50 parts by weight of an expansive additive based on 100 parts by weight of cement after filling the board (100). Composite exterior structure for construction where the inorganic flat layer is highly integrated with the net layer. The method according to claim 1,
The flameproof panel 100 is formed with a raised protrusion 120 at a position corresponding to the fixture 200. The protrusion 120 is compressed by the pressing force when the fixture 200 is fastened, And the height of the fixture (200) is limited by the high-density insulation layer (140) so that the surface of the fixture (200) is maintained so as to maintain the outer surface and flatness of the fireproof insulation panel (100) Composite exterior structure for construction where the inorganic flat layer is highly integrated with fiber netting. The method according to claim 1,
The dewatering water discharge line 10 includes a plurality of U-shaped branch pipes 12 (see FIG. 1) that are installed at an oblique angle to the building outer wall 1 and collect dew condensed water on the inner wall of the building 1 and the inner wall of the fire- And a drain pipe 14 connected to the lower side end of the U-shaped branch pipe 12 for discharging condensed water collected therein. The drain pipe 14 has a valve 16 and a fire extinguishing agent inlet 18 And a fire extinguisher tank 19 which is opened and closed by a control unit including a fire detection sensor is connected to the fire extinguishing agent inlet port 18. When a fire is detected by the control unit, the valve 16 is turned off and the fire extinguisher tank 19 And the fire extinguishing agent is sprayed between the building outer wall 1 and the fire-retardant insulating panel 100. The inorganic flat layer is formed by using the aluminum thin plate layer and the glass fiber net layer, Exterior structure. delete The method according to claim 1,
When at least two of the flame-retardant insulating panels 100 are overlapped, the side overlapping boundary line of the flame-retardant insulating panel 100 is finished by the flame-retardant heat insulating tape 180, or the side overlapping boundary line of the flame- Wherein the inorganic flat layer is highly integrated with the aluminum thin plate layer and the glass fiber net layer, wherein the inorganic flat layer is finished by the hot expansion tape (190) coated with the combustible saturation layer (400). 6. The method of claim 5,
The inorganic combustible saturated layer 400 may include 1 to 30 parts by weight of a capsule containing an aluminum metal oxide whose moisture content is controlled and at least one inert inflatable powder of sodium silicate, calcium carbonate or silicate, sodium silicate, calcium carbonate, And 0.01 to 3 parts by weight of a stabilized foam auxiliary material composed of at least one kind selected from aluminum hydroxide, magnesium hydroxide, copper hydroxide, calcium carbonate, boric acid, phosphate and phosphorus flame retardant, And the inorganic combustible saturation layer (400) is provided to expand the capsules due to high temperature when a fire occurs. By using the aluminum thin plate layer and the glass fiber net layer, the inorganic flat layer is highly integrated with the building, Exterior structure. The method according to claim 1,
An inorganic combustible saturation layer (400) is applied to the outer circumferential surface of the fireproof panel (100), and the inorganic combustible saturation layer (400) is formed of an aluminum metal oxide having a controlled moisture content and at least one of sodium silicate, calcium carbonate, 1 to 30 parts by weight of a capsule containing at least one inert expandable powder, 20 to 70 parts by weight of a binder composed of at least one of sodium silicate, calcium carbonate and silicate, aluminum hydroxide, magnesium hydroxide, copper hydroxide, calcium carbonate, boric acid, And 0.01 to 3 parts by weight of a stabilized foam auxiliary material composed of at least one of phosphorus flame retardant and inorganic flame retardant, wherein the inorganic combustible saturated layer (400) is provided to expand capsules due to high temperature when a fire occurs, And a glass fiber mesh layer, the inorganic flat layer is highly integrated. 6. The method of claim 5,
The fixture 200 includes a plate type head part 220 pressed against the outer side surface of the fireproof insulation panel 100 and a shaft pin part 240 fixed to the building outer wall 1 to support the plate type head part 220 Like head portion 220 is formed on the outer side surface of the plate-shaped head portion 220 so as to increase the adhesive force with the inorganic combustible saturated layer 400. A plurality of extension bands 224 And a recessed groove portion 226 is formed between the extended band 224 and the plate-shaped head portion 220. When the fastener 200 is fastened, the recessed groove 226 is formed in the same shape as the recessed heat- 100) is formed to be engaged and fixed with an oblique angle structure. The composite flat external structure for building having high flatness of the inorganic flat layer by using the aluminum thin plate layer and the glass fiber net layer. 9. The method of claim 8,
The plate-shaped head part 220 is separated from the shaft pin part 240 so that a fastening hole 228 is formed at the center thereof. A flange plate 228a is formed on the inner circumferential surface of the fastening hole 228, And a stop projection 242 is formed at a position corresponding to the flange 228a while being fitted to the coupling hole 228 of the plate-like head 220. The stop projection 242 is formed by a serration- Or the plate type head part 220 is separated from the shaft pin part 240 so that a coupling hole 228 is formed at the center and a key groove 228b is formed at the inner peripheral surface of the coupling hole 228. The shaft pin part 240 Like head portion 220 is fitted to the shaft pin portion 240 while the stop protrusion 242 is formed at a position corresponding to the key groove 228b while being fitted into the fastening hole 228 of the plate- When the plate-shaped head portion 220 is rotated with the fastening holes 228 of the fastening holes 228 interposed therebetween, the fastening holes 228 are engaged with the stop projections 242 to be fixed in position. Composite facade structure for construction where the inorganic flat layer is highly integrated by using a thin sheet metal layer and a fiberglass mesh layer. The method according to claim 1,
The fixture 200 includes a plate-shaped head portion 220 having a fastening hole 228 formed at the center thereof while being pressed against the outer side surface of the fire-proof and heat insulating panel 100, a shaft pin portion 240 fixed to the building outer wall 1, Shaped head tube 220 and a hollow insulated mesh tube 220 inserted into the fastening hole 228 of the plate-shaped head part 220. The other end of the hollow heat- And a closure cap (290) coupled to the coupling hole (228) of the plate-shaped head part (220) in a state of being fitted in the heat insulating mesh tube (280) , The composite flat structure with a high degree of integration is used. 11. The method according to any one of claims 8 to 10,
An insulating washer 260 is provided on the inside or the outside of the plate type head part 220 or an insulating washer 260 coated on the inside or outside of the plate type head part 220 with an inorganic combustible saturated layer 400 And the inorganic combustible saturation layer (400) of the heat insulating washer (260) is compressed and fixed on the outer circumferential surface of the fireproof thermal insulating panel (100) together with the inorganic combustible saturated layer (400) And a glass fiber mesh layer, the inorganic flat layer is highly integrated. The method according to claim 6,
Between the fireproof panel 100 at the location corresponding to the upper or lower or upper and lower portions of the window 2 formed in the building outer wall 1 or at the location corresponding to each building boundary line of the building, the mineral wool, (500), which is formed of a fireproof insulation block (520) including an aluminum flat plate layer (400), is constructed. Exterior structure. 13. The method of claim 12,
A fire extinguishing agent pack 540 containing 50 to 100 parts by weight of carbon dioxide based on 100 parts by weight of the fire extinguishing agent is installed in the fire fighting line 500. The fire extinguishing agent pack 540 is blown out by a carbon dioxide Wherein the inorganic flat layer is highly integrated with the aluminum thin plate layer and the glass fiber net layer.

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