KR101793046B1 - Building insulation material and its manufacturing method - Google Patents

Abstract

The inner board 100 and the outer board 200 are formed of a fireproof or flame retardant fabric material. The inner board 100 and the outer board 200 are made of a flame retardant material. To prevent diffusion. The inner board 100 is made of a calcium silicate-based ore material which is an environmentally friendly inorganic material. The calcium silicate-based ore material maintains high-temperature safety and does not ignite, has a low thermal conductivity, and has insulation, warming effect, suppresses corrosion of inner member as much as possible, and does not absorb atmospheric moisture. The outer board 200 is made of a material mainly composed of silica (SiO ₂ ), aluminum oxide (Al ₂ O ₂ ), lime (CaO), and silica sand as a main component of cement. With such a component, the outer board 200 has high strength and impact resistance, is strong in fire resistance, water resistance and chemical resistance, has little change in length due to moisture absorption, and has a light weight effect.

Description

{Building insulation material and its manufacturing method}

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a building insulation material used for a building exterior wall surface, and more particularly, to a building insulation material having excellent fire resistance, which is used for prevention of flame diffusion when a fire is produced by using fire-

Generally, building insulation is used in buildings to prevent heat from the outside and to prevent internal heat from being released. The building insulation is attached to the exterior wall of the building to form an insulation wall. It blocks heat from the outside of the building and prevents the internal heat from being released. However, the conventional heat insulating material 30 is not treated in an unburned or flame-retardant manner. The conventional heat insulator 30 has a heat insulation performance, but has a problem of being vulnerable to high temperature, and various problems have been pointed out in a building fire accident. Particularly, when a fire occurs in a building without incombustibility or flame-retarding treatment, the heat insulating material becomes a combustible material, and the flame can be rapidly diffused. If the flame spreads, toxic gases are released in large quantities, causing serious property damage and human casualties.

These issues have been amended to prevent the spread of fire in the recently revised Korean Building Code and its Enforcement Decree. In particular, buildings in commercial areas or buildings with more than 6 stories or 22 meters or more must comply with the fire prevention standard in accordance with Article 61 of the Enforcement Decree of the Building Act.

Here, the building fire prevention standard is to prevent vertical fire spreading in case of fire. During the construction of the building, the space between the outer wall finishing material and the supporting structure of the outer wall finishing material is filled with a fireproof material of at least 400mm thick.

 The building insulation material of the former styrofoam is deformed and damaged by the pressing force of the fixing member when the fixing member is inserted into the outer wall surface of the building. At this time, due to deformation and damage of the heat insulating material, there is a disadvantage in the field work. Deformed and damaged thermal insulation can reduce thermal insulation and thermal insulation effects. This results in an uneven insulation wall due to the damage of the insulation, thereby providing an additional construction process to fill the deformed and damaged portions. Therefore, there is a problem that it is relatively complicated, and it takes a long time and a high cost.

1. Registration Patent No. 10-1218238 " Insulation for building and method for manufacturing the same " 2. Registered Patent Publication No. 10-1313983 " Insulation for Building and Method of Manufacturing the Same &

SUMMARY OF THE INVENTION Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art, and it is an object of the present invention to provide a method of manufacturing the same. Another object of the present invention is to provide a building insulation material and a method of manufacturing the same that prevent relative movement and damage due to the pressing force of the fixing member when the fixing member is inserted into the insulation material.

The heat insulating material having excellent fire resistance of the present invention is obtained by laminating inorganic fibers produced by melting and liquefying calcium silicate-based ores at a high temperature to have a predetermined height and having a predetermined width (W), length (L) and height An inner board 100, an outer board 200 attached to one or both sides of the inner board 100, a fixing member 300 for fixing the inner board 100 through the outer board 200 and the inner board 100, And a control unit.

The inner board 100 may be divided into at least one unit inner board 100 having a predetermined unit length I or unit width dw by cutting the inner board 100 at regular intervals in the direction of the length L or the width W, Wherein the unit inner board 100 is rotated so that the unit length I or the unit width dw is equal to the height H of the inner board, 100 are bonded to each other.

In order to facilitate fixing of the inner board 100 to the wall surface and to reduce deformation of the inner board 100 when the fixing member 300 is fixed to the wall surface, Further includes an insertion guide 400 which is inserted and fixed in the hole h, further comprising a hole h passing through the outer board 100 and the outer board 200.

The present invention is also characterized in that the inner board 100 is placed on the lower surface of the inner board 100 before the outer board 200 is attached to the inner board 100, And a packaging member 500 surrounding the packaging member 500.

The method for manufacturing a heat insulating material having excellent fire resistance according to the present invention comprises the steps of laminating inorganic fibers produced by melting and liquefying calcium silicate-based ores at a high temperature with a predetermined height to form a predetermined width (W), a length (L) A unit inner board manufacturing step of cutting the inner board 100 having the inner board 100 having the predetermined unit length l or the unit width dw by cutting the inner board 100 in the longitudinal direction, The unit inner board 100 is rotated so that the unit length l or the unit width dw becomes a height so that the cut unit inner boards 100 are bonded to each other so that the height H of the unit inner board 100, A packaging member packaging step of wrapping the surface of the inner board 100 with the packaging member 500 after the inner board 100 is rearranged and a packaging member packaging step of wrapping the inner board 100 To an outer board joining step for joining the outer board 200 to the outer board joining step Characterized in that the row.

The present invention also includes a hole drilling step for drilling a hole h for penetrating the inner board 100 to which the outer board 200 is bonded, a fixing step of inserting the fixing member 300 into the hole h, Member insertion step.

Using the improved building insulation according to the present invention and the method of manufacturing the same, the inner board 100 and the outer board 200 are prevented from spreading by using fire-retardant or flame retardant materials during a fire. The calcium silicate-based ore material used for the inner board 100 maintains high-temperature safety and does not ignite, has a low thermal conductivity, and has an effect of heat insulation and thermal insulation. It suppresses the corrosion of the inner member as much as possible, There is no effect. The outer board 200 is made of silica (SiO ₂ ), aluminum oxide (Al ₂ O ₂ ), lime (CaO), and silica sand as main components of cement. With these components, the outer board 200 has high strength and impact resistance, is excellent in fire resistance, strong in chemical resistance, has little change in length due to moisture absorption, is excellent in water resistance, and has a light weight effect .

 Also, the inner board 100 can be manufactured by cutting the inner board 100 at regular intervals, rotating it, and bonding it to improve the compressive strength, strengthen the fire resistance function, and make it easy to construct and dust-free.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a cross-sectional view showing a conventional heat insulating material fixed on a wall surface of a building and a heat insulating and fixing member having excellent fire resistance.
2 is a perspective view showing a main configuration of an inner board, an outer board and a fixing member of the present invention.
3 is an enlarged view showing an enlarged portion "A" of the present invention.
4 is a cross-sectional view showing a problem when pressing a building insulation.
5 is a perspective view illustrating a process of manufacturing the inner board of the present invention by cutting the inner board in the longitudinal direction.
6 is a perspective view showing a process of manufacturing the inner board of the present invention by cutting it in the width direction.
7 is a perspective view showing a process of wrapping an inner board of the present invention with a packaging member.
8 is a perspective view showing a main configuration of cutting, rearrangement and joining of an inner board of the present invention, and an outer board and a fixing member.

Hereinafter, one embodiment of the present invention will be described in detail with reference to the drawings.

FIG. 1 is a cross-sectional view illustrating a conventional heat insulating material 30, a building heat insulating material 1000 and a fixing member 300 which are fixed to a building outer wall surface 10. FIG. 2 is a side view of the inner board 100 and the outer board FIG. 3 is an enlarged view of the 'A' portion of the present invention, and FIG. 4 is a perspective view showing a problem that occurs when the building insulation 1000 is pressed. FIG. 5 is a perspective view showing a process of manufacturing the inner board 100 according to the present invention by cutting the inner board 100 in the longitudinal direction L. FIG. 6 is a plan view of the inner board 100 according to the present invention, FIG. 7 is a perspective view showing a process of wrapping the inner board 100 of the present invention with the wrapping member 500, FIG. 8 is a perspective view illustrating a cutting and rearrangement of the inner board 100 according to the present invention. And the joining, the outer board 200, and the fixing member 300 according to an embodiment of the present invention.

Referring to FIG. 1, a heat insulating material of a fibrous material is attached to the outer wall surface 10 of the building to be filled tightly in order to improve the heat insulation and heat insulating function of the building. If a fire occurs in a building when the structure of the insulation is not flame retarded or flame-retarded, the organic compound material of the insulation becomes a flammable material, and the flame of the building is rapidly diffused during the fire. To overcome this disadvantage, the thermal insulation structure 1000 of the present invention uses a non-burnable fabric material to prevent flame spread in the event of a fire. The space between the outer wall finishing material and the supporting structure of the outer wall finishing material is filled tightly with incombustible insulation material. More preferably, the width W of the heat insulating material 1000 may be 400 mm or more. Due to the vertical diffusion preventing structure, it is possible to prevent the spread of the incineration during the fire.

Referring to FIG. 2, the structure of the building insulation 1000 of the present invention can be known. The inner board 100 has a predetermined width W, a length L and a height H. The outer board 200 is bonded to the inner board 100. At this time, the inner board 100 and the outer board 200 are formed to have the same area so that a single plate shape can be formed at the time of bonding. A through hole h for smoothly fixing the inner wall 100 and the inner wall 100 to the inside of the inner board 100 and for reducing the deformation of the inner board 100 when the inner board 100 is fixed is formed . The insertion guider 400 is inserted and fixed in the hole h. The insertion guider 400 may be made of vermiculite, ferrite, cement, or the like, which has a nonflammable property. The fixing member 300 is provided for attaching the heat insulating material to the wall of the building and is inserted into the insertion hole 401 of the insertion guider 400.

The inner board 100 is made of an inorganic material such as calcium silicate based ore material (natural ore such as basalt, phylactric rock, limestone or granite) or slag (a material of nonmetallic composition Or a metal oxide composition generated on the bath surface when the metal is dissolved).

The inner board 100 is made of a calcium silicate-based ore material that is an environmentally friendly inorganic material. It is characterized in that the calcium silicate-based ore material is used to maintain high-temperature safety and does not ignite, has a low thermal conductivity, has insulation, has a warming effect, suppresses corrosion of the inner member as much as possible, and does not absorb atmospheric moisture.

The outer board 200 may be attached to one or both sides of the inner board 100. And is attached to the upper surface of the inner board 100 in order to increase the resistance against the pressing force for inserting the fixing member 300 at the time of installation. When attached to both sides of the inner board 100, are attached to the upper surface and the rear surface, respectively. The outer board 200 attached to the back surface is brought into contact with the outer wall surface 10 of the building. At this time, the surface of the building heat insulator 1000 is made flat so that it can be adhered to the building outer wall surface 10 without any gap

The outer board 200 mixes the mixture obtained by mixing the main components of cement and the mixture obtained by mixing the non-burnable pulp chips, the abrasive powder and the fibers, and then the mixture is stirred again to stir the water glass. The material obtained after stirring is put into a mold, hot pressed under pressure, molded, dried and aged to obtain a uniform thickness and surface.

The outer board 200 is made of silica (SiO ₂ ), aluminum oxide (Al ₂ O ₂ ), lime (CaO), and silica sand as main components of cement. It has strength and impact resistance, is excellent in fire resistance, is strong in chemical resistance, has little change in length due to moisture absorption, is excellent in water resistance, and is light in weight.

Referring to FIG. 3, which is an enlarged view of FIG. 2, the fixing member 300 includes a fixing rib 310 and a fixing pin 320. The fixed rib 310 is composed of a wing portion 311, a body portion 312, a wall fixing portion 313 and a fixing pipe 314. The wing portion 311 is formed in the shape of a plate so that a penetrating portion serving as an entrance of the fixing pipe 314 is formed at the center. The body 312 is inserted through the inner board 100 and the outer board 200 of the building insulation 1000. The wall fixing portion 313 is partially inserted into the concrete wall 20 for fixing to the building outer wall surface 10. The fixing pipe 314 is in the shape of a hollow cylinder so that the fixing pin 320 can be inserted. The fixing pin 320 has a relatively small diameter for insertion into the fixing tube 314. The nail body 321 is inserted into the fixing tube 314 and the nail end 322 is extended outside the fixing tube 314 to be partly inserted into the concrete wall 20.

Referring to FIG. 4, the fixing member 300 is inserted into the outer wall surface 10 of the building to fix the inner board 100 to the inner board 100 to compress and deform the inner board 100 when pressure is applied thereto. At this time, when the fixing member 300 is inserted into the hole h of the inner board 100 without the insertion guider 400, the inner board 100 is deformed like the solid line a. The inner board 100 is compressed and deformed by the pressing force in the height direction H for inserting the fixing member 300. [

5, there is a problem that the inner board 100 of the heat insulating material is compressed when the pressure is applied in the height H direction. The inner board 100 is manufactured using a calcium silicate-based ore material in which fibers are first melted and fibers are separated. When supplied in a molten state to the fiber producing means for producing the mineral wool fibers, the mineral wool fibers are discharged to the discharge pipe. The discharged fibers are deposited on a moving means and fixed and compressed by a vacuum force to form a mineral wool fiber layer. Therefore, the heat insulating material formed as the layer is sequentially stacked in the direction of the height (H), so that a space may be formed between the spaces in the height direction, so that it may be easily compressed when a compressive force is applied in the direction of the height (H).

5, the inner board 100 has a predetermined width W, a length L, and a height H, as shown in FIG. And is formed as a unit inner board 100 having a predetermined unit length I, a height H and a width W by cutting at regular intervals in the direction of the length L. The unit inner board 100 rotates so that the unit length I becomes the height H of the inner board 100 before cutting. And the rotated unit inner board 100 are bonded to each other. The inner board 100 having been rearranged and joined is improved in the compressive force in the height H direction. Therefore, when the fixing member 300 is inserted, the problem of compression and deformation due to the insertion force can be solved.

6, the inner board 100 can be cut not only in the length L direction but also in the width W direction.

When cutting in the width W direction, the inner board 100 can be cut at a smaller number of times than when cut in the length L direction.

7, the packaging member 500 is placed on the lower surface of the inner board 100 before the outer board 200 is attached. And surrounds the inner board 100 to cover a part of the upper surface. At this time, the surface C marked by the solid line may be cut off so that the packaging members 500 do not overlap. The packaging member (500) protects the outside of the inner board (100). Since the outside of the board is protected, it is possible to work without dust, so that workability is easy and environmental pollution problem can be solved. The packaging member 500 may be formed of a woven fabric of silver or glass fiber.

That is, referring to FIGS. 1 to 8, the inner board 100 and the outer board 200 of the building heat insulator 1000 are made of a material having nonflammability. The inner board 100 is made of a calcium silicate-based ore material which is an environmentally friendly inorganic material. The outer board 200 is made of a CRC board (Cellulose Fiber Reinforced Cement Board) as a main raw material for cement. The building insulation 1000 made of a nonflammable material can prevent the spread of the incineration during a fire.

The inner board 100 cuts the length L so as to be the unit length I. The cut inner board 100 is rotated so that the unit length I becomes the height H. The rotated unit inner boards 100 are joined to each other to have a predetermined width W, length L, and height H, respectively. It is possible to manufacture the inner board 100 in which the compressive stress is strengthened in the height direction H by cutting, rearrangement and joining. The outer board 200 is bonded to one or both surfaces of the inner board 100. At this time, the inner board 100 and the outer board 200 are formed to have the same area so that a single plate shape can be formed at the time of bonding. A through hole h for smoothly fixing the inner wall 100 and the inner wall 100 to the inner wall 100 and reducing the deformation of the inner wall 100 when the inner wall 100 is fixed . And an insertion guider 400 inserted and fixed in the hole h. The insertion guider 400 may be made of vermiculite, ferrite, cement, or the like, which has a nonflammable property. The insertion guider 400 improves the compressive stress with respect to the force for inserting the fixing member 300. And also has an insertion hole 401 inside the insertion guider 400. The fixing member 300 inserted into the insertion hole 410 is installed to adhere the heat insulating material to the building outer wall surface 10. Since the insertion guider 400 is provided, the fixing member 300 can be easily inserted into the heat insulating material when the building is constructed.

It is possible to manufacture the building heat insulator 1000 of the present invention improved by inserting the insulated inner board 100 and the outer board 200, rearrangement of the inner board 100 to strengthen the compressive strength, and insertion of the inserting guider 400 .

In addition, the inner board 100 may be wrapped with the packaging member 500 to protect the inner side of the inner board 100. The packaging member 500 is placed on the lower surface of the inner board 100. The packaging member 500 surrounds the inner board 100 and covers a part of the upper surface of the inner board 100. The packaging member 500 is made of a silver foil or a glass fiber cloth. Since it covers the inner board 100, it can work without dust during cutting and construction work. It is easy to work because there is no dust, and the problem of environmental pollution can be reduced.

The building insulation 100 of the present invention may be made of a constructional material characterized by a nonflammable structure to prevent flame spread during a fire. In addition, by improving the compressive stress of the building insulation 1000, it is easy to install and dust-free. It is possible to increase the life of the insulation effect by reducing the deformation at the time of construction, and to improve the efficiency and the durability.

10: Building exterior wall surface 20: Concrete wall
30: Conventional insulation
100: inner board 200: outer board
300: fixing member 310: fixed rib
311: wing portion 312:
313: wall fixing part 314: fixing pipe
320: fixing pin 321: nail body
322: nail end portion 400: insertion guider
401: insertion hole 500: packing member
1000: Building insulation
h: Hall W: Width
H: Height L: Length
I: unit length Unit width: dw

Claims (6)

An inner board (100) having a predetermined width (W), a length (L), and a height (H) by stacking inorganic fibers prepared by melting and liquefying calcium silicate-based ores at a high temperature with a predetermined height;
An outer board 200 attached to the inner board 100;
And a fixing member (300) for fixing the outer board (200) and the inner board (100) through a wall,
In order to fix the inner board 100 and the wall surface smoothly, and to reduce the deformation of the inner board 100 when the fixing member 300 is fixed to the wall surface, the inner board 100 and the outer side Further comprising a hole (h) passing through the board (200)
Further includes an insertion guider 400 inserted and fixed in the hole h to improve the compressive stress of the inner board 100 and formed with an insertion hole 401 into which the fixing member 300 is inserted ,
The fixing member 300 includes a fixing rib 310 inserted into the insertion guider 400 and a fixing pin 320 inserted into the fixing rib 310,
The fixing rib 310 includes a fixing tube 314 which is hollow and hollow to insert the fixing pin 320 therein.
A wing portion 311 protruding in a plate shape at a top entrance portion of the fixing pipe 314;
A body 312 extending from a lower end of the fixing pipe 314 and passing through the inner board 100 and the outer board 200;
A wall surface fixing part 313 protruded from the lower end of the body part 312 and fixed to the wall surface to fix the outer board 200 and the inner board 100 to the wall surface; Lt; / RTI >
The fixing pin 320 includes a nail body 321 having a diameter smaller than the diameter of the fixing tube 314 inserted into the fixing tube 314;
And a nail end portion (322) formed at one side of the nail body (321) so that a part of the end portion is inserted into the wall surface. The method according to claim 1,
The inner board (100)
And at least one unit inner board 100 having a predetermined unit length I or unit width dw by cutting the inner board 100 at regular intervals in the direction of the length L or the width W, ,
The unit inner board 100 is rotated so that the unit length l or the unit width dw of the unit inner board 100 becomes the height H of the inner board, And the boards (100) are bonded to each other. delete 3. The method according to claim 1 or 2,
A packaging member (not shown) which is placed on a lower surface of the inner board 100 before the outer board 200 is attached to the inner board 100 and surrounds the upper surface of the inner board 100 by surrounding the inner board 100 500). ≪ / RTI > delete delete

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