KR20190066388A - Fire resistance dry wall structure - Google Patents

Abstract

The present invention relates to a dry fireproof wall. According to one embodiment of the present invention, a dry fireproof wall includes: a plurality of studs lengthily installed between a ceiling and a floor in a building in a vertical direction; a plurality of back surface finishing boards provided on the back of the plurality of studs; a plurality of front surface foundation boards provided in front of the stud and spaced apart from the back surface finishing board in a thickness direction crossing with the vertical direction to be provided thereon; and a plurality of retardant boards provided on a front surface of the front surface foundation board, wherein a first joint portion, in which two adjacent retardant boards meet with each other in a surface direction horizontally crossing with the thickness direction among the plurality of retardant boards, is provided with a first retardant sheet including flame retardant.

Description

{FIRE RESISTANCE DRY WALL STRUCTURE}

The present invention relates to a dry refractory wall.

The fire prevention measures of buildings are safety of people in the building, securing of fire fighting activities, prevention of fire spread, protection of property, prevention of building collapse, and prevention of danger around site. The most important of the fire prevention measures implemented in each building to achieve this purpose is to secure the fire resistance performance of the building members.

If the fire in the building can be restricted through a certain space of the fire protection zone, it will be easier to protect the residents' evacuation and human life. In addition, damage to buildings and water supplies can be reduced.

It is a partition member such as a floor and a wall that constitute a member space that plays a role directly in the fire prevention. This partition member can safely protect the evacuation passage from fire, and can also perform the digestive activity or rescue operation of the fire brigade without obstacle It has an important role in securing a base.

Domestic refractory products are rated from 30 minutes to 2 hours of refractory performance. By structure, it can be classified into stud wall type using fireproof gypsum board, steel wall type known as sandwich panel, concrete panel and rock surface, glass surface , Which is used in the field.

The steel structure wall structure showed a fire resistance performance of maximum 1 hour, and it seems that there is a limit to the application of the high-rise building and drywall was used. Currently, the most widely used method has been confirmed as a method of fixing a fireproof gypsum board to CH-STUD.

However, in the case of forming a drywall by using the fireproof gypsum board as described above, there is a disadvantage in that the fire wall can be easily diffused through an empty space inside the wall due to the nature of the dry wall, , The structure of the wall can be easily deformed if the external heat is not blocked due to the structure of the wall using the steel pillar as steel.

An object of the present invention is to provide a fireproof wall having improved fire resistance.

According to an embodiment of the present invention, there is provided a dry fireproof wall comprising: a plurality of bridges installed vertically between a ceiling and a floor in a building; A plurality of rear finishing boards disposed behind the plurality of spacers; A plurality of front deskboards disposed on the front side of the standpost and spaced apart from each other in the thickness direction perpendicular to the backside finish board; And a plurality of flame retardant boards disposed on a front surface of the front board, wherein a first joint portion where two flame retardant boards adjacent to each other in a plane direction intersecting with the thickness direction crosses the thickness direction, 1 nonflammable sheet is provided.

Here, the first joint portions of the plurality of flame retardant boards are staggered with respect to the second joint portions of the plurality of front board boards, and the first joint portions of the plurality of flame retardant boards are divided into a plurality of spaced- As shown in Fig.

In addition, each of the plurality of flame retardant boards may include a fire board disposed in contact with a front surface of the front board; A compressed fiber sheet covering a front surface of a fireproof board and containing a fiber sheet formed of a plastic nonwoven fabric material and a flame retardant; And a finish steel sheet for covering the side surface of the fireproof board and the front surface of the compressed fiber sheet. The finish steel sheet provided on each of the plurality of flame retardant boards may double cover the front board board exposed through the first joint portions.

Here, the first non-burnishing sheet may be positioned between the finishing steel sheet and the front base board at the first joint portion.

The width of the first non-burnishing sheet in the plane direction is larger than the width in the plane direction of the first joint portion, is smaller than twice the width in the normal direction of the joint portion, the thickness of the first non-burning sheet is larger than the thickness of the finishing steel sheet, In the range smaller than the fire board thickness, it may be between 0.5 mm and 2 mm.

Further, the material of the first cohesionless sheet may include flame-retardant particles containing graphite dispersed in the fiber sheet, and the flame-retardant particles may further include at least one of inorganic heat insulating material, urethane resin, and inorganic flame-retardant particles in addition to graphite.

The studs include a CH stud. The front surface of the CH stud is connected to the front board by screwing. The recessed grooves provided on both sides of the CH stud are provided with a plurality Each of the backside finish boards can be inserted and coupled.

Here, a second cohesive sheet including a flame retardant may be provided between the depressed grooves provided on both sides in the surface direction of the CH-type stud and the planar side surfaces of the plurality of back finishing boards.

Here, the width of the second cohesionless sheet in the thickness direction may be equal to the thickness of the plurality of back finishing boards, the thickness of the second cohesionless sheet may be between 0.5 mm and 2 mm, and the material of the second cohesionless sheet may be, It may be the same as the material of the sheet.

In addition, the plurality of back finishing boards are positioned such that each side faces in the vertical direction, and the H-type studs are positioned between each of the vertically oriented back finishing boards, and the H-type studs have depressed grooves on both sides in the vertical direction And the upper and lower side surfaces of each back surface finish board can be inserted into the depression grooves and coupled.

Here, a third non-burnable sheet including a flame retardant may be provided between the depressed grooves of the H-shaped stud and the upper and lower sides of each of the backside finish boards.

A dry fireproof wall according to an embodiment of the present invention includes a fireproof board disposed on a front surface of a fireproof wall and a first fireproof sheet including a fire retardant agent in a first joint portion between the fireproof boards, It is possible to more effectively block heat transmitted through the portion, thereby further improving the heat shielding function of the wall.

FIG. 1 is an example of a perspective view in which a dry fireproof wall according to the present invention is installed in a vertical direction between a ceiling and a floor in a building.
2 is an example of a front view of the dry fireproof wall shown in Fig.
3 is an example of a rear view of the dry fireproof wall shown in Fig.
4 is an example of a vertical sectional view of the dry fireproof wall shown in Fig.
5 is an example of a horizontal sectional view of the dry fireproof wall shown in Fig.
6 is an example of a horizontal sectional view of the flame retardant board of the dry fireproof wall shown in Fig.
FIG. 7 is an enlarged view of the first joint portion in FIG. 5 to explain the structure of the first joint portion of the flame-retardant board and the first non-burnable sheet in the dry fireproof wall shown in FIG.
8 is an example of a horizontal cross-sectional view of a quadrangular pyramid applied to a dry fireproof wall according to the present invention.
Fig. 9 is an enlarged view of the portion K1 in Fig. 5 for explaining the second cohesive sheet of the present invention.
10 is a view for explaining a third non-burning sheet of the present invention.
11 is a view for explaining a comparative example in which first, second and third incombustible sheets according to the present invention are not provided.
FIG. 12 is a view showing a case in which a flame is applied to a joint portion of a flame-retardant board on the entire surface of a fire-proof wall, a first example of a refractory wall having only a first incombustible sheet of the present invention, And FIG. 5 is a graph showing the temperature measured on the rear surface of each of the fire resistant walls according to the second example and the comparative example.
Fig. 13 is a graph showing the results of measurement of temperature at the front surface of each of the first example of the refractory wall according to the comparative example, the first example of the refractory wall of the present invention and the second example of the refractory wall when flames are applied to the joint part of the back finish board at the rear surface of the refractory wall Experimental graph.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

In the drawings, the thickness is enlarged to clearly represent the layers and regions.

In addition, the meaning of the front or rear face of a dry fire wall may be the front and back of a dry fire wall, but if one side of the dry fire wall is referred to as the front, the back face may refer to the opposite side of either side have.

In addition, the same thickness, width, or length means the same within an error within 10%.

1 to 8 are views for explaining an example of a dry fireproof wall according to the present invention.

1 is a perspective view of a dry fire wall according to the present invention installed vertically in a vertical direction between a ceiling and a bottom of a building, FIG. 2 is an example of a front view of the dry fire wall shown in FIG. 1, 1 is an example of a vertical cross-sectional view of the dry fireproof wall shown in Fig. 1, Fig. 5 is an example of a horizontal cross-sectional view of the dry fireproof wall shown in Fig. 1, Fig. 7 is a cross-sectional view of the flame-retardant board shown in Fig. 5 in order to explain the structure of the first joint portion of the flame-retardant board and the first incombustible sheet in the dry- And FIG. 8 is an example of a horizontal cross-sectional view of a quadrangular pyramid applied to a dry fireproof wall according to an example.

1 to 5, a dry fire wall according to an exemplary embodiment of the present invention may include a front board 10, a back board 20, a post 30a, and a flame retardant board 40 .

The dry fireproof wall is installed between the ceiling 1 and the floor 2 in the vertical direction z so as to extend in the thickness direction y to the front board 10, A plurality of front board boards 10 and a plurality of rear board boards 20 are elongated in a longitudinal direction in a plane direction x crossing the thickness direction y, .

As shown in Figs. 1 and 4, such a dry fireproof wall has a structure in which an upper runner 3 installed in a ceiling 1 inside a building and a part of a lower runner 4 installed and fixed on the floor 2 are inserted And can be fixed.

Here, the upper runner 3 and the lower runner 4 can be U-shaped runners and can be elongated in the plane direction x.

As shown in FIGS. 1 and 4, the rear finishing board 20 and the post column 30a of the dry fire wall can be inserted and fixed to the upper runner 3 and the lower runner 4, The base board 10 and the flame retardant board 40 can be screwed and fixed to the horizontal column 30a fixed to the upper runner 3 and the lower runner 4. [

Here, a plurality of back finishing boards 20 are inserted into the upper runner 3 and the lower runner 4 to form a plurality of back finishing boards 20 in the vertical direction z from the ceiling 1 to the floor 2, A plurality of rear finishing boards 20 can be arranged in a long direction in the plane direction x and a plurality of rear finishing boards 20 can be inserted into recessed recesses formed in the rear side of the spacers 30a in the planar direction x, And can be fixed in a row in the plane direction (x).

Here, the planar direction x width of the rear surface finishing board 20 may be the same as the center spacing between the adjacent columns 30a, as shown in Figs.

For example, the width x in the plane direction of the back finish board 20 may be between 350 mm and 650 mm, and the thickness y in the thickness direction y of the back finish board 20 may be between 22.5 mm and 27.5 mm .

The plurality of front board boards 10 are installed long in the vertical direction z from the ceiling 1 to the floor 2 as shown in Figs. 1 to 5, (10) may be formed long.

The front board 10 may be spaced apart from the rear board 20 in the thickness direction y and may be disposed in front of the posts 30a and a plurality of the boards may be fixed to the posts 30a May be arranged in a line in the plane direction (x).

Here, the width (x) in the plane direction of one front board 10 is set to be equal to the width in the plane direction (x) of the rear finishing board 20 or between the adjacent columns 30a And may be formed to be smaller than three times the center spacing between the rising columns 30a.

The thickness x of the front board 10 may be between 850 mm and 1250 mm and the thickness y of the front board 10 may be less than the thickness of the back board 20 Direction (y) thickness, and may be formed to be, for example, between 13.5 mm and 16.5 mm.

The front board 10 may be fixed to the posts 30a by screws 70, as shown in FIGS.

As shown in FIGS. 1 and 5, the space in the thickness direction (y) between the front board 10 and the rear board 20 is relatively filled with air or filled with mineral wool or glass wool, It is possible to further improve the fire resistance performance of the dry fireproof wall.

The distance in the thickness direction (y) between the front board 10 and the rear board 20 may be greater than the thickness of the front board 10 and the rear board 20, respectively.

Accordingly, the spacing between the front board 10 and the rear board 20 can be sufficiently ensured to further improve the fire resistance of the dry fire wall.

For example, the distance in the thickness direction (y) between the front board 10 and the back board 20 may be between 45 mm and 55 mm.

A plurality of front board boards 10 are disposed on the second joint part 12 of the front board board 10 adjacent to each other in the face direction x. May be located at a portion overlapping the post pole 30a.

The front board 10 may be fixed to the horizontal column 30a by a screw 70 in the second joint portion 12 of the front board 10.

The front board 10 and the rear board 20 may be made of a gypsum board, an MGO board, a CRC board, and a nonflammable board. For example, in order to improve the fire resistance, Fire retardant gypsum board, which is a flame retardant grade material determined by Korean Industrial Standards according to the law, can be used.

The plurality of flame retardant boards 40 have planes formed in the plane direction x and extend in the vertical direction z from the ceiling 1 to the floor 2 as shown in Figs. 1 to 5, (Not shown).

A plurality of such flame retardant boards 40 may be provided on the front surface of the front board 10 in the plane direction x.

1 and 2, the first joint portion 49 of the flame-retardant board 40, in which the plurality of flame retardant boards 40 are adjacent to each other, is located at a portion overlapping the cross cylinder 30a And the first joint portion 49 of the flame retardant board 40 and the second joint portion 12 of the front board 10 are not overlapped with each other but staggered in the plane direction x, , And can be alternately positioned.

In addition, the first joint portions 49 of the plurality of flame retardant boards 40 may overlap with some of the plurality of spacers 30a in the thickness direction y.

For example, the spacers 30a overlapping the first joint portions 49 of the flame-retardant board 40 and the second columns 30a overlapping the second joint portions 12 of the front board 10 may be alternately arranged in the planar direction (x).

The width x in the plane direction of the flame retardant board 40 is greater than the width x in the plane direction of the rear finishing board 20 and is equal to the width x in the plane direction of the front board 10 . The thickness y of the flame retardant board 40 may be less than the thickness y of the front board 10 and may be in the range of 11.5 mm to 13.5 mm, mm. < / RTI >

As described above, according to the present invention, the first joint portion 49 of the flame-retardant board 40 and the second joint portion 12 of the front base board 10 are alternately positioned, And it is possible to further improve the fire resistance performance of the dry fireproof wall.

In addition, the flame retardant board 40 according to the present invention includes silicon dioxide (SiO 2) which is resistant to high temperature, so that the fire resistance performance of the dry fireproof wall can be further improved.

1 to 5, by placing the flame retardant board 40 on the outermost front surface of the dry fireproof wall, the front board 10, It is possible to delay the transfer of heat to the riser 30a, the rear finishing board 20 and the rister 30a to the maximum, thereby further improving the refractory performance of the dry refractory.

The structure of the flame retardant board 40 will be described in more detail as follows.

6, the flame retardant board 40 of the present invention may include a fireproof board 41, a compressed fiber sheet 43, and a steel sheet 45 for finishing.

The fireproof board 41 may be disposed on the front surface of the front board 10, and may be made of a gypsum board, an MGO board, a CRC board, and a nonflammable board. For example, Fire gypsum boards can be used to further improve performance.

The thickness of the fire board 41 may be between 11.5 mm and 13.5 mm.

The compressed fiber sheet 43 is formed by laminating a fiber sheet coated with a flame retardant and may be disposed to cover the entire surface of the fire board 41, as shown in Figs.

The thickness of the compressed fiber sheet 43 may be 0.5 mm or more and 1 mm or less.

Such a compressed fiber sheet 43 can be formed by containing a fiber sheet and a flame retardant as described above.

Here, the fiber sheet may be formed of a plastic non-woven material, and may be formed of, for example, polyester, nylon, polypropylene or polyolefin.

The fiber sheet according to the present invention may be formed of, for example, a polyolefin resin. As described above, when the fiber sheet is formed to include a polyolefin resin, the moisture resistance and sound insulation of the flame retardant board 40 can be further improved by the characteristics of the polyolefin resin having hydrophobicity.

The flame retardant of the compressed fiber sheet 43 may be formed by coating at least one of a halogen-based flame retardant, a phosphorus-based flame retardant or an inorganic flame retardant to the fiber sheet.

Here, the halogen-based flame retardant functions to slow the chemical reaction occurring during combustion with radicals generated in the halogen-based flame retardant or to block the contact of oxygen with a high-density gas generated in the halogen-based flame retardant. Examples thereof include fluorine, bromine, A substance such as iodine may be contained.

The phosphorus flame retardant agent forms a char during combustion to prevent contact with the removable portion. For example, phosphate phosphorus, phosphate, phosphonate, phosphinate, , Phosphine oxide, phosphazene, and the like.

The inorganic flame retardant has a function of discharging water upon combustion, and may be formed, for example, by containing at least one of aluminum hydroxide, antimony oxide, magnesium hydroxide, a boron-containing compound, or silicon dioxide (SiO2, silica).

Here, the halogen-based flame retardant is excellent in flame retardant performance, but toxic substances are released at the time of burning, which is not environmentally friendly, and the phosphorus flame retardant has a disadvantage that the flame retardant performance is relatively weak and expensive.

However, the inorganic flame retardant does not release toxic substances upon combustion, and is advantageous in that it is relatively inexpensive than phosphorus flame retardant.

Therefore, in the present invention, the case where the compressed fiber sheet 43 is formed of silicon dioxide (SiO2) which is more environmentally friendly than the inorganic flame retardant as the flame retardant is described as an example.

However, the flame retardant contained in the compressed fiber sheet 43 of the present invention is not necessarily limited to silicon dioxide (SiO2).

As described above, when the compressed fiber sheet 43 of the present invention is formed to include silicon dioxide (SiO2), the fire resistance of the flame retardant board 40 can be further increased by the characteristics of silicon dioxide (SiO2) have.

More specifically, for example, the compressed fiber sheet 43 according to the present invention may be formed to include a fiber sheet formed of a polyolefin-based resin and a yellow soil containing a large amount of silicon dioxide.

Here, when the fiber sheet is formed of a polyolefin-based resin, the moisture resistance and sound insulation of the flame-retardant board 40 can be further improved by the characteristics of the polyolefin-based resin having hydrophobicity.

In addition, when the flame-retardant board 40 is formed by mixing the loess with silicon dioxide in an amount of 60% or more with the fiber sheet formed of such a polyolefin-based resin, as compared with the flame-retardant board including the fiber sheet formed only from the polyolefin- The flame-retardant board 40 according to the present invention can further increase the strength of the flame-retardant board 40 due to the silicon dioxide contained in the loess, and can further increase the flame retardancy and impact absorbability.

In addition, since the flame-retardant board 40 according to the present invention includes yellow soil, it is possible to provide an environmentally-friendly dry fireproof wall having almost no harmful effects to human bodies as compared with a dry fireproof wall including a conventional gypsum board or a magnesium fire- .

The finishing steel plate 45 may be arranged to cover the sides of the fire retardant board 41 and the compressed fiber sheet 43 covering the entire surface of the fire board 41 as shown in Fig.

The thickness of the finishing steel sheet 45 may be 0.6 mm or more and 1 mm or less. For example, a galvanized steel sheet may be used.

6, the finishing steel plate 45 may further include a joint 47 protruding in a planar direction x from a portion covering the side face of the fire board 41. In this case, as shown in Fig.

The joints 47 of the steel strips 45 provided on each of the plurality of flame retardant boards 40 can double cover the front board 10 exposed through the first joints 49. [

7, the joints 47 of the respective flame retardant boards 40 adjacent to each other in the first joint portion 49 of the flame retardant board 40 can be overlapped and positioned, The flame retardant board 40 can be fixed to the posts 30a by the screws 70 passing through the overlapped joints 47. [

The joint part 47 may be provided with a space for screwing and fixing the front board board 10 exposed between the first joint parts 49 when fixing the flame retardant board 40 to the horizontal post 30a. So that when a fire occurs, it is possible to delay the spread of heat from the fire through the dry fire wall to another area.

As shown in FIGS. 1 to 5, the horizontal post 30a is inserted into the upper runner 3 and the lower runner 4 and is installed in a vertical direction z from the ceiling 1 to the bottom 2, The front board 10 and the rear board 20 can be spaced apart from each other in the thickness direction y by being positioned between the front board 10 and the rear board 20, And may be spaced apart.

For example, the spacing between the centers of each row 30a spaced apart in two horizontal directions (x) may be between 850 mm and 1250 mm, for example.

The light pole 30a may be a lightweight steel pole 30a. For example, the post pole 30a may be composed of a CH-type stud as shown in FIG. However, the spacing 30a is not necessarily limited to the CH-type stud, and it is also possible that the c-type stud is used in some cases.

Hereinafter, a case in which the alternating column 30a is composed of a CH-type stud will be described as an example.

As shown in FIG. 8, the CH stud has a recessed portion 31a at the rear, a front portion 33a at the front, and a connecting portion 35a connecting the recessed recess 31a and the front portion 33a .

More specifically, the recess 31a of the CH-type stud used as the post 30a may be located behind the CH-type stud and may include a recessed portion on both sides in the plane direction (x).

A plurality of rear finishing boards 20 may be inserted into and coupled to the side recessed grooves 31a of the CH stud.

The front face portion 33a of the CH stud used as the horizontal post 30a means a portion having a face in the plane direction x on the front face of the CH stud, 5 and 7, the screw 70 is passed through and fastened to the front board portion 10 and the front portion 33a of the CH-type stud, (10) can be coupled and fixed to the front portion (33a) of the CH-type stud.

The connecting portion 35a of the CH-type stud can connect the recessed groove 31a and the front portion 33a of the above-mentioned CH-type stud in the thickness direction y.

The flame retardant board 40 is screwed to the front portion 33a of the CH-type stud together with the front base board 10 by means of screws 70 penetrating the joint portion 47 of the finishing steel sheet 45 .

7, a first fireproof sheet 61 including a flame retardant is attached to a first joint portion 49 where two adjacent flame retardant boards 40 meet, May be provided.

The first joint portion 49 of the flame retardant board 40 may be provided with the first fireproof sheet 61 to prevent the fire from spreading through the first joint portion 49 when a fire occurs.

The first non-burnishing sheet 61 may be positioned between the finishing steel plate 45 and the front board 10 in the first joint portion 49 to more effectively block the flames.

The width W61 in the plane direction x of the first cohesionless sheet 61 is larger than the width w49 in the plane direction x of the first joint portion 49 and the width W49 in the plane direction of the double- ≪ / RTI >

As described above, by making the plane direction (x) width W61 of the first cohesionless sheet 61 larger than the planar direction x width of the first joint portion 49, (X) width of the first joint portion 49 is widened or a clearance is generated even when the front board 10 is deformed or the front board 10 is shrunk, And the expansion of the heat can be blocked.

The thickness t61 of the first cohesionless sheet 61 can be formed to be between 0.5 mm and 2 mm in a range larger than the thickness of the steel sheet for finishing 45 and smaller than the thickness of the fireproof board.

The material of the first cohesionless sheet 61 may be formed by distributing flame-retardant particles containing graphite dispersed in the fiber sheet.

Here, the use of graphite as the flame-retardant particle is due to the peculiar nature of graphite that expands and expands when it receives heat from the outside.

Therefore, when a fire occurs, when the first cohesive non-burning sheet 61 is exposed to a flame or heat, the graphite expands and foams to form a carbonized layer generated by foaming of graphite, The first joint portion 49 is hermetically sealed and shielded between the steel plate 45 and the front base board 10 to block the flames and the heat flowing into the inside of the refractory wall.

Further, the flame-retardant particles dispersed in the fiber sheet of the first cohesionless sheet 61 may further include at least one of inorganic heat insulating material, urethane resin, and inorganic flame retardant particle in addition to graphite.

In addition, the first non-burning sheet 61 is not located on the front surface of the finishing steel sheet 45 exposed to the outside in the first joint portion 49, but is located between the finishing steel sheet 45 and the front base board 10 The flame and the heat can be blocked more effectively.

That is, when the first incombustible sheet 61 is located on the first joint portion 49 and is exposed to the outside of the front surface of the refractory wall, even if the first incombustible sheet 61 is expanded and expanded, The degree of hermetic sealing and shielding of the one joint portion 49 may be significantly deteriorated.

However, in the case where the first non-burning sheet 61 is located between the finishing steel sheet 45 and the front base board 10 as in the present invention, the first non-burning sheet 61 is disposed between the finishing steel sheet 45 and the front surface board 10, The carbonized layer can be formed under the pressure between the steel sheet for finishing 45 and the front base board 10 since the carbonized layer is expanded and foamed while being held in the space between the base boards 10, The joint between the finishing steel plate 45 and the front base board 10 can be completely shielded from the one joint portion 49.

Accordingly, the fire-proof wall according to the present invention is provided with the first fire-retarding sheet 61 so as to more effectively prevent the flame or the heat from expanding from the front surface to the rear surface of the fire wall when a fire occurs on the entire surface of the fire- have.

Fig. 9 is an enlarged view of the portion K1 in Fig. 5 for explaining the second incombustible sheet 62 of the present invention.

A refractory wall according to an example of the present invention is characterized in that a CH-type stud includes a recessed recess provided on both sides in the plane direction (x) and a second non-burned sheet (62) may be further provided.

Here, the material of the second incombustible sheet 62 may be the same as the material of the first incombustible sheet 61. Therefore, when the flame and the heat are externally applied to the second incombustible sheet 62, The sheet 62 is expanded and foamed to form a carbonized layer between the recessed groove 31a of the CH type stud and the rear surface finish board 20 to form a carbonized layer between the recessed groove 31a of the CH type stud and the rear surface finish board 20. [ It is possible to effectively prevent the flame or the heat from progressing through the refractory wall.

The width W62 of the second cohesionless sheet 62 in the thickness direction y may be equal to the thickness of the plurality of back finish boards 20 and the thickness t62 of the second cohesionless sheet 62 May be formed between 0.5 mm and 2 mm.

Accordingly, the refractory wall according to the present invention is provided with the second incombustible sheet 62, so that when a fire occurs on the rear surface of the refractory wall, it is possible to more effectively block the expansion of the flame or the heat from the back surface to the front surface of the refractory wall have.

10 is a view for explaining a third cohesionless sheet 63 of the present invention.

3 and 4, the plurality of back finishing boards 20 may be positioned such that the respective side faces are opposed to each other in the vertical direction (z).

10, an H-shaped stud is located between each of the back surface finishing boards 20 located in the vertical direction z, and the H-shaped stud has depressed grooves on both sides in the vertical direction (z) And the upper and lower side surfaces of each rear surface finishing board 20 can be inserted into the recessed groove and coupled.

In addition, a third non-burning sheet 63 including a flame retardant may be provided between the depressed grooves of the H-shaped stud and the upper and lower sides of the back surface finish board 20, respectively.

The material of the third incombustible sheet 63 may be the same as that of the first incombustible sheet 61.

 Accordingly, when the flame and the heat are externally applied to the third incombustible sheet 63, the third incombustible sheet 63 is expanded and foamed to form a carbonized layer between the recessed grooves of the H- So that the joint between the depression groove of the H-shaped stud and the rear surface finishing board 20 can be sealed, thereby effectively preventing the flame or the heat from progressing through the refractory wall.

The width W63 of the third non-burning sheet 63 in the thickness direction y may be equal to the thickness of the plurality of rear finishing boards 20 and the thickness t63 of the third non- May be formed between 0.5 mm and 2 mm.

Although the first, second, and third non-burnished sheets have been described so far, at least one of the first, second and third non-burned sheets may be mixed with the same refractory wall as the present invention.

Hereinafter, the effect of the present invention will be described.

11 is a view for explaining a comparative example in which the first, second and third non-burning sheets according to the present invention are not provided, and FIG. 12 is a view for explaining a comparative example in which a flame is applied to a joint portion of the flame- The temperature of the back surface of each of the first and second fire-resistant walls of the first and second fire-proof walls provided with the first and second fire-resistant sheets of the present invention, FIG. 13 is a graph showing the relationship between the temperature at the front surface of each of the first example of the refractory wall of the present invention and the second example of the refractory wall when the flame is applied to the joint at the rear surface of the refractory wall, This is the experimental graph measured.

In comparison with the comparative example, the refractory wall according to the comparative example is different from the refractory wall structure according to the present invention except that the front base board 10 is composed of two layers, The back finish board, the front base board 10 and the flame retardant board 40 are the same.

Therefore, in the case of the comparative example, the front board 10 is thicker than the present invention.

In the experiment, a large-sized LPG torch was used. In the case of FIG. 12, the flame was radiated at a temperature of 1200 ° C or more for 2 hours from the front of each of the fire resistant walls according to the first, second and comparative examples of the present invention, The temperature was measured at the rear surface of the refractory wall. In the case of FIG. 13, the flame was radiated from the rear surface of each of the fire walls according to the first, second and comparative examples of the present invention to a large LPG torch at a temperature of 1200 ° C or higher for 2 hours, The temperature was measured at the front of each refractory wall.

As a result of the test, expansion and foaming of the first, second and third incombustible sheets started from 5 minutes after the heating of the refractory body according to the first and second aspects of the present invention, and the carbonaceous layer began to fill the respective joints or joint portions.

12, when the front surface of each refractory wall is heated, the temperature of the rear surface of the refractory wall between the first and second examples of the present invention and the comparative example varies from after about 30 minutes of heating The temperature difference between the first and second examples of the present invention and the comparative example was about 12 ° C or higher for 2 hours thereafter.

In addition, as shown in FIG. 13, when the rear surface of each of the refractory walls is heated, the temperature of the rear surface of the refractory wall is different between the first and second examples of the present invention, The temperature difference between the first and second examples of the present invention and the comparative example was about 23 ° C or higher for 2 hours thereafter.

As described above, according to the present invention, the first, second and third non-burnable sheets are applied, and it is confirmed that the fireproof performance is superior to the case where the front board 10 is double- .

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, Of the right.

Claims (15)

A plurality of vertical columns extending vertically between the ceiling and the floor in the building;
A plurality of rear finishing boards disposed behind the plurality of spacers;
A plurality of front desk boards disposed on the front side of the horizontal posts and spaced apart from each other in a thickness direction intersecting with the vertical direction;
And a plurality of flame retardant boards disposed on the front surface of the front desk board,
And a first non-burnishing sheet including a flame retardant is provided in a first joint portion where two flame retardant boards adjacent to each other in a plane direction intersecting with the thickness direction of the plurality of flame retardant boards meet. The method according to claim 1,
Wherein the first joint portions of the plurality of flame retardant boards are staggered with respect to the second joint portions of the plurality of front board boards in the plane direction,
Wherein the first joint portions of the plurality of flame retardant boards are overlapped with a part of the plurality of spacers in the thickness direction. The method according to claim 1,
Each of the plurality of flame retardant boards
A fire board disposed in contact with a front surface of the front board;
A compressed fiber sheet covering a front surface of the fireproof board and containing a fiber sheet formed of a plastic nonwoven fabric material and a flame retardant; And
And a finishing steel sheet covering the side surface of the fireproof board and the front surface of the compressed fiber sheet,
Wherein the finishing steel sheet provided on each of the plurality of flame retardant boards double-covers the front board board exposed through the first joint portions. The method of claim 3,
Wherein the first non-burnishing sheet is located between the finishing steel sheet and the front substrate board at the first joint portion. The method according to claim 1,
Wherein the surface direction width of the first cohesionless sheet is larger than the surface direction width of the first joint portion and is smaller than twice the width direction of the joint portion. The method according to claim 1,
Wherein the thickness of the first non-burning sheet is greater than the thickness of the steel sheet for finishing and is between 0.5 mm and 2 mm in a range smaller than the thickness of the fire board. The method according to claim 1,
The material of the first cohesionless sheet is such that flame retardant particles containing graphite are dispersed in the fibrous sheet,
Wherein the flame-retardant particles further include at least one of an inorganic heat insulating material, a urethane resin, and inorganic flame retardant particles in addition to graphite. The method according to claim 1,
The stud includes a CH stud,
The plurality of rear finishing boards are inserted into coupling recesses provided at both sides in the plane direction on the rear side of the CH studs. Dry Firewall. 9. The method of claim 8,
And a second non-burning sheet including a flame retardant is provided between the recessed recesses provided on both sides in the plane direction of the CH stud and the side faces of the plurality of rear surface finishers. 10. The method of claim 9,
And the width of the second cohesive sheet in the thickness direction is equal to the thickness of the plurality of rear finishing boards. 10. The method of claim 9,
And the thickness of the second cohesionless sheet is between 0.5 mm and 2 mm. 10. The method of claim 9,
And the material of the second non-burning sheet is the same as the material of the first non-burning sheet. The method according to claim 1,
Wherein the plurality of back finishing boards are positioned such that each side faces in the vertical direction. 14. The method of claim 13,
An H-shaped stud is positioned between each of the vertically disposed rear surface finishing boards,
The H-shaped studs have depressed grooves on both sides in the vertical direction, and upper and lower side surfaces of each of the rear surface finishing boards are inserted into the depressed grooves and coupled. 15. The method of claim 14,
And a third non-burnishing sheet including a flame retardant is provided between the depressed recess of the H-shaped stud and the upper and lower side surfaces of the respective rear surface finishing boards.

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