KR101536475B1 - Drywall system using ceramic fiber blanket - Google Patents

Abstract

The present invention relates to a runner member provided as an upper runner and a lower runner installed above and below a drywall system, A plurality of vertically arranged steel studs between the runner members; A ceramic fiber blanket provided on the runner member and the steel stud, the ceramic fiber blanket comprising an inorganic fiber material to provide refractory performance to the drywall system; And a steel material track disposed on the steel stud and supporting the ceramic fiber blanket, wherein the ceramic fiber blanket is formed by connecting a plurality of refractory fiber members, Wherein the ceramic fiber blanket includes a first refractory fiber member and a second refractory fiber member that is overlapped and overlapped at a connection portion with the first refractory fiber member, A first connecting member for installing the steel track and a second connecting member for connecting the overlapping portion of the first refractory fiber member and the second refractory fiber member, , And the deterioration is blocked by at least one of the first refractory fiber member and the second refractory fiber member. A drywall system is provided.

Description

[0001] DRYWALL SYSTEM USING CERAMIC FIBER BLANKET USING CERAMIC FIBER BLANKET [0002]

The present invention relates to a drywall system using a ceramic fiber blanket, and more particularly, to a drywall system using a ceramic fiber blanket using a ceramic fiber blanket as a refractory material having excellent fire resistance and light weight inside a drywall system .

Recently, in constructing various structures such as houses, buildings, and factories, a new structure type is widely used, which is constructed by using lightweight steel beams, which are not used in conventional methods such as a reinforced concrete structure, a steel frame, have.

If the framing of the structure is constructed as a steel product, the products manufactured at the factory can be assembled in the field, so that the construction speed is fast and the general operator can be constructed easily. Which has many advantages in terms of workability and economical efficiency. In recent years, the spread is gradually spreading.

Particularly, in the housing sector, Steel Framed House utilizing lightweight drywall has been established as a form of residential building in connection with the above-mentioned trend of dry and industrialization of construction of the structure.

A lightweight drywall is a wall installed to divide the space of a building, and it is divided into a load bearing wall and a non-load bearing wall (partition wall and fitting wall) depending on the load sharing of the wall.

Generally, as shown in Fig. 1, a steel stud for attachment of a fire-gypsum board and load sharing, a steel track for fixing the position of the steel stud, a heat insulating material for securing the heat insulating performance between the walls, And a fire-resistant gypsum board for surface treatment.

The required fireproof performance of lightweight drywall is determined according to the regulations and standards of construction in each country according to the use and size of the building, and fireproof performance up to 2 hours is required. Details of the general 2 hour fireproof and lightweight wall are shown in FIG. 1, and the construction is carried out as follows.

First, an upper runner and a lower runner are provided on the floor and the ceiling, spaced apart from each other at regular intervals in the vertical direction, and the stud and runner members are stacked with three layers of fire resistant gypsum boards (15 mm) .

The existing two-hour refractory structure requires 15-mm fireproof gypsum board to be 3-ply. Therefore, quality control is difficult, material cost is high, and there are many joints for connecting fireproof gypsum board and frame. There is a great risk of damaging the cross section of the steel stud.

In addition, when the steel stud having such a section defect is exposed in a large axial load, there is a problem that breakage due to buckling or the like can be easily caused.

In addition, in the case of the above-described two-hour fireproof and lightweight wall, there is a problem in that the application of the pre-fabrication method for the purpose of prefabricating and installing the lightweight wall by the excessive gypsum board has a problem.

In addition, studs used in drywall systems typically have a galvanized steel sheet having a thickness of 0.8 mm to 1.6 mm, which is processed to have a C-shaped cross section to increase its strength. Such a stud has a thermal conductivity A heat bridging phenomenon in which the heat of perfusion is concentrated on the stud may occur. This causes condensation and wastes energy depending on the heat loss of the building.

The present invention is realized by recognizing at least any one of the requirements or problems that arise in the refractory structure of the conventional drywall system.

In one aspect, the present invention relates to a ceramic fiber blanket which can form a refractory structure by utilizing a ceramic fiber blanket, which is a heat insulating material having no standardized shape, and can remarkably improve workability by simple molding and construction of a wall system To provide a used drywall system.

In one aspect, the present invention provides a drywall system using a ceramic fiber blanket suitable for the production and installation of a lightweight wall by utilizing a ceramic fiber blanket as a lightweight building material compared to a gypsum board as a conventional fireproof system.

In one aspect, the present invention provides a drywall system using a ceramic fiber blanket capable of preventing a deterioration of a fireproof system of a drywall through a connecting member used when installing a fireproof system on a drywall system.

In one aspect, the present invention provides a dry wall system utilizing a ceramic fiber blanket capable of effectively preventing a relative flow phenomenon through a structural member of a drywall system, such as a stud, .

The present invention, in one aspect, provides a drywall system utilizing a ceramic fiber blanket capable of providing additional insulation performance with insulation installed in a drywall system.

According to one aspect of the present invention, there is provided a dry wall system, comprising: a runner member provided as an upper runner and a lower runner installed on upper and lower sides of a drywall system; A plurality of vertically arranged steel studs between the runner members; A ceramic fiber blanket provided on the runner member and the steel stud, the ceramic fiber blanket comprising an inorganic fiber material to provide refractory performance to the drywall system; And a steel material track disposed on the steel stud and supporting the ceramic fiber blanket, wherein the ceramic fiber blanket is formed by connecting a plurality of refractory fiber members, Wherein the ceramic fiber blanket includes a first refractory fiber member and a second refractory fiber member that is overlapped and overlapped at a connection portion with the first refractory fiber member, A first connecting member for installing the steel track and a second connecting member for connecting the overlapping portion of the first refractory fiber member and the second refractory fiber member, , And the deterioration is blocked by at least one of the first refractory fiber member and the second refractory fiber member. A drywall system is provided.

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Preferably, the steel track further comprises a fixing plate provided on the steel stud, a support plate provided parallel to the fixing plate for supporting the back surface of the ceramic fiber blanket, and a support plate interposed between the fixing plate and the support plate, And a mounting plate for supporting a lower end of the mounting plate.

Preferably, the ceramic fiber blanket is formed by connecting a plurality of refractory fiber members having a first refractory fiber member and a second refractory fiber member that is overlapped and overlapped at a connection portion with the first refractory fiber member, Wherein the ferrule channel is fixed to the steel stud by a first connecting member passing through the steel stud and the fixing plate so that deterioration through the first connecting member is blocked, Wherein the second refractory fiber member is fixed to the ferrule channel by a second connecting member that penetrates the supporting plate and blocks the deterioration through the second connecting member, The first refractory fiber member may be inserted into the space formed by the mounting plate.

Preferably, the steel track may be provided as a noise channel which is press-fitted in a state where the refractory fiber member is overlapped with the connecting portion of the adjacent ceramic fiber blanket.

Preferably, the noise channel is formed of a member having a U-shaped cross section, and the ceramic fiber blanket may be fixed to the space inside the U-shaped cross section.

Preferably, a heat insulating material between the steel studs to provide thermal insulation to the drywall system, and a finish plate disposed on the front and back surfaces of the runner member and disposed on both sides of the ceramic fiber blanket.

Preferably, the steel track and the ceramic fiber blanket may be provided on at least one of both sides of the steel stud.

According to another aspect of the present invention, there is provided a drywall system, comprising: a runner member provided as an upper runner and a lower runner installed on upper and lower sides of a drywall system; A plurality of vertically arranged steel studs between the runner members; A ceramic fiber blanket provided on the runner member and the steel stud, the ceramic fiber blanket comprising an inorganic fiber material to provide refractory performance to the drywall system; And a steel track mounted on the steel stud and supporting the ceramic fiber blanket, wherein the ceramic fiber blanket is made of alumina, alumina-silica, mullite, clay, zircon, silicon carbide, Zirconia, mullite or a combination of two or more thereof, and a wire mesh layer or a metal lath layer for reinforcing the tear strength of the ceramic fiber blanket is formed in the ceramic fiber blanket. And provides a used drywall system.

According to one embodiment of the present invention as described above, the refractory structure is formed by utilizing the ceramic fiber blanket, which is a heat insulating material having no shaped shape, and the molding and the construction of the wall system are simplified, There is an effect that can be.

According to one embodiment of the present invention, by utilizing a ceramic fiber blanket as a lightweight building material compared to a gypsum board as a refractory system, it is possible to manufacture a lightweight wall by prefabrication It is possible to easily apply the present invention.

According to an embodiment of the present invention, the ceramic fiber blanket is formed by connecting a plurality of refractory fiber members, and the connecting portion of the refractory fiber member is constructed by overlapping adjacent refractory fiber members, It is possible to prevent the deterioration of the refractory system of the drywall through the connecting member used in the installation.

According to one embodiment of the present invention, by forming a refractory structure utilizing a ceramic fiber blanket, the ceramic fiber blanket is flexible and can be precisely formed at the connection portion of the drywall system .

According to one embodiment of the present invention, by providing a refractory system using ceramic fiber blanks on both side surfaces of the structural members of the steel stud and the runner member, it is possible to effectively prevent the structural member from being deteriorated by fire.

According to an embodiment of the present invention, a ceramic fiber blanket is provided together with a heat insulating material installed in a drywall system to provide additional heat insulating performance, thereby effectively preventing the associated flow phenomenon through the structural member and the resulting heat loss and condensation There is an effect that can be done.

1 is a top view of a conventional drywall system.
2A is a top view of a drywall system in accordance with an embodiment of the present invention in which ceramic fiber blanketing is provided on both sides.
Figure 2b is a top view of a drywall system according to another embodiment of the present invention in which a ceramic fiber blanket is installed on one side.
3 is a cross-sectional view of a drywall system according to another embodiment of the present invention in which a ceramic fiber blanket is provided on one side.
4A to 4D are views illustrating a process of installing a drywall system according to an embodiment of the present invention.
Figs. 5A to 5C are partial enlarged views of A, B and C shown in Figs. 4B to 4D.
6A and 6B are perspective views illustrating a ceramic fiber blanket and a finishing plate of a drywall system according to an embodiment of the present invention.
7 is a cross-sectional view of a drywall system according to another embodiment of the present invention in which a ceramic fiber blanket is provided on one side.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. However, the embodiments of the present invention can be modified into various other forms, and the scope of the present invention is not limited to the embodiments described below. Further, the embodiments of the present invention are provided to more fully explain the present invention to those skilled in the art. The shape and size of elements in the drawings may be exaggerated for clarity.

Hereinafter, a drywall system 10 utilizing a ceramic fiber blanket 300 according to an embodiment of the present invention will be described in detail with reference to the drawings.

1 to 7, a drywall system 10 according to an embodiment of the present invention includes a runner member 100, a steel stud 200, a ceramic fiber blanket 300, and a steel track 400 And may further include a connecting member 500, a finishing plate F, and a heat insulating material I.

The drywall system 10 includes a runner member 100 provided with upper and lower runners 110 and 130 installed on upper and lower sides thereof and a plurality of vertically arranged members A ceramic fiber blanket 300 provided on the runner member 100 and the steel stud 200 and made of an inorganic fiber material so as to provide a fireproof performance to the drywall system 10; And a steel track 400 mounted on the steel stud 200 to support the ceramic fiber blanket 300.

6A and 6B, the runner member 100 includes an upper runner 110 installed above the drywall system 10 and a lower runner 130 installed below the drywall system 10, . ≪ / RTI >

As shown in FIG. 4A, the steel stud 200 is a member vertically installed between the upper runner 110 and the lower runner 130, and a plurality of the steel studs 200 may be spaced apart from each other at regular intervals.

As shown in FIGS. 2A and 2B, the shape of the steel stud 200 is composed of a web, a flange in which both ends are bent, and a steel member having a C-shaped cross section made of a bent rib bent at the end of the flange .

As shown in FIGS. 2A and 2B, the ceramic fiber blanket 300 is a member that provides refractory performance to the drywall system 10.

4B, the steel track 400 is a member that is fixed to the steel stud 200 by a connecting member 500 or the like, and supports the following ceramic fiber blanket 300.

First, referring to FIGS. 4A to 5C, a process of installing the drywall system 10 according to the present invention will be described.

As shown in FIG. 4A, a plurality of steel studs 200 are installed between the upper runner 110 and the lower runner 130 at regular intervals.

As shown in FIG. 4B, a multi-stage steel track 400 can be installed in a horizontal direction across a plurality of vertically installed steel studs 200.

The first refractory fiber member 311 constituting the ceramic fiber blanket 300 may be provided on the steel track 400 provided on the steel stud 200 as shown in Fig. Likewise, a second refractory fiber member 313 installed on the lower side of the lower end of the first refractory fiber member 311 may be installed in a superimposed manner.

At this time, a supporting plate 413 of the ferrule channel 410 may be disposed between the first refractory fiber member 311 and the second refractory fiber member 313, which are overlapped as shown in FIG. 5C.

The ceramic fiber blanket 300 is a member that provides refractory performance to the drywall system 10. In addition, it is possible to additionally provide heat insulation performance to the drywall system 10 together with the heat insulating material I provided between the stud members.

The ceramic fiber blanket 300 is a heat insulating material that does not have a regular shape and can be easily formed and constructed when the drywall system 10 is constructed by utilizing the ceramic fiber blanket 300, thereby dramatically improving the workability.

2A and 2B, the ceramic fiber blanket 300 is installed and attached between the steel stud 200 and the installation surface of the finishing plate F so that the ceramic fiber blanket 300 can be easily installed, The space between the adjacent steel studs 200 is filled with the original thickness to improve the refractory performance and the heat insulation performance.

As shown in FIGS. 2A and 2B, the ceramic fiber blanket 300 may be provided to surround the drywall system 10. The ceramic fiber blanket 300 may be provided on at least one side of the runner member 100 and the steel stud 200.

Specifically, the ceramic fiber blanket 300 may be provided with ceramic fiber blanket 300 on both sides in the case of a wall installed inside the building. In the case of an outer wall, a ceramic fiber blanket 300 may be installed only on an inner side of the building .

The ceramic fiber blanket 300 is formed by connecting a plurality of refractory fiber members 310 and the connecting portion of the refractory fiber member 310 may be installed so that the adjacent refractory fiber members 310 are overlapped with each other.

The ceramic fiber blanket 300 includes a first refractory fiber member 311 and a plurality of refractory fiber members 313 having a second refractory fiber member 313 overlapped and overlapped at a connection portion with the first refractory fiber member 311 And a member 310 may be connected. A first connecting member 510 for mounting the steel track 400 to the steel stud 200 and a second connecting member 510 for connecting the overlapped portion of the first refractory fiber member 311 and the second refractory fiber member 313 The first connecting member 510 and the second connecting member 530 are connected to each other through the first refractory fiber member 311 or the second refractory fiber member 313, Deterioration can be blocked by at least one of them.

In addition, a plurality of refractory fiber members 310 can be superimposed on the entire area where the ceramic fiber blanket 300 is installed. When the ceramic fiber blanket 300 is formed of the refractory fiber member 310 to be overlapped, only a part of the plurality of refractory fiber members 310 is damaged by tearing or the like when a factor that damages the refractory system acts, The member 310 has an effect of exerting normal fire resistance. In other words, the entire ceramic fiber blanket 300 can be prevented from being damaged at its end face, thereby preventing deterioration of the ceramic fiber blanket 300.

The appropriate thickness of the ceramic fiber blanket 300 is 35 to 60 mm. This is because when the ceramic fiber blanket 300 is installed at a thickness of 35 mm or less, the fireproof performance of the drywall system 10 is not sufficiently manifested.

On the other hand, when the ceramic fiber blanket 300 is formed to have a thickness of 60 mm or more, the economical efficiency is lower than that of the ceramic fiber blanket 300. Therefore, the ceramic fiber blanket 300 is required to have a thickness of 35 mm, .

However, considering the possibility of damages on the construction of the runner member 100, the steel stud 200, and the steel track 400, the ceramic fiber blanket 300 is most preferable to be installed in a thickness of 35 to 45 mm Do.

The ceramic fiber blanket 300 may comprise alumina, alumina-silica, mullite, clay, zircon, silicon carbide, silicon nitride carbon fiber, zirconia, mullite or a combination of two or more thereof.

A wire mesh layer or a metal lath layer for reinforcing the tear strength of the ceramic fiber blanket 300 may be formed in the ceramic fiber blanket 300. In this case, the size of the lattice may be in the range of 0.1 to 2 mm.

The ceramic fiber blanket 300 may include refractory microparticles and the average size of the refractory microparticles is preferably at least 4 times and at most 10 times the internal diameter of the ceramic fiber blanket 300.

5A to 5C, the steel track 400 is a member that is fixed to the steel stud 200 by a connecting member 500 or the like to support the ceramic fiber blanket 300 described below.

3, 5B and 5C, the steel track 400 may be constituted by a ferrule channel 410 including a stationary plate 411, a support plate 413, and a stationary plate 415.

As shown in FIG. 4B, the steel track 400 may be formed as a Z-shaped transverse member having a cross section.

5B and 5C, the steel track 400 includes a fixing plate 411 installed on the steel stud 200 and a fixing plate 411 provided in parallel with the fixing plate 411, A support plate 413 for supporting the back surface of the ceramic fiber blanket 300 and a support plate 413 for supporting the lower end of the ceramic fiber blanket 300 in cooperation with the support plate 413, And may be provided with a ferring channel 410 including

The steel track 400 may be fixed to the steel stud 200 by a connecting member 500 such as a pin member or a screw. At this time, the pin member or the screw may be deteriorated by the refractory fiber member 310 It is possible to prevent breakage of the refractory structure of the drywall system 10.

3, the ceramic fiber blanket 300 includes a first refractory fiber member 311 and a second refractory fiber member 313 that is overlapped and overlapped at the connection portion with the first refractory fiber member 311 A plurality of refractory fiber members 310 may be connected.

5C, the ferrule channel 410 is fixed to the steel stud 200 by a first connecting member 510 passing through the steel stud 200 and the fixing plate 411, The second refractory fiber member 313 is installed on the upper surface of the first connecting member 510 so that deterioration through the first connecting member 510 is blocked, Is fixed to the ferrule channel (410) by a second linking member (530) passing through the support plate (413) and is fixed to the supporting plate (413) The first refractory fiber member 311 may be inserted into a space formed by the mounting plate 415.

Through this, it is possible to prevent the deterioration of the fireproof system of the drywall through the connecting member 500 used when the fireproof system is installed in the drywall system 10.

As shown in FIG. 7, the steel track 400 may be provided with a noise channel 430 for compressing and bonding the refractory fiber member 310 in a state where the refractory fiber member 310 is superimposed on a connecting portion of the adjacent ceramic fiber blanket 300 have.

The noise channel 430 may be a member having a U-shaped cross section, and the ceramic fiber blanket 300 may be fixed to a space in a U-shaped cross section.

As shown in Figures 2a and 2b, a drywall system 10 includes a heat insulating material I between the steel studs 200 to provide thermal insulation to the drywall system 10, And a finishing plate F disposed on both sides of the ceramic fiber blanket 300. At this time, a general gypsum board (thickness: 12.5 mm) other than the refractory gypsum board may be used as the finishing board (F).

When the finishing plate F is installed by the steel track 400 constituted by the ferrule channel 410, the mounting plate 415 and the second refractory fiber member 313 and the finishing plate F can be connected by the second connecting member 530. [ At this time, the first refractory fiber member 311 is inserted into the space formed by the support plate 413 and the mounting plate 415, which are the lower end of the installation site of the second connection member 530, The refractory structure of the installation portion of the apparatus can be maintained.

The steel track 400 of the drywall system 10 and the ceramic fiber blanket 300 may be installed on at least one of both sides of the steel stud 200.

2A, when it is necessary to provide refractory performance on both sides of the drywall system 10, the steel track 400 and the steel track 400 are provided on both sides of the steel stud 200 and the runner member 100, A ceramic fiber blanket 300 may be provided.

2b, when the steel track 400 and the ceramic fiber blanket 300 need to have a fire resistance only at one side of the drywall system 10, the steel stud 200 And the one side of the runner member 100.

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, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. And will be apparent to those skilled in the art.

1: conventional drywall system
2: Steel stud 3: Refractory gypsum board
10: Drywall system
100: a runner member 110: an upper runner
130: Lower runner 200: Steel stud
300: ceramic fiber blanket 310: refractory fiber member
311: first refractory fiber member 313: second refractory fiber member
400: steel track 410: ferring channel
411: Fixing plate 413:
415: mounting plate 430: noise channel
500: connecting member 510: first connecting member
530: second connecting member F: finish plate
I: Insulation

Claims (10)

delete delete A runner member provided as an upper runner and a lower runner installed above and below the drywall system;
A plurality of vertically arranged steel studs between the runner members;
A ceramic fiber blanket provided on the runner member and the steel stud, the ceramic fiber blanket comprising an inorganic fiber material to provide refractory performance to the drywall system; And
And a steel track mounted on the steel stud and supporting the ceramic fiber blanket,
Wherein the ceramic fiber blanket is formed by connecting a plurality of refractory fiber members,
Wherein the connecting portion of the refractory fiber member is installed so that the adjacent refractory fiber member is overlapped,
In the ceramic fiber blanket,
A first connecting member provided with a first refractory fiber member and a second refractory fiber member overlapped on the connecting portion with the first refractory fiber member to install the steel material track on the steel stud, And a second connecting member connecting the first refractory fiber member and the second refractory fiber member,
Wherein the first connection member and the second connection member are deteriorated by at least one of the first refractory fiber member and the second refractory fiber member. 4. The method according to claim 3,
A fixing plate installed on the steel stud;
A support plate provided parallel to the fixing plate and supporting the back surface of the ceramic fiber blanket; And
And a mounting plate connected between the fixing plate and the support plate and supporting a lower end of the ceramic fiber blanket. The drywall system according to claim 1, wherein the ceramic fiber blanket is a ceramic fiber blanket. 5. The method of claim 4,
In the ceramic fiber blanket,
A plurality of refractory fiber members having a first refractory fiber member and a second refractory fiber member superimposed on the connecting portion of the first refractory fiber member and the first refractory fiber member are connected and formed,
Wherein the ferrule channel is fixed to the steel stud by a first connecting member that passes through the steel stud and the fixing plate,
A second refractory fiber member is installed on an upper surface of the first connecting member to prevent deterioration through the first connecting member,
Wherein the second refractory fiber member is fixed to the ferrule channel by a second connecting member which penetrates the supporting plate,
Wherein the first refractory fiber member is inserted into a space formed by the support plate and the mounting plate so as to prevent deterioration through the second connection member. 4. The method according to claim 3,
Wherein the ceramic fiber blanket is provided with a noise channel in a state where the refractory fiber member is overlaid on a connecting portion of the adjacent ceramic fiber blanket. The method according to claim 6,
Wherein the noise channel is formed of a member having a U-shaped cross section, and the ceramic fiber blanket is fixed to the space inside the U-shaped cross section while being compressed. The method of claim 3,
A heat insulating material between the steel studs to provide thermal insulation to the drywall system; And
Further comprising a finishing plate disposed on the front and back surfaces of the runner member and disposed on both sides of the ceramic fiber blanket. The method of claim 3,
Wherein the steel track and the ceramic fiber blanket are installed on at least one of both sides of the steel stud. A runner member provided as an upper runner and a lower runner installed above and below the drywall system;
A plurality of vertically arranged steel studs between the runner members;
A ceramic fiber blanket provided on the runner member and the steel stud, the ceramic fiber blanket comprising an inorganic fiber material to provide refractory performance to the drywall system; And
And a steel track mounted on the steel stud and supporting the ceramic fiber blanket,
In the ceramic fiber blanket,
Alumina, alumina-silica, mullite, clay, zircon, silicon carbide, carbon nitride nitride, zirconia, mullite or a combination of two or more thereof,
And a wire mesh layer or a metal lath layer for reinforcing the tear strength of the ceramic fiber blanket is formed in the ceramic fiber blanket.

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