KR20090003503U - Drywall with Resilient Channels - Google Patents

Abstract

The present invention relates to a dry wall using a resilient channel, and after installing a resilient stud connecting a ceiling and a floor of a building, The present invention relates to a drywall using a resilient channel that fits a resilient channel to the resilient stud and couples a finishing member such as a gypsum board to the resilient channel to improve sound insulation and vibration reduction performance. .

The drywall using the resilient channel of the present invention is installed vertically to connect the ceiling and the floor of the building, and the 'c' cross-section of the resilient studs (Join Stud) is formed on one side or the other side; A resilient channel fitted to a coupling portion of the resilient stud in a horizontal direction perpendicular to the resilient stud; Insulation or sound insulation filled between the resilient studs; And an outer finish coupled to the outer surface of the resilient channel. Characterized in that it comprises a.

As the external finish material is coupled to the resilient channel without contacting the resilient stud as described above, the sound insulation performance is improved by minimizing the transmission of vibration, and the external finish material is coupled to the resilient channel to install the interval of the resilient stud. Since it is possible to widen the workability is improved, there is an effect of reducing the material cost.

Drywall, Studs, Channels

Description

Drywall using resilient channels {A Dry-Wall Using the Resilient Channel}

The present invention relates to a dry wall using a resilient channel, and after installing a resilient stud connecting a ceiling and a floor of a building, The present invention relates to a drywall using a resilient channel that fits a resilient channel to the resilient stud and couples a finishing member such as a gypsum board to the resilient channel to improve sound insulation and vibration reduction performance. .

Conventionally, wet partitioning methods using bricks or blocks have been mainly used as internal partition walls that require sound insulation and fireproof performance, but recently, foreigners use plasterboard fixed partition walls for lightweight and dry structures. Doing.

The conventional wet forming method is to form an inner wall by stacking bricks or blocks, and finish by plastering the wall surface of the inner wall with mortar, and a separate insulating material should be attached for insulation performance. Curing time is required. In addition, due to the weight of the brick and the block itself there was a problem that is not easy to install.

Recently, the dry-wall method is mainly applied as an internal partition wall, and the drywall reduces self-weight due to the high-rise of buildings, and facilitates the change of space division, simplifies the on-site work process, and the external climate. It is used for the purpose of the ease of maintenance, etc. when the construction method which is not received is needed.

1 and 2 show a conventional drywall, a plurality of studs (Stud) 110 made of wood or steel serves as a pillar of the wall while supporting the insulation or sound insulation 130 between and gypsum, External finishes 140 such as cement wood, metal plates, and synthetic resins are installed on both sides of the studs by means of coupling means 150 such as nails or screws. The construction is to be fixed to the bonding surface between the outer finish material (140).

In the case of drywall construction as described above, since the external finishing material 140 is directly coupled to the stud 110, the number of installation of the stud 110 should be varied according to the width of the external finishing material 140, and the stud 110 There is a problem in that the construction cost increases and the workability is lowered because it should be installed to maintain the correct interval.

In addition, since the external finishing material 140 is directly coupled to the stud 110, the vibration applied to the external finishing material of the other side is transmitted to the external finishing material of one side through the stud, so that there is a problem of being vulnerable to vibration and thereby generating noise. .

The present invention is devised to solve the above problems, the external finish of the drywall is coupled to the resilient channel coupled with the resilient studs to prevent the transmission of vibration to improve the sound insulation performance, the external As the finishing material is coupled to the resilient channel, it is possible to freely change the number and spacing of the resilient studs, thereby providing a drywall using the resilient channel with improved construction.

The drywall using the resilient channel of the present invention is installed vertically to connect the ceiling and the floor of the building, and the 'c' cross-section of the resilient studs (Join Stud) is formed on one side or the other side; A resilient channel fitted to a coupling portion of the resilient stud in a horizontal direction perpendicular to the resilient stud; Insulation or sound insulation filled between the resilient studs; And an outer finish coupled to the outer surface of the resilient channel. Characterized in that it comprises a.

The coupling portion of the resilient stud is a rectangular plane horizontal to the ground, characterized in that the three sides except for the edge of the ground is cut and bent outward at a predetermined angle.

The resilient channel includes a fitting portion fitted to the coupling portion of the resilient stud, a first bent surface portion bent at a predetermined angle from the fitting portion, an outer portion extending from the first bent surface portion, and the external finishing material coupled thereto. Finishing material coupling surface, characterized in that formed in the second comb surface portion extending from the outer finishing material coupling surface and bent in the opposite direction to the first comb surface portion.

The resilient channel may be spaced apart from the resilient stud by the end of the second bevel portion of the resilient channel when fitted to the coupling portion of the resilient stud.

As the external finish material is coupled to the resilient channel without contacting the resilient stud as described above, the sound insulation performance is improved by minimizing the transmission of vibration, and the external finish material is coupled to the resilient channel to install the interval of the resilient stud. Since it is possible to widen the workability is improved, there is an effect of reducing the material cost.

Hereinafter, the drywall using the resilient channel of the present invention will be described in detail with reference to the accompanying drawings.

3 is a perspective view of the drywall of the present invention, Figure 4 is a perspective view of the resilient studs of the present invention, Figure 5 is a perspective view of the coupling of the resilient studs and the resilient channel of the present invention, Figure 6 Combined cross-sectional view of the resilient stud and the resilient channel of the invention, Figure 7 is a cross-sectional view of the drywall attached to the outer finish material of the present invention, Figure 8 is a cross-sectional view of the drywall attached to the double outer finish material of the present invention to be.

As shown in FIG. 3, the drywall using the resilient channel of the present invention is vertically installed to connect the ceiling and the floor of the building, and the coupling portion 14 is formed on one side or the other side as the 'c' cross section. A resilient stud 10 formed; A resilient channel 20 fitted to the coupling part 14 of the resilient stud 10 in a horizontal direction perpendicular to the resilient stud 10; Insulation or sound insulation (30) is filled between the resilient studs (10); And an outer finisher 40 coupled to the outer side of the resilient channel 20. Is made of.

The resilient stud 10 is cut and fixed to a distance between the ceiling and the floor of the space where the drywall is installed in order to partition the internal space of the building into a columnar shape having a 'c' cross section. As shown in FIG. 4, coupling portions 14 to which fitting portions 22 of the resilient channels 20 are fitted are formed at both sides of the resilient stud 10. The coupling portion 14 is a rectangular plane that is horizontal to the ground, the three sides except for the edge of the ground is cut and bent at a predetermined angle to the outside of the resilient stud 10. Coupling portion 14 is not limited to the rectangular plane in the above, it can be variously modified to form a space fitted in the direction of gravity.

As shown in FIGS. 5 and 6, the resilient channel 20 is fitted at the fitting portion 14 of the resilient stud 10, at the fitting portion 22. A first comb surface portion 24 that is bent at a predetermined angle, an outer finishing material joining surface 26 extending from the first comb surface portion 24 and to which the outer finishing material 40 is coupled, and the outer finishing material joining surface 26 The second inclined surface portion 28 is bent at a predetermined angle in a direction opposite to the first inclined surface portion 24.

As shown in FIG. 6, when the resilient channel 20 is fitted through the fitting portion 22 to the coupling portion 14 of the resilient stud 10, the resilient channel 20 is connected. End of the second bevel portion 28 is spaced a predetermined distance from the side of the resilient stud 10, so that the resilient stud 10 and the resilient channel 20 are in contact with each other only a part of the There is an effect of reducing the transmission of vibration.

When describing the construction method of the drywall of the present invention, the resilient stud 10 is cut in accordance with the distance between the ceiling and the floor of the place where the construction is firmly fixed installation. Since the installation interval of the resilient stud 10 is not directly coupled to the resilient stud 10, the installation cost of the resilient stud 10 is wider than the width of the outer finish material 40, thereby reducing construction cost and construction time. To make it possible. After the resilient stud 10 is installed at a predetermined interval, the resilient channel to match the distance between both walls of the space in which the drywall is formed in the coupling portion 14 of the resilient stud 10. Cutting (20) to the fitting portion 22 of the resilient channel 20 to the coupling portion 14 of the resilient stud 10 is fitted. Afterwards, the sound insulation and the heat insulating material 30 are filled between the resilient studs 10 to reduce noise and heat transfer between the divided spaces, and the outer surface of the resilient channel 20 is coupled to the outer finishing material coupling surface 26. The external finishing material 40 is coupled through the fastening means 50.

The external finish material 40 is generally used gypsum board and as shown in Figure 7, the finish may be made of a single layer gypsum board, as shown in Figure 8, the base gypsum board 42 on the inside Combine the finishing gypsum board 44 to improve the appearance on the outside of the base gypsum board 42, and the base gypsum board 42 and the finishing gypsum board 44 to improve vibration reduction and sound insulation performance ), A soundproof layer, a sound absorbing layer 46, or the like may be further formed. In addition, it is possible to maximize the sound insulation and vibration reduction ability by filling a sealant in the gap between gypsum boards.

As described above, the present invention is not limited to the described embodiments, and it is apparent to those skilled in the art that various modifications and variations can be made without departing from the spirit and scope of the present invention. Therefore, such modifications or variations will have to belong to the utility model registration claims of the present invention.

1 is a perspective view of a conventional drywall.

2 is a cross-sectional view of a conventional drywall.

3 is a perspective view of the drywall of the present invention.

4 is a perspective view of the resilient stud of the present invention.

5 is a perspective view of the coupling of the resilient stud and the resilient channel of the present invention.

6 is a cross-sectional view of a coupling of the resilient stud and the resilient channel of the present invention.

Figure 7 is a cross-sectional view of the drywall attached to the external finish of the present invention.

Figure 8 is a cross-sectional view of the drywall attached to the double outer finish material of the present invention.

** Description of the symbols for the main parts of the drawings **

10: resilient stud 14: coupling

20: Resilient Channel 22: Fitting

24: first inclined surface portion 26: outer finishing material mating surface

28: second inclined portion 30: insulation, sound insulation

40: exterior finishing material 42: base gypsum board

44: finishing gypsum board 46: insulation layer, soundproof layer

50: fastening means

Claims (4)

A resilient stud 10 installed vertically to connect the ceiling and the floor of the building, and having a coupling part 14 formed on one side or the other side of the 'c' cross-section; A resilient channel 20 fitted to the coupling part 14 of the resilient stud 10 in a horizontal direction perpendicular to the resilient stud 10; Insulation or sound insulation (30) is filled between the resilient studs (10); And An outer finisher 40 coupled to the outer side of the resilient channel 20; Drywall using a resilient channel comprising a. The method of claim 1, Coupling portion 14 of the resilient stud 10 is a rectangular plane horizontal to the ground using a resilient channel, characterized in that the three sides except for the edge of the ground is cut and bent outward at a predetermined angle Drywall. The method of claim 2, The resilient channel 20 is a fitting portion 22 to be fitted to the coupling portion 14 of the resilient stud 10, the first inclined portion bent at a predetermined angle from the fitting portion 22 ( 24, an outer finisher coupling surface 26 extending from the first sloped surface portion 24 to which the outer finisher 40 is coupled, and extending from the outer finisher coupling surface 26 and the first sloped surface portion 24. Dry wall using a resilient channel, characterized in that formed in the second inclined surface portion 28 is bent in the opposite direction. The method of claim 3, wherein When the resilient channel 20 is fitted to the coupling portion 14 of the resilient stud 10, the end of the second inclined surface portion 28 of the resilient channel 20 is the resilient stud. Dry wall using a resilient channel, characterized in that spaced apart from the (10).

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