KR20190127039A - Noise insulated stud structure include runner - Google Patents

Abstract

The present invention relates to a stud, which forms a dry wall, and specifically, to a noise insulation stud installing structure, which is installed with a runner in a stud so that noise insulation is improved. The noise insulation installing structure comprises: a web molded in a board shape; a board connecting part in which both sides of the web are bent and extended from the web; a stud comprising a runner inserting hole; and a runner comprising both side walls so that a cross section is molded in a square shape.

Description

Noise insulated stud structure include runner with runner installed inside stud

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to studs constituting drywall, and more particularly, to a sound insulation stud installation structure in which a runner is installed inside a stud to improve sound insulation.

In general, various building structures such as houses and factories have been constructed by a wet construction method using frame, large concrete, and rebar.

This wet method has many problems, such as installing the formwork, weaving reinforcing bars, then placing concrete, curing, to complete the construction is long, expensive, and difficult construction without skilled workers.

Recently, a lot of dry buildings using dry construction methods, such as prefabricated houses and steel houses, which do not use water, are being constructed, and the demand thereof is rapidly increasing.

This method has the advantage of easy construction, short construction period and cost reduction.

In particular, drywall is easy to construct, so it is widely applied as an inter-generational boundary wall that divides households in apartments, residential complexes, and the like.

Typically, drywall is installed vertically stud 30 at predetermined intervals between the horizontal upper runner 20 fastened to the ceiling and the horizontal lower runner 20 fastened to the floor as shown in Figure 1 and stud 30 The walls are constructed by installing gypsum board 10 of one or two layers on each side.

Such a dry wall has a problem that sound or vibration performance is degraded as vibrations or noises generated between generations are easily transmitted across the wall through the stud 30 and the runner 20.

In order to increase sound insulation of the drywall, the sound absorbing material 40 is filled between the gypsum boards 10 as shown in FIG. 2 to prevent noise and vibration from crossing the wall, but the vibration and noise are crossed across the wall through the stud 30. There is still a problem.

In order to solve the problem that noise and vibration are transmitted through the wall through the stud 30 as described above, the cross section of the web of the stud 30 is formed in a 'W' state as shown in FIG. To reduce the noise.

However, as well as the studs 30, the upper and lower runners 20 in contact with the gypsum board 10, there was a problem that the noise and vibration is crossed across the wall.

(Document 1) Patent No. 10-1765673, Republic of Korea Patent Office, "Assembled sound insulation stud" (Document 2) Korean Patent Office Publication No. 10-1089315, "Steel Stud Structure for Drywall Sound Insulation" (Document 3) Korea Patent Office Publication No. 10-1751666, "Sound Stud Structure for Dry Wall"

The present invention has been made in order to solve the above problems, it is an object of the present invention to provide a sound insulation stud installation structure that can block the noise and vibration that goes across the drywall through the runner.

In order to achieve the above object, the sound insulation stud installation structure according to the present invention includes a plate 101 formed in a plate shape, and both sides of the web 101 are bent from the web 101 and the board contact portion 102. And a cutout portion 105 formed in a hole shape in the web 101 at predetermined intervals, and a runner insertion hole 103 formed at each of the upper and lower ends of the web 101 and having a runner 20 inserted therein. Stud 100; And a runner 200 having both sidewalls and having a cross-section formed in a square shape, such that the runner 20 is inserted into the runner insertion hole 103 formed at the upper and lower ends of the stud 100 so that the stud 100 Gypsum board fastened to the) is configured to be spaced apart from the runner 20 by a predetermined interval.

At this time, one side or both sides of the cutout 105 is characterized in that the wing 106 protruding in the vertical direction with the web 101 is formed.

In addition, both sides of the runner insertion hole 103 is characterized in that the runner contact plate 104 protruding in the vertical direction with the web 101 is formed.

In addition, the board contact portion 102 is characterized in that the groove is formed in the vertical direction.

In addition, the runner insertion hole 103 and the runner contact plate 104 formed on the top and bottom of the stud 100 are cut and cut, respectively, 105 and wing 106 are formed.

In addition, the end of the board contact portion 102 is bent inwardly extending is characterized in that the auxiliary runner contact portion 107 is spaced apart from the board contact portion 102 by a predetermined interval.

At this time, the spacing between the auxiliary runner plate portion 107 and the board plate portion 102 is the same as the space between the board plate portion 102 and the runner plate portion 104.

In addition, the stud 100 is characterized in that molded in two layers of overlapping metal plate.

In addition, a continuous corrugation portion 22 is formed on the side wall 21 of the runner 20, so that the contact area between the side wall 21 of the runner 20 and the stud 100 is minimized.

In addition, the side wall 21 of the runner 20 is formed so that the pleats 22 continuous in the vertical direction, so that the end of the auxiliary runner plate 107 of the stud 100 is inserted into the pleats 22. It is characterized by.

In the present invention configured as described above, the runners installed on the ceiling and the floor do not come into contact with the surface finishing material, so that vibration and noise are not transmitted across the drywall through the runner, thereby providing excellent sound insulation of the drywall.

1 is a partial cross-sectional perspective view showing a conventional drywall configuration.
2 is a cross-sectional view showing a conventional drywall configuration.
Figure 3 is a perspective view of a stud according to an embodiment of the present invention.
4 is a cross-sectional view showing a stud according to an embodiment of the present invention.
5 is a front view showing a stud according to an embodiment of the present invention.
Figure 6 is a perspective view showing a state in which the runner and the stud according to the present invention is fastened.
7 is a cross-sectional view showing a state in which the runner and the stud are fastened according to the present invention.
8 is a perspective view showing a stud according to another embodiment of the present invention.
Figure 9 is a perspective view of a stud according to another embodiment of the present invention.
10 is a perspective view showing a state in which a stud and a runner are fastened according to still another embodiment of the present invention.
Figure 11 is a perspective view showing that the wrinkles formed on the side wall of the runner.
Fig. 12 is a perspective view showing a vertical corrugation formed on the sidewall of the runner, wherein the auxiliary runner contact portion of the stud is inserted and fixed to the corrugation.

Hereinafter, with reference to the preferred embodiments of the present invention and the accompanying drawings will be described in detail, the same reference numerals in the drawings will be described on the assumption that the same components.

When any one element in the description or claims of the invention "includes" another element, unless otherwise stated, it is not limited to consisting only of that element, and other elements are not interpreted. It should be understood that it may include more.

The sound insulation stud installation structure according to the present invention includes a runner 20 respectively installed on the ceiling and the floor and a vertical stud 100 installed at predetermined intervals between the runners 20.

Stud 100 of the present invention, as shown in Figures 3 to 5 both side ends of the plate-like web 101 is extended in the lateral direction of the web 101 to form a board contact portion 102, respectively, so that the cross-sectional shape The stud 100 is formed in the 'c' shape.

The board contact portion 102 is a part of the gypsum board 10 is fastened and fixed in contact with the gypsum board 10.

And by processing the groove (unsign) perpendicular to the board contact portion 102, by minimizing the contact area with the gypsum board 10 is configured so that less vibration and noise transmitted through the gypsum board into the stud 30 It is desirable to.

The web 101 of the stud 100 is cut in a 'H' shape at predetermined intervals as shown in FIG. 3 to form an incision 105 having a hole shape, and the web 101 on both sides of the incision 105. Form a pair of wings 106 protruding vertically.

The wing 106 may be separately formed and fastened to the web, but the web 101 formed of a thin metal plate is cut in a 'H' shape to fold both sides of the wing 106 and the cutout portion ( It is preferable to simultaneously form 105).

In the exemplary embodiment of the present invention, the wings 106 are formed to protrude in the vertical direction with the web 101 on both sides of the cutout 105, but only the cutout 105 may be formed without the wings 106. .

As shown in FIG. 6, the runner 20 bends and forms a thin plate-shaped metal into a square shape having one side open at a cross section.

At this time, the width of the runner 20 (the distance between the side wall 21 and the side wall 21) is equal to the distance between the wing 106 and the wing 106 of the cutout portion 105 of the stud 100, The width of the runner 20 is shaped slightly smaller than the distance between the wings 106 of the stud 100 so that the runner 20 can be easily inserted between the wings 106.

The runner 20 formed as described above is fastened and fixed to the ceiling and the bottom, respectively, the runner 20 installed on the ceiling is installed so that the open portion faces downward, and the runner 20 installed on the floor is opened. The installed part is installed to face upwards.

The stud 100 is installed vertically at predetermined intervals between the ceiling and the runner 20 installed on the floor. As shown in FIG. 3, a part of the web 101 is cut at the top and the bottom of the stud 100 vertically. The folded and molded runner contact part 104 and the hole-type runner insertion hole 103 are positioned.

When the stud 100 is installed in the field, the stud 100 is cut according to the site situation. When the stud 100 is cut on the cutout 105, the cutout is cut when the stud 100 is cut. The runner insertion hole 103 and the runner contact part 104 are formed automatically by cutting the 105 and the wing 106.

If the cutting position of the stud 100 is not the position of the cutout portion 105 but the web 101 portion, a separate runner insertion hole 103 and a runner contact part 104 should be formed through post-processing.

When the stud 100 is installed between the runner 20 fastened to the ceiling and the floor, respectively, the runner 20 of the ceiling is inserted into the runner insertion hole 103 formed on the top of the stud 100 as shown in FIG. The stud 100 is installed so that the runner 20 is inserted into the runner insertion hole 103 formed at the bottom of the stud 100.

At this time, both sides of the runner contact plate 104 may be formed to be curved in a predetermined curvature in an arc shape so that the runner 20 is smoothly inserted into the runner insertion hole 103.

When the stud 100 is installed such that the runner 20 is inserted into the runner insertion hole 103 of the stud 100 as described above, as shown in FIGS. 6 and 7, runner contacts respectively formed on the upper and lower portions of the stud 100 are provided. The stud 100 is firmly fixed to the runner 20 while the plate 104 is in close contact with both sidewalls 21 of the runner 20.

The gypsum board 10 is brought into close contact with the board contact part 102 of the stud 100, and then the gypsum board 10 is fastened to the board contact part 102 of the stud 100 by using a piece to fix the piece. When the stud 100 is twisted (rotated) in the runner 20, the piece may not be properly lodged when driven.

The runner contact portion 104 formed on the top and bottom of the stud 100 is in close contact with the side wall 21 of the runner 20, so that the stud 100 is not twisted in the runner 20 when the piece is driven. It serves to fix.

3 and 4, the end of the board contacting part 102 is rolled inward to form an auxiliary runner contacting part 107 at the end thereof, and the auxiliary runner contacting part 107 and the board contacting part 102 are formed. It is preferable to configure so that the space | interval between them may become the same space | interval between the board board | plate board part 120 and the runner board | plate part 104.

As described above, the spacing between the board contacting part 102 and the auxiliary runner contacting part 107 of the stud 100 is equal to the spacing between the board contacting part 102 and the runner contacting part 104. When the runner 20 is inserted into the insertion hole 103, as shown in FIG. 7, the runner contact part 104 and the auxiliary runner contact part 107 closely contact the sidewalls 21 of the runner 20, so that the stud 100 is runner. It is more firmly fixed to 20.

In addition, since the board contacting part 102 of the stud 100 does not bend when the piece is put in order to fasten the gypsum board 10 to the stud 100, the piece may be smoothly fastened.

When the gypsum board 10 is fastened to both sides of the stud 100 vertically installed at predetermined intervals between the ceiling and the runner 20 of the floor as described above, the gypsum board 10 contacts the runner 20 as shown in FIG. 7. It will be spaced apart at regular intervals.

As described above, when the gypsum board 10 and the runner 20 are spaced at a predetermined interval, the vibration and noise (vibration and noise transmitted through the gypsum board) of the gypsum board 10 are not transmitted to the runner 20, and thus, are transmitted to the wall. There is a significant reduction in the vibration and noise.

Vibration and noise transmitted through the gypsum board 10 is transmitted over the wall only through the stud 100 in contact with the gypsum board 10, as shown in FIG. 3 at predetermined intervals in the web 101 of the stud 100. Since the cutout 105 is formed in a hole shape, the area of the web 101 is reduced, thereby reducing the vibration and noise transmitted through the web 101.

In addition, since the wings 106 protruding in the vertical direction with the web 101 are formed at both sides of the cutout 105, a part of the vibration transmitted through the web 101 is transmitted to the wings 106 and disappeared so that the studs ( The vibration and noise transmitted through 100 are reduced.

As described above, the stud 100 described in the embodiment of the present invention is manufactured by forming a stud 100 by bending a thin metal plate, and overlapping two sheets of thin metal plate and bending the stud 100 to form another one shown in FIG. 8. The stud 100 of the embodiment may be molded.

The stud 100 shown in FIG. 8 overlaps and forms two metal plates, so that the web 101 constituting the stud 100, the board contact part 102, the blade 106, and the runner contact part 104 are two. It is composed of two layers.

The stud 100 formed in two layers as described above has a high vibration damping rate compared to the stud 100 formed in one layer, and thus has excellent sound insulation. As a result of comparing and experimenting with studs formed of a metal plate of one layer with the same thickness as the stud 100 formed of two layers, the sound insulation of the studs formed of two layers thinner than the studs formed of a thick one layer was excellent. .

9 and 10 are perspective views showing a stud 100 according to another embodiment of the present invention.

The stud 100 according to another embodiment of the present invention is formed on one side or both sides of the runner contact plate 104 and the cutout 105 formed on one or both sides of the runner insertion hole 103 in the above-described embodiment of FIG. 3. The formed wing 106 configuration is an embodiment in which it is deleted.

The runner plate portion 104 formed at the side of the runner insertion hole 103 serves to more firmly support the stud 100 with respect to the runner 20 inserted into the runner insertion hole 103, but the runner plate portion 104 is formed. It is possible to implement even if there is no configuration.

Similarly, the wing 106 formed on the side of the cutout 105 serves to attenuate the vibration-type noise transmitted through the stud 100, but can be implemented even if the wing 106 is omitted.

As shown in FIG. 11, horizontal wrinkles 22 are formed on the sidewall 21 of the runner 20 so as to be continuous in the vertical direction, thereby minimizing the contact area between the runner 20 and the stud 100 so that the stud 100 is minimized. It is preferable to configure to minimize the transmission of noise in the form of vibration from the runner (20).

More preferably, as shown in FIG. 12, the wrinkles 22 are formed on the side wall 21 of the runner 20 so that the vertical wrinkles 22 are continuous in the horizontal direction, thereby forming a gap between the runner 20 and the stud 100. By minimizing the contact area to minimize the transmission of noise in the form of vibration from the stud 100 to the runner 20, when the stud 100 is installed in the runner 20, the auxiliary runner plate of the stud 100 ( More preferably, the end of the 107 is inserted into the vertical pleats 22 so as to firmly fix the stud 100 in the runner 20 so as not to slip in the horizontal direction.

As shown in FIGS. 11 and 12, a hole-shaped cutout 23 is formed at the bottom of the runner 20 at predetermined intervals, so that noise in the form of vibration from one sidewall 21 to the other sidewall 21 is generated. It is desirable to configure to minimize delivery.

In the present invention configured as described above, the runner 20 installed on the ceiling and the floor does not come into contact with the gypsum board 10, and thus the vibration and noise transmitted to the other side of the drywall through the runner 20 are significantly reduced.

The technical spirit of the present invention has been described through the above-described embodiment.

It will be apparent to those skilled in the art that various modifications or variations can be made to the embodiments described above from the description of the invention.

In addition, even if not explicitly shown or described, those skilled in the art to which the present invention pertains various forms of modification including the technical idea according to the present invention from the description of the present invention. Is obvious and still belongs to the scope of the present invention.

The above embodiments described with reference to the accompanying drawings are described for the purpose of illustrating the present invention, and the scope of the present invention is not limited to these embodiments.

10: Gypsum Board
20: runner
21: sidewall
22: wrinkles
23: incision
100: stud
101: web
102: board contact part
103: runner insertion hole
104: Runner contact part
105: incision
106: wings
107: auxiliary runner plate

Claims (11)

Web 101 formed in the form of a plate,
Both sides of the web 101 and the board contacting portion 102 is extended from the web 101,
A stud 100 formed at each of the upper and lower ends of the web 101 and having a runner insertion hole 103 into which a runner 20 is inserted; And
By having a runner 20 formed in a rectangular shape having a cross-section with both side walls,
The runner is characterized in that the runner 20 is inserted into the runner insertion hole 103 formed at the top and bottom of the stud 100 so that the gypsum board fastened to the stud 100 is spaced apart from the runner 20 by a predetermined interval. Sound stud mounting structure installed inside the stud.
The method of claim 1,
The runner insertion hole (103) has a width equal to the distance between the sidewalls of the runner (20), the sound stud installation structure is installed inside the stud, characterized in that the runner is formed narrower than the width of the web (101).
The method of claim 1,
The end of the board contact part 102 is bent inwardly and spaced apart from the board contact part 102 by a predetermined interval, and the auxiliary runner contact part 107 is formed in which the end is in contact with the side wall of the runner 20. Sound insulation stud mounting structure with runner installed inside the stud.
The method of claim 3,
The height of the auxiliary runner contact portion 107 protruding from the board contact portion 102 is equal to the distance from the board contact portion 102 to the runner insertion hole 103. Installation structure.
The method of claim 1,
Sound cut stud installation structure is provided with a runner is installed inside the stud, characterized in that the cut portion 105 in the form of holes at predetermined intervals in the web (101).
The method of claim 1,
One or both sides of the runner insertion hole 103 is formed with a runner contact plate 104 protruding perpendicular to the web 101, the runner is installed in the stud inside the stud installation structure.
The method of claim 5,
One side or both sides of the cutout 105, the soundproof stud installation structure is installed inside the stud, characterized in that the wing 106 protruding from the web 101 is formed.
The method of claim 1,
The board contacting part 102 is a sound stud installation structure is installed inside the stud, characterized in that the groove is formed in the vertical direction.
The method according to claim 1, wherein
The stud 100 is a sound stud installation structure is installed inside the stud, characterized in that the molded with two layers of overlapping metal plate.
The method of claim 1,
The runner stud is configured to minimize the contact area between the stud 100 and the side wall 21 of the runner 20 by forming a continuous crease 22 in the side wall 21 of the runner 20. Soundproof stud mounting structure installed inside.
The method of claim 3,
The side wall 21 of the runner 20 is formed by forming the pleats 22 continuous in the vertical direction, so that the end of the auxiliary runner plate 107 of the stud 100 is inserted into the pleats 22. Sound stud mounting structure with a runner installed inside the stud.

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