KR102544913B1 - Reinforcement structure of slab effective against noise between floors - Google Patents

Abstract

In the present invention, in the slab concrete structure,
Two slab formworks (F) spaced apart from each other to form a separation portion (G) and mounted horizontally;
A slab reinforcing mechanism (1000) installed in the spaced part (G) at a level lower than that of the slab formwork (F);
It consists of,
Slab concrete (C) is poured on top of the slab formwork (F) and the slab reinforcing mechanism (1000),
The slab formwork (F) provides a slab reinforcing structure effective in preventing noise between floors, characterized in that it is demolded.

Description

Reinforcement structure of slab effective against noise between floors}

The present invention is intended to be applied to slabs that are divided into spaces in which upper and lower floors are different generations, such as apartment houses, and are effective in preventing noise between floors by suppressing vibration of the slab according to living loads in apartment houses where noise between floors is a problem. It is about a slab reinforcement structure effective for prevention.

In buildings where the upper and lower floors are divided into different generations, such as apartment buildings, inter-floor noise is divided into 'light impact sound' of mid- and high-frequency components such as the sound of dragging a chair, and 'heavy impact sound' of low-frequency components caused by heavy and soft impacts such as walking. In particular, as a residential habit in Korea, where people live barefoot indoors, weight impact noise is a serious problem.

Inter-floor noise is called solid sound and is transmitted through the structure, and is greatly affected by the vibration of the structure. It is a representative structure of an apartment house due to its excellent workability. It is very vulnerable to noise, and since the 1980s, when the housing type was centered on apartment houses, it has become a social problem such as frequent murder cases. is not getting

As a countermeasure, the thickness of the slab is regulated to be more than the structurally necessary thickness, but due to the slab thickness more than necessary, the load of the entire structure is increased and the structure is burdened, and satisfactory results are not obtained for noise between floors.

As a more active method, a method of structurally reinforcing the slab against vibration (bending deformation) of the slab has been proposed.

Registration Patent No. 10-0722520 is a method of attaching a reinforcing material (FRP) to the bottom of the slab, and it is very difficult to join the slab and the reinforcing material, which causes problems in construction. The effect is low, so there is no clear improvement in noise between floors, and it is not economical.

Registered Patent No. 10-0613418 is a method of supporting the central part of the slab by installing a bracket on the bottom of the slab and fixing the steel wire to introduce tensile force, and supports the slab moving vertically with the tensile force of the horizontally installed steel wire. Because of the striking, the transmission of force can inefficiently affect large deformations, so the effect cannot be expected on micro-vibrations such as inter-floor noise, and there are disadvantages in that construction is difficult, such as fixing braces and introducing uniform tension in more than two directions. In addition, since the installation is installed between the lower part of the slab and the ceiling, it is difficult to apply it to wall structures sensitive to floor height due to spatial limitations.

In addition, the above-described technologies are slab reinforcement methods in pre-constructed structures and are not suitable for new structures, so there is a need for slab reinforcement that is economical, easy to construct, effective in reducing noise between floors, and applicable to new structures.

Accordingly, the present inventor is installed inside the slab and applies tension to the strand installed inside the slab only by tightening the bolts at the lower part of the slab center, thereby raising the slab upward through the elastic support part and elastically supporting it to effectively function in reducing inter-floor noise. (Registered Patent No. 10-2155909).

Since the above invention is installed inside the slab, it is free from spatial constraints, and there is no structural effect such as an increase in the load of the slab or a decrease in yield strength, and is characterized in that it can be applied without structural change within the existing structural design.

On the other hand, according to 「Act on Fire Prevention, Installation and Maintenance of Fire Protection Facilities, and Safety Management」 and 「Rules on Equipment Standards of Buildings,」 a sprinkler and ventilation system are required between the lower part of the slab and the ceiling. Although a space of 150 mm or more is required for the intersection light, it is possible to utilize the space because it is installed only in some parts.

As a result of the experiment of the above invention, it was confirmed that the installation was concentrated on the center of the slab with the most vibration, and the thicker the slab was, the more effective it was. Improved slab reinforcement using

[Document 1] Republic of Korea Patent Registration No. 10-0722520 ‘Slab Floor Structure’, filed on May 19, 2005 [Document 2] Republic of Korea Patent No. 10-0613418 ‘Floor Impact Sound Reduction Device’, filed on December 14, 2004

The present invention is presented in order to solve the various conventional problems as described above. Its purpose is to suppress slab vibration in apartment houses where inter-floor noise due to slab vibration due to living load is a problem, effective in inter-floor noise prevention, economical, easy to construct, and effective in preventing inter-floor noise applicable to new structures. It is intended to provide a reinforcing structure.

In order to solve the above technical problem, the present invention is a slab concrete structure,

Two slab formworks (F) spaced apart from each other to form a separation portion (G) and mounted horizontally;

A slab reinforcing mechanism (1000) installed in the spaced part (G) at a level lower than that of the slab formwork (F);

It consists of,

Slab concrete (C) is poured on top of the slab formwork (F) and the slab reinforcing mechanism (1000),

The slab formwork (F) provides a slab reinforcing structure effective in preventing noise between floors, characterized in that it is demolded.

According to the present invention, the following effects are expected.

First, in an apartment house where inter-floor noise due to slab vibration due to living load is a problem, a slab reinforcement structure effective in preventing inter-floor noise that reduces weight impact noise by suppressing slab vibration is provided.

Second, it provides a slab reinforcement structure that is economical, easy to construct, and effective in preventing inter-floor noise applicable to new structures.

Third, since it is installed inside the slab, it provides a slab reinforcement structure that is effective in preventing inter-floor noise free from spatial restrictions.

Fourth, it provides a slab reinforcement structure effective in preventing inter-floor noise that can be applied within the existing structural design without structural effects such as the slab's resistance.

1 is an exploded perspective view of a slab reinforcing mechanism used in a slab reinforcing structure effective for preventing noise between floors according to the present invention.
Figure 2 is a combined perspective view of Figure 1;
Figure 3 shows a slab viewed from the bottom after all the formwork is demolded in the slab reinforcement structure effective for preventing inter-floor noise of the present invention.
4 is an exploded perspective view of a tension reinforcement tool used in the present invention.
5 is a detailed view of an elastic support part in a tension reinforcement tool used in the present invention.
6 and 7 explain the construction process of the slab reinforcing structure effective in preventing inter-floor noise of the present invention.
Figure 8 shows the concept of adjusting the tensile force of the strand and the transmission process of the force in the slab reinforcement structure effective for preventing noise between floors according to the present invention.

Hereinafter, the present invention will be described in more detail through an embodiment in which the concept of the present invention as described above is preferably implemented in conjunction with the accompanying drawings.

1 is an exploded perspective view of a slab reinforcing mechanism used in a slab reinforcing structure effective for preventing noise between floors according to the present invention.

Figure 2 is a combined perspective view of Figure 1;

Figure 3 shows a slab viewed from the bottom after all the formwork is demolded in the slab reinforcement structure effective for preventing inter-floor noise of the present invention.

4 is an exploded perspective view of a tension reinforcement tool used in the present invention.

5 is a detailed view of an elastic support part in a tension reinforcement tool used in the present invention.

6 and 7 explain the construction process of the slab reinforcing structure effective in preventing inter-floor noise of the present invention.

Figure 8 shows the concept of adjusting the tensile force of the strand and the transmission process of the force in the slab reinforcement structure effective for preventing noise between floors according to the present invention.

As shown in FIGS. 6 and 7, the slab reinforcement structure effective in preventing inter-floor noise of the present invention,

In the slab concrete structure,

Two slab formworks (F) spaced apart from each other to form a separation portion (G) and mounted horizontally;

A slab reinforcing mechanism (1000) installed in the spaced part (G) at a level lower than that of the slab formwork (F);

It consists of,

Slab concrete (C) is poured on top of the slab formwork (F) and the slab reinforcing mechanism (1000),

The slab formwork (F) is characterized in that it is demolded.

And as shown in Figures 1 and 2,

The slab reinforcement mechanism 1000,

Reinforcement formwork (100);

Tension means and truss reinforcing bars 300 installed above the reinforcing formwork 100;

It consists of,

It is characterized in that the tension means is tensed to apply prestress before or after the casting of the slab concrete (C).

And as shown in Figure 7,

The reinforcing formwork 100 is characterized in that it is demolded.

As the tension means, a conventional means may be used, but in the present invention, it is preferable to use the shown tension reinforcing member 200.

The truss reinforcement 300 may use a conventional triangular truss composed of an upper bar 310, a lower bar 320 and a lattice 330.

The truss reinforcing bar 300 is a structural material and serves to protect the tensile reinforcement 200 described later in the construction process.

As shown in FIGS. 1 to 2 and 4 to 7,

The tensile reinforcing sphere 200 used in the present invention,

A fixing unit 220 embedded in the reinforcing slab (S`);

An elastic support part 230 buried under the reinforcing slab (S`) and having a lower end exposed to the lower part of the reinforcing slab (S`);

a strand 210 connected between the fixing part 220 and the elastic support part 230;

It consists of including,

After curing the reinforcing slab (S`), the reinforcing slab (S`) is elastically supported by introducing a tensile force to the strand 210 using the tension adjusting means 234 under the elastic support part 230,

It is characterized in that the reinforcing slab (S`) and the slab (S) are effective in reducing noise between floors by suppressing vibration of the reinforcing slab (S`) and the slab (S) due to the life load on the upper part.

and

The fixing unit 220 is composed of two,

The two strands 210 connected to the two fixing parts 220 are characterized in that they form an obtuse V shape with each other around the elastic support part 230.

The stranded wire 210 is preferably manufactured by twisting a steel wire having corrosion resistance and durability so as to secure tensile force.

In addition, in order to prevent adhesion (friction) with the reinforcing slab (S`) when the tension is adjusted, the strand 210 is preferably unbonded at least 1/2 of the length of the member, and the unbonding treatment ( unboned), a vinyl tube, etc. can be used.

In addition, it is preferable that the strands 210 are installed in the same direction as the span direction of the reinforcing slab (S′), that is, the direction of the tensile rebar.

The fixing unit 220,

An anchor 221 embedded in the reinforcing slab (S′);

An anchorage 222 for fixing the strand 210 coupled to the middle of the anchor 221;

It is composed of.

The elastic support part 230,

An embedding box 231 with an open bottom;

A tension introduction bolt 233 installed inside the embedding box;

a pressure support plate 232 installed under the embedding box 231 and exposing a lower end of the tension introducing bolt 233 through a central hole 232a;

a tension adjusting means 234 fastened to the lower end of the tension introducing bolt 233 exposed to the lower portion of the pressure support plate 232;

It consists of,

An inlet 231a is formed on the side of the embedding box 231, and the sleeve pipe 211 is introduced and installed from the outside obliquely from top to bottom through the inlet 231a,

The strand wire 210 is introduced into the sleeve pipe 211 and is fastened to the hook hole 233a at the upper end of the tension introducing bolt 233.

The sleeve pipe 211 is preferably made of a material that is easily bent, such as a corrugated tube having elasticity, in consideration of workability.

When the fixing part 220 is composed of two, and the two strands 210 connected to the two fixing parts 220 form an obtuse V shape with respect to the elastic support part 230,

As shown in FIG. 5, the strands 210 are two when viewed from the outside, but substantially one strand is drawn into the sleeve pipe 211 and passed through the hook hole 233a to the sleeve pipe 211 on the opposite side. will exit with

The external circumferential surface of the tension introducing bolt 233 is formed with a male thread 233b, and when the tension adjusting means 234 in the form of a nut is rotated, the tension introducing bolt 233 raises and lowers the strands 210. ), the tensile force is released or applied.

The reinforcing formwork 100 is composed of a horizontal board 110 constituting a horizontal lower surface and a vertical board 120 vertically installed at both ends of the horizontal board 110.

The horizontal board 110 and the vertical board 120 are preferably formed integrally by bending a plate material, but separate members may be assembled and used depending on site circumstances.

As shown, since the horizontal board 110 is installed at a level lower than the slab formwork F, a step difference occurs, and the vertical board 120 serves to fill the step difference.

The height of the vertical board 120 is the distance between the lower part of the slab and the ceiling, excluding the minimum space for the conventional ventilation system and sprinkler, and the conventional demolding method using a formwork material or the sloped method using a galvanized steel sheet as a material (all-in-one) is also possible.

The tension adjusting means 234 passes through the hole 111 of the horizontal board 110.

The reinforcing slab (S`) is thicker than the surrounding slabs (S) and is structurally advantageous in sagging (vibration). It is elastically supported while being raised upward, and as a result, it is characterized in that it effectively functions to reduce noise between floors by suppressing vibration of the slab (S) due to living loads such as walking.

As shown in Figures 6 and 7,
The present invention further includes two wall forms (FW) installed vertically apart from each other at a predetermined distance, and the upper end of the wall formwork (FW) is leveled down by the height of the vertical board 120 and the width is It is integrally cut to be the same as the width of the horizontal board 110,
The end of the horizontal board 110 is mounted on the leveled down part of the upper end of the wall formwork (FW), and the end of the slab formwork (F) is mounted on the remaining part of the upper end of the wall formwork (FW) that is not leveled down. is mounted,
It is characterized in that the reinforcing slab (S`) is constructed in the longitudinal direction of the girder.
And as shown in Figures 6 and 7, the construction method of the present invention,

① Assemble and install the tension reinforcing ball 200 and the truss reinforcing bar 300 in the reinforcing formwork 100, but pull the fixing part 220 obliquely to tense the strand 210 with a predetermined tension and the anchor A preparation step of binding and fixing (221) to the upper muscle (310);

② After the two slab formworks (F) are spaced apart from each other at a certain distance to form a separation portion (G) and installed horizontally, the slab reinforcement mechanism ( 1000) slab formwork installation step of installing;

③ After the reinforcement (not shown) and facility piping (not shown) construction is completed, the slab concrete (C) is poured and cured on the upper part of the slab formwork (F) and the slab reinforcement mechanism (1000), and then the slab formwork ( F) a slab concrete construction step of demolding the reinforcing formwork 100;

④ Tightening the tension adjusting means 234 protruding from the lower part of the reinforcing slab (S`) to lower the tension introducing bolt 233 downward, thereby causing a change in the length of the strand 210, thereby introducing tension. step;

It is characterized in that it is configured to include.

However, in the step ③ above, when the reinforcing form 100 is made of galvanized steel and integrated with the truss reinforcing bar 300, it is not necessary to demold.

And as in step ④ above,

When the tension adjusting means 234 protruding from the lower part of the reinforcing slab (S`) is tightened and the tension introducing bolt 233 is lowered downward so that the length of the strand 210 is changed and tension is introduced,

In the state in which the fixing part 220 is fixed to the reinforcing slab (S`), the restoring force according to the tension of the strand 210 raises the tension introduction bolt 233 connected to the strand 210 upward. do.

Therefore, as a result, the concrete slab (S) is raised upward through the tension introducing bolt (233) - tension adjusting means (234) - pressurized support plate (232), like a bow [concrete slab (S)] - bow string [strength wire (210) )] - It has the same structure as the arrow [tension introduction bolt 233].

Therefore, the pressure support plate 232 elastically supports the reinforcing slab (S`) and tensions the reinforcing slab (S`), so that the reinforcing slab (S`) and the reinforcing slab (S`) It is characterized in that it functions effectively in reducing noise between floors by suppressing vibration of S`) and the slab (S).

Although the present invention has been described in relation to the preferred embodiments as mentioned above, various modifications and variations are possible within the scope without departing from the gist of the present invention, and can be used in various fields.

Accordingly, the claims of this invention include the modifications and variations which fall within the true scope of this invention.

G: Separation
F: slab formwork
FW: Wall formwork
C: slab concrete
S: slab
S`: Reinforcing slab
1000: slab reinforcement mechanism
100: reinforcement formwork
110: horizontal board
111: hole
120: vertical board
200: tensile reinforcement
210: strand
211: sleeve tube
220; fixing unit
221: Anchor
222: anchorage
230: elastic support
231: purchase box
231a: inlet
232: pressure support plate
232a hole
233: tension introduction bolt
233a: hook hole
233b: Male thread
234: tension adjusting means
300: truss reinforcement
310: upper muscle
320: lower muscle
330: lattice

Claims (3)

In the slab concrete structure,
Two slab formworks (F) spaced apart from each other to form a separation portion (G) and mounted horizontally; A slab reinforcing mechanism (1000) installed at a level lower than the slab formwork (F) in the separation portion (G); slab concrete on top of the slab formwork (F) and the slab reinforcement mechanism (1000) (C) is cast, and the slab formwork (F) is characterized in that it is demolded,
The slab reinforcement mechanism 1000 includes a reinforcing form 100; It is composed of a; tension means and truss reinforcing bars 300 installed on the upper part of the reinforcing formwork 100; characterized in that the tension means is tensioned to give prestress before or after pouring of the slab concrete (C) and
The reinforcing formwork 100 is characterized in that it is demolded,
The tension means is a tension reinforcing sphere 200, the tension reinforcing sphere 200 is a fixing unit 220 embedded in the reinforcing slab (S`); An elastic support part 230 buried under the reinforcing slab (S`) and having a lower end exposed to the lower part of the reinforcing slab (S`); A strand wire 210 connected between the fixing part 220 and the elastic support part 230; after curing the reinforcing slab (S`), the tension adjusting means 234 under the elastic support part 230 ), by introducing tensile force into the strand 210, the reinforcing slab (S`) is elastically supported, and the reinforcing slab (S`) and the reinforcing slab (S It is effective in reducing inter-floor noise by suppressing `) and the slab (S) from vibrating. Is characterized by forming an obtuse V shape with each other around the elastic support part 230,
The fixing part 220 includes an anchor 221 embedded in the reinforcing slab (S′); It is configured to include; an anchorage 222 for fixing the strand 210 coupled to the middle of the anchor 221,
The elastic support part 230 includes a buried box 231 with an open bottom; a tension introduction bolt 233 installed inside the embedding box; a pressure support plate 232 installed under the embedding box 231 and exposing a lower end of the tension introducing bolt 233 through a central hole 232a; It is configured to include a; tension adjusting means 234 fastened to the lower end of the tension introducing bolt 233 exposed to the lower portion of the pressure support plate 232, and an inlet 231a is formed on the side of the embedding box 231 The sleeve pipe 211 is inserted and installed from the outside obliquely from top to bottom through the inlet 231a, and the strand wire 210 is drawn into the sleeve pipe 211 to hook the upper end of the tension introducing bolt 233. (233a),
The reinforcing formwork 100 is composed of a horizontal board 110 constituting a horizontal lower surface and a vertical board 120 installed vertically at both ends of the horizontal board 110,
The horizontal board 110 is leveled down from the slab formwork F to generate a step, and the vertical board 120 serves to fill the step, and the hole 111 of the horizontal board 110 has the Since the tension adjusting means 234 penetrates,
The reinforcing slab (S`) is thicker than the surrounding slabs (S) to secure structural performance against sagging, and the slab (S) is pushed upward through the elastic support part (230) by the restoring force of the tensioned strand (210). It is raised and elastically supported, and it is characterized in that it functions effectively in reducing inter-floor noise by suppressing the vibration of the slab (S) due to living load,
Two wall forms (FW) installed vertically spaced apart from each other; are further included,
The upper end of the wall formwork (FW) is leveled down by the height of the vertical board 120 and the width is integrally cut to be the same as the width of the horizontal board 110,
The end of the horizontal board 110 is mounted on the leveled down part of the upper end of the wall formwork (FW), and the end of the slab formwork (F) is mounted on the remaining part of the upper end of the wall formwork (FW) that is not leveled down. is mounted,
Slab reinforcement structure effective in preventing inter-floor noise, characterized in that the reinforcing slab (S`) is constructed in the longitudinal direction of the girder. delete delete

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