KR102311231B1 - Concrete slab and its construction method for decreasing heavy impact sound - Google Patents

Abstract

The present invention relates to technology for reducing floor noise caused by a floor shock load in an apartment building or the like. In regard to a concrete slab comprising an upper area including an upper rebar, a lower area including a lower rebar, and a middle area formed between the upper and lower areas, a tension reinforcement material connecting the upper and lower areas with each other vertically or at a random angle is separately added to the middle area of the slab, wherein the tension reinforcement material comprises an I-shaped unit member formed with an I-shaped cross section by comprising an upper fixing part, a lower fixing part and a tension connection part connecting the upper and lower fixing parts, and a horizontal connection member formed to connect upper fixing parts of a plurality of I-shaped unit members with each other by comprising a plate material of a predetermined length or a steel wire having a circular cross section, and, accordingly, the upper fixing part and the horizontal connection member are located in the upper area, and the lower fixing part is located in the lower area.

Description

Concrete slab and its construction method for decreasing heavy impact sound

The present invention relates to a concrete slab for reducing weight impact noise and a construction method thereof, and more particularly, to a technology for reducing inter-floor noise generated in apartment houses due to floor impact load. Concrete slab for reducing the heavy impact sound to reduce the heavy impact sound by additionally adding a tensile reinforcing material to the internal structure of the slab in addition to the means for reducing the light impact sound so that deflection and flexural rigidity (or bending stiffness) are strengthened without increasing the thickness of the slab; It is about the construction method.

As shown in FIG. 1, the conventional floor structure for floor impact sound reduction is to laminate a cushioning material, lightweight foam concrete, finishing mortar and floor finishing material on the upper part of the concrete slab. In general, in apartment houses, etc., the floor impact sound is reduced by a combination of the following four technologies. The characteristics of the region (heavy impact sound) and the high frequency region (light impact sound) are sequentially shown.

First, the surface buffer method that changes the characteristics of the impact source uses a flexible floor covering material such as carpet and foamed vinyl-based cardboard, so that the peak impact force is reduced even if the overall impact force is not changed, so that the impact sound is reduced. As shown in FIG. 2A , this is effective for a light impact sound in a high frequency band, but has a disadvantage in that it has little effect on a heavy impact sound in a low frequency band.

Second, the weight and high rigidity flooring method, which makes it difficult to vibrate the reinforced concrete slab from impact, increases the weight and stiffness when the thickness of the slab is increased. Accordingly, vibration of the floor in response to the impact is difficult, and the floor impact sound is also reduced. In particular, as shown in FIG. 2B , the effect of reducing the weight impact sound is obtained. However, there are problems such as an increase in the total construction cost and an increase in the design height due to an increase in self-weight due to an increase in thickness.

Third, the floating floor construction method, which prevents vibration or impact energy from being transmitted to the reinforced concrete slab, uses the characteristics of a resonance system composed of a cushioning material and a floating floor layer, that is, the characteristic of a resonance system composed of supporting a mass with an elastic material. This is a way to reduce vibration transmission. In the case of a floating floor, as shown in FIG. 2c , although effective in reducing the light impact sound, there are cases in which the weight impact sound is rather disadvantageous.

Fourth, the sound insulation double ceiling method, which blocks the sound emitted from the reinforced concrete slab, secures a sufficient air layer in the ceiling under the floor slab and at the same time increases the surface density of the ceiling material, ) is a method to reduce the impact sound by adding a device, etc. However, in general ceilings, there is a problem in that the blocking performance of the heavy impact sound tends to deteriorate due to the resonance caused by the ceiling material and the air layer.

As such, in the technology for reducing the weight impact noise, which accounts for the largest portion of the complaints against inter-floor noise, there is no effective technical measure to date other than the method of increasing the thickness of the slab (high-stiffness floor method). It is known through the results of several studies that the method of increasing the compressive strength has no impact sound reduction effect).

As described above, if the thickness of the concrete slab is increased, the floor impact sound, especially the weight impact sound, is reduced by the phenomenon of decreasing the slab deflection and increasing the flexural rigidity (high stiffness). In addition, as the bending rigidity of the slab increases (high rigidity), the natural frequency band of the slab increases, so that the weight impact sound is more effectively reduced.

However, in this method, if the thickness is increased, the structure must be further strengthened by the increased weight, which significantly increases the overall construction cost of the structure. When the slab thickness is increased, all structural members (slab beam wall column foundation, etc.) should be strengthened together. In addition, this increases the total weight of the building, which adversely affects external shock loads such as earthquakes, and thus requires additional reinforcement of the entire structure. There is also an analysis that increases by about 5%.)

In addition, when the slab thickness is increased, there is a problem in that the height of the building must be increased by the increased thickness of the slab in order to maintain the existing design height (ceiling height) of the indoor space of the building.

In addition to the existing method of strengthening the flexural rigidity by increasing the slab thickness as described above, as a special case for increasing the flexural rigidity of the slab (high rigidity), Patent Registration No. 1188323 “Improved floor structure for reducing floor impact noise” (Patent Document) 1) is there. In the patent document, 'in the floor structure for reducing the floor impact sound, the slab (S) located at the bottom of the floor structure; a cushioning material (B) installed on the slab (S); a finishing mortar (F) formed on the cushioning material (B); The lower end is fixed inside the slab (S) and the upper end is a tension connection part (SS) which is installed in the interior of the finishing mortar (F); And, the foamed concrete (A) formed between the cushioning material (B) and the finishing mortar (F); A portion of the impact force generated from the upper part is dispersed and transmitted to the slab (S) through the tension connection part (SS) to reduce the low-frequency band noise amplification phenomenon to reduce the weight impact sound. We propose an improved floor structure for

However, in the background art, as shown in FIG. 11, in order to increase the slab bending rigidity, the slab (S) and the finishing mortar (F) layer are integrally joined through the tension connection part (SS) with the cushioning material (B) interposed therebetween. A method for increasing the slab's flexural stiffness and reducing its deflection is presented. However, in this way, the lower part of the tension connection part (SS) is fixed to the slab reinforcing bar, and the upper part of the tension connection part (SS) protrudes to the outside of the slab floor, and the slab construction is finished. After that, a cushioning material (B), an elastic material, is installed between the plurality of tension connection parts (SS) protruding to the upper part of the slab floor, and the finishing mortar (F) layer is finally worked, and the top of the tension connection part (SS) is a finishing mortar (F) layer will be buried inside Here, the cushioning material (B) and the finishing mortar (F) layer is a relatively weak material state compared to the high rigidity concrete slab (S), and it is difficult to expect the effect of integration with the concrete slab (S). Occurs.

Patent Registration No. 1188323 "Improved floor structure to reduce floor impact noise"

The present invention is to solve the above problems, and by reinforcing the flexural rigidity of the slab without increasing the thickness of the concrete slab, not only the light impact sound, but also reducing the deflection and reinforcing the flexural rigidity to reduce the weight impact sound. An object of the present invention is to provide a concrete slab and a construction method therefor.

The present invention relates to a concrete slab comprising an upper area (A) including upper reinforcing bars, a lower area (B) including lower reinforcing bars, and an intermediate area (C) formed between the upper and lower areas, the upper area and A tension reinforcing material that interconnects the lower areas vertically or at an arbitrary angle is additionally configured in the middle area of the slab. It is formed of an I-shaped unit member formed to have a -shaped cross section, and a horizontal connecting member configured to connect the upper fixing parts of a plurality of I-shaped unit members to each other, which is made of a flat plate material of a certain length or an iron wire of a circular cross section, An object of the present invention is to provide a concrete slab for reducing the weight impact sound, characterized in that the fixing unit and the horizontal connecting member are located in the upper region (A), and the lower fixing unit is located in the lower region (B).

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In addition, it is intended to provide a concrete slab for reducing the weight impact sound, characterized in that the horizontal connecting member is configured in two rows on both sides of the upper fixing part.

In addition, the I-type unit member is to provide a concrete slab for reducing the weight impact sound, characterized in that made by butt-joining two C-shaped members.

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In addition, (a) installing a lower spacer on the upper part of the slab formwork, and reinforcing a lower reinforcing bar on the upper part of the lower spacer; (b) installing an upper spacer on the upper part of the formwork, and reinforcing an upper reinforcing bar on the upper part of the upper spacer; (c) an I-type unit member formed to have an I-shaped cross-section, consisting of an upper and lower anchorage and a tension connection connecting the upper and lower anchorages, and a flat plate material of a certain length or an iron wire with a circular cross section. In the construction of a tension reinforcing material formed of a horizontal connecting member configured to connect the upper fixing parts of a plurality of I-shaped unit members to each other, the horizontal connecting member is installed to be mounted on the upper reinforcing bar; (d) pouring concrete on the upper part of the formwork; to provide a method for constructing a concrete slab for reducing the weight impact sound, characterized in that it comprises a.

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The concrete slab and its construction method for reducing the weight impact sound of the present invention is a technology for reducing inter-floor noise generated in apartment houses due to the floor impact load. A very useful effect to reduce the weight impact sound generated in apartment houses, etc. by reducing the deflection of the slab without increasing the slab thickness and strengthening the flexural rigidity by separately adding a tensile reinforcing material to strengthen the flexural rigidity of the slab in the internal structure of the there is

The following drawings attached to this specification illustrate preferred embodiments of the present invention, and serve to further understand the technical idea of the present invention together with the detailed description of the present invention, so the present invention is limited to the matters described in the accompanying drawings It should not be construed as being limited.
1 is a cross-sectional view showing a floor structure for reducing a conventional floor impact sound.
2 is a graph sequentially showing the characteristics of the low-frequency region (weight impact sound) and high-frequency region (light impact sound) of the surface buffer method, the weight-high rigidity floor method, the floating floor method, and the sound insulation double ceiling method.
3A is a conceptual diagram of stress when a general concrete slab and floor impact force are applied.
3b is a conceptual diagram of stress when a concrete slab and floor impact force are applied for weight impact sound reduction according to the present invention.
4 is a perspective view of an embodiment of the tensile reinforcement of the present invention.
5 is a cross-sectional view illustrating various modified examples of FIG. 4 .
FIG. 6 is a perspective view illustrating an embodiment of installation in the main and vicinity directions of FIG. 4 .
7 is a view sequentially showing an embodiment of the method for constructing a concrete slab for reducing the weight impact sound of the present invention.
8 is a view showing another embodiment of the concrete slab for reducing the weight impact sound of the present invention.
9 is a diagram showing another embodiment of a concrete slab for reducing the weight impact sound of the present invention.
10 is a diagram showing a load-displacement graph of a slab flexural stiffness comparative experiment for a concrete slab for reducing the weight impact sound of the present invention.
11 is a diagram illustrating a floor structure for reducing floor impact sound of Patent Document 1 to be cited.

Hereinafter, the present invention will be described in detail with reference to the embodiments shown in the accompanying drawings, but the presented embodiments are illustrative for a clear understanding of the present invention, and the present invention is not limited thereto.

Hereinafter, the technical configuration of the present invention will be described in detail according to a preferred embodiment.

3A is a conceptual diagram of stress when a general concrete slab and floor impact force are applied, and FIG. 3B is a conceptual diagram of stress when a concrete slab and floor impact force are applied for weight impact sound reduction according to the present invention.

As shown in Figure 3a, the cross section of the general concrete slab 20 to which the impact force is applied and the simplified tensile-compression model (Strut and Tie Model) are divided into an upper area (A), a lower area (B) and an intermediate area (C). can be distinguished.

The upper area (A) is the upper section of the slab including the upper reinforcing bar in charge of tensile force, and the lower area (B) is the lower section of the slab including the lower reinforcing bar in charge of the tensile force. And the middle area (C) is a section between the upper area (A) and the lower area (B), and the existing slab consists only of concrete as shown in the figure, and is a section in which the concrete must simultaneously bear tensile and compressive forces.

In this case, the concrete material is very strong in compressive force, but relatively weak in tensile force (10% or less of compressive strength), and the intermediate region (C) has very weak tensile strength compared to compressive strength. The characteristics of the intermediate region (C) are expressed by simplifying the width of the 'compression' part and narrowing the width of the 'tensile' part in the tensile-compression model.

On the other hand, in the present invention, as shown in FIG. 3b, a tension reinforcing material that interconnects the upper region (A) and the lower region (B) at a vertical or arbitrary angle is additionally configured in the middle region (C) of the slab separately to form an intermediate region By reinforcing the tensile strength of (C), the deflection of the slab 20 is reduced and the flexural rigidity is strengthened.

That is, the concrete slab for reducing the weight impact sound of the present invention is the upper region (A) and the lower region (B) of the slab in the concrete slab 20 in which the upper reinforcing bar 210 and the lower reinforcing bar 220 are reinforced. To reinforce the tensile strength of the intermediate region (C) connecting the

4 is a perspective view of an embodiment of the tensile reinforcement of the present invention, FIG. 5 is a cross-sectional view illustrating various modifications of FIG. 4, and FIG. 6 is a perspective view illustrating an embodiment of installation in the main and vicinity directions of FIG. 4 .

One embodiment of the tensile reinforcement 10 of the present invention, as shown in FIGS. 4 to 6 , an upper fixing part 111 and a lower fixing part 112 , and an upper fixing part 111 and a lower fixing part 112 . A plurality of I-type unit members 110 made of an I-shaped unit member 110 that is formed to have an I-shaped cross-section by connecting a tensile connecting part 113, and a flat plate material of a certain length or an iron wire having a circular cross-section. It is formed of a horizontal connecting member 120 configured to connect the upper fixing part 111 to each other.

Such a horizontal connecting member 120 portion of the tensile reinforcement 10 is mounted on the upper reinforcing bar in the upper region A, and the lower fixing part 112 of the tensile reinforcement 10 is located in the slab lower region B, respectively. By construction, it can be configured to strengthen the tensile capacity of the intermediate region (C) of the concrete slab.

At this time. Tensile reinforcement unit member 110 having an I-shaped cross-section having an upper fixing part 111 and a lower fixing part 112 may be manufactured as an integral body or each member may be separately manufactured and joined to be used, as shown in FIG. 5 ( As in c), it may be made by butt bonding two C-shaped members 110a and 110b.

Preferably, the horizontal connecting member 120 is joined to both sides of the upper fixing part 111 of the tensile reinforcement unit member 110 in two rows, and in another case, it may be joined to the central part of the upper fixing part 111 in one row. In addition, the horizontal connecting member 120 may be made of a flat plate material of a certain length, as in FIGS. 5(a) and 5(c), and in another case, as in FIG. may be made of

In this way, the tension reinforcing material 10 having the tensile reinforcing unit member 110 and the horizontal connecting member 120 of the I-shaped section is completed after the reinforcing work of the slab is completed as shown in FIG. 210), since the horizontal connecting member 120 only needs to be mounted on the part, the installation of the tension reinforcement for strengthening the tension capacity of the slab is simple, and the position of the tension reinforcement is very easy to modify, correct, reinstall, and the like.

8 is a diagram showing another embodiment of a concrete slab for reducing the weight impact sound of the present invention, and FIG. 9 is a diagram showing another embodiment of the concrete slab for reducing the weight impact sound of the present invention.

As shown in FIG. 8 , the tensile reinforcing material 10 surrounds the upper reinforcing bar 210 of the upper region A as the upper fixing part 111 and the lower reinforcing bar 220 in the lower region B as the lower fixing part 112 . ) in the form of a reinforcing bar stirrup (or single loop tie) constructed so as to surround each of the slabs, it is possible to strengthen the tensile capacity of the intermediate region (C) of the slab.

In addition, as shown in FIG. 9 , the tensile reinforcing material 10 may be formed of a truss-shaped iron wire grid having a triangular (or 1-character) cross-section. At this time, the upper anchoring part 111 of the wire grid is located inside the upper area (A) under the upper reinforcing bar, and the lower anchoring part 112 is located inside the lower area (B) above the lower reinforcing bar, so that the slab middle area It can be made to strengthen the tensile capacity of (C).

As described above, the tension reinforcing material 10 additionally configured in the slab intermediate region C of the present invention can use all of I-type, stirrup type and truss type, and the tensile reinforcing material 10 of the three embodiments is In the same way, the upper fixing unit 111 and the lower fixing unit 112 are respectively located inside the upper area (A) and the lower area (B) of the slab, and the upper fixing unit 111 and the lower fixing unit 112 are formed. It consists of a connecting tensile connection part 113, and is configured to strengthen the tensile ability of the slab intermediate region (C).

7 is a diagram showing an embodiment of the construction method of a concrete slab for reducing the weight impact sound of the present invention in order, and FIG. 8 is a diagram showing another embodiment of the concrete slab for reducing the weight impact sound of the present invention. 9 is a diagram showing another embodiment of a concrete slab for reducing the weight impact sound of the present invention.

The construction method of the concrete slab for reducing the weight impact sound of the present invention is first, as shown in FIG. 7a, by installing the lower spacer 2 on the upper part of the slab formwork 3, and the lower reinforcing bar 220 on the upper part of the lower spacer 2 ) to be placed (a).

Here, the lower spacer 2 is installed to maintain the covering thickness of the lower reinforcing bar 220, and all known various spacers can be used.

Thereafter, the upper spacer 4 is installed on the upper part of the form 3, and the upper reinforcing bar 210 is reinforced on the upper part of the upper spacer 4 (b).

Here, the upper spacer 4 is installed to adjust the height at which the upper reinforcing bar 210 is installed, and may be formed of various known members or shapes in addition to the illustrated shape.

Thereafter, as shown in FIG. 7b , the tension reinforcing material 10 is installed (c).

An I-shaped unit member formed to have an I-shaped cross section, consisting of an upper fixing part 111 and a lower fixing part 112 and a tension connecting part 113 connecting the upper fixing part 111 and the lower fixing part 112 . Tension formed by 110 and a horizontal connecting member 120 configured to connect the upper fixing part 111 of the plurality of I-shaped unit members 110 to each other, which is made of a flat plate material of a certain length or an iron wire having a circular cross section In the construction of the reinforcing material 10, the horizontal connecting member 120 is installed to be mounted on the upper reinforcing bar 210, so that the upper fixing part 111 and the lower fixing part 112 are respectively located in the upper region of the cross section of the slab 20 ( It is installed so as to be located in A) and the lower area (B), respectively.

Finally, as shown in Fig. 7c, by pouring concrete on the top of the formwork 3, the deflection is reduced without increasing the thickness of the slab and the reinforced slab 20 with enhanced flexural rigidity is completed (d).

As shown in FIG. 8, in the case of the stirrup type tension reinforcing material 10, the reinforcing steel stirrup type tension reinforcing material ( 10) The tensile ability of the middle region (C) is strengthened by inserting the construction.

As such, when the tension reinforcing material 10 is made of reinforcing bar stirrup, it is distinguished from the I-type tension reinforcing material construction method in which steps (a) and (b) of the slab reinforcing process are completed and then reinforcement is installed. have

In addition, as shown in FIG. 9, when the tension reinforcing material is made of a truss-shaped iron wire grid, after step (a) is completed, the wire grid, which is the tension reinforcement material 10, is mounted thereon, and then the step (b) reinforcing reinforcement operation is performed. and finally pour concrete to complete the slab 20 . This also has a construction feature that is different from the I-type tension reinforcement construction method, which is installed after completing both steps (a) and (b).

10 is a diagram showing a load-displacement graph of a slab flexural stiffness comparison experiment for a concrete slab for reducing the weight impact sound of the present invention.

NSR is an existing general concrete slab (there is no tension reinforcing material in the middle area C), and the other three are concrete slabs in which the tensile capacity is additionally reinforced by configuring the tensile reinforcing material 10 in the middle area (C) of the slab. Slab thickness and upper and lower reinforcing bars are the same)

As shown in FIG. 10, when the tensile capacity is additionally reinforced in the middle region (C) of the slab using the tensile reinforcing material 10, the deflection of the slab with respect to the applied load is reduced, thereby increasing the flexural rigidity of the slab. Able to know. In particular, in the range of 200 kN or less, which corresponds to a general impact load, the effect of increasing the flexural stiffness is evident, in which the amount of deflection is reduced by about half compared to the non-reinforced NSR. Therefore, it is possible to strengthen the flexural rigidity without increasing the thickness of the slab, and through this, the effect of reducing the weight impact sound of the slab can be expected.

The concrete slab and its construction method for reducing the weight impact sound of the present invention as described above is a technology for reducing inter-floor noise generated in apartment houses, etc. due to the floor impact load. In addition, in the internal structure of the concrete slab, a tensile reinforcing material is additionally configured. That is, by separately adding a tension reinforcing material connecting the upper area (A) including the upper reinforcing bar and the lower area (B) including the lower reinforcing bars at a vertical or arbitrary angle in the middle area (C) of the slab, the There is a very useful effect of reducing the slab's weight impact sound by reducing the deflection without increasing the thickness and enhancing the flexural rigidity.

So far, the present invention has been described in detail with reference to the presented embodiments, but those skilled in the art can make various modifications and modified inventions without departing from the technical spirit of the present invention with reference to the presented embodiments. will be. The present invention is not limited by such variations and modifications, but only by the claims appended hereto.

2: lower spacer
3: Formwork
4: upper spacer
10: Tensile reinforcement
110: I-type unit member
111: upper fixing part
112: lower fixing part
113: tension connection
120: horizontal connection member
20: slab
210: upper reinforcing bar
220: lower reinforcing bar
A: upper area
B: lower area
C: middle area

Claims (8)

To the upper area (A) including the upper reinforcing bar 210, the lower area (B) including the lower reinforcing bar 220, and the intermediate area (C) formed between the upper area (A) and the lower area (B) In the concrete slab 20 made of,
A tension reinforcing material 10 that interconnects the upper region (A) and the lower region (B) at a vertical or arbitrary angle is separately configured in the middle region (C) of the slab,
The tensile reinforcement 10 is,
An I-shaped unit member formed to have an I-shaped cross section, consisting of an upper fixing part 111 and a lower fixing part 112 and a tension connecting part 113 connecting the upper fixing part 111 and the lower fixing part 112 . (110) and a horizontal connecting member 120 configured to connect the upper fixing part 111 of the plurality of I-shaped unit members 110 to each other made of a flat plate material of a certain length or an iron wire having a circular cross section,
The upper fixing part 111 and the horizontal connecting member 120 are located in the upper region (A), and the lower fixing part 112 is located in the lower region (B) Concrete slab for reducing the weight impact sound, characterized in that it is configured to be located in the lower region (B) . delete The method according to claim 1,
The horizontal connecting member 120 is a concrete slab for reducing weight impact sound, characterized in that it is configured in two rows on both sides of the upper fixing unit 113 . The method according to claim 1,
I-shaped unit member 110 is a concrete slab for reducing the weight impact sound, characterized in that made by butt-joining two C-shaped members (110a, 110b). delete delete (a) installing the lower spacer (2) on the upper part of the slab formwork (3), and reinforcing the lower reinforcement (220) on the upper part of the lower spacer (2);
(b) installing the upper spacer (4) on the upper part of the formwork (3), and reinforcing the upper reinforcing bar (210) on the upper part of the upper spacer (4);
(c) I-, which is formed to have an I-shaped cross section, consisting of the upper fixing part 111 and the lower fixing part 112 and the tension connecting part 113 connecting the upper fixing part 111 and the lower fixing part 112 A horizontal connecting member 120 configured to connect the upper fixing parts 111 of the plurality of I-shaped unit members 110 to each other, which is made of a flat unit member 110 and an iron wire of a predetermined length or a circular cross section. Installing the horizontal connecting member 120 to be mounted on the upper reinforcing bar 210 in the construction of the formed tension reinforcing material 10;
(d) pouring concrete on top of the formwork (3); Concrete slab construction method for reducing the weight impact sound, characterized in that it comprises a. delete

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