KR102184548B1 - Reinforced concrete slab structure incorporating Kagome truss for noise reduction and manufacturing method thereof - Google Patents

Abstract

The present invention relates to a reinforced concrete slab structure, and more specifically, to a noise reduction type reinforced concrete slab structure and manufacturing method of a new structure with improved vibration and noise reduction performance while reducing its thickness compared to a conventional reinforced concrete slab structure. About.

Description

TECHNICAL FIELD [Reinforced concrete slab structure incorporating Kagome truss for noise reduction and manufacturing method thereof]

The present invention relates to a reinforced concrete slab structure, and more specifically, to a noise reduction type reinforced concrete slab structure and manufacturing method of a new structure with improved vibration and noise reduction performance while reducing its thickness compared to a conventional reinforced concrete slab structure. About.

Reinforced concrete structures are used in many cases among collective residential structures such as multi-family houses and apartments, and when constructing such structures, safety and usability are considered to satisfy the standards stipulated by design standards or housing laws. Safety and usability are designed and constructed in consideration of a sufficient safety factor in accordance with the design standards, so there is little inconvenience to users or residents, but inter-floor noise, which has become a social issue in recent years, depends on the surrounding conditions of users or residents There is a problem in that the degree and frequency of occurrence are different, and the degree of acceptance varies depending on the physical or psychological state of the victim.

Article 21-2 (Inter-floor noise standards, etc.) of the Noise and Vibration Control Act, paragraph 3, is required to determine the range and standards of inter-floor noise by decrees of the Ministry of Environment and the Ministry of Land, Infrastructure and Transport. "In Article 2, the range of inter-floor noise is defined as noise generated by the activities of tenants or users. In subparagraph 1 of Article 2 of the same rule, direct impact noise is defined as noise generated by standing or walking movements, and in Article 3, the floor noise standard is 43 dB during the day and 38 dB at night based on the equivalent noise level for 1 minute. It is prescribed. In addition, in regulations on housing construction standards, etc., the standards for blocking performance of floor impact sound are being reinforced.

In general, a conventional floor layer structure consists of a slab constituting a floor and a wall, and an insulating layer for buffering and heat insulation is disposed on the upper surface of the slab, and a lightweight foamed concrete layer is disposed on the upper surface of the insulating layer, A finishing mortar layer is disposed on the upper surface of the lightweight foamed concrete layer, and a parquet or vinyl sheet is installed on the upper surface of the finished mortar layer.

Through this structure, all of the conventional standard floor structures have a buffer material or insulation material in common, and a lightweight foamed concrete is optionally included, but the buffering effect by controlling the thickness of the buffer material, insulation material, or finishing mortar depending on the structure. And sound insulation effects are obtained.

However, since effective inter-floor noise blocking has not been achieved, the current law regulates the thickness of reinforced concrete slab applied to domestic apartment houses to be 210 mm or more, much thicker than 150 mm, the thickness for maintaining structural safety. Compared to the situation, it has been significantly increased and applied.

In this way, if the thickness of the slab is increased to reduce the inter-floor noise, the concrete slab must be formed thicker than 210 mm, so the height of the floor layer increases due to the thickness of the slab, and the actual space used is narrowed, and the construction period also takes a long time. There was a problem. In addition, there are disadvantages that adversely affect the environment, such as environmental destruction and radon gas generation problems due to an increase in concrete usage.

Therefore, there is a need to develop a new reinforced concrete slab structure having a vibration damping effect superior to that of a reinforced concrete slab having a thickness of 210 mm or more while reducing the thickness of the reinforced concrete slab as much as possible.

Patent registration number 10-1801328 Patent Registration No. 10-766127

As a result of a number of studies, the present inventors have completed the present invention by dividing the structure of a reinforced concrete slab into an area for structural safety and an area for vibration damping, and constructing the material differently.

Accordingly, an object of the present invention is to divide the structure of the reinforced concrete slab constituting the floor structure for a building into an area for structural safety and an area for vibration attenuation, and to configure the area for vibration attenuation with a material having excellent vibration damping effect. It is to provide a new structure of reinforced concrete slab structure effective in reducing inter-floor noise by reducing vibration and noise of public houses or buildings and a method of manufacturing the same.

Another object of the present invention is a reinforced concrete slab having a more environmentally friendly structure because less cement can be used by securing structural safety as well as excellent vibration damping performance while reducing its thickness compared to the conventional reinforced concrete slab having a thickness of 210 mm or more. It is to provide a structure and a method of manufacturing the same.

Another object of the present invention is to include a reinforced concrete slab structure that has a reduced thickness compared to the conventional reinforced concrete slab and has excellent interlayer noise reduction performance, thereby increasing the height of the floor layer due to the thickness of the slab, thereby solving the problem of narrowing the actual space used. It is to provide a floor structure for buildings.

The object of the present invention is not limited to the above-mentioned object, and even if not explicitly mentioned, the object of the invention that one of ordinary skill in the art can recognize from the description of the detailed description of the invention to be described later may naturally be included. .

In order to achieve the object of the present invention described above, the present invention first includes a slab layer for structural support, including reinforcing bars and concrete, for structural safety; A vibration damping slab layer formed of a high damping polyurethane composite on the structural support slab layer; And it provides a noise reduction type reinforced concrete slab structure comprising a; and a three-dimensional kagome truss member which is installed so as to be located in the slab layer for structural support, the rest of the slab layer for vibration damping.

In a preferred embodiment, the three-dimensional kagome truss member is partially or entirely formed between the structural support slab layer and the vibration damping slab layer.

In a preferred embodiment, the polyurethane composite includes a plurality of coarse aggregates in which one or more portions are in contact with each other in a state in which the slab layer for structural support is a lower surface and is arranged to form a three-dimensional object having a predetermined height; And a solid polyurethane matrix that fills the space formed between the thick aggregates so that no voids are formed inside the three-dimensional object, and surrounds the thick aggregate that is exposed to the outside of the three-dimensional object. The solid polyurethane matrix moves to the original position of the fine position change of the coarse aggregate that occurs while attenuating, thereby maintaining the attenuation performance of the coarse aggregate.

In a preferred embodiment, the three-dimensional kagome truss member has a height of 70 mm to 150 mm.

In a preferred embodiment, the structural support slab layer has a thickness of 125 mm to 165 mm, and the vibration damping slab layer has a thickness of 40 mm to 80 mm or less.

In addition, the present invention is a structural support slab layer forming step of forming a structural support slab layer in charge of structural safety using reinforcement and concrete; A kagome truss member forming step of installing a three-dimensional cargo truss member so that a part of the slab layer for structural support is located and the remaining part protrudes in the forming of the structural support slab layer; And a vibration damping slab layer forming step of forming a high damping polyurethane composite at a predetermined height on the structural support slab layer. It provides a method for manufacturing a noise-reducing reinforced concrete slab structure.

In a preferred embodiment, the step of forming the slab layer for structural support comprises: reinforcing the reinforcing bar to a predetermined height; Arranging at least one three-dimensional kagome truss member on the reinforced reinforcement; And curing the three-dimensional cargo truss member by pouring concrete to a height in which a part is located in the slab layer for structural support and the remaining part protrudes.

In a preferred embodiment, in the step of forming the vibration damping slab layer, a three-dimensional object having a height equal to or greater than the height at which the rest of the protruding three-dimensional kagome truss member is covered with the structural support slab layer as a lower surface is thick. Aggregate placement step of filling thick aggregates so that all of them are filled with aggregates; A polyurethane treatment step of filling the remaining internal space not filled with the coarse aggregate by processing liquid polyurethane; And a curing step in which a solid polyurethane matrix for bonding the coarse aggregates to each other is formed by curing the liquid polyurethane, wherein the aggregate repositioning step includes 1 It is performed so as to be in contact with the portion or more, and the remaining internal space includes a space formed between the thick aggregate and a space formed between the hollow portion and the thick aggregate.

In a preferred embodiment, in the step of installing the 3D Kagome truss member, the 3D Kagome truss member has a height of 70 mm to 150 mm, and is partially or entirely formed between the structural support slab layer and the vibration damping slab layer. do.

In addition, the present invention provides a floor structure for a multi-storey building including any one of the above-described noise-reducing reinforced concrete slab structures or a noise-reducing reinforced concrete slab structure manufactured by any one manufacturing method.

In a preferred embodiment, the floor structure excludes any one or more of a heat insulating buffer layer, a lightweight foamed concrete layer, a cement mortar layer, and a flooring layer sequentially stacked on the noise reduction reinforced concrete slab structure, or reduces noise. It is transformed to have a characteristic.

The reinforced concrete slab structure of the present invention described above, and the manufacturing method thereof, divides the structure of the reinforced concrete slab constituting the floor structure for a building into an area for structural safety and an area for vibration attenuation, and the area for vibration attenuation is attenuated. It is effective in reducing the noise between floors as it can reduce vibration and noise of multi-family public houses or buildings by using materials with excellent effects.

In addition, according to the reinforced concrete slab structure and the manufacturing method of the present invention, the thickness of the reinforced concrete slab is reduced compared to the conventional reinforced concrete slab having a thickness of 210 mm or more, while securing excellent vibration damping performance as well as structural safety, so that less cement is used More environmentally friendly.

In addition, according to the floor structure for a multi-storey building of the present invention, the thickness of the floor is increased due to the thickness of the slab by including a reinforced concrete slab structure having a reduced thickness compared to the conventional reinforced concrete slab and excellent in noise reduction performance between floors. Can be solved.

These technical effects of the present invention are not limited only to the ranges mentioned above, and even if not explicitly mentioned, the effects of the invention that can be recognized by those of ordinary skill in the art from the description of specific details for the implementation of the invention described later are also Of course it is included.

1 is a cross-sectional view showing a general laminated state of a floor structure for a multi-storey building.
2 is a cross-sectional view of a noise reduction type reinforced concrete slab structure according to an embodiment of the present invention.
3 is a cross-sectional view of a noise reduction type reinforced concrete slab structure according to another embodiment of the present invention.
4 is a schematic diagram showing the configuration of a high-attenuation polyurethane composite constituting a slab layer for vibration damping applied to the noise-reducing reinforced concrete slab structure shown in FIGS. 2 and 3.
5 is a schematic diagram showing an embodiment of a three-dimensional kagome truss member applied to the noise reduction reinforced concrete slab structure shown in FIGS. 2 and 3.
6 is a cross-sectional view showing a noise reduction type floor structure to which the noise reduction type reinforced concrete slab structure shown in FIG. 2 is applied.

The terms used in the present invention are only used to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise. In the present application, terms such as "comprise" or "have" are intended to designate the existence of features, numbers, steps, actions, elements, parts, or a combination thereof described in the description of the invention, but one or more other It is to be understood that it does not preclude the presence or addition of features, numbers, steps, actions, components, parts, or combinations thereof.

Terms such as first and second may be used to describe various elements, but the elements should not be limited by the terms. These terms are only used for the purpose of distinguishing one component from another component. For example, without departing from the scope of the present invention, a first component may be referred to as a second component, and similarly, a second component may be referred to as a first component.

Unless otherwise defined, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which the present invention belongs. Terms as defined in a commonly used dictionary should be interpreted as having a meaning consistent with the meaning in the context of the related technology, and should not be interpreted as an ideal or excessively formal meaning unless explicitly defined in the present invention. Does not.

In interpreting the constituent elements, it is interpreted as including an error range even if there is no explicit description. In particular, when the terms "about", "substantially" and the like of degree are used, it can be interpreted as being used in or close to that value when manufacturing and material tolerances specific to the stated meaning are presented. .

In the case of a description of a temporal relationship, for example,'after','following','after','before', etc. It includes cases that are not continuous unless' is used.

Hereinafter, the technical configuration of the present invention will be described in detail with reference to the accompanying drawings and preferred embodiments.

However, the present invention is not limited to the embodiments described herein and may be embodied in other forms. The same reference numerals used to describe the present invention throughout the specification denote the same elements.

The technical feature of the present invention is that the thickness of the reinforced concrete slab constituting the floor structure for buildings is divided into an area for structural safety and an area for vibration attenuation, and the area for vibration attenuation is made of a material having excellent vibration damping effect. Is reduced, and the vibration attenuation performance is in the improved noise reduction reinforced concrete slab structure.

In other words, it is currently attempted to block inter-floor noise in various ways, but there is still no effective inter-floor noise blocking, so the thickness of the reinforced concrete slab applied to domestic apartment houses by law is much more than 125 mm to 150 mm, the thickness that maintains structural safety. This is because it is being applied by increasing it by specifying it as thicker than 210 mm.

Accordingly, the noise-reducing reinforced concrete slab structure of the present invention includes a slab layer for structural support, including reinforcement and concrete, for structural safety; A vibration damping slab layer formed of a high damping polyurethane composite on the structural support slab layer; And a three-dimensional kagome truss member installed to be partially positioned on the slab layer for structural support and the remaining portion positioned on the slab layer for vibration damping.

Here, as for the three-dimensional cargo truss member, one or more three-dimensional cargo truss members may be used as shear connection members so that the slab layer for structural support and the slab layer for vibration damping behave integrally.

Next, the noise reduction type reinforced concrete slab structure manufacturing method of the present invention comprises a structural support slab layer forming step of forming a structural support slab layer in charge of structural safety by using reinforced reinforcement and concrete; A kagome truss member forming step of installing a three-dimensional cargo truss member so that a part of the slab layer for structural support is located and the remaining part protrudes in the forming of the structural support slab layer; And a vibration damping slab layer forming step of forming a high damping polyurethane composite at a predetermined height on the structural support slab layer. Here, the step of forming the slab layer for structural support is performed in combination with the step of forming the Kagome truss member, and as an embodiment, the step of reinforcing reinforcing bars to a predetermined height; Arranging at least one three-dimensional kagome truss member on the reinforced reinforcement; And curing the three-dimensional cargo truss member by pouring concrete to a height at which a part is located on the slab layer for structural support and the remaining part protrudes.

1 is a cross-sectional view showing a laminated state of a general multi-storey building floor structure, and FIG. 2 is a cross-sectional view of a noise reduction type reinforced concrete slab structure according to an embodiment of the present invention. FIG. 3 is a cross-sectional view of a noise-reducing reinforced concrete slab structure according to another embodiment of the present invention, and FIG. 4 is a sectional view of a vibration damping slab layer applied to the noise-reducing reinforced concrete slab structure shown in FIGS. 2 and 3 It is a schematic diagram showing the composition of a high damping polyurethane composite. 5 is a schematic diagram showing an embodiment of a three-dimensional kagome truss member applied to the noise-reducing reinforced concrete slab structure shown in FIGS. 2 and 3, and FIG. 6 is a noise-reducing reinforcing bar shown in FIGS. 2 and 3 It is a cross-sectional view showing a noise-reducing floor structure with a concrete slab structure applied.

As shown in Figure 1, the floor structure (1) of a typical multi-story building is laminated on the concrete slab structure (100) of an indoor space formed by a reinforced concrete slab structure (100) and a concrete wall (600). On the heat insulation buffer layer 200, the light foam concrete layer 300 laminated on the heat insulation buffer layer 200, the cement mortar layer 400 laminated on the lightweight foam concrete layer 300 and the cement mortar layer 400 It consists of a flooring layer 500 that is laminated on.

Here, the reinforced concrete slab structure 100 has a thickness of 210 mm or more, the heat insulation buffer layer 200 has a thickness of 20 mm or more, and the lightweight aerated concrete layer 300 has a thickness of 40 mm or more, and the cement The mortar layer 400 has a thickness of 40 mm or more. In particular, the insulation buffer layer 200 and the lightweight foamed concrete layer 300 may be optionally included, and depending on the structure, the type of the cushioning material or the insulating material or the thickness of the lightweight foamed concrete layer 300 or the cement mortar layer 400 is adjusted. By doing so, a buffer effect and sound insulation effect are obtained.

The reinforced concrete slab structure of the present invention changes the structure of the reinforced concrete slab structure 100 formed with a thickness of 210 mm or more in the conventional floor structure shown in FIG. 1 to make the thickness thinner, while structural safety as well as better vibration damping performance. Is secured.

2 and 3, the reinforced concrete slab structure 100 of the present invention includes a slab layer 110 for structural support, a slab layer 120 for vibration damping, and a slab layer 110 for structural support. Consisting of a three-dimensional kagome truss member 130 included and inserted between the vibration damping slab layer 120, the combined thickness of the structural support slab layer 110 and the vibration damping slab layer 120 is conventional reinforced concrete It consists of less than 210 mm, which is the thickness of the slab.

Here, the slab layer 110 for structural support is an area responsible for structural safety, and it is recognized that structural safety is maintained before the regulations on interlayer noise are reinforced. It can be formed using.

The vibration damping slab layer 120 is a region for reducing interlayer noise by performing vibration damping, and may be formed of a high damping polyurethane composite having excellent vibration damping effect. As the thickness of the slab layer 120 for vibration damping increases, the vibration damping effect becomes more excellent, but may be implemented in a range of 40 mm to 80 mm in consideration of the thickness of the entire reinforced concrete slab structure.

The high damping polyurethane composite constituting the vibration damping slab layer 120 is composed of a plurality of coarse aggregates 121 and a solid polyurethane matrix 122, as shown in FIG. 3. When the coarse aggregate 121 is arranged and configured in the solid polyurethane matrix 122 as described above, the fine position change of the coarse aggregate 121 generated while attenuating the external vibration applied to the reinforced concrete slab structure 100 is reduced to the solid polyurethane. The matrix 122 may be moved to the original position to maintain the attenuation performance of the thick aggregate 121.

First, a plurality of coarse aggregates 121 are configured such that one or more portions are in contact with each other in a state in which the slab layer 110 for structural support is placed as a lower surface and arranged to form a three-dimensional object having a predetermined height. When the coarse aggregates 121 arranged in this way have parts in contact with each other and are engaged, when vibrations from the outside occur, the coarse aggregates that are engaged with each other have a minute change in position, and vibration energy is reduced by friction between the coarse aggregates. It shows excellent damping ability. In the present invention, the high-attenuation polyurethane composite can control the content of the coarse aggregate occupied in the vibration damping slab layer 120 by controlling the particle size distribution of the coarse aggregate.

In addition, the solid polyurethane matrix 122 maintains an arrangement structure in which all the thick aggregates 121 included in the high-attenuation polyurethane composite come into contact with each other and at the same time acts as a binder so that no voids are formed at all. A coarse aggregate 121 disposed so that no voids are formed inside a three-dimensional object of a certain shape, that is, a vibration damping slab layer 120, which is formed by treating liquid polyurethane on the coarse aggregate 121 and then curing it. This is because it has a structure that fills the space formed therebetween and surrounds the thick aggregate 121 in contact with the vibration damping slab layer 120 and the concrete wall 600 exposed to the outside of the three-dimensional object. As a result, when vibration comes from the outside, the solid polyurethane matrix 122 can reduce the amount of vibration transmitted by dissipating vibration energy by the polyurethane, which has excellent damping performance, and not only attenuates external vibration by itself. It plays the role of maintaining the damping performance of the coarse aggregate by moving the minute change in position of the coarse aggregate to its original position while attenuating it. That is, since the solid polyurethane matrix 122 having high elasticity and deformation performance returns the coarse aggregate 121 having a finely changed position to its original position, there is no reduction in damping performance due to repeated vibrations. If necessary, the solid polyurethane matrix 122 may have a tensile strength of 3-20 MPa, an elongation of 100 to 300%, and a resilience of 10 to 60%.

The three-dimensional kagome truss member 130 acts as a shear connector so that the slab layer 110 for structural support and the slab layer 120 for vibration damping can behave integrally, the slab layer 110 for structural support and the vibration damping Since at least one is inserted between the slab layer 120 for use, it does not affect the overall thickness of the noise-reducing reinforced concrete slab structure 100 of the present invention. Therefore, the three-dimensional cargo truss member 130 applicable to the present invention may be partially located on the slab layer 110 for structural support, and the rest may be installed to be located on the vibration damping slab layer 120, and the cargo truss As long as it is a shape structure, it is not limited.

As shown in Fig. 2, the noise reduction type reinforced concrete slab structure 100 of the present invention has a three-dimensional cargo truss member 130 between the slab layer 110 for supporting the structure and the slab layer 120 for vibration damping. It may be installed to be included as a whole, or may be partially included as shown in FIG. 3 to induce an integral behavior of the slab layer 110 for structural support and the slab layer 120 for vibration damping.

As shown in FIG. 2, when the three-dimensional cargo truss member 130 is entirely included between the slab layer 110 and the vibration damping slab layer 120, the slab layer 110 for structural support and the vibration damping A three-dimensional kagome truss member 130 having the same area as the width of the slab layer 120 may be used.

When the 3D cargo truss member 130 is partially included between the structural support slab layer 110 and the vibration damping slab layer 120 as shown in FIG. 3, a 3D cargo truss member having a certain area A plurality of 130 may be prepared and included between the slab layer 110 for structural support and the slab layer 120 for vibration damping at a predetermined interval.

As an embodiment, a three-dimensional kagome truss member having a structure as shown in FIG. 5 may be used. In the three-dimensional kagome truss member 130, the members constituting the truss shape are not gathered at one node, but are shifted from each other. As a result, the number of members to be joined to the nodes and the length of the members are small, making it easy to join, lightweight, and excellent structural properties such as strength and buckling. In the present invention, since the 3D Kagome truss member 130 is included as a shear connector, the installation area of the 3D Kagome truss member 130 and the height of the 3D Kagome truss member 130 may be in inverse proportion to each other.

Next, the method of manufacturing a noise-reducing reinforced concrete slab structure of the present invention includes a slab layer forming step for structural support, a three-dimensional kagome truss member installation step, and a slab layer forming step for vibration damping, as shown in Figs. As described above, since a three-dimensional cargo truss member 130 is inserted and included between the structural support slab layer 110 and the vibration damping slab layer 120, a method of pouring and curing using reinforcing bars and concrete Before completing the slab layer 110 for structural support so as to have a thickness of 125 mm to 165 mm, the three-dimensional Kagome truss member 130 needs to be installed. Accordingly, the step of forming the slab layer 110 for supporting the structure and the step of installing the three-dimensional cargo truss member 130 may be combined and performed.

As an embodiment, a reinforcing bar is reinforced with a three-dimensional cargo truss member 130 having the same area as the structural support slab layer 110 after reinforcing the reinforcing bar to a certain height to form the structural support slab layer 110 It is installed on the top, or a plurality of small three-dimensional kagome truss members 130 are prepared and installed on reinforcing bars arranged at regular intervals. After that, when the concrete is poured to the height at which a part of the 3D Kagome truss member 130 is included and cured, the remaining part of the 3D Kagome truss member 130 protrudes from 125 mm to 165 mm thick structural support slab Layer 110 may be formed. At this time, the 3D cargo truss member 130 may be implemented such that at least 1/2 of the total length is located on the slab layer 110 for structural support, and the remaining portion is located on the slab layer 120 for vibration damping.

Reinforced concrete slab is formed by forming a high damping polyurethane composite in the following order on the structural support slab layer 110 from which the rest of the three-dimensional cargo truss member protrudes to complete the vibration damping slab layer 120. The structure 100 may be manufactured.

First, an aggregate placement step is performed in which thick aggregates are filled in the indoor space formed by the structural support slab layer 110 and the concrete wall 600 to be filled with thick aggregates 121 to a certain height. It is important that the thick aggregates 121 filled in the indoor space up to a certain height are arranged to contact each other at least one part. That is, all the coarse aggregates included must have portions in contact with each other, as shown in FIG. 4, but when vibration comes from the outside, a minute change in the position of the coarse aggregates that are engaged with each other occurs, and the vibration energy is reduced by friction between the coarse aggregates. This is because it can play the role of letting go.

After that, the polyurethane treatment step is performed by filling the remaining interior space not filled with thick aggregates arranged up to a certain height of the indoor space by processing liquid polyurethane. Stirring homogeneously; And filling the homogeneously mixed liquid polyurethane to a predetermined height of the indoor space. Here, the remaining internal space includes a space formed between thick aggregates and a space formed between the inner wall surface of the concrete wall 600 and the thick aggregate 121 forming a certain height of the indoor space.

In addition, a curing step, which is a step in which a solid polyurethane matrix 122 that bonds a plurality of coarse aggregates 121 arranged up to a certain height of the indoor space to each other, is formed by curing the treated liquid polyurethane is performed. It may be carried out at room temperature for 24 hours or more until the polyurethane is completely cured.

Example 1

A three-dimensional kagome truss member was installed while forming a slab layer for structural support so that it is 3,300 mm in width and 2,800 mm in length, and has a thickness of 150 mm. That is, in order to form the slab layer for structural support, first, the tensile reinforcing bars and compression reinforcing bars of the size of D10 were laid in the form of a wire mesh having a distance of 250 mm so that the cover thickness was 20 mm. After that, a 100 mm high three-dimensional kagome truss member was placed on the reinforced reinforcement. After placing the three-dimensional kagome truss member, concrete was poured and cured for 5 days. At this time, the slab layer for structural support was manufactured to be supported by pillars located at four corners, and the pillar has a cross section of 300 mm x 300 mm and a height of 400 mm.

Next, after installing the formwork to surround the cured structural support slab layer, a plurality of coarse aggregates (size: 13 mm) were placed so as to contact each other at least one part up to a height of 40 mm. After that, a liquid polyurethane mixed in a weight ratio of 1 to 1 so that the subject (PF-359 product of Gangnam Hwaseong) and the hardener (E-145 product of Gangnam Hwaseong) can react 100% with each other as shown in Table 1 below After treatment between the arranged coarse aggregates, it was cured at room temperature for 24 hours to form a 40 mm thick vibration damping slab layer composed of a high damping polyurethane composite to prepare a noise-reducing reinforced concrete slab structure 1.

division Viscosity (mPa.s) importance working time
(min) Curing time
(hrs) The tensile strength
(MPa) Elongation
(%) Resilience
(%) subject 2,000-4,500 1.05 30-70 24 6.9 250 40 Hardener 2,000-6,000 1.35

Example 2

In the step of forming the slab layer for structural support in Example 1, a plurality of three-dimensional cargo truss members having a width of 500 mm x 500 mm and a height of 100 mm were installed at intervals of 1000 mm x 1000 mm, and then the structure was supported. A noise-reducing reinforced concrete slab structure 2 was manufactured by performing the same method as in Example 1 except that the slab layer was cured. Here, the three-dimensional kagome truss member was installed so that 60 mm was located on the slab layer for structural support and 40 mm was located on the slab layer for vibration damping.

Comparative example

A comparative example reinforced concrete slab structure was formed by forming the thickness of 210 mm in the same manner as in the method of forming the structural support slab layer of Example 1, except that the three-dimensional cargo truss member was disposed on the reinforced reinforcing bar in Example 1. Was prepared.

Experimental Example 1

The reinforced concrete slab structures obtained in Examples 1, 2 and Comparative Examples were subjected to impact with a bang machine to measure the sound pressure level for each frequency band and the inverse A characteristic weighted normalized floor impact sound level, and the results are shown in Table 2. Indicated.

Frequency (Hz) Sound pressure (dB) Comparative example Example 1 Example 2 31.5 106.2 105.4 105.8 63 88.9 86.2 87.8 135 78.1 73.5 73.9 250 62.0 53.1 54.0 500 56.7 51.2 52.1 Reverse A level
(Li,Fmax,AW) 62 57 58

As can be seen from the experimental results shown in Table 2, the noise-reducing reinforced concrete slab structures 1 and 2 obtained in the examples of the present invention were all compared with the comparative example reinforced concrete slab structures obtained in the comparative example, which is the reference slab in the current legislation. The noise reduction of Example 1 shows lower sound pressure level in the frequency band, and in the reverse A level, which comprehensively represents this, a three-dimensional kagome truss member is applied, so that the slab layer for structural support and the slab layer for vibration damping behave integrally. It can be seen that the type reinforced concrete slab structure 1 exhibited a 5 dB lower value than the comparative example.

Experimental Example 2

Structural safety of the reinforced concrete slab structures obtained in Example 2 and Comparative Example was evaluated according to the Building Structural Standard (2016), and the results are shown in Table 3. At this time, it is assumed as a one-way slab of unit width (1m), the boundary condition is fixed at both ends, and the fixed load is finish, ondol, slab, and lower ceiling, and the live load is 2.0 kN/m ² (Building Structure Standard 2016) And satisfies the expression " φM _n (design strength) ≥ M _u (design member force)", and the design member force is the maximum moment reflecting the load factor through structural analysis, and the design strength is the stress strain curve of the material. Reflected and obtained through a layered cross-sectional analysis.

φM _n (Design strength) kNㅇm M _u (member force for design) kNㅇm Structural safety Example 1 18.3 9.2 Satisfaction Comparative example 19.7 9.9 Satisfaction

From Table 3, through a design strength comparison showing the load-resistance capacity of the slab, the load-resistance capacity of the noise-reducing reinforced concrete slab structure 1 obtained in Example 1 of the present invention containing a vibration-attenuating material is more thick. Despite the reduction, it can be seen that it appears similar compared to the comparative example reinforced concrete slab structure composed of purely reinforced concrete.

The above experimental results show that the noise reduction type reinforced concrete slab structure of the present invention satisfies the structural safety standard while reducing noise at the same time even when the thickness of the reinforced concrete slab structure of the present invention is reduced by 20 mm or more compared to the existing 210 mm thick reinforced concrete slab structure.

Therefore, the floor structure for a multi-storey building including the noise-reducing reinforced concrete slab structure of the present invention can secure a wide indoor space and secure eco-friendliness by reducing the use of cement. Furthermore, as shown in FIG. 6 of the insulation buffer layer, the lightweight foam concrete layer, the cement mortar layer, and the insulation buffer layer or the lightweight foam concrete layer among the flooring layers, which are sequentially stacked on the noise reduction reinforced concrete slab structure of the present invention. In the same way, if any one is omitted or its thickness is installed thin to secure a wider indoor space, or if necessary, if it is transformed to have a noise reduction characteristic, it will have better noise reduction characteristics and thus solve the interfloor noise, which is a major problem in apartment houses. You will be able to contribute.

Although the present invention has been illustrated and described with a preferred embodiment as described above, it is not limited to the above-described embodiment, and within the scope of the spirit of the present invention, those of ordinary skill in the art Various changes and modifications will be possible.

One ; Floor structure for multi-storey buildings
100: reinforced concrete slab structure
110: structural support slab layer 120: vibration damping slab layer
121: coarse aggregate 122: solid polyurethane matrix
130: 3D Kagome truss member 200: Insulation buffer layer
300: lightweight foamed concrete layer 400: cement mortar layer
500: flooring layer

Claims (11)

Structural support slab layer responsible for structural safety, including reinforcement and concrete;
A vibration damping slab layer formed of a high damping polyurethane composite on the structural support slab layer; And
Includes; a three-dimensional cargo truss member installed to be partially positioned on the slab layer for structural support, and the rest of the slab layer for vibration damping,
The three-dimensional cargo truss member is partially or entirely formed between the structural support slab layer and the vibration damping slab layer, so that the structural support slab layer and the vibration damping slab layer can be integrated as a shear connector. Noise-reducing reinforced concrete slab structure, characterized in that acting.
delete The method of claim 1,
The polyurethane composite includes a plurality of thick aggregates in which one or more portions are in contact with each other in a state in which the slab layer for structural support is a lower surface and is arranged to form a three-dimensional object having a predetermined height; And a solid polyurethane matrix that fills the space formed between the thick aggregates so that no voids are formed inside the three-dimensional object, and surrounds the thick aggregate that is exposed to the outside of the three-dimensional object. A noise reduction type reinforced concrete slab structure, characterized in that the solid polyurethane matrix moves the fine position change of the coarse aggregate generated while attenuating to its original position to maintain the damping performance of the coarse aggregate.
The method of claim 1,
The three-dimensional kagome truss member is a noise reduction type reinforced concrete slab structure, characterized in that the height is 70 mm to 150 mm.
delete Structural support slab layer forming step of forming a structural support slab layer in charge of structural safety by using reinforcement and concrete; A kagome truss member installation step of installing a three-dimensional cargo truss member so that a part of the slab layer for structural support is located and the remaining part protrudes in the structural support slab layer forming step; And a vibration damping slab layer forming step of forming a high damping polyurethane composite at a predetermined height on the structural support slab layer.
The step of forming the slab layer for supporting the structure includes reinforcing the reinforcing bar to a predetermined height; Arranging at least one three-dimensional kagome truss member on the reinforced reinforcement; And the step of curing the three-dimensional cargo truss member by pouring concrete to a height in which a part is located in the slab layer for structural support and the remaining part protrudes; including,
In the step of forming the vibration damping slab layer, the slab layer for structural support is used as the lower surface, and the three-dimensional object having a predetermined height equal to or higher than the height at which the rest of the protruding three-dimensional cargo truss member is covered is filled with a thick aggregate Aggregate placement step of filling the aggregate; A polyurethane treatment step of filling the remaining internal space not filled with the coarse aggregate by processing liquid polyurethane; And a curing step in which a solid polyurethane matrix for bonding the coarse aggregate to each other is formed by curing the liquid polyurethane.
The 3D Kagome truss member installed in the installation step of the Kagome truss member is formed partially or entirely between the structural support slab layer and the vibration damping slab layer, so that the structural support slab layer and the vibration damping slab layer are integrally formed. A method for manufacturing a noise-reducing reinforced concrete slab structure, characterized in that it acts as a shear connector that can behave as.
delete The method of claim 6,
In the vibration damping slab layer forming step, the aggregate arranging step is performed so that the coarse aggregates are arranged to contact each other at least one part, and the remaining internal space includes a space formed between the coarse aggregates. Type reinforced concrete slab structure manufacturing method.
The method of claim 6,
In the three-dimensional kagome truss member installation step, the three-dimensional kagome truss member has a height of 70 mm to 150 mm, characterized in that the noise reduction type reinforced concrete slab structure manufacturing method.
The noise reduction reinforced concrete slab structure according to any one of claims 1, 3 and 4 or the noise reduction reinforced concrete slab structure manufactured by the manufacturing method of any of claims 6, 8, and 9 As a floor structure for a multi-storey building comprising a,
The floor for a multi-storey building, characterized in that the slab layer for structural support and the slab layer for vibration attenuation constituting the noise reduction type reinforced concrete slab structure are formed to be integrally operated by a three-dimensional cargo truss member, and thus have noise reduction characteristics. Structure. delete

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