KR20060014964A - Floor system and its construction method for decreasing heavy impact sound - Google Patents

Abstract

1. TECHNICAL FIELD OF THE INVENTION

The present invention relates to a floor structure system and its construction method.

2. The technical problem to be solved by the invention

The present invention shortens the construction period by reducing the wet process from two times to one time by developing a floor structure system that replaces lightweight foam concrete, and improves the performance of reducing heavy impact sound in the floor impact sound by increasing the rigidity of the upper layer of the cushioning material. It is an object of the present invention to provide a floor structure system and a construction method thereof.

3. Summary of Solution to Invention

The present invention is a floor structure system with improved weight impact sound reduction performance, and the thermal insulation buffer installed on the concrete slab; A reinforcing member which is formed in a lattice form and is installed at a predetermined height apart from the upper part of the thermal insulation buffer by supporting a plurality of supports below; A heating pipe disposed on the reinforcing material at predetermined intervals; And cement mortar which is poured onto the heating pipe and the reinforcement.

As a construction method of the floor structure system for this purpose, the first step of installing a thermal insulation buffer on the concrete slab; A second step of installing a reinforcing material formed in a lattice form and supporting a lower portion with a plurality of supports on an upper portion of the insulation buffer; A third step of disposing a heating pipe on the reinforcing material; And a fourth step of pouring cement mortar on the heating pipe and the reinforcement.

4. Important uses of the invention

It is used in flooring structure system and construction method for reducing heavy axial sound.

Floor structure, heavy impact sound, shock absorber, reinforcement

Description

Floor system and its construction method for improving heavy impact sound reduction performance             

1 is a cut perspective view of a conventional general floor structure system.

Figure 2 is a cut perspective view showing a cushioning step installation according to the present invention.

Figure 3 is a cut perspective view showing the step of installing the reinforcing material according to the present invention.

Figure 4 is a cut perspective view showing a heating pipe excretion step according to the present invention.

Figure 5 is a cut perspective view showing a completed state of the floor structure system according to the present invention.

* Explanation of symbols for the main parts of the drawings

10 concrete slab 20 insulation buffer

30: reinforcement 40: heating piping

50: cement mortar

The present invention relates to a floor structure system for reducing the floor impact sound of a general building, such as a multi-unit house, a multi-story building, and a construction method thereof. Specifically, a floor structure system for reducing the weight impact sound between floors, and a construction thereof It is about a method.

1 illustrates a conventional general floor structure system. Referring to the construction method of the conventional floor structure system, first, the concrete slab 1 is poured into a thickness of 150 to 180 mm, and the upper surface of the concrete slab 1 is 20 mm. After installing the inner and outer insulation buffers (2), the light-bubble concrete (3) of about 40mm in the upper portion is poured. Then, the heating pipe 4 is installed with a pipe fixing pin (not shown in the drawing) on the lightweight foamed concrete 3, and the finishing mortar 5 is poured.

However, the conventional floor structure system constructed in the above-described method is subjected to two wet processes such as lightweight foamed concrete (3) construction and finishing mortar (5) construction, due to the nature of the wet process requires a curing period Not only did the construction period last longer, but there was a limit that the impact amount could not be sufficiently reduced even in the measurement result of the floor impact sound by the standard weight impact source specified in KS A 2810-2.

In the building, the application of floating floor structure, flexible material shock absorber installation, and the increase of thickness and rigidity are essential factors to reduce the floor impact sound.

However, the bottom impact sound reduction methods as mentioned above may have a reduction effect on the light impact sound among the floor impact sound, but it is reported that there is no substantial reduction effect on the heavy impact sound as intended in the present invention.

In the case of heavy impact sound, unlike the light impact source, the impact amount is very large. Therefore, as in the conventional case, by applying a cushioning material between lightweight foam concrete and concrete slab or increasing the thickness and rigidity of the concrete slab, It is due to the fact that the impact amount is transmitted locally to the concrete slab layer as it is, and thus does not have a substantial reduction effect.

In fact, even in the case of using the shock absorber in the field experiments according to the evaluation method based on the inverse A characteristic, it was found that the measured value of the weight shock sound was similar to 54 to 55 dB in both cases.

The present invention is to solve the above problems, by reducing the wet process from one to two times the existing construction process through the development of a floor structure system to replace lightweight foamed concrete, by increasing the rigidity of the upper buffer layer The present invention provides a floor structure system and a construction method thereof that can improve weight shock sound reduction performance among floor impact sounds.

In order to achieve the above object, the present invention, the impact source generated when the impact sound (mainly heavy impact source) is generated by replacing the existing lightweight foam cone concrete layer with cement mortar and reinforcing the high rigidity reinforcement to the cement mortar layer In the cement mortar layer having increased stiffness by increasing the thickness and installing the reinforcing material, the dispersion is primarily damped, and the amount of impact remaining after the damping is further attenuated by the insulation buffer at the bottom to maximize the impact sound reduction effect to the lower layer. It features.

To this end, the floor structure system according to the present invention includes an insulation buffer installed on the concrete slab; A reinforcing member which is formed in a lattice form and is installed at a predetermined height apart from the upper part of the thermal insulation buffer by supporting a plurality of supports below; A heating pipe disposed on the reinforcing material at predetermined intervals; And cement mortar which is poured onto the heating pipe and the reinforcement.

In addition, the construction method of the floor structure system, the first step of installing a thermal insulation buffer on the concrete slab; A second step of installing a reinforcing material formed in a lattice form and supporting a lower portion with a plurality of supports on an upper portion of the insulation buffer; A third stage for disposing a heating pipe on the reinforcing material; And a fourth step of pouring cement mortar on the heating pipe and the reinforcement.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

Figure 2 is a cut perspective view showing the cushioning material installation step according to the invention, Figure 3 is a cut perspective view showing a reinforcing material installation step according to the present invention, Figure 4 is a cut perspective view showing a heating pipe excretion step according to the present invention. 5 is a cut perspective view illustrating a completed state of the floor structure system according to the present invention.

As shown in the figure, the floor structure system according to the present invention is a thermal insulation buffer 20 is installed on the concrete slab 10, the reinforcement material 30 is installed to be spaced apart a certain height above the thermal insulation buffer 20, The heating pipe 40 is disposed on the upper portion of the reinforcing material 30 at predetermined intervals, and the cement mortar 50 is placed on the heating pipe 40 and the upper portion of the reinforcing material (30).

At this time, the insulation buffer 20 may be used as long as the material having a function similar to EVA, EPP, PE, EEPS, natural rubber, and the like, the preferred embodiment for the optimal system thickness of the insulation buffer 20 It is desirable to design the to about 30mm.

The reinforcing material 30 is a member for reinforcing the rigidity of the cement mortar 50 to be poured on the upper part and fixing the heating pipe 40 to the upper part. The support 31 is installed to support the reinforcement 30 to a predetermined height. At this time, the reinforcing material 30 may be a material such as plastic, steel and aluminum.

Hereinafter, the construction method of the floor structure system according to the present invention with reference to the accompanying drawings in detail as follows.

When the concrete slab 10 is hardened to a predetermined strength, the heat insulating buffer 20 is installed to a predetermined thickness on the concrete slab 10 (see FIG. 2).

After the thermal insulation buffer 20 is installed, a reinforcing material 30 formed in a lattice form and supporting the lower portion with a plurality of supports 31 is installed on the thermal insulation buffer 20 (see FIG. 3).

Subsequently, the heating pipe 40 is disposed on the reinforcing material 30 using a pipe fixing pin (not shown) (see FIG. 4), and when the heating pipe 40 is completed, the heating is completed. A cement mortar 50 is poured onto the pipe 40 and the reinforcing material 30 to finish.

Hereinafter, after applying the floor structure system and the existing floor structure system according to the present invention to the actual construction site, respectively, and shows the table to compare and analyze the results of the light impact sound and heavy impact sound. The result of the measurement of the light impact sound and the heavy impact sound is the result performed in the 34-flat apartment house, and the floor finishing material is measured without construction.

Analyzing the performance evaluation results of the floor structure system and the existing floor structure system according to the present invention measured under the above conditions, it was found that the reduction effect on the weight impact sound is improved by 4 ~ 5dB than the existing floor structure system, lightweight The impact sound was improved by about 2dB.

[Table 1] Light impact sound measurement results

 (Unit: dB)

 frequency  125 Hz  250 Hz  500 Hz  1KHz  2KHz  Inverse A characteristic value  Existing structure  70.5  66.8  58.2  53.0  50.1  56  Pattern structure  69.6  65.7  48.4  44.0  39.9  54

[Table 2] Measurement result of heavy impact sound

            (Unit: dB)

 frequency  63 Hz  125 Hz  250 Hz  500 Hz  Inverse A characteristic value  Existing structure  82.3  69.2  59.3  39.2  54  Pattern structure  78.7  64.7  55.2  38.8  50

As described above, the floor structure system and its construction method according to the present invention have the effect of reducing the weight impact sound in the floor structure system, which is particularly problematic in the lifestyle of walking barefoot as in the country.

In addition, by replacing the existing lightweight foam concrete construction with cement mortar construction and dismissing the wet process, which was carried out twice, the curing time required for the wet construction can be shortened, which greatly shortens the overall construction date. There is.                     

In addition, by increasing the thickness and stiffness of the cement mortar layer, there is a side effect of increasing the thermal capacity than the existing lightweight foam concrete to improve the heat storage effect.

Claims (4)

In the floor structure system, An insulation buffer installed on the concrete slab; A reinforcing member which is formed in a lattice form and is installed at a predetermined height apart from the upper part of the thermal insulation buffer by supporting a plurality of supports below; A heating pipe installed on the reinforcing material at predetermined intervals; And Floor structural system with improved weight impact sound reduction performance, characterized in that consisting of cement mortar is poured on the heating pipe and the reinforcement. The method of claim 1, The insulation buffer is Floor structure system with improved weight impact sound reduction performance, characterized by consisting of at least one of EVA, EPP, PE, EEPS, natural rubber. The method of claim 1, The reinforcement is Floor structure system with improved impact performance, characterized in that made of one of plastic, steel or aluminum material. In the construction method of the floor structure system, A first step of installing an insulation buffer on the concrete slab; A second step of installing a reinforcing material formed in a lattice form and supporting a lower portion with a plurality of supports on an upper portion of the insulation buffer; A third step of disposing a heating pipe on the reinforcing material; And And a fourth step of placing cement mortar on the heating pipe and the reinforcing material. 4.

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