KR200374808Y1 - Floating floor structure for reducing floor a crashing sound in apartment house - Google Patents

Abstract

The present invention relates to a floor structure of a multi-family house for reducing the floor impact sound. The floor structure of the present invention forms a sound absorbing layer on the upper part of the concrete slab, and forms a buffer layer and a finishing mortar layer to minimize the transmission force transmitted to the floor of the building above the sound absorbing layer, the buffer layer is a spring of the buffer material The thickness is adjusted to reduce the constant, and the finishing mortar layer is formed by adjusting its thickness and specific gravity so as to increase the surface density. Therefore, the structure of the present invention provides an effect capable of minimizing the weight impact sound in the floor structure in the apartment.

Description

Floating floor structure for reducing floor a crashing sound in apartment house

The present invention relates to a floor structure of a multi-family house, and relates to a floor structure for reducing the floor impact sound to solve the floor noise of the multi-family house.

When the floor impact sound is classified into a light impact sound and a heavy impact sound according to the type of impact source, the mat-type floor impact sound insulation material applied for the purpose of reducing the floor impact sound in domestic apartment houses has a slight difference depending on the material of the sound insulation material used. Although there may be, the sound insulation performance index for the lightweight impact sound has been improved by about L-5 ~ L-15 compared to the conventional floor structure. However, it is difficult to expect an improvement effect on the weight shock sound such as the sound of a child running at all, so the weight shock sound measures are insufficient.

The floor structure of MDU is divided into concrete slab, foam concrete and mortar finish according to the construction order. The conventional floor structure for reducing the floor impact sound is glass wool-like vibration between the concrete slab and foam concrete layer. By providing a buffer material, it was intended to reduce the vibration applied at the top.

The floor structure of such a multi-family house will be described with reference to FIG. 1.

1 is a cross-sectional view showing the floor structure of such a general apartment house.

Referring to Figure 1, the floor structure of the multi-family building is a concrete slab (1), a buffer layer (2), lightweight foam concrete layer (3), piping (4), finishing mortar layer (5) and floor covering layer (6) It is constructed to be laminated in stages.

Concrete slab (1) is mostly made of reinforced concrete, and currently it is generally applied to the thickness of 125-150mm to apply to the multi-family house in Korea. In addition, the buffer material to be installed in the buffer layer 2, there are a variety of materials, such as waste tire chips, rubber-based mat, glass-based mat, the thickness is usually about 10-20mm.

Lightweight foamed concrete layer (3) on the buffer layer (2) is composed of a heat insulating layer and a heat storage layer as an ondol layer, the ondol pipe (4) is embedded thereon, most of the lightweight foam to satisfy the thermal insulation performance prescribed by the law I use concrete. And the thickness of the lightweight foam concrete layer (3) depends on the thickness of the buffer layer (2), but the total thickness is around 70mm. The upper part of the pipe 40 is embedded as a finishing material in most cases to form a mortar layer (5) of about 50mm mortar (mortar), and finally to the floor by installing a floor covering like floorboard The underfloor pipe 4 and the floor covering layer 6 may not be constructed depending on the use purpose of the building to form the floor covering layer 6. And the pillar-buffer (F) is attached to the side construction.

In general, the floor structure described above shows improvement of 1-3 grades compared to the unapplied floor structure in the case of lightweight impact sound by using the floor structure improvement technology applied with the cushioning material, but the impact sound is mainly reduced in the high frequency band rather than in the low frequency band. to be. On the other hand, in the case of the heavy impact sound, the improvement in the low range is not made, and most of them are similar to the unapplied floor structure or show a slight improvement effect of the first grade.

Floor impact sound reducing materials used to reduce the floor impact sound is generally a soft buffer material of elastic material that absorbs the floor impact, such as waste tires, rubber chip EVA chip (ethyline vinyl acetate chip), foamed styrene foam, EPS (expended poly) styrene), but when the material is applied on the slab, the elastic modulus is increased due to insufficient thickness of the cushioning material. Therefore, the effect of the cushioning material due to the floating bottom structure is not shown.

That is, most of the sound insulation structures are intended to be blocked through the floating floor structure as described above, but in the living room of the span, the inner room, etc., the floating floor itself behaves greatly as a whole, generating a phenomenon that sounds like a drum. The thickness of the slab may be increased to remove the thickness of the slab, but the height of the floor increases, which increases the amount of material put into the construction, and also delays the curing time of the concrete, thus prolonging the construction period. There is an economic disadvantage due to the extension, so there is a problem that is practically impossible to apply.

Theoretically, the best way to reduce floor impact sounds is to make the floor double. In other words, if the wall density (kg / m ² ) is doubled in the mass law of sound insulation, that is, if the wall thickness is doubled, the sound insulation performance is increased by about 6 decibels, but the space between them is doubled. In the case of the double wall type, the sound insulation performance is increased by about 15 decibels or more. This means that the separation of the wall plays an important role, among other things, to block air propagation or floor impact sounds.

Various floor impact sound reducing materials used in the past have been used as part of the method for forming the floating floor structure, but when the density of the used material is low, there is a problem that cracks occur in the floor due to the settlement phenomenon. When using, there is a problem that the floor impact sound insulation performance is degraded. In addition, the cushioning materials such as glass wool, dustproof mat, carbide cork, rubber mat, and foam rubber mat used in the upper part of the slab of MDU according to this method are satisfactory to satisfy the floor impact sound insulation performance along with the expensive materials. There was a problem that could not be improved.

Therefore, the object of the present invention is to reduce the weight impact sound, such as the sound of people running by forming a floating floor type bottom structure to raise the surface density of the floating floor layer and lower the spring constant of the buffer material to solve the above problems. It is to provide a floor structure of a multi-family house for reducing the floor impact sound.

1 is a cross-sectional view showing a floor structure of a common apartment house,

Figure 2 is a cross-sectional view showing a floor structure of a multi-family house for reducing the floor impact sound according to an embodiment of the present invention,

Figure 3 is a table showing the result for the weight impact sound level according to an embodiment of the present invention,

Figure 4 is a graph showing the results for the weight impact sound level according to an embodiment of the present invention.

* Explanation of symbols for main parts of the drawings

10: concrete slab 20: dry sand layer

30: sound absorption panel 40: buffer layer

50: finishing mortar layer 60: piping

70: floor covering layer

The floor structure of the multi-family house for reducing the floor impact sound according to the present invention for achieving the above object is to form a sound absorbing layer on the top of the concrete slab, the transmission force transmitted to the floor of the building to the top of the sound absorbing layer is minimal To form a buffer layer and the finishing mortar layer, the buffer layer is characterized in that the thickness and specific gravity is adjusted so that the spring constant of the buffer material is small, and the thickness of the finishing mortar layer is adjusted to increase the surface density.

In addition, according to the present invention, the sound-absorbing layer is characterized by forming a sound-absorbing panel of the plate vibration-absorbing structure by stacking a dry sand layer on the bottom, inducing plate vibration of the low frequency sound band to the top.

In addition, according to the present invention, the dry sand layer is characterized in that the thickness of 5-15mm.

In addition, according to the present invention, the sound absorbing panel is characterized in that the thickness of 9-20mm.

In addition, according to the present invention, the finishing mortar layer is characterized in that the pipe is embedded and the floor covering layer is formed thereon.

In addition, according to the present invention, the side of the floor structure is characterized in that the pillar buffer is attached.

In addition, according to the present invention, the pillar buffer is characterized in that the thickness is 10mm and the width 100-150mm.

In addition, according to the present invention, the buffer layer is a thickness of 25-45mm and the finishing mortar layer is characterized in that the thickness of 90-120mm.

Hereinafter, with reference to the accompanying Figures 2 and 3 will be described in detail a preferred embodiment of the present invention.

2 is a cross-sectional view showing a floor structure of a multi-family house for reducing the floor impact sound according to an embodiment of the present invention.

Referring to Figure 2, the floor structure of the apartment building is a concrete slab 10, dry sand layer 20, sound absorbing panel 30, buffer layer 40, finishing mortar layer 50, piping 60, and the floor The jangpan layer 70 is constructed to be laminated in stages. And the side of the floor structure is installed by attaching a side pillar buffer (F) having a thickness of 10mm and width 100-150mm in order to prevent the transmission of impact sound.

Concrete slab 10 is mostly made of reinforced concrete in the present embodiment is constructed to the thickness of about 180-210mm. Then, the dry sand layer 20 and the sound absorbing panel 30 are sequentially formed thereon.

Dry sand layer 20 is installed 5-15mm for the buffer to the sound absorbing panel 30 of the upper side to form a horizontal maintenance and secondary dust-proof structure. Dry sand is the most efficient material layer that can absorb the vibration shock, and serves to secondaryly block the noise and vibration blocked in the primary dustproof structure to be described later. The thickness of the dry sand layer is preferably at least 5 mm, which is the minimum thickness for absorbing the impact, and preferably at most 15 mm for the stability of the installation structure.

In addition, the sound absorbing panel 30 is a plate vibration absorbing structure by inducing low frequency plate vibration absorbing, and is installed to induce plate vibration by adhering a heat insulating reinforcement to a 3-5mm rigid body to dissipate vibration energy. That is, the 3-5 mm steel body uses one of a cement board, a fiber and pulp mixed cement board (CRC board), an asbestos cement board (balm light, wood light, etc.), wood board, wood fiber board, and steel structure board. And, the heat insulating reinforcing material bonded to such a rigid body uses a styrofoam of 30Kg / m ³ ~ 35Kg / m ³ . The sound absorbing panel 30 is taped to prevent water from entering or the upper part is treated with a vinyl sheet to form a primary dustproof structure. Therefore, the thickness of the sound absorbing panel is adjusted to be 9-20 mm in total by adding the thermal insulation reinforcement bonded to the rigid body to the 3-5mm rigid body. 3-5 mm is preferred as a thickness for inducing efficient plate vibration, and this range can also be appropriately changed from the area of the floor to be constructed. The thickness of the insulation reinforcement material is adjusted to 6-15 mm, which is a preferable thickness to play the role of absorption and sound absorption of the plate vibration.

The buffer layer 40 is formed on the sound absorbing panel 30. The buffer layer 40 may include various materials such as waste tire chips, rubber-based mats, glass-based mats, and the like. In this embodiment, the buffer layer 40 has a thickness of 25-45 mm. In order to reduce the spring constant Kc of the buffer of the buffer layer 40, the thickness of the buffer is thickened.

The finishing mortar layer 50 is formed on the buffer layer 40. Finishing mortar layer 50 is formed of a total thickness of 90-120mm of the existing mortar layer 40-60mm and lightweight foamed concrete layer 40-60mm. Here, the finishing mortar layer 50 is a floating bottom layer, and formed to have a heavier mass than the conventional one in order to increase the surface density (Mf) of the floating bottom layer. While the thickness of the buffer layer 40 is 25-45mm, when the thickness of the finishing mortar layer is adjusted to 90-120mm, the blocking efficiency of vibration transmission that is conventionally obtained is greatly improved. Here, the surface density of the finishing mortar layer can be further increased by replacing the existing lightweight concrete layer with a mortar layer. As such, the present invention aims to obtain a target interlayer noise level by controlling the thickness and specific gravity of the mortar layer which plays a mass role.

In addition, a pipe 60 is embedded in the upper part of the finishing mortar layer 50, and a floor covering layer 70 is formed by constructing a floor covering material such as sheet paper at the top of the finishing mortar layer 50.

With reference to the partially enlarged portion of Figure 2 will be described in more detail with respect to the finishing mortar layer 50 and the buffer layer 40 that serves as a spring for the float layer.

2, Mf is the surface density of the floating bottom layer which is the finishing mortar layer 50, and Kc is the spring constant of the buffer material of the buffer layer 40. As shown in FIG. Strictly speaking, the bottom layer should be modeled as a two-dimensional multi-degree-of-freedom vibration system, but the modeling of one-degree-of-freedom system can be applied to the multi-degree of freedom system as it is. If the transmission force for the bottom impact sound generated in the upper portion T is the following equation (1).

At this time, since the transmission force for the floor impact sound must be small, noise between floors can be minimized as a floor structure of a multi-family house, and in order to reduce T, the natural frequency fn must be small. The natural frequency fn is given by Equation 2 below.

Here, fn is a natural frequency, Kc is a spring constant (N / m ² ) of the cushioning material of the buffer layer, and Mf is a surface density (Kg / m ² ) of the floating bottom layer which is a finishing mortar layer.

Therefore, in order to reduce the natural frequency fn, Mf must be large in Equation 2 and Kc must be small.

This Kc is shown in Equation 3 below.

Where K _oc is the elastic modulus of the cushioning material, ρ is the density of air, c is the sound transfer rate of the air layer, and d is the thickness of the buffer material.

Therefore, in order to increase Mf, the weight of the finishing mortar layer 50, which is the floating bottom layer, is formed to be heavy, and in order to decrease Kc, the elastic modulus of the cushioning material is made small to form the thickness of the buffer layer 40 thick. That is, the finishing mortar layer replaces the existing lightweight concrete layer to increase the surface density or increase its weight to increase the surface density.

The sound absorbing panel 30 and the dry sand layer 20 are separately formed under the finishing mortar layer 50 and the buffer layer 40 formed as described above. In the sound absorbing panel, the first vibration energy passing through the buffer layer is exhausted, but there is still a limitation in blocking the vibration energy of the low frequency. The dry sand layer is efficient in absorbing low-frequency impact energy and absorbs most of the energy in the high-frequency band that has not been exhausted before.

Experimental results in which the weight impact sound is actually reduced from the floor structure are shown in FIGS. 3 and 4 in a graph and a graph.

3 is a diagram showing a result for the weight impact sound level according to an embodiment of the present invention with the existing results, Figure 4 is a graph showing a result for the weight impact sound level according to an embodiment of the present invention with the existing results to be.

Figure 3a shows the result of the weight impact sound in the conventional structure.

As shown in FIG. 3A, the measurement value of the impact sound and the inverse A characteristic reference curve (reference value) for each frequency band are shown. The measured value can be obtained in decibels less than the reference value at the center frequency of 250. That is, it can be seen that at the center frequency 250, the reference value is 58 [dB] but the measured value is 54.7 [dB] lower than this. In addition, at the center frequency 500, the reference value is 52 [dB], but the measured value is 44.6 [dB]. If this is displayed as a graph, it is as shown in FIG.

Referring to FIG. 4A, it can be seen that the impact sound level of the reference curve of the inverse A characteristic is measured at 52 [dB] at a frequency of 500 Hz, and the measured value is 44.6 [dB].

Figure 3b shows the result of the weight shock sound of the present invention.

As shown in FIG. 3B, the measurement value of the impact sound and the inverse A characteristic reference curve (reference value) for each frequency band are shown. In the center frequency 500, the reference value is 45 [dB], but the measured value is 40.7 [dB]. It can be seen that the weight shock sound (45 dB) significantly less than the conventional weight shock sound measurement (52 dB) of the table shown in Figure 3a. This is shown in a graph as shown in Figure 4b.

Referring to FIG. 4B, it can be seen that the impact sound level of the reference curve of the inverse A characteristic is measured at 45 [dB] at a frequency of 500 Hz, and the measured value is 40.7 [dB].

Therefore, it can be seen from the graph that when the construction according to the embodiment of the present invention has a weight impact sound of a lower level than the conventional measurement of the weight impact sound of Figure 4a.

As such, it can be seen that when the floor structure proposed in the present embodiment is used, noise between floors can be significantly reduced compared to the existing floor structure.

Therefore, the structure of the present invention provides an effect capable of minimizing the weight impact sound in the floor structure in the apartment.

Claims (7)

In the floor structure formed by laminating on the concrete slab floor of the building, A sound absorbing layer is formed on the upper portion of the concrete slab, and a buffer layer and a finishing mortar layer are formed so that the transmission force transmitted to the floor of the building is minimized above the sound absorbing layer. The buffer layer is adjusted to the thickness of the spring constant of the buffer material is reduced, and the finishing mortar layer is formed by adjusting the thickness and specific gravity so as to increase the surface density floor structure of the apartment house for reducing the floor impact sound. The method of claim 1, The sound absorbing layer is A floor structure of a multi-family house for floor impact sound reduction, characterized in that the dry sand layer is laminated on the lower part, and the plate vibration of the low frequency sound band is induced to the upper part, thereby forming a sound absorbing panel having a plate vibration absorbing structure. The method of claim 2, The dry sand layer is a floor structure of a multi-family house for the floor impact sound reduction, characterized in that the thickness of 5-15mm. The method of claim 2, The sound absorbing panel is a floor structure of a multi-family house for floor impact sound reduction, characterized in that the thickness of 9-20mm. The method of claim 1, Pipes are embedded in the finishing mortar layer and the floor structure of the multi-family housing for reducing the floor impact sound, characterized in that the floor covering layer is formed on the top. The method of claim 1, Floor structure of a multi-family house for reducing the floor impact sound, characterized in that the filler is attached to the side of the floor structure. The method of claim 1, The buffer layer has a thickness of 25-45mm and the finishing mortar layer has a thickness of 90-120mm floor structure of the apartment house for reducing the floor impact sound.