KR20230140196A - Building Slab Structure with Gravelly Layer and Construction Method thereof - Google Patents

Abstract

The present invention relates to a slab structure for a building with a gravel layer that allows heat from a hot water pipe to be conducted to the gravel in the gravel layer, thereby saving energy, and to a method of constructing the same. In the present invention, when hot water is supplied to the hot water pipe, heat is conducted to the gravel of the gravel layer in contact with the hot water pipe, so floor heating can be maintained for a long time, serves as a gudeuljang, a traditional Korean ondol method, and is efficient for energy saving. It works. In addition, if a hot water pipe is constructed on a concrete layer and then gravel is laid to form a gravel layer and then the bottom layer is constructed, even if an impact is applied to the upper part of the bottom layer, the gravel layer acts as a primary buffer, so in the case of residential facilities, inter-floor noise This is reduced by half, and has the effect of significantly reducing shock or sound transmitted to the lower floor.

Description

Building slab structure with gravel layer and construction method thereof {Building Slab Structure with Gravelly Layer and Construction Method there}

The present invention relates to a building slab structure having a gravel layer and a construction method thereof. More specifically, to a building slab structure having a gravel layer that allows heat from a hot water pipe to be conducted to the gravel in the gravel layer to save energy, and to a building slab structure having a gravel layer and its construction method. It's about construction methods.

In general, buildings such as houses are equipped with a hot water heating system that heats the inside of the building by circulating high temperature hot water through hot water pipes installed on the slab. The hot water heating system is adapted from Korea's unique Ondol method and has a unique form that is rarely seen in the world.

Looking at the structure of the hot water heating system, hot water pipes for heating are constructed on the upper part of the concrete layer that acts as a slab, and when the hot water pipes for heating are constructed, a mortar finish layer of cement is poured and plastered. And the heat emitted from the hot water pipes is stored in the finishing layer and radiant heating occurs.

The heat storage performance of this finishing layer is largely dependent on the heat capacity of the concrete itself. Since the size and shape of the finishing layer are determined by physical dimensions to ensure structural stability, there are restrictions on arbitrarily increasing the heat storage capacity. Therefore, there is a problem in that the heat emitted from the hot water pipe is not stored in the finishing layer for a long time, resulting in low heating efficiency.

Meanwhile, in Korea, as urbanization and nuclear families have progressed rapidly due to rapid industrialization, apartment complexes have been popularized in earnest since the late 1980s, and currently, two out of three citizens live in apartment complexes. Due to the nature of apartment complexes where people live with thin walls and floors in between, it is recognized that noise between floors is inevitable.

The noise between floors becomes even worse if the floor is a slab that has been properly watered and poured at a construction site, then leveled the surface and cured it. In the case of these slabs, even with a moderate impact, a resonance phenomenon may occur in a small space due to water draining inside the concrete, resulting in a drum-like sound (ringing). In the case of floor impact on the upper floor, a ringing phenomenon may occur, amplifying the noise between floors. do.

This noise between floors is recognized as the most damaging problem in residential environments such as villas or apartments that form communal housing. In particular, it is a fatal factor for patients with nervous breakdowns, sudden stress in social life, or insomnia. This can be. When there is a conflict with neighbors due to noise between floors, it is difficult to find a solution, so people protest, but when no progress is made, they avoid it and plan to move to another area, or there are many unfortunate cases where the relationship between neighbors leads to a relationship between victims and perpetrators.

As a technical approach to solving inter-floor noise, there is a way to increase the performance of building elements. For example, in the case of slab concrete pouring with a depth of 210m/m, the pouring depth is increased by about 5% to 10% to account for water drainage or shrinkage during the curing process, so that the slab depth (slump) after curing is within the target value in the specifications. must be accessible.

Domestic Patent Publication No. 10-2018-0029335

The purpose of the present invention to solve the problems of the prior art as described above is to provide a slab structure for buildings with a gravel layer that maximizes heating efficiency and saves energy by allowing the heat of the hot water pipe to accumulate in the gravel of the gravel layer, and the same. It provides construction methods.

In addition, another object of the present invention is to provide a slab structure for a building with a gravel layer that can significantly reduce inter-floor noise without increasing the thickness of the slab, and a method of constructing the same.

In order to achieve the above object, the present invention provides a slab structure for buildings, including a concrete layer constructed by mixing concrete materials; A hot water pipe installed in a zigzag shape on top of the concrete layer; A gravel layer formed by placing gravel on the upper part of the concrete layer where the hot water pipe is installed; and a bottom layer constructed on top of the gravel layer. It provides a slab structure for buildings having a gravel layer.

In addition, a slab structure for buildings having a gravel layer is provided, wherein the gravel has a diameter of 25 mm to 40 mm.

In addition, it provides a slab structure for buildings having a gravel layer, characterized in that a wire mesh is installed between the concrete layer and the hot water pipe.

In addition, it provides a slab structure for buildings having a gravel layer, wherein when hot water is supplied to the hot water pipe, the heat energy of the hot water is conducted to gravel in contact with the hot water pipe.

In addition, the present invention relates to a method of constructing a slab structure for a building, including a concrete layer construction process of mixing concrete materials to construct a concrete layer; A hot water pipe installation process of installing hot water pipes in a zigzag shape on the upper part of the concrete layer; A gravel layer construction process of constructing a gravel layer by laying gravel on the upper part of the concrete layer where the hot water pipe is installed; and a bottom layer construction process of constructing a bottom layer on top of the gravel layer. It provides a construction method of a slab structure for a building having a gravel layer.

In addition, in the process of constructing the gravel layer, a method of constructing a slab structure for a building having a gravel layer is provided, wherein the diameter of the gravel is 25 mm to 40 mm.

In addition, between the concrete layer construction process and the hot water pipe installation process, it further includes a wire mesh installation process of installing a wire mesh on the upper part of the concrete layer, and in the hot water pipe installation process, hot water is installed on the upper part of the wire mesh. Provides a method of constructing a slab structure for a building with a gravel layer, characterized by installing pipes.

In addition, the concrete layer construction process includes: a mixing step of mixing and mixing concrete materials; a pouring step of pouring the mixed concrete at the construction location to form a concrete layer; A vibration step of applying vibration to the concrete layer using a vibrator; and a curing step of curing the concrete layer. It provides a method of constructing a slab structure for a building having a gravel layer.

In the present invention, when hot water is supplied to the hot water pipe, the heat emitted from the hot water pipe is stored in the gravel of the gravel layer in contact with the hot water pipe for a long time, so floor heating can be maintained for a long time, improving heating efficiency and saving energy. There is a possible effect.

In addition, if a hot water pipe is constructed on a concrete layer and then gravel is laid to form a gravel layer and then the bottom layer is constructed, even if an impact is applied to the upper part of the bottom layer, the gravel layer acts as a primary buffer, so in the case of residential facilities, inter-floor noise This is reduced by half, and has the effect of significantly reducing shock or sound transmitted to the lower floor.

In addition, since it is configured to apply vibration using a vibrator to the concrete layer formed by pouring the concrete, blisters (water pockets) and air layers are not created inside the concrete layer, increasing the density of the concrete layer and causing resonance due to the air layer. This has the effect of preventing inter-floor noise from being generated.

In addition, when vibration is applied to the rebar through a vibrator, the vibration is transmitted evenly through the rebar to the entire area of the poured concrete, so an air layer is not created inside the concrete layer, which further increases the density of the concrete layer and prevents noise between layers. There is.

In addition, since it is configured to apply vibration to each unit area formed in the concrete layer using a vibrator, vibration can be applied evenly to the entire area of the concrete layer, which has the effect of evenly increasing the density of the concrete layer.

In addition, when the vibrator is moved while inserted into the concrete layer, the vibrator can be moved quickly, which has the effect of applying vibration to the concrete layer at a high speed.

In addition, since the concrete is poured so that the thickness of the concrete layer exceeds the target value, even if water drainage occurs during the curing process, there is an effect of constructing the slab so that the thickness is close to the target value.

In addition, since the thickness of the slab does not need to be thicker than necessary, there is no need to increase the floor height to solve inter-floor noise, and there is an effect of not increasing construction costs.

Figure 1 is a diagram schematically showing a method of constructing a slab structure for a building with a gravel layer according to a preferred embodiment of the present invention.
Figure 2 is a diagram schematically showing the concrete layer construction process of the construction method of a slab structure for a building with a gravel layer according to a preferred embodiment of the present invention.
3 to 6 are diagrams schematically showing various examples for explaining the vibration stage of the concrete layer construction process according to a preferred embodiment of the present invention.
Figure 7 is a diagram schematically showing the stopping stage of the concrete layer construction process according to a preferred embodiment of the present invention.
Figure 8 is a diagram schematically showing a slab structure for a building with a gravel layer constructed by the method of constructing a slab structure for a building with a gravel layer according to a preferred embodiment of the present invention.
Figure 9 is a diagram showing a sampling frame according to a preferred embodiment of the present invention.
Figure 10 is a diagram showing the state of pouring concrete into a specimen frame according to a preferred embodiment of the present invention.
Figure 11 is a diagram showing a state in which concrete is poured into a specimen frame according to a preferred embodiment of the present invention to form a concrete layer.
Figure 12 is a diagram showing the operation of applying vibration to a concrete layer formed in a specimen frame according to a preferred embodiment of the present invention.
Figure 13 is a diagram showing a state in which the surface of a concrete layer subjected to vibration has been flattened according to a preferred embodiment of the present invention.
Figure 14 is a diagram showing a slab on which construction has been completed according to a preferred embodiment of the present invention.
Figure 15 is a view showing the side of a slab on which construction has been completed according to a preferred embodiment of the present invention.
Figure 16 is a diagram showing a sample frame for constructing a comparative slab for comparison with the slab of the present invention.
Figure 17 is a diagram showing a comparative slab for comparison with the slab of the present invention.
Figure 18 is a view showing a side view of a comparative slab for comparison with the slab of the present invention.
Figures 19 and 20 are diagrams showing the results of measuring noise applied to a slab constructed by the construction method of a building slab structure with a gravel layer according to a preferred embodiment of the present invention using different smartphones.
Figures 21 and 22 are diagrams showing the results of measuring noise applied to a comparison slab for comparison with the slab of the present invention using different smartphones.

Hereinafter, the construction method of a slab structure for a building with a gravel layer according to a preferred embodiment of the present invention will be described in more detail with reference to the attached drawings.

Figure 1 is a diagram schematically showing a method of constructing a slab structure for a building with a gravel layer according to a preferred embodiment of the present invention.

Referring to Figure 1, the method of constructing a slab structure for a building having a gravel layer according to a preferred embodiment of the present invention is a method of constructing a slab structure for a building having a gravel layer, wherein the concrete layer is constructed by mixing concrete materials. Construction process (S100), wire mesh installation process (S200) of installing a wire mesh on the upper part of the concrete layer, hot water pipe installation process of installing a hot water pipe in a zigzag shape on the upper part of the wire mesh installed on the upper part of the concrete layer (S300), a gravel layer construction process (S400) of constructing a gravel layer by laying gravel on top of the concrete layer where the hot water pipe is installed, and a bottom layer construction process (S500) of constructing a bottom layer on top of the gravel layer. Hereinafter, the construction method of a building slab structure with a gravel layer will be described in detail with reference to the drawings.

Figure 2 is a diagram schematically showing the concrete layer construction process of the construction method of a building slab structure with a gravel layer according to a preferred embodiment of the present invention, and Figures 3 to 6 are concrete layers according to a preferred embodiment of the present invention. This is a diagram schematically showing various examples for explaining the vibration stage of the construction process, and Figure 7 is a diagram schematically showing the stopping stage of the concrete layer construction process according to a preferred embodiment of the present invention.

Referring to Figure 2, the concrete layer construction process (S100) includes a mixing step (S110) in which concrete materials are mixed and mixed, and a pouring step (S120) in which the mixed concrete is poured at the construction location to form the concrete layer 100. , a vibration step (S130) of applying vibration to the formed concrete layer 100 using the vibrator 10, a stopping step (S140) of flattening the surface of the formed concrete layer 100, and curing the formed concrete layer 100. It includes a curing step (S150).

Mixing step (S110)

Concrete is created by mixing concrete materials. The mixing ratio of concrete materials is made by mixing 5 to 15 parts by weight of cement, 15 to 25 parts by weight of fine aggregate, 35 to 45 parts by weight of coarse aggregate, and 0.5 to 5 parts by weight of water. It is desirable to sufficiently mix these concrete materials on site using a mixer. If the mixing ratio of concrete materials is exceeded, there is a problem of deterioration of constructability.

Pouring stage (S120)

The mixed concrete is poured at the construction location to form the concrete layer 100. The construction location may, for example, consist of a formwork for forming a building slab, that is, a building slab for constructing floors, ceilings, etc. Here, it is preferable that reinforcing bars 110 are previously arranged in a grid at the construction location to increase strength.

And, when pouring the mixed concrete at the construction location to form the concrete layer 100, the concrete is poured so that the thickness of the concrete layer 100 exceeds the target value by more than 5%, causing the phenomenon of concrete draining. It is advisable to prepare for. In other words, the concrete layer 100 experiences water loss during the curing process, which causes the thickness of the slab to become thinner than the target thickness, causing poor construction. In order to solve this problem, the present invention pours concrete so that the thickness of the concrete layer 100 exceeds the target value by more than 5% at the pouring stage, so that even if water drainage occurs during the curing process, the thickness of the slab is thick enough to be close to the target value. Construction. As such, in the present invention, in the pouring stage, concrete is poured so that the thickness of the concrete layer 100 exceeds the target value, so even if water drainage occurs during the curing process, there is an effect of constructing the slab so that the thickness is close to the target value.

Oscillation stage (S130)

When the concrete layer 100 is formed at the construction location, vibration is applied to increase the density of the formed concrete layer 100. For this purpose, as shown in FIG. 3, vibration can be directly applied to the concrete layer 100 formed at the construction location using a vibrator 10 (see FIG. 12). At this time, the vibrator 10 performs compaction while vibrating the concrete layer 100 formed between the reinforcing bars 110 and the reinforcing bars 110 to prevent air pockets due to blisters from being created inside the concrete layer 100. , to increase the density of the concrete layer 100. The vibrator 10 is formed long along the longitudinal direction so that it can be inserted deeply into the concrete layer 100, and vibration is supplied.

In this way, since the present invention is configured to apply vibration to the formed concrete layer 100, an air layer is not created inside the concrete layer 100, thereby increasing the density of the concrete layer 100. As the density of the concrete layer 100 increases, the resonance phenomenon caused by the air layer does not occur, which has the effect of preventing inter-floor noise.

Additionally, as shown in FIG. 4, vibration may be applied to the reinforcing bars 110 placed at the construction location using the vibrator 10, thereby indirectly providing vibration to the concrete layer 100 formed at the construction location. In this way, when vibration is applied to the reinforcing bar 110 using the vibrator 10, the vibration applied to the entire reinforcing bar 110 is transmitted to the concrete layer 100, and the concrete layer 100 is subjected to vibration evenly without any shaded areas.

In this way, the present invention is configured to apply vibration evenly to the entire area of the concrete layer 100 formed through the reinforcing bars 110, so an air layer is not created inside the concrete layer 100, which has the effect of further increasing the density of the concrete layer 100. There is. As the density of the concrete layer 100 increases, the resonance phenomenon caused by the air layer does not occur, which has the effect of preventing inter-floor noise.

In addition, as shown in FIG. 5, the vibration step (S130) is performed by setting the upper surface of the concrete layer 100 formed in the form M to a plurality of unit areas (a), and then dividing the points corresponding to each unit area (a). It may be configured to insert the vibrator 10 for each (P). The point P corresponding to each unit area (a) may be located, for example, at the center of each unit area (a). Then, the worker inserts the vibrator 10 into the point P of the unit area a to give vibration to the unit area a, and then inserts the vibrator 10 into the point P of the unit area a, and then gives vibration to the point P of the unit area a. By moving the vibrator 10 to (P), it may be configured to apply vibration to each point (P) of each unit area (a).

In this way, the present invention is configured to apply vibration to each unit area (a) formed in the concrete layer 100 using the vibrator 10, so that vibration can be applied evenly to the entire area of the concrete layer 100. , which has the effect of uniformly increasing the density of the concrete layer 100.

In addition, as shown in FIG. 6, the vibration step (S130) is performed after setting the upper surface of the concrete layer 100 formed in the form M to a plurality of unit areas (a), and then the first unit area of the plurality of unit areas (a) It may be configured to pass sequentially up to the last unit area (a) with the vibrator 10 inserted in (a). For example, the vibrator 10 is inserted into the first unit area (a) and moves in a zigzag shape (W) to reach the last unit area (a).

In this way, when the vibrator 10 is moved while inserted into the concrete layer 100, the vibrator 10 can be moved quickly, which has the effect of applying vibration to the concrete layer 100 at a high speed.

Stop phase (S140)

When the vibration step is completed, the uneven surface of the formed concrete layer 100 is evenly flattened so that the floor surface is finished smoothly.

Curing stage (S150)

Once the stopping step is completed, the formed concrete layer 100 is cured for 25 to 35 days to form a slab. Then, water is sprayed on the surface of the formed concrete layer 100 to prevent surface drying while curing the formed concrete layer 100. At this time, water is sprayed on the surface of the formed concrete layer 100 for 25 to 35 days to prevent surface drying, and can be sprayed once per day. Preferably, the curing period is about 30 days, and water is sprayed once a day. And after the curing construction is completed, the form is dismantled to complete the concrete layer 100 as shown in FIG. 7.

As such, the present invention consists of a simple method of imparting vibration to the poured concrete during the construction process (S100) of the large concrete layer, so there is no need to make the slab thicker than necessary, so it is inevitable to increase the floor height in order to solve inter-floor noise. There is no need to increase , and it has the effect of not increasing construction costs.

Figure 8 is a diagram schematically showing a slab structure for a building with a gravel layer constructed by the method of constructing a slab structure for a building with a gravel layer according to a preferred embodiment of the present invention.

Referring to Figures 1 and 8, the construction method of a building slab structure with a gravel layer according to a preferred embodiment of the present invention includes a concrete layer construction process (S100), a wire mesh installation process (S200), and a hot water pipe installation process (S300). ), gravel layer construction process (S400), and bottom layer construction process (S500). Since the concrete layer construction process (S100) has been described above, the following will describe the wire mesh installation process (S200), the hot water pipe installation process (S300), the gravel layer construction process (S400), and the bottom layer construction process (S500).

Wire mesh installation process (S200) and hot water pipe installation process (S300)

When the concrete layer 100 is constructed in the concrete layer construction process (S100), a wire mesh 210 to serve as a support is constructed on the upper part of the concrete layer 100 (S200). Afterwards, a hot water pipe is constructed on the top of the wire mesh 210 (S300). The hot water pipe 220 supplies hot water, and is installed tightly so that the warmth of the hot water spreads evenly in all directions from the top of the concrete layer 100.

Gravel layer construction process (S400)

Afterwards, the gravel layer 200 is constructed by laying gravel on the upper part of the concrete layer 100 where the hot water pipe 220 is installed (S400). At this time, gravel is placed between the hot water pipes 220 so that the gravel is in contact with the hot water pipe 220.

The gravel provided in the gravel layer 200 may have a diameter of 25 mm to 40 mm. If the diameter of the gravel is smaller than 25 mm, there is a problem that the warmth cannot be maintained for a long time, and if the diameter of the gravel is larger than 40 mm, there is a problem that an empty space is created between the gravel.

And when hot water is supplied to the hot water pipe 220, the heat energy of the hot water is conducted to the gravel in contact with the hot water pipe 220, so the gravel has the effect of maintaining warmth for a long time. In this way, in the present invention, when hot water is supplied to the hot water pipe 220, heat is conducted to the gravel of the gravel layer 200 in contact with the hot water pipe 220, so floor heating can be maintained for a long time, and the traditional Korean ondol method. It serves as a food source and is effective in saving energy.

Bottom layer construction process (S500)

Afterwards, the bottom layer 300 is constructed using cement mortar, plastering mortar, etc. (S500). In this way, when a hot water pipe is constructed on a concrete layer and then gravel is laid before constructing the bottom layer, even if an impact is applied to the upper part of the bottom layer, the gravel layer acts as a primary buffer, so in the case of residential facilities, inter-floor noise is reduced by 40 to 50%. This has the effect of reducing shock and sound transmitted to the lower floor by more than 90%.

Hereinafter, the results of comparing the shapes of a concrete layer constructed by the construction method of a building slab structure with a gravel layer according to a preferred embodiment of the present invention and a comparative concrete layer constructed by a general method will be described.

Figure 9 is a diagram showing a specimen frame according to a preferred embodiment of the present invention, Figure 10 is a diagram showing a state of pouring concrete into a specimen frame according to a preferred embodiment of the present invention, and Figure 11 is a diagram showing a specimen frame according to a preferred embodiment of the present invention. This is a diagram showing a state in which concrete is poured into a specimen frame according to a preferred embodiment to form a concrete layer, and Figure 12 is a diagram showing the operation of applying vibration to the concrete layer formed in the specimen frame according to a preferred embodiment of the present invention. 13 is a view showing a state in which the surface of a concrete layer subjected to vibration has been flattened according to a preferred embodiment of the present invention, and FIG. 14 is a view showing a concrete layer on which construction has been completed according to a preferred embodiment of the present invention. 15 is a view showing the side of a concrete layer on which construction has been completed according to a preferred embodiment of the present invention.

First, referring to Figures 10 and 11, concrete materials, that is, cement, fine aggregate (sand), coarse aggregate (gravel), and water, were mixed at a ratio of 1: 2: 4: 0.2. Then, sufficiently mixed concrete was poured at the construction location to form a concrete layer. At this time, in order to measure inter-floor noise, a sample frame with a width of 100 cm, a length of 100 cm, and a depth of 25.5 cm was manufactured as shown in Figure 9, and the sample frame was set as the construction location. In the specimen frame, reinforcing bars were arranged crosswise at a width of 10 cm and a height of 10 cm, and were arranged in two rows, each 5 cm apart when viewed from the top. Considering the concrete pouring depth of 21cm, rebar was installed at the bottom 3cm, the middle 15cm, and the top 3cm.

Thereafter, referring to FIG. 12, after the concrete was poured at the construction location, sufficient vibration was applied to the concrete layer using the vibrator 10 to increase the density of the concrete.

Afterwards, referring to Figure 13, grading work was performed to flatten the surface of the concrete layer (A), and referring to Figure 14, the concrete layer (A) that completed the grading work was cured, but during this process, the surface was dried. To prevent this, water was sprayed on the surface of the concrete layer (A) once a day for 30 days. And after the curing construction was completed, the foam frame was dismantled to complete the concrete layer (A). It can be seen that the thickness of the concrete layer (A) was built at a final thickness of 21.5cm as a result of adding 1cm to the regular stone pouring (22cm), applying vibration, and curing. We were able to secure a concrete layer (A) with a thickness of 21.5cm, which is 0.5cm more than the construction target of 21cm.

Finally, referring to FIG. 15, the concrete layer (A) of the present invention was vibrated by a vibrator to increase the density after pouring the concrete at the construction location, so the concrete layer (A) No air layer due to blisters can be found inside, and you can tell that it is solid with the naked eye.

Figure 16 is a diagram showing a sample frame for constructing a comparative concrete layer for comparison with the concrete layer of the present invention, Figure 17 is a diagram showing a comparative concrete layer for comparison with the concrete layer of the present invention, and Figure 18 is a diagram showing the comparative concrete layer for comparison with the concrete layer of the present invention. This is a drawing showing the side of a comparative concrete layer for comparison with the concrete layer of the invention.

Referring to Figures 16 and 17, the comparative concrete layer (B: shown in Figure 17) for comparison with the concrete layer of the present invention is constructed in the same manner as the concrete layer of the present invention except that the vibration step is removed in the present invention. . That is, the mixed concrete is poured into the sample frame of FIG. 16, and the poured concrete goes through a grading and curing process, and then the sample frame is dismantled and constructed as a comparative concrete layer (B).

Finally, referring to FIG. 18, the comparative concrete layer (B) did not undergo vibration construction to increase density after pouring the concrete at the construction location, and an air layer was formed due to blisters inside the comparative concrete layer (B). You can see that it has been done. This air layer has the problem of accompanying a resonance phenomenon when the cause of inter-floor noise occurs.

Hereinafter, the results of comparing the inter-floor noise wavelength of a concrete layer constructed by the construction method of a building concrete layer according to a preferred embodiment of the present invention and a comparative concrete layer constructed by a general method will be described.

Figures 19 and 20 are diagrams showing the results of measuring noise applied to a concrete layer constructed by the method of constructing a concrete layer for a building according to a preferred embodiment of the present invention using different smartphones.

Referring to Figure 19, the experimenter applied an impact to the concrete layer (A: shown in Figure 15) of the present invention by forcefully hitting it with a 1KG hammer. Afterwards, Samsung's Galaxy Note 20 smartphone was brought into contact with the concrete layer (A) to measure the noise applied to the concrete layer (A). Looking at the measurement results, it can be seen that the noise applied to the concrete layer (A) is a small noise similar to that of hitting a rock with high density.

Referring to Figure 20, the experimenter applied an impact to the concrete layer (A: shown in Figure 15) of the present invention by forcefully hitting it with a 1KG hammer. Afterwards, Apple's iPhone 11 Pro smartphone was brought into contact with the concrete layer (A) to measure the noise applied to the concrete layer (A). Looking at the measurement results, it can be seen that the noise applied to the concrete layer (A) is a small noise similar to that of hitting a rock with high density.

In this way, the present invention applies vibration using a vibrator in the process of constructing the concrete layer (A), so that an air layer due to water bubbles is not formed inside the concrete, so that the density is increased, and accordingly, the concrete layer (A) of the present invention is formed. ) is judged to not generate noise between floors because the resonance phenomenon caused by the air layer does not occur.

Figures 21 and 22 are diagrams showing the results of measuring noise applied to a comparative concrete layer for comparison with the concrete layer of the present invention using different smartphones.

Referring to Figure 21, the experimenter applied an impact to the comparison concrete layer (B: shown in Figure 18) by forcefully hitting it with a 1KG hammer. Afterwards, Samsung's Galaxy Note 20 smartphone was brought into contact with the comparative concrete layer (B) to measure the noise applied to the comparative concrete layer (B). Looking at the measurement results, it can be seen that the noise applied to the comparative concrete layer (B) is a mid-low sound similar to the sound of a drum.

Referring to Figure 22, the experimenter applied an impact to the comparison concrete layer (B: shown in Figure 18) by forcefully hitting it with a 1KG hammer. Afterwards, Apple's iPhone 11 Pro smartphone was brought into contact with the comparative concrete layer (B) to measure the noise applied to the comparative concrete layer (B). Looking at the measurement results, it can be seen that the noise applied to the comparative concrete layer (B) is a mid-low sound similar to the sound of a drum.

In this way, since the process of applying vibration using a vibrator was omitted during the construction process of the comparative concrete layer (B), an air layer is formed due to water bubbles inside the concrete, so that the density is lowered. Accordingly, the comparative concrete layer (B) is formed in the air layer. It is believed that a resonance phenomenon occurs due to this, resulting in noise between floors.

Although the present invention has been described in detail in the above embodiments, it is obvious that the present invention is not limited thereto, and it is clear to those skilled in the art that various changes and modifications are possible within the scope of the technical idea of the present invention, and such changes and modifications are attached. If it falls within the scope of the claims, the technical idea should also be considered as belonging to the present invention.

10: Vibrator
100: concrete layer 110: rebar
200: gravel layer 210: wire mesh
220: hot water pipe 300: bottom layer

Claims (8)

In the slab structure for buildings,
A concrete layer constructed by mixing concrete materials;
A hot water pipe installed in a zigzag shape on top of the concrete layer;
A gravel layer formed by placing gravel on the upper part of the concrete layer where the hot water pipe is installed; and
A slab structure for buildings having a gravel layer, characterized in that it includes a bottom layer constructed on top of the gravel layer.
According to claim 1,
A slab structure for buildings having a gravel layer, characterized in that the diameter of the gravel is 25 mm to 40 mm.
According to claim 1,
A slab structure for buildings having a gravel layer, characterized in that a wire mesh is installed between the concrete layer and the hot water pipe.
According to claim 1,
A slab structure for a building having a gravel layer, characterized in that when hot water is supplied to the hot water pipe, the heat energy of the hot water is conducted to gravel in contact with the hot water pipe.
In the construction method of a building slab structure,
Concrete layer construction process of mixing concrete materials to construct a concrete layer;
A hot water pipe installation process of installing hot water pipes in a zigzag shape on top of the concrete layer;
A gravel layer construction process of constructing a gravel layer by laying gravel on the upper part of the concrete layer where the hot water pipe is installed; and
A method of constructing a slab structure for a building having a gravel layer, comprising a bottom layer construction process of constructing a bottom layer on top of the gravel layer.
According to claim 5,
During the gravel layer construction process,
A method of constructing a slab structure for a building having a gravel layer, characterized in that the diameter of the gravel is 25 mm to 40 mm.
According to claim 5,
Between the concrete layer construction process and the hot water pipe installation process,
Further comprising a wire mesh installation process of installing a wire mesh on the upper part of the concrete layer,
In the process of installing the hot water pipe, a method of constructing a slab structure for a building having a gravel layer, characterized in that installing a hot water pipe on the upper part of the wire mesh.
According to claim 5,
The concrete layer construction process is:
Mixing step of mixing concrete materials:
A pouring step of pouring the mixed concrete at the construction location to form a concrete layer;
A vibration step of applying vibration to the concrete layer using a vibrator; and
A method of constructing a slab structure for a building with a gravel layer, comprising a curing step of curing the concrete layer.

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