KR102380357B1 - Double floor structure system to reduce inter-floor noise with vibration control anchor bolts - Google Patents

Abstract

The present invention relates to a double-floor structure system for reducing a noise between floors having a vibration control anchor bolt. More specifically, the present invention relates to the double-floor structure system for reducing the noise between floors having the vibration control anchor bolt, in consideration of vibration suppression using a member supporting an upper floor slab and a natural vibration ratio of a lower floor slab. To this end, the present invention provides the double-floor structure system for reducing the noise between the floors having the vibration control anchor bolt, comprising: an upper floor slab; a lower floor slab; and the vibration control anchor bolt.

Description

{Double floor structure system to reduce inter-floor noise with vibration control anchor bolts}

The present invention relates to a double-floor structure system for reducing noise between floors having a vibration control anchor bolt. More specifically, by making a groove in the lower floor slab to secure a space to install a member supporting the upper floor slab (floating floor slab), the upper floor slab (floating floor slab) is slab), and by using the space secured through the grooves made in the lower floor slab, the vibrations generated in the upper floor slab (floating floor slab) are transmitted to the wall as much as possible, and the vibration generated in the upper floor slab (floating floor slab) is By preventing the impact and vibration from being transmitted directly to the lower floor slab, it is possible to effectively reduce inter-floor noise (especially heavy impact sound), and a member supporting the upper floor slab by providing an anchor bolt to control the upper vibration of the upper floor slab. And it relates to a double floor structure system for reducing noise between floors equipped with a vibration control anchor bolt considering vibration suppression using the natural vibration resistance of the lower floor slab.

MDUs have structural characteristics that are vulnerable to noise damage because many parts, such as the boundary wall and floor structure, are shared with neighboring households. In particular, the floor impact noise generated by the upper household accounts for the largest portion of inter-floor noise complaints, and it is a social task that needs to be addressed first.

Inter-floor noise (層間 騷音) is noise pollution mainly generated in multi-family houses or apartments. Inter-floor noise is a generic term for toilet water, floor impact sound, piano sound, audio sound, dialogue sound, and TV sound. are classified

In the past, life focused on single-family houses, but today, as multi-unit houses such as apartments become common, problems began to emerge.

In particular, among floor noise, floor impact sound generated by a direct impact on the concrete surface has the property of being easily transmitted to adjacent households. These noises are mainly the sounds of children running upstairs and downstairs, and the sounds of objects being dragged or dropped. Like other noise pollution, inter-floor noise has a bad effect on mental and physical health, and as a result, it is emerging as a social problem such as many problems and complaints between neighbors.

The noise generated by the impact applied to the floor slab when a person walks, moves an object, or an object falls as a source of impact in an apartment building is called a heavy impact sound.

Heavy impact sound is a solid propagation sound generated by vibration of a structure caused by an impact applied to the floor slab (structure), which is a sound in the low frequency band.

The heavy impact sound generated by the vibration of the structure lingers for a long time and causes severe discomfort, which is the main cause of noise between floors.

Among the methods to reduce such a weight impact sound, a structural approach is to adjust the stiffness (or weight) of the floor slab (structure) to change the frequency band of the noise.

In the past, there have been attempts to reduce the impact sound by changing the natural frequency of the floor slab (structure) by various methods, but it is possible to dramatically change the frequency by giving large changes in stiffness and weight within limited conditions (thickness range of structures and finishing materials). Giving is limited.

On the other hand, there is a method of dispersing the impact force by forming a floating floor structure (double floor structure) in a way that effectively reduces the response to vibration of the floor slab (structure) without changing the stiffness and weight of the floor slab (structure). This method is known to have a higher noise-blocking effect than other methods. However, in order to form a floating floor so that the impact load is not directly transmitted to the floor slab, a structural member supporting the floating floor must be formed. there is.

In addition, in order to prevent noise between floors in such a multi-layer structure, a conventional interlayer structure is constructed by arranging an insulating material on a floor slab, pouring lightweight foam concrete thereon, and laminating a finishing mortar and a floor finishing material.

However, since such lightweight foamed concrete is usually poured at the construction site, it is difficult to maintain uniform quality, and it takes time to pour, which makes it difficult to shorten the construction period.

In addition, such a conventional interlayer structure has a problem in that the effect of preventing interlayer noise is not obtained satisfactorily.

Prior art literature: KR Registered Patent Publication No. 10-0818161 (2008.03.31. Announcement)

The present invention was devised to solve the above problems, and by digging grooves at regular intervals in the lower floor slab, a support member for installing the upper floor slab (floating floor slab) separated from the lower floor slab can be interpolated. It is possible to form a double-floor structure completely isolated from the floor structure without changing the existing finish thickness, and provides a double-floor structure system for reducing noise between floors equipped with vibration control anchor bolts to suppress vibration of the upper floor slab It is intended to

The double-floor structure system for inter-floor noise reduction provided with vibration control anchor bolts according to the present invention devised to achieve the above object is located between one wall and the other wall with a plurality of them spaced apart at a predetermined interval, and the impact caused by the load A deck plate support member capable of dispersing and transmitting The upper floor slab is composed of a material capable of absorbing shock and vibration, the upper end is in contact with the deck plate support member, and the lower end is in contact with the floor slab to include a shock absorber that absorbs the shock and vibration of the deck plate support member; A lower floor slab having a groove for installing the deck plate support member; and a vibration control anchor bolt capable of restraining the upward vibration of the deck plate support member, wherein the vibration control anchor bolt can be fixed to the longitudinal center of the groove for installing the deck plate support member of the lower floor slab. those in which the part is formed; In the longitudinal central portion of the deck plate support member, the vibration control anchor bolt is interpolated and an anchor bolt interpolation portion that can penetrate is formed; And the vibration control anchor bolts include those that can be fixed to the anchor bolt fixing portion of the lower floor slab through the anchor bolt insertion portion formed on the deck plate.

In addition, the impact cushioning material has a height, and the upper end is in contact with the deck plate support member, and the lower end is in contact with the floor slab, so that the deck plate is spaced apart from the upper side of the lower floor slab by a predetermined interval in the height direction by the impact cushioning material. capable of being located; And the deck plate further includes a deck plate fixing portion is formed at both ends coupled to the deck plate support member, which can be positioned at a predetermined distance in the height direction on the upper side of the lower floor slab through the fixing portion.

In addition, it is combined with the deck plate support member further comprises a load distribution member capable of dispersing the shock and vibration transmitted by the load distribution member deck plate support member, the load distribution member is at the front end and rear end of both sides of the deck plate support member It further includes each coupled and between the load distributing member and the lower floor slab, an impact shock absorber having a height formed therein so that the load distributing member can be positioned at an upper side of the floor slab at a predetermined interval in the height direction. .

According to the present invention, the upper floor slab (floating floor slab) completely separated from the lower floor slab is formed without changing the finished thickness, and the impact force applied from the upper floor slab (floating floor slab), especially, is applied from the center of the floor slab. The impact force is not transmitted directly to the lower floor slab, but is dispersed toward the wall, and the vibration (displacement response) of the lower floor slab that causes inter-floor noise is greatly reduced. there is

In addition, the wall and the upper floor slab (floating floor slab) are insulated so that the vibration generated from the upper floor slab (floating floor slab) is not transmitted to the wall, so that the vibration generated in the upper floor slab (floating floor slab) passes through the wall to the lower floor. And it has the effect of not being transferred to the upper layer.

In addition, there is an effect that can reduce the vibration that may occur in the upper floor slab by using the difference in natural frequencies between the deck plate support member and the lower floor slab by providing the vibration control anchor bolts.

1 is a view showing the load distribution principle of a double-floor structure system for reducing inter-floor noise with a vibration control anchor bolt according to a preferred embodiment of the present invention;
2 is a view showing a formwork installation step, a reinforcement reinforcement step, a Styrofoam installation step, a concrete pouring step, and a Styrofoam removal step among the installation methods of a double-floor structure system for reducing noise between floors with vibration control anchor bolts;
3 is a view showing a support member installation step, a deck plate installation step, and a finishing step among the installation methods of a double floor structure system for reducing noise between floors having a vibration control anchor bolt;
Figure 4 is a flow chart showing the sequence of the installation method of the double-floor structure system for reducing noise between floors provided with a vibration control anchor bolt;
5 is a view showing the displacement change according to the impact load applied position;
Figure 6 is a plan view of the deck plate support member, the shock absorber is installed,
7 is a plan view in which the deck plate is installed in FIG. 6;
Fig. 8 is a cross-sectional view in the longitudinal direction of Fig. 7;
9 is a plan view in which a deck plate support member, a shock absorber and a load distribution member are installed;
Figure 10 is a plan view in which the deck plate is installed in Figure 9;
11 is a cross-sectional view in the longitudinal direction of FIG. 10;
12 is a plan view in which the deck plate support member, the shock absorber and the load distribution member are installed;
13 is a plan view in which the deck plate is installed in FIG. 12;
14 is a cross-sectional view in the longitudinal direction of FIG. 13;
15 is a cross-sectional view in the width direction of FIGS. 7, 10, and 13;
16 is a cross-sectional view in the width direction of the deck plate of FIGS. 7, 10 and 13;
17 is a view three-dimensionally illustrating a load distribution principle.
18 is a view showing a first embodiment of the deck plate support member and the deck plate bonding method;
19 is a view showing a second embodiment of the deck plate support member and the deck plate bonding method;
20 is a view showing a third embodiment of the deck plate support member and the deck plate bonding method;
21 is a view showing a fourth embodiment of the deck plate support member and the deck plate bonding method;
22 is a view showing a fifth embodiment of the deck plate support member and the deck plate bonding method;
23 is a view showing a sixth embodiment of the deck plate support member and the deck plate joining method;
24 is a view showing a seventh embodiment of the deck plate support member and the deck plate bonding method.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. First of all, it should be noted that in adding reference numerals to the components of each drawing, the same components are given the same reference numerals as much as possible even though they are indicated on different drawings. In addition, in describing the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted. In addition, preferred embodiments of the present invention will be described below, but the technical spirit of the present invention is not limited thereto and may be variously implemented by those skilled in the art without being limited thereto.

1 is a view showing the load distribution principle of a double-floor structure system for reducing inter-floor noise with vibration control anchor bolts according to a preferred embodiment of the present invention, and FIG. 2 is for reducing inter-floor noise with vibration control anchor bolts Among the installation methods of the double floor structure system, a view showing the formwork installation step, the reinforcement reinforcement step, the Styrofoam installation step, the concrete pouring step and the Styrofoam removal step, FIG. 3 is a double floor structure for reducing noise between floors with vibration control anchor bolts A view showing the support member installation step, the deck plate installation step and the finishing step among the installation methods of the system, FIG. 4 is a flow chart showing the sequence of the installation method of the double floor structure system for reducing noise between floors with vibration control anchor bolts, 5 is a view showing the displacement change according to the impact load applied position, FIG. 6 is a plan view where the deck plate support member and the shock absorber are installed, FIG. 7 is a plan view where the deck plate is installed in FIG. 6, FIG. 8 is the longitudinal direction of FIG. of the sectional view, FIG. 9 is a plan view in which a deck plate support member, a shock absorber and a load distribution member are installed, FIG. 10 is a plan view in which the deck plate is installed in FIG. 9, FIG. 11 is a cross-sectional view in the longitudinal direction of FIG. A plan view in which the member, the shock absorber and the load distribution member are installed, FIG. 13 is a plan view in which the deck plate is installed in FIG. 12, FIG. 14 is a longitudinal cross-sectional view of FIG. 13, and FIG. 15 is the width direction of FIGS. Fig. 16 is a cross-sectional view in the width direction of the deck plate of Figs. 7, 10 and 13, Fig. 17 is a three-dimensional view showing the load distribution principle, Fig. 18 is the first implementation of the deck plate support member and deck plate joining method Figure 19 is a view showing a second embodiment of the deck plate support member and the deck plate joining method, Figure 20 is a view showing a third embodiment of the deck plate support member and the deck plate joining method, 21 is a view showing a fourth embodiment of a deck plate support member and a deck plate joining method, FIG. 22 is a view showing a fifth embodiment of a deck plate support member and a deck plate joining method, and FIG. 23 is a deck plate support A view showing a sixth embodiment of a member and a deck plate joining method, FIG. 24 is a deck plate It is a view showing a seventh embodiment of the rate support member and the deck plate bonding method.

A characteristic of the present invention is to form a double floor slab structure of the lower floor slab and the upper floor slab (floating floor slab) separated from the lower floor slab without changing the existing finish thickness by making a groove in the lower floor slab, thereby forming the upper floor slab (floating floor). The vibration generated in the slab) and the resulting noise are not transmitted to the lower floor to prevent inter-floor noise, and the upper floor slab (float slab) is equipped with vibration control anchor bolts and uses the difference in natural frequencies between the deck plate support member and the lower floor slab. It is to reduce the vibration that may occur in the floor slab).

6 to 17, the double floor structure system for reducing noise between floors provided with vibration control anchor bolts according to a preferred embodiment of the present invention is an upper floor slab 100, a vibration anchor bolt 150 and a lower floor It is composed of a slab 200 , and the upper floor slab 100 includes a deck plate support member 110 , a deck plate 120 , and a shock absorber 130 .

Hereinafter, the components of a double-floor structure system for reducing inter-floor noise having a vibration control anchor bolt according to a preferred embodiment of the present invention will be described in detail.

The deck plate support member 110 is installed between the wall and the wall of the space where the double-floor structure of the present invention will be installed.

The deck plate support member 110 functions to transmit the shock and vibration caused by the load toward the wall as much as possible, and a plurality of them may be installed to be spaced apart from each other at a predetermined interval between one wall and the other wall.

In the central part of the deck plate support member 110, an anchor bolt interpolation part into which the vibration control anchor bolt can be interpolated is formed, and the anchor bolt is interpolated in the anchor bolt interpolation part to restrain the upward vibration of the deck plate support member 110. can

The deck plate 120 is coupled between the wall and each deck plate support member 110 positioned spaced apart from the wall, and the shock and vibration caused by the load can be transmitted and distributed to the deck plate support member 110. .

The deck plate 120 may be positioned on the upper side of the lower floor slab 200 by the deck plate support member 110 at predetermined intervals in the height direction.

More specifically, the deck plate 120 is fixed in height by the deck plate fixing part 121, and referring to FIG. 18, the deck plate fixing part may be formed on the deck plate support member, and referring to FIG. 21 , , the deck plate fixing part may be formed on the deck plate in a protruding shape, and referring to FIG. 19, without a separate deck plate fixing part, the lower side of the deck plate may be fixed in such a way that it is in contact with the upper side of the deck plate support member, , 21, 22, 23, the deck plate fixing part can form a protrusion on the deck plate support member to fix the position of the deck plate, and referring to Figure 24, the upper surface of the deck plate support member is closed It is not open, so it can be formed in a structure that a finishing member including concrete can enter into the interior of the deck plate support member, and the deck plate fixing part can be formed outside the upper surface of the open deck plate support member. .

18 to 24 show various embodiments of fixing the deck plate to the deck plate support member, the deck plate fixing method is not limited by these embodiments, and work including constructability and ease of manufacture (economical) It can be applied with various modifications considering the environment.

As one of the representative embodiments for fixing the deck plate, as shown in FIG. 18, when the deck plate fixing part 121 is formed on the deck plate 120, both side cross-sections coupled with the deck plate support member 110 The deck plate fixing part 121 is formed, the deck plate fixing part 121 is formed to protrude from the upper part of the deck plate 120, and the lower surface of the deck plate fixing part 121 is a deck plate support member. In contact with the upper surface of the 110, the deck plate 120 may be located on the upper side of the lower floor slab 200 spaced apart by a predetermined interval in the height direction.

As another representative embodiment for fixing the deck plate, the deck plate fixing part 121 is not formed on the deck plate 120, but on the deck plate support member 110 as shown in FIG. 19. When the deck plate fixing part 121 is formed on the deck plate support member 110, it is formed to protrude from the center of the deck plate support member 110, and the upper surface of the deck plate fixing part 121 and the deck plate 120. The lower surface of the deck plate 120 is in contact with the upper side of the lower floor slab 200 may be located spaced apart a predetermined distance in the height direction.

In addition, referring to FIG. 20, when there is no deck plate fixing part, the shape of the deck plate support member may be formed to have a low height and a wide width, and the lower surface of the deck plate and the upper surface of the deck plate support member are in contact Thus, the deck plate 120 may be spaced apart from each other by a predetermined interval in the height direction on the upper side of the lower floor slab 200, and in this case, a plurality of deck plate support members may be located on the upper side of the deck plate support member, The deck plate positioned on the upper side of the deck plate support member may be connected to each other.

In addition, referring to FIG. 21 , the deck plate fixing part may be formed to protrude from the upper surface of the deck plate support member, and the height at which the deck plate fixing part protrudes corresponds to the deck plate height, and the lower surface of the deck plate is the deck plate It is in contact with the upper surface of the support member, and one side of the deck plate is in contact with one side of the deck plate fixing part, so that the deck plate may be located at a predetermined distance in the height direction above the lower floor slab.

In addition, referring to FIG. 22, the deck plate fixing part may be formed to protrude in a 'T' shape from the upper surface of the deck plate support member, and the height at which the deck plate fixing part protrudes corresponds to the deck plate height, and the deck plate The lower surface of the deck plate is in contact with the upper surface of the deck plate support member, and the upper end of the deck plate side and the upper part of the deck plate support member are in contact, so that the deck plate is spaced apart from the upper side of the lower floor slab by a predetermined distance in the height direction.

In addition, referring to FIG. 23, the deck plate fixing part may be formed to protrude in a 'T' shape from the upper side of the deck plate support member, and the height at which the deck plate fixing part protrudes is the height at which the finishing material including the concrete will be constructed. Correspondingly, the lower surface of the deck plate is in contact with the upper surface of the deck plate support member, so that the deck plate is located on the upper side of the lower floor slab at a predetermined distance in the height direction. A finishing material may be drawn in to fix the position of the deck plate.

In addition, referring to FIG. 24 , the upper surface of the deck plate support member is not closed, but is open, so it can be formed in a structure in which a finishing member including concrete can enter the interior of the deck plate support member, and the deck plate is fixed The part may be formed outside the upper surface of the open deck plate support member, and the lower end surface of the deck plate is in contact with the upper surface of the deck plate fixing part and is spaced apart from each other by a predetermined distance in the height direction on the upper side of the lower floor slab, A finishing member including concrete is inserted between the deck plates and the deck plate support member, so that the position of the deck plate can be fixed.

18 to 24 show examples in which the deck plate is in contact with the deck plate support member, and the deck plate can be positioned at a predetermined distance in the height direction on the upper side of the lower floor slab. A method that can be placed in contact with the upper side of the lower floor slab at a predetermined interval in the height direction can be applied with various modifications in consideration of constructability and economic feasibility, and FIGS. 18 to 24 are for limiting this deck plate bonding method. It is not intended to be interpreted as being limited thereto, rather, it is intended to be described by way of example.

The shock absorber 130 is made of a material capable of absorbing shock and vibration including silicon, and the upper surface of the shock absorber 130 is in contact with the deck plate support member 110, and the lower surface is the lower floor slab 200 ) and can absorb the shock and vibration of the deck plate support member 110 in contact.

In addition, the shock absorber 130 has a height, and the upper and lower surfaces are in contact with the deck plate support member 110 and the lower floor slab 200, respectively, so that the deck plate support member 110 is a shock absorber ( 130), it may be located on the upper side of the lower floor slab 200 spaced apart from each other by a predetermined interval in the height direction.

The deck plate support member 110 is spaced apart in the height direction on the upper side of the lower floor slab 200 and cannot use a member with high rigidity due to spatial restrictions, so the natural frequency of the primary vibration mode is about 6 to 10 Hz, and when the natural frequency is 6 Hz or less, an impact load and resonance due to a fast walking of a person may occur, and noise may be amplified and unpleasant sensation may be felt.

Typically, the primary vibration mode natural frequency of the lower floor slab made of reinforced concrete material is formed around 30 Hz, so that the ratio of the natural frequencies of the deck plate support member 110 and the lower floor slab is three times or more different.

When the natural frequency ratio between the vibration source and the structure differs by more than 2 times, interference occurs and the amplitude decreases. Using this principle, the impact load applied to the deck plate and the deck plate support member is Install the vibration control anchor bolts that can restrain the vibration of the deck plate support member and the lower floor slab without being transmitted to the slab.

When the vibration control anchor bolt is installed, downward vibration is not constrained, but upward vibration is constrained. effect occurs.

In addition, if the impact at regular intervals on the upper slab (floating slab) is repeated, the upper slab (floating slab) may vibrate. can be prevented

The lower floor slab 200 has a groove 210 for installing the deck plate support member 110, and an anchor bolt fixing part to which the vibration control anchor bolt can be fixed is formed in the center of each groove 210, The anchor bolt interpolated into the anchor bolt interpolation part of the deck plate support member may be fixed to the anchor bolt fixing part of the lower floor slab through the deck plate support member through the anchor bolt interpolation part of the deck plate support member.

When the anchor bolt penetrates the deck plate support member and is fixed to the anchor bolt fixing part of the lower floor slab, the vibration of the deck plate support member is restrained in the upward direction, thereby reducing the amplitude by vibrating downward.

In terms of strength, the thickness of the lower floor slab 200 is sufficient if 150 to 180 mm, but the standard floor slab thickness suggested in the 'Recognition and management standards for floor impact sound blocking structures for apartment houses' announced by the Ministry of Land, Infrastructure and Transport under the current laws and regulations is to be constructed at 210 mm. there is.

When the thickness of the lower floor slab 200 is constructed to 210 mm, there is a margin in terms of strength. .

In the lower floor slab 200 of the present invention, a support member capable of supporting the upper floor slab 100 can be interpolated into the groove, so that a double floor structure completely isolated from the existing floor structure without changing the existing finished thickness has the advantage of being able to form

In addition, a plurality of grooves 210 for installing the deck plate support member are formed in the lower floor slab 200 so that the deck plate support member supports the upper floor slab 100, so that the lower floor slab 200 bears Since the load is reduced, it is possible to reduce the thickness of the lower floor slab 200 in terms of strength. This has the effect of reducing the weight of the overall structure.

The load distribution member 140 is coupled with the deck plate support member 110 to distribute the shock and vibration transmitted by the deck plate support member 110 .

In addition, the load distributing member 140 may be coupled to the front end and the rear end of both sides of the deck plate support member 110, respectively, and the lower side of the load distributing member 140 is provided with a height-formed shock absorber to distribute the load. The members 140 may be positioned on the upper side of the lower floor slab 200 to be spaced apart from each other by a predetermined interval in the height direction.

The vibration control anchor bolt 150 may be fixed to the vibration control anchor bolt fixing part of the lower floor slab by passing through the anchor bolt insertion part formed in the longitudinal central part of the deck plate support member 110 .

The upper floor slab 100 and the lower floor slab 200 including the deck plate support member 110, the load distribution member 140 and the deck plate 120 are not in direct contact, and the upper floor slab 100 and the lower The impact cushioning material 130 is located between the floor slabs 200, and when an impact load and vibration are generated in the upper floor slab 100, the impact load and vibration are absorbed by the impact buffer material, and the resulting noise is transmitted to the lower floor. It is not transmitted, and the vibration control anchor bolt 150 restrains the upper vibration of the deck plate support member 110 to reduce the ratio of the natural frequencies of the deck plate support member 110 and the lower floor slab to reduce the noise between floors. can

Hereinafter, the principle of noise reduction between floors of the double floor structure system for reducing noise between floors according to the present invention will be described in detail.

Even if the impact load applied to the floor is the same, the response magnitude varies depending on the location where the impact load is applied.

Referring to FIG. 5 , under the same load conditions, the largest displacement occurs at the center of the floor slab, and the magnitude of the displacement decreases toward the end (wall). That is, the closer to the end direction of the floor slab, the greater the rigidity is, so that the amount of displacement is reduced.

The floor structure according to the present invention forms a double floor so that the impact applied from the upper floor slab (floating floor slab) acts on the end of the lower floor slab, thereby increasing the stiffness according to the change in the load point, thereby reducing the amplitude of the floor As a result, the wave of the air is also reduced, which can exert the effect of reducing noise.

That is, the deck plate support member and the deck plate of the upper floor slab (floating floor slab) are located above the lower floor slab (floating floor slab) at a predetermined interval in the height direction, so that the upper floor slab (floating floor slab) and the lower floor An empty space is formed between the slabs to prevent the vibration and impact of the upper floor slab (floating floor slab) from being transmitted to the lower floor slab.

In addition, the shock absorber positioned between the deck plate support member and the lower floor slab is provided at both ends of the deck plate support member, and the space between the upper floor slab (floating floor slab) and the lower floor slab is equal to the height of the shock absorber. can be formed.

The shock absorber comprises a vertical shock absorber in contact with the lower surface of the deck plate support member and a side shock absorber in contact with the side surface of the deck plate support member.

The vertical shock absorber can reduce the impact load of the upper floor slab (floating floor slab) and the resulting vibrations are transmitted to the lower floor slab. It is possible to prevent vibration from being transmitted to the wall.

Therefore, the impact load of the upper floor slab (floating floor slab) and the resulting vibration are transmitted to the end (wall) by the deck plate and the deck plate support member, and the impact and vibration transmitted to the end is a vertical shock absorber and a side shock absorber It has an effect of preventing the transmission of noise due to impact and vibration to the upper floor as well as the lower floor as it is absorbed by the floor slab and not transmitted to the wall.

Conventionally, when a space is formed between the upper floor slab (floating floor slab) and the lower floor slab in a double-floor structure, the overall thickness of the floor slab becomes thick, which is uneconomical.

The present invention forms a double floor slab in order to solve this problem, but forms a groove in the lower floor slab into which the deck plate support member supporting the upper floor slab (floating floor slab) can be interpolated to change the overall floor slab thickness It has the advantage of being able to form a completely isolated double-floor structure.

Hereinafter, a construction method of a double-floor structure system for reducing noise between floors according to a preferred embodiment of the present invention will be described.

Referring to FIG. 4 for the construction method of the double-floor structure system for reducing inter-floor noise, the formwork installation step (S100), the rebar reinforcement step (S200). Styrofoam installation step (S300), concrete pouring step (S400), Styrofoam removal step (S500), supporting member installation step (S600), deck plate installation step (S700), and finishing step (S800) are made, including.

2, in the formwork installation step (S100), a concrete formwork is installed at a place where a double-floor structure system for inter-floor noise reduction is to be installed.

In the reinforcing reinforcement step (S200), the reinforcing bars to be located inside the concrete are placed on the upper side of the formwork.

In the Styrofoam installation step (S300), Styrofoam corresponding to the size of the deck plate support member is installed at a place where the deck plate support member is to be installed.

In the concrete pouring step (S400), reinforcing bars are reinforced, and concrete is poured into the formwork installed with Styrofoam.

In the Styrofoam removal step (S500), the Styrofoam installed after the concrete poured in the concrete pouring step (S400) is hardened is removed. When the Styrofoam is removed, a groove corresponding to the shape of the Styrofoam is formed in the concrete.

Referring to Figure 3, in the support member installation step (S600), a shock buffer material is installed at each support point in the groove formed by removing the Styrofoam, and then the deck plate support member is inserted, and the anchor bolt formed in the center of the deck plate support member is interpolated. Insert the anchor bolt through the part and fix it to the anchor bolt fixing part formed in the lower floor slab through the deck plate support member.

In the deck plate installation step (S700), a deck plate is installed between each deck plate support member.

In the finishing step (S800), a hot water pipe is installed on the upper deck plate and a finishing mortar is poured to finish the floor.

In the construction method of a double-floor structure system for reducing noise between floors according to a preferred embodiment of the present invention, a groove for installing the deck plate support member into which the deck plate support member is inserted can be simply formed through the installation and removal of Styrofoam. .

The above description is merely illustrative of the technical idea of the present invention, and those of ordinary skill in the art to which the present invention pertains may make various modifications, changes and substitutions within the scope without departing from the essential characteristics of the present invention. will be. Accordingly, the embodiments disclosed in the present invention and the accompanying drawings are for explaining, not limiting, the technical spirit of the present invention, and the scope of the technical spirit of the present invention is not limited by these embodiments and the accompanying drawings . The protection scope of the present invention should be construed by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

100 - upper floor slab 110 - deck plate support member
120 - Deckplate 130 - Shock Absorber
140 - load distribution member 150 - vibration control anchor bolt
200 - lower floor slab

Claims (3)

A deck plate support member capable of distributing and transmitting an impact caused by a load by placing a plurality of them spaced apart at a predetermined interval between one wall and the other wall;
A deck plate coupled between the deck plate support member and the deck plate support member and capable of transmitting and distributing shock and vibration caused by a load to the deck plate support member, and
It is composed of a material that can absorb shock and vibration including silicon, and the upper part is in contact with the deck plate support member, and the lower part is in contact with the floor slab to absorb the shock and vibration of the deck plate support member.
An upper floor slab comprising;
A lower floor slab having a groove for installing the deck plate support member; and
Vibration control anchor bolt that can restrain the upward vibration of the deck plate support member
including,
In the longitudinal center of the groove for installing the deck plate support member of the lower floor slab, an anchor bolt fixing part to which the vibration control anchor bolt can be fixed is formed;
In the longitudinal central portion of the deck plate support member, the vibration control anchor bolt is interpolated to form an anchor bolt interpolation portion that can penetrate; and
Vibration control anchor bolts that can be fixed to the anchor bolt fixing portion of the lower floor slab through the anchor bolt insertion portion formed in the deck plate support member
including,
When the anchor bolt penetrates the deck plate support member and is fixed to the anchor bolt fixing part of the lower floor slab, the vibration of the deck plate support member is restricted to the upper side and vibrates only downward. ;
The shock absorber includes a vertical shock absorber in contact with the lower surface of the deck plate support member and a side shock absorber in contact with the side of the deck plate support member. Prevents transmission to the floor slab, and the side impact shock absorber can prevent the impact load of the upper floor slab and the resulting vibration from being transmitted to the wall; and
The shock absorber is provided at both ends of the deck plate support member, and a space can be formed between the upper floor slab and the lower floor slab as much as the height of the shock absorber.
Double floor structure system for reducing noise between floors with vibration control anchor bolts including According to claim 1,
The impact cushioning material has a height, and the upper end is in contact with the deck plate support member, and the lower end is in contact with the floor slab, so that the deck plate is spaced apart from the upper side of the lower floor slab by a predetermined distance in the height direction by the impact cushioning material. can; and
When the deck plate is combined with the deck plate support member,
Deck plates that can be located on the upper side of the lower floor slab at a predetermined distance in the height direction
Further comprising, a double-floor structure system for reducing noise between floors having a vibration control anchor bolt. According to claim 1,
A load distribution member that is combined with the deck plate support member to distribute the shock and vibration transmitted by the deck plate support member
further comprising,
The load distribution member is coupled to the front end and the rear end of both sides of the deck plate support member, respectively, and
Between the load distributing member and the lower floor slab, an impact shock absorber with a height formed therein is positioned so that the load distributing member can be located above the floor slab at a predetermined distance in the height direction
Including, a double-floor structure system for reducing noise between floors with a vibration control anchor bolt.

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