KR20210080284A - Manufacturing method for a panel for interlayer sound insulation - Google Patents

Abstract

In accordance with the present invention, an independent panel for inter-floor sound insulation includes: a main layer including a sound absorption part comprising a fiber mat, and an elastic support part of an elastic material placed in the sound absorption part; an upper layer joined to an upper side of the main layer, and made of a soft waterproof sheet; and a lower layer joined to a lower side of the main layer, and made of a soft panel. In accordance with the present invention, through the independent panel for inter-floor sound insulation and a manufacturing method thereof and a construction method employing the same, the fiber mat and the elastic material are provided together in the main layer, thereby absorbing an inter-floor noise while bringing about a vibration control effect, which can lead to a high sound insulation effect. Moreover, the sagging of the main layer can be prevented through the elastic support part of the main layer, an elastic panel and an elastic pillar to secure a space for the fiber mat, which can lead to an enhancement in its effect and an improvement in structural stability. Further, a plurality of plate-shaped sound absorption members and a plurality of plate-shaped elastic support means are stacked, and then, are cut in a direction, in which the members and the means are stacked, to manufacture the main layer into a panel shape, thereby improving manufacturing efficiency due to its convenient manufacturing method.

Description

Method for manufacturing a single panel for interlayer sound insulation {Manufacturing method for a panel for interlayer sound insulation}

The present invention relates to a single panel for sound insulation between floors, a method for manufacturing the same, and a construction method to which the same is applied, and to a single panel for sound insulation between floors for reducing the impact noise transmitted by placing it between floors of a multi-family building such as an apartment house and manufacturing the same It relates to the method and the construction method to which it is applied.

BACKGROUND ART In general, apartment houses, residential and commercial complexes, and multi-family houses, such as multi-family houses, are buildings in which different multi-family houses are built to face each other, and noise generated between the furniture is transmitted through the floors to generate inter-floor noise.

That is, in the case of an apartment house, when a vibration of the floor is generated, such as when a person walks or an object falls from the upper floor, it is transmitted to the lower floor through the ceiling or wall. Concrete slabs that form between floors of a multi-family house can play a primary sound insulation function between the upper and lower floors, but only a part of the floor impact sound is attenuated and transmitted to other adjacent households or lower floors, causing inconvenience. Such inter-floor noise is a problem that continues to occur as the number of multi-unit dwellings such as apartments increases.

As the noise problem between floors continues to occur as described above, in order to reduce the noise between floors, a sound insulation panel between floors interposed in a concrete slab during the construction of an apartment house has been developed. The interlayer sound insulation panel is formed of Styrofoam of a certain thickness and installed between the layers to absorb the impact sound generated from the upper layer.

Meanwhile, interfloor noise can be divided into light impact sound (frequency 125-2000 Hz) and heavy impact sound (frequency 63-500 Hz). In the case of a light impact sound, it can be easily attenuated using a conventional interlayer sound insulation panel, but there is a limit to attenuating the interlayer noise of a heavy impact sound. That is, the conventional interlayer sound insulation panel has a problem in that when a weight impact sound is generated, the sound insulation effect cannot be exhibited and the interlayer noise is transmitted as it is. Accordingly, the interlayer sound insulation panel of various structures can be manufactured in order to attenuate the weight impact sound, but there is a disadvantage that the manufacturing efficiency may be lowered due to the complicated structure or increased manufacturing cost.

As a conventional technology related to a single panel for interlayer sound insulation, Korean Patent Laid-Open No. 10-2012-0032608 has been disclosed.

The present invention was created to solve the above problems, and an object of the present invention is to provide a single panel for interlayer sound insulation, which has improved sound insulation effect and improved manufacturing efficiency, a manufacturing method thereof, and a construction method to which the same is applied.

According to a single panel for interlayer sound insulation according to a first embodiment of the present invention for achieving the above object, a main layer comprising a sound absorbing part composed of a fiber mat and an elastic support part of an elastic material disposed in the sound absorbing part ; an upper layer bonded to the upper surface of the main layer and made of a soft waterproof material sheet; and a lower layer joined to the lower surface of the main layer and made of a rigid panel.

Here, the sound-absorbing part includes a plurality of sound-absorbing members formed in a rod shape, and the elastic support part includes a plurality of elastic support means formed in a rod shape and arranged to abut against one side of the sound-absorbing member, the sound absorption It is preferable that the member and the elastic support means are repeatedly arranged.

In this case, the main layer may be formed in a panel shape by cutting along the stacked direction in a state in which a plurality of plate-shaped sound-absorbing members and the plurality of plate-shaped elastic support means are repeatedly stacked with each other.

In addition, it is preferable that the sound-absorbing part is made of a polyester fiber, and the elastic support part is made of a rubber material.

In addition, the upper layer is preferably composed of a soft polyethylene (Low Density Polyethylene) foam sheet, and the lower layer is preferably composed of a rigid polystyrene (Polystyrene) foam panel.

On the other hand, according to the interlayer sound insulation sole panel according to the second embodiment of the present invention, an elastic panel formed of an elastic material with elastic holes spaced apart from each other at regular intervals along the longitudinal and lateral directions, and the elastic hole a main layer interposed therebetween and including a fiber member composed of a fiber mat; It is bonded to the upper and lower portions of the main layer, and includes an upper layer and a lower layer made of a waterproof material sheet.

And according to the interlayer sound insulation single panel according to the third embodiment of the present invention, a fiber panel having pillar holes spaced apart from each other at regular intervals along the longitudinal and lateral directions and composed of a fiber mat; The main layer is interposed and includes an elastic column composed of an elastic material; It is bonded to the upper and lower portions of the main layer, and includes an upper layer and a lower layer made of a waterproof material sheet.

On the other hand, the single panel for interlayer sound insulation is spaced apart from the lower surface of the lower layer at regular intervals, and may further include a floor adhesion layer made of an elastic material and in close contact with the slab floor surface, wherein the floor adhesion layer has a circular cross section or It is preferably formed in a "C" shape.

In addition, according to the method for manufacturing a single panel for interlayer sound insulation according to the fourth embodiment of the present invention, the main layer comprising a plurality of sound absorbing members composed of a fiber mat and a plurality of elastic support means disposed on one side of the sound absorbing member and which are elastic materials And, an upper layer bonded to the upper surface of the main layer and made of a soft waterproof material sheet, and a lower layer bonded to the lower surface of the main layer and made of a hard panel. In the following, the main layer manufacturing step of manufacturing the main layer in which the plurality of sound-absorbing members and the plurality of elastic support means are repeatedly arranged with each other; an upper layer bonding step of bonding the upper layer to the upper surface of the main layer manufactured in the main layer manufacturing step; and a lower layer bonding step of bonding the lower layer to the lower surface of the main layer.

On the other hand, according to the construction method to which the interlayer sound insulation single panel according to the fifth embodiment of the present invention is applied, the main layer including a sound absorbing part composed of a fiber mat, and an elastic support part disposed within the volume of the sound absorbing part and made of an elastic material; , an upper layer joined to the upper surface of the main layer and made of a soft waterproof material sheet, a lower layer joined to the lower surface of the main layer and made of a rigid panel, and spaced apart from the lower surface of the lower layer at regular intervals and made of an elastic material In the floor impact sound buffer construction method to which a single panel for interlayer sound insulation including a floor adhesion layer in close contact with the floor is applied, an interlayer sound insulation panel comprising arranging a plurality of single panels for interlayer sound insulation so that the slab floor surface and the floor adhesion layer come into contact with each other placement step; a watertight means arrangement step of disposing a watertight means on the upper surface of the plurality of interlayer sound insulation single panels disposed in the interlayer sound insulation panel arrangement step; a side finishing material installation step of installing a side finishing material of an elastic material along the inner circumference of the construction wall and the upper surface of the interlayer sound insulation panel disposed in the interlayer sound insulation panel arrangement step; a pipe installation step of installing pipes according to a predetermined interval on the upper surface of the interlayer sound insulation panel disposed in the interlayer sound insulation panel arrangement step; and a concrete pouring step of producing a concrete layer by pouring concrete over the pipe installed in the pipe installation step.

According to the single panel for interlayer sound insulation according to the present invention, the manufacturing method thereof, and the construction method to which the same is applied, a fiber mat and an elastic material are provided on the main layer together, so that the interlayer noise can be absorbed and the vibration damping effect can be obtained at the same time, so that the high sound insulation effect can provide

In addition, it is possible to prevent the sagging of the main layer by the elastic support part of the main layer, the elastic panel and the elastic column, so that the space of the fiber mat can be secured to increase the sound-absorbing effect, and the structural stability can be improved.

And by laminating a plurality of plate-shaped sound-absorbing members and a plurality of plate-shaped elastic support means and cutting along the stacked direction to produce the main layer in the form of a panel, the manufacturing method is simple, so the manufacturing efficiency can be improved and it has excellent workability. can

In addition, since the upper layer is composed of a soft waterproof material sheet, cracks caused by concrete mortar can be prevented, and it can be stably adhered to the slab bottom surface by the floor adhesion layer.

1 is a perspective view showing a single panel for interlayer sound insulation according to a first embodiment of the present invention;
2 is an exploded perspective view of the single panel for interlayer sound insulation shown in FIG. 1;
3 is a state diagram schematically showing the state of manufacturing the main layer of the single panel for interlayer sound insulation shown in FIG.
4 is an exploded perspective view showing a single panel for interlayer sound insulation according to a second embodiment of the present invention;
5 is an exploded perspective view showing a single panel for interlayer sound insulation according to a third embodiment of the present invention;
6 is a flowchart illustrating a method for manufacturing a single panel for interlayer sound insulation according to a fourth embodiment of the present invention.

Hereinafter, preferred embodiments according to the present invention will be described in detail with reference to the accompanying drawings. Prior to this, the terms or words used in the present specification and claims should not be construed as being limited to their ordinary or dictionary meanings, and the inventor should properly understand the concept of the term in order to best describe his invention. Based on the principle that can be defined, it should be interpreted as meaning and concept consistent with the technical idea of the present invention.

Therefore, the embodiments described in this specification and the configurations shown in the drawings are only the most preferred embodiments of the present invention, and do not represent all the technical ideas of the present invention, so at the time of the present application, they are equivalent It should be understood that there may be variations.

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

1 to 3 , a single panel 10a for interfloor sound insulation according to the first embodiment of the present invention is provided between floors of a multi-family house to attenuate noise, and the main floor 100a, the upper layer 200a) , a lower layer 300a and a bottom adhesion layer 400 .

The main layer 100a is a central layer of the interlayer sound insulation panel 10a for attenuating noise, and includes a sound absorbing part 110 and an elastic support part 120 .

The sound-absorbing part 110 is composed of a fiber mat, more specifically, preferably composed of a polyester fiber. Since the sound absorption unit 110 is composed of a fiber mat, it is possible to diffusely reflect and absorb the noise generated, thereby reducing the noise and improving the sound absorption effect by immediately absorbing the generated noise. The sound absorbing part 110 may include a plurality of sound absorbing members 111, and it is preferable that the plurality of sound absorbing members 111 are formed in a rod shape.

The elastic support part 120 is disposed in the sound absorption part 110 and is made of an elastic material, and more specifically, it is preferably made of a rubber material. Since the elastic support part 120 is made of a rubber material and is disposed in the sound absorbing part 110 , an interlayer space of the sound absorbing part 110 can be secured, thereby increasing the effect. In addition, it is possible to prevent the sagging of the sound absorbing portion 110 can provide structural stability. In addition, the elastic support part 120 can absorb vibrations using elastic force, so that it can have the effect of a vibration damping function of vibrations generated by noise. The elastic support part 120 may include a plurality of elastic support means 121 , and the plurality of elastic support means 121 are formed in a rod shape and disposed to abut against one side of the sound absorbing member 111 . It is preferable to be That is, the plurality of sound absorbing members 111 and the plurality of elastic support means 121 may be alternately and repeatedly arranged on one side to form a panel shape. Since the elastic support part 120 is formed in a rod shape, it is possible to minimize the use of rubber in a range capable of securing support, thereby reducing manufacturing costs.

Meanwhile, the main layer 100 is formed in a panel shape by cutting along the stacked direction in a state in which a plurality of plate-shaped sound-absorbing members 111 and the plurality of plate-shaped elastic support means 121 are repeatedly stacked on each other. can be That is, by cutting the plate-shaped sound-absorbing member 111 and the plate-shaped elastic support means 121, the sound-absorbing member 111 and the elastic support means 121 can be formed in a rod shape, and a plurality of main layers 10a ) can be easily manufactured, so manufacturing efficiency can be improved and excellent processability can be obtained.

The upper layer 200a is bonded to the upper surface of the main layer 100a and is made of a soft waterproof material sheet. More specifically, the upper layer 200a is preferably composed of a soft polyethylene (Low Density Polyethylene) foam sheet or a polypropylene (polypropylene) foamed flexible resin sheet. Since the upper layer 200a is made of a soft polyethylene foam sheet, it is possible to protect the sound-absorbing member 111, and when concrete is mortared on the upper layer of the upper layer 200a, cracks occur even when a continuous force is applied by the mortared concrete. It can be prevented in advance.

The lower layer 300a is bonded to the lower surface of the main layer 100a and is made of a rigid panel. More specifically, the lower layer 300a is preferably made of a rigid polystyrene foam panel. Since the lower layer 300a is composed of a rigid polystyrene foam panel, the sound absorbing member 111 can be protected and the overall smoothness of the interlayer sound insulation panel 10a including the main layer 100a can be supported, and additionally heat insulation It is possible to provide a functional effect.

The bottom adhesion layer 400 is attached to the lower surface of the lower layer 300a, and is in close contact with the bottom surface of the slab. That is, the bottom adhesion layer 400 is in close contact with the bottom surface of the slab so that the interlayer sound insulation single panel 10a is stably disposed on the bottom surface of the slab. The bottom adhesion layer 400 is made of an elastic material spaced apart from each other at regular intervals on the lower surface of the lower layer 300a. In this case, the bottom adhesion layer 400 is preferably a rubber strip having a circular or “C” cross-section, and by applying a rubber strip having a circular or “C” cross-section, the elastic force is maintained and at the same time. material can be reduced. The bottom adhesion layer 400 is not limited to a rubber strip having a circular or “C” cross-section, and may be applied as a lattice-shaped rubber frame.

Hereinafter, a single panel 10b for interlayer sound insulation according to a second embodiment of the present invention will be described with reference to FIG. 4 . Here, the same reference numerals shown in FIGS. 1 to 3 are the same members having the same configuration and action, and thus a repetitive description will be omitted. The single panel 10b for interlayer sound insulation may include a main layer 100b, an upper layer 200b and a lower layer 300b, and a bottom adhesion layer 400 .

The main layer 100b is a central layer of the single panel 10b for interlayer sound insulation for attenuating noise, and includes an elastic panel 130 and a fiber member 140 .

The elastic panel 130 is formed of an elastic material, and more specifically, it is preferably made of a rubber material. The elastic panel 130 is formed in a plate shape, and elastic holes 130h that are spaced apart from each other at regular intervals along the longitudinal and lateral directions may be formed. In other words, the elastic hole 130h is preferably formed in a cylindrical shape. Since the elastic support part 120 is made of a rubber material, a stable space is secured in which the fibrous member 140, which will be described later, is interposed in the elastic hole 130h, thereby safely protecting the fibrous member 140, thereby improving the sound absorption effect. can be increased, and can provide structural stability. In addition, the elastic panel 130 can adjust elasticity through the design of the elastic hole 130h and can absorb vibrations using elastic force, so that the elastic panel 130 can have an effect of damping vibrations generated by noise.

The fiber member 140 is composed of a fiber mat, and more specifically, preferably a polyester fiber. The fiber member 140 is interposed in the elastic hole 130h. Since the fiber member 140 is composed of a fiber mat, it is possible to diffusely reflect and absorb the noise generated, thereby reducing the noise and improving the sound absorption effect by immediately absorbing the generated noise.

On the other hand, the elastic panel 130 is formed such that the spacing between the opposite circumferences between the fiber members 140 arranged in parallel in the longitudinal direction gradually increases from the center of the fiber member 140 in the lateral direction. and the elastic panel 130 is such that the spacing between the opposite circumferences between the fibrous members 140 arranged in parallel in the transverse direction gradually increases from the center of the fibrous member 140 in the longitudinal direction. is formed That is, in the elastic panel 130, the elastic hole 130h is formed in a cylindrical shape and the fiber member 140 is formed in a cylindrical shape. The circumferential distance is formed to gradually increase from the center of the fiber member 140 in the transverse direction, and the elastic panel 130 is opposite to each other between the fiber members 140 arranged in parallel in the transverse direction. The beam is formed such that the distance between the circumferences is gradually increased from the center of the fiber member 140 in the longitudinal direction to stably support the fiber member 140 .

The upper layer 200b and the lower layer 300b are bonded to the upper and lower portions of the main layer 100b, and are made of a waterproof material sheet. Accordingly, the upper layer 200b and the lower layer 300b can safely protect the fiber member 140 during wet construction.

Hereinafter, a single panel 10c for interlayer sound insulation according to a third embodiment of the present invention will be described with reference to FIG. 5 . Here, the same reference numerals shown in FIGS. 1 to 4 are the same members having the same configuration and action, and thus a repetitive description will be omitted. The single panel 10c for interlayer sound insulation may include a main layer 100c, an upper layer 200c and a lower layer 300c, and a bottom adhesion layer 400 .

The main layer 100c is a central layer of the single panel 10c for interlayer sound insulation for attenuating noise, and includes a fiber panel 150 and an elastic column 160 .

The fiber panel 150 is composed of a fiber mat, and more specifically, preferably a polyester fiber. The fiber panel 150 may have pillar holes 150h spaced apart from each other at regular intervals along the longitudinal and transverse directions, and the pillar holes 150h are preferably formed in a cylindrical shape. In other words, the pillar hole 150h can be formed simply by applying water pressure to the fiber panel 150 using a water pressure gun. Since the fiber panel 150 is composed of a fiber mat, it is possible to diffusely reflect and absorb the noise generated, thereby reducing the noise and improving the sound absorption effect by immediately absorbing the generated noise.

Meanwhile, it is preferable that a side watertight sheet (not shown) is further provided along the outer circumference of the fiber panel 150 . The side watertight sheet can prevent moisture and moisture from penetrating by protecting the outer surface of the fiber panel 150 . The side watertight sheet is preferably a waterproof material, and is made of an elastic sheet.

The elastic pillar 160 is formed of an elastic material and has a cylindrical shape. More specifically, the elastic pillar 160 is preferably made of a rubber material. The elastic pillar 160 is interposed in the pillar hole 150h. Since the elastic pillar 160 is made of a rubber material and disposed in the pillar hole 150h, the interlayer space of the fiber panel 150 can be secured and supported, thereby increasing the sound absorption effect of the fiber panel 150. can do it In addition, it is possible to prevent sagging of the fiber panel 150, thereby providing structural stability. Moreover, the elastic pillar 160 can absorb vibration by using an elastic force, so that it can have the effect of a vibration damping function of vibration generated by noise.

The upper layer 200c and the lower layer 300c are bonded to the upper and lower portions of the main layer 100c, and are made of a waterproof material sheet. Accordingly, the upper layer 200c and the lower layer 300c can safely protect the fiber panel 150 during wet construction.

Meanwhile, FIG. 6 is a flowchart illustrating a method (S10) for manufacturing a single panel for interlayer sound insulation according to a fourth embodiment of the present invention. The method ( S10 ) for manufacturing a single panel for interlayer sound insulation is a method for manufacturing the single panel for interlayer sound insulation ( 10a ). Here, the interlayer sound insulation single panel (10a) includes a plurality of sound absorbing members 111 composed of a fiber mat and a plurality of elastic support means 121 that are disposed on one side of the sound absorbing member 111 and are elastic materials. The main layer 100a, an upper layer 200a bonded to the upper surface of the main layer 100a and made of a soft waterproof material sheet, and a lower layer 300a bonded to the lower surface of the main layer 100a and made of a hard panel. do. Here, the same reference numerals of the single panel 10a for interlayer sound insulation are the same members having the same configuration and operation, and thus a repetitive description will be omitted.

The method (S10) for manufacturing a single panel for interlayer sound insulation may include a main layer manufacturing step (S100), an upper layer bonding step (S200), and a lower layer bonding step (S300).

4, the main layer manufacturing step (S100) is for manufacturing the main layer 100a, which is the central layer of the single panel 10a for interlayer sound insulation, and includes the plurality of sound absorbing members 111 and the plurality of elastic members. The main layer 100a is manufactured so that the supporting means 121 are repeatedly arranged with each other. In other words, the main layer manufacturing step (S100) may include a lamination step (S110) and a cutting step (S120).

In the lamination step (S110), a plurality of plate-shaped sound absorbing members 111 and a plurality of plate-shaped elastic support means 121 are alternately and repeatedly laminated with each other. Although the figure shows that the plate-shaped sound-absorbing member 111 and the plate-shaped elastic support means 121 are stacked by 5 and 6, respectively, the number of the sound-absorbing member 111 and the elastic support means 121 to be stacked is manufactured. It will be appropriately changeable in accordance with the size of the main layer (100a) for.

The cutting step (S120) is a step of cutting the sound absorbing member 111 and the elastic support means 121 stacked in the stacking step (S110) along the stacking direction. By cutting the plate-shaped plurality of sound-absorbing members 111 and the elastic support means 121 in a stacked direction corresponding to a preset thickness, the panel-shaped main layer 100a can be manufactured. By laminating a plurality of plate-shaped sound absorbing members 111 and elastic support means 121 and cutting them to produce the main layer 100a, the process is simplified and manufacturing time can be saved, thereby improving manufacturing efficiency and excellent processability. can have

The upper layer bonding step (S200) is a step of bonding the upper layer 200a to the main layer 100a. The upper layer 200a is bonded to the upper surface of the main layer 100a manufactured in the main layer manufacturing step S100. Here, the upper layer 200a is a soft waterproof material, and by bonding the upper layer 200a to the upper surface of the main layer 100a, it is possible to protect the sound absorbing member 111 from moisture and moisture.

The lower layer bonding step (S300) is a step of bonding the lower layer (300a) to the main layer (100a), and the lower layer (300a) is bonded to the lower surface of the main layer (100a) produced in the main layer manufacturing step (S100). Here, the lower layer 300a is preferably a rigid panel. Since the lower layer 300a is composed of a rigid polystyrene foam panel, it is possible to support the overall smoothness of the single panel 10a for interlayer sound insulation including the main layer 100a, and additionally provide a thermal insulation effect.

Meanwhile, the method (S10) for manufacturing a single panel for interlayer sound insulation may further include a step of attaching a floor adhesion layer (S400).

In the bottom adhesive layer attaching step (S400), a plurality of bottom adhesive layers 400 are attached to the lower surface of the lower layer 300a joined in the lower layer bonding step (S300). The bottom adhesion layer 400 is preferably formed of an elastic material and may be applied as a rubber strip having a circular or "C" cross-section or a lattice-shaped rubber frame. In the bottom adhesive layer attaching step (S400), the plurality of bottom adhesive layers 400 are attached to the lower surface of the lower layer 300a by being spaced apart from each other at regular intervals. The bottom adhesive layer 400 attached through the bottom adhesive layer attaching step (S400) is in close contact with the slab bottom surface so that the interlayer sound insulation sole panel 10a is stably disposed on the slab bottom surface.

On the other hand, the following relates to the construction method (S20) to which the interlayer sound insulation sole panel 10a according to the fifth embodiment of the present invention is applied, wherein the interlayer sound insulation sole panel 10a is a sound-absorbing part ( 110), and a main layer 10a disposed within the volume of the sound-absorbing part 110 and including an elastic support part 120 made of an elastic material, and a soft waterproof material sheet bonded to the upper surface of the main layer 10a The upper layer 200a, the lower layer 300a bonded to the lower surface of the main layer 10a and made of a rigid panel, and spaced apart from the lower surface of the lower layer 300a at regular intervals and made of an elastic material to be in close contact with the floor surface and a bottom adhesion layer 400 . Here, the same reference numerals of the single panel 10a for interlayer sound insulation are the same members having the same configuration and operation, and thus a repetitive description will be omitted.

The construction method (S20) to which the interlayer sound insulation single panel is applied relates to a floor impact sound buffer construction method, and the interlayer sound insulation panel arrangement step (S21), the watertight means arrangement step (S22), the side finishing material installation step (S23), It includes a pipe installation step (S24), a concrete pouring step (S25).

In the interlayer sound insulation panel arrangement step (S21), a plurality of the interlayer sound insulation independent panels 10a are arranged so that the bottom surface of the slab and the floor adhesion layer 400 come into contact with each other. That is, a plurality of interlayer sound insulation panels 10a are arranged to correspond to the size of the slab bottom surface. At this time, it is possible to construct a floor structure in which the sole panel 10a for interlayer sound insulation is floated by the floor adhesion layer 400 , so that the interlayer sound insulation effect can be maximized by the formed air layer.

Referring to Figure 1, the watertight means arrangement step (S22) is a step for disposing the watertight means 500, and the plurality of interlayer sound insulation single panels 10a disposed in the interlayer sound insulation panel arrangement step (S21). Place the watertight means 500 on the upper surface of the. In other words, in the watertight means arrangement step (S22), the watertight tape 500 may be attached along the boundary line of the upper layer 200a, which is a connection portion of the plurality of interlayer sound insulation panels 10a. That is, by attaching the watertight tape 500 to the watertight means 500 along the boundary line of the upper layer 200a, penetration of moisture and moisture through the boundary line can be prevented in advance.

Meanwhile, the watertight means arrangement step (S22) may be applied to arrange the vinyl sheet on the entire upper surface of the upper layer 200a of the plurality of interlayer sound insulation single panels 10a disposed in the interlayer sound insulation panel arrangement step S21. have.

In the side finishing material installation step (S23), the side finishing material is installed along the inner circumference of the construction wall on the upper surface of the interlayer sound insulation single panel (10a) disposed in the interlayer sound insulation panel arrangement step (S22). The side finishing material is preferably an elastic material, and more specifically, an elastic rubber. By installing the side finishing material along the inner periphery of the construction wall, the gap with the side of the interlayer sound insulation single panel 10a is closed, elastic support is possible, and noise movement along the wall can be minimized, so that between floors It can increase the sound insulation effect.

In the pipe installation step (S24), a pipe is installed at a predetermined interval on the upper surface of the interlayer sound insulation single panel (10a) disposed in the interlayer sound insulation panel arrangement step (S23). In other words, the pipe may be fixed through a fixing pin or the like, and the number of pipes may be appropriately changed and applied according to the type or place of construction. A detailed description of the pipe is a well-known technology, and a detailed description thereof will be omitted here.

In the concrete pouring step (S25), concrete is poured into the upper part of the pipe installed in the pipe installation step (S24) to produce a concrete layer. That is, in the concrete pouring step (S25), concrete is poured onto the upper part of the interlayer sound insulation single panel 10a. At this time, in the concrete pouring step (S25), it is preferable to pour the concrete at a height corresponding to the height of the side finishing material installed in the side finishing material installation step (S23). A concrete layer may be formed by the concrete poured through the concrete pouring step (S25).

According to the single panel for interlayer sound insulation and the manufacturing method according to the present invention, since the main layer is provided with a fiber mat and an elastic material, it is possible to absorb interlayer noise and have a vibration damping effect, thereby providing a high sound insulation effect.

In addition, it is possible to prevent sagging of the main layer by the elastic support part of the main layer, the elastic panel and the elastic column, so that the space of the fiber mat can be secured to increase the effect, and the structural stability can be improved.

And after laminating a plurality of plate-shaped sound absorbing members and a plurality of plate-shaped elastic support means, cutting along the stacked direction to produce the main layer in the form of a panel, the manufacturing method is simple, and the manufacturing efficiency can be improved and excellent workability can have

In addition, since the upper layer is composed of a soft waterproof material sheet, cracks caused by concrete mortar can be prevented, and it can be stably adhered to the slab bottom surface by the floor adhesion layer.

Although the present invention has been described with reference to the embodiments shown in the drawings, which are merely exemplary, those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims.

10a, 20b, 30c: Sole panel for sound insulation between floors
100a, 100b, 100c: main layer 110: sound absorbing part
111: sound absorbing member 120: elastic support part
121: tin top support means 130: elastic panel
130h: elastic hole 140: fiber member
150: fiber panel 150h: pillar hole
160: elastic column 200a, 200b, 200c: upper layer
300a, 300b, 300c: lower layer 400: floor adhesion layer
500: watertight means

Claims (1)

In the manufacturing method of a single panel for interlayer sound insulation provided in a pre-manufactured form rather than being assembled at a construction site,
It is made of an elastic rubber material and in a rod shape to prevent sagging of the sound-absorbing member composed of a fiber mat and to absorb vibration by elasticity, which is in surface contact with the entire surface or the entire other surface of the sound-absorbing member, has a width smaller than the width of the absorption member A main layer comprising a plurality of elastic support means to be formed, wherein the sound absorbing member and the elastic support means are alternately and repeatedly arranged to form a panel shape of a certain thickness, and an upper layer bonded to the upper surface of the main layer and made of a soft waterproof material sheet and a lower layer bonded to the lower surface of the main layer and made of a rigid polystyrene foam panel, and the width of the elastic support means is 1/5 or less of the width of the sound absorbing member. In the single panel manufacturing method,
After alternately laminating a sheet-shaped fiber mat and a sheet-shaped elastic rubber plate, the plurality of sound-absorbing members and each of the plurality of elastic support means are repeatedly arranged and combined in a form having a rectangular pole bar shape to form a panel shape of a certain thickness. A main layer manufacturing step of manufacturing the main layer by vertically cutting at intervals of the thickness of the main layer;
an upper layer bonding step of bonding the upper layer to the upper surface of the main layer manufactured in the main layer manufacturing step; and
and a lower layer bonding step of bonding the lower layer to the lower surface of the main layer.

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