JP2023058731A - sound insulation panel - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve sound insulation property of a resin structure inside which a plurality of cells are arranged in parallel.

SOLUTION: A sound insulation panel includes: a hollow plate-shaped resin structure 10 inside which column-shaped cells S are arranged; and a sheet body 50. The resin structure 10 includes: a side wall part for partitioning the cells S; and a pair of block walls for blocking an upper part and a lower part of the side wall part. At least one of the pair of block walls is set to be a first block wall in which a communication hole 15 for communicating the inside and outside of the cell S is formed. One or a plurality of communication holes 15 are formed in different places in each cell S. The sheet body 50 is laminated on at least one outer surface of the resin structure 10.

SELECTED DRAWING: Figure 1

COPYRIGHT: (C)2023,JPO&INPIT

Description

The present invention relates to sound insulation panels.

2. Description of the Related Art Conventionally, there is known a hollow plate-shaped resin structure in which a plurality of polygonal prismatic or cylindrical cells are arranged side by side. For example, in the resin structure disclosed in Patent Document 1, a core layer in which a plurality of hexagonal prism-shaped cells are defined is formed by folding a thermoplastic resin sheet material having a predetermined shape. Skin layers, which are sheet materials made of thermoplastic resin, are bonded to both upper and lower surfaces of the core layer.

JP 2013-163351 A

The hollow plate-shaped resin structure described in Patent Document 1 is relatively lightweight and has sufficient strength, and is therefore expected to be used in various applications. However, Patent Document 1 does not mention the use of the resin structure as a sound insulating material. The sound insulation performance of an object is proportional to the logarithm of the product of its mass per unit area and the sound frequency. There is still room for improvement.

In order to solve the above problems, the present invention provides a sound insulation panel comprising a hollow plate-shaped resin structure in which a plurality of columnar cells are arranged side by side, and a sheet body, wherein the resin structure comprises: A side wall that partitions the cell into a columnar shape and a pair of blocking walls that block upper and lower portions of the side wall, and at least one of the pair of blocking walls has a communication hole that communicates the inside and outside of the cell. The communicating hole is formed in one or a plurality of different locations in each cell, and the sheet body is a hollow body having a plurality of columnar cells arranged side by side inside. It is characterized by being laminated on at least one outer surface of a plate-like resin structure.

In the above invention, at least one of the upper and lower blocking walls that block the columnar cells of the resin structure is formed with a communication hole that communicates the inside and outside of the cell. A sheet body is laminated on the surface. According to this configuration, in addition to the effect of improving the sound insulation performance of the sound insulation panel by increasing the mass of the entire sound insulation panel by laminating the sheet bodies, the sheet body is laminated on the first blocking wall in which the communication hole is formed. By doing so, the sound insulation is further improved. This is probably because the sheet body vibrates on the first blocking wall having the communication hole, and as a result, the sound insulation is improved by more than the increase in the mass of the sheet body.

According to the present invention, it is possible to improve the sound insulation of a hollow plate-shaped resin structure in which a plurality of columnar cells are arranged side by side.

Partial perspective view of the sound insulation panel. (a) is a partial perspective view of the resin structure, (b) is a cross-sectional view along the β-β line in (a), and (c) is a cross-sectional view along the γ-γ line in (a). (a) is a perspective view of a sheet material forming a core layer of a resin structure, (b) is a perspective view showing a state in which the sheet material is being folded, and (c) is a perspective view showing a state in which the sheet material is folded. FIG. (d) is a cross-sectional view showing a state in which communicating holes are formed in the resin structure; FIG. 4 is a schematic diagram showing an arrangement state of the sound insulation panel of the example. FIG. 4 is a schematic diagram showing an arrangement state of the sound insulation panel of the example.

A sound insulation panel embodying the present invention will be described below with reference to FIGS. 1 and 2. FIG.
As shown in FIG. 1, the sound insulation panel of this embodiment includes a resin structure 10 and a sheet body 50 laminated on the upper surface 10a thereof. The resin structure 10 is formed in the shape of a hollow plate in which a plurality of columnar cells S are arranged side by side, and the upper surface 10a and the lower surface are formed in a rectangular shape. A communication hole 15 is formed in the upper surface 10a of the resin structure 10 to allow the inside and outside of the cell S to communicate with each other. The sheet body 50 is laminated so as to cover the entire upper surface 10a. The sheet body 50 is joined and fixed to the peripheral edge portion of the upper surface 10a of the resin structure 10 with tacks 70 over the entire circumference of the peripheral edge portion.

Each of the resin structure 10 and the sheet body 50 constituting the sound insulation panel of the present embodiment will be described below.
As shown in FIG. 2(a), the resin structure 10 is composed of a core layer 20 in which a plurality of cells S are arranged side by side, and sheet-like skin layers 30 and 40 bonded to both upper and lower surfaces of the core layer 20. It is As shown in FIGS. 2(b) and 2(c), the core layer 20 is formed by folding one thermoplastic resin sheet material molded into a predetermined shape. The core layer 20 is composed of an upper wall portion 21, a lower wall portion 22, and a side wall portion 23 erected between the upper wall portion 21 and the lower wall portion 22 to divide the cells S into a hexagonal prism shape. It is

As shown in FIGS. 2B and 2C, the cells S defined inside the core layer 20 include a first cell S1 and a second cell S2 having different configurations. As shown in FIG. 2B, in the first cell S1, the upper wall portion 21 having a two-layer structure is provided above the side wall portion 23 . Each layer of the upper wall portion 21 having the two-layer structure is joined to each other. In addition, in the first cell S1, a lower wall portion 22 having a one-layer structure is provided below the side wall portion 23 . On the other hand, as shown in FIG. 2C, in the second cell S2, the upper wall portion 21 having a one-layer structure is provided above the side wall portion 23 . Further, in the second cell S2, a lower wall portion 22 having a two-layer structure is provided below the side wall portion 23 . Each layer of the lower wall portion 22 having the two-layer structure is joined to each other. Further, as shown in FIGS. 2B and 2C, adjacent first cells S1 and adjacent second cells S2 are partitioned by side wall portions 23 having a two-layer structure, respectively. there is

As shown in FIG. 2A, the first cells S1 are arranged in rows along the X direction. share an edge. Similarly, the second cells S2 are arranged in rows along the X direction, and when viewed from above, two adjacent second cells S2 share one side of the hexagon. The columns of the first cells S1 and the columns of the second cells S2 are alternately arranged in the Y direction orthogonal to the X direction. The core layer 20 as a whole has a honeycomb structure with these first cells S1 and second cells S2.

As shown in FIGS. 2(a) to 2(c), a skin layer 30, which is a thermoplastic resin sheet material, is joined to the upper surface of the core layer 20 configured as described above. A skin layer 40 that is a thermoplastic resin sheet material is joined to the lower surface of the core layer 20 . In this embodiment, the upper portion of the side wall portion 23 of the core layer 20 is closed with the upper wall portion 21 of the core layer 20 and the skin layer 30 . Therefore, the upper wall portion 21 of the core layer 20 and the skin layer 30 form a blocking wall that blocks the upper portion of the side wall portion 23 . Similarly, the lower portion of the side wall portion 23 of the core layer 20 is closed by the lower wall portion 22 of the core layer 20 and the skin layer 40 . Therefore, the lower wall portion 22 of the core layer 20 and the skin layer 40 form a blocking wall that blocks the lower portion of the side wall portion 23 . In FIGS. 2(b) and 2(c), of the three cells S shown, the cell S on the leftmost side is labeled as a representative, but the same applies to the other cells S. .

As shown in FIGS. 2B and 2C, the upper surface 10a of the resin structure 10 is provided with communication holes 15 that allow the inside and outside of the cells S to communicate with each other. Specifically, as shown in FIG. 2B, in the first cell S1, the communication hole 15 is provided so as to penetrate the skin layer 30 on the upper surface side and the upper wall portion 21 of the two-layer structure. Further, as shown in FIG. 2(c), in the second cell S2, the communication hole 15 is provided so as to penetrate the skin layer 30 on the upper surface side and the upper wall portion 21 of the one-layer structure. That is, the communication hole 15 is provided in one of the closing walls of each cell S that closes the upper portion of the side wall portion 23 . Here, the blocking wall (upper surface 10a of the resin structure 10) in which the communication hole 15 is formed corresponds to the first blocking wall referred to in the claims.

As shown in FIG. 2( a ), one communication hole 15 is provided at approximately the central portion of the upper closing wall of each cell S. As shown in FIG. As shown in FIGS. 2B and 2C, the diameter of each communication hole 15 is set to be equal to or less than the length of one side of a hexagon when the cell S is viewed from above. Specifically, the diameter of the opening of each communication hole 15 is set to a fraction (for example, about 0.5 to 2 mm) of the interval P1 between the centers of cells S adjacent to each other in the X direction.

Next, the sheet body 50 will be explained. The sheet body 50 of the present embodiment is laminated so as to cover substantially the entire upper surface 10a of the resin structure 10, that is, the blocking wall in which the communication hole 15 is formed. As the sheet body 50, a generally known synthetic resin sheet, wood, plywood, metal sheet (metal foil), paper, cloth, gypsum board, or the like can be used. Examples of synthetic resin sheets include polypropylene (PP), polyvinyl chloride (PVC), and polystyrene (PS), and examples of metal sheets include lead sheets.

The thickness of the sheet body 50 is not particularly limited, but is set to a fraction to several tenths (for example, about 1 to 5 mm) of the thickness of the resin structure 10 .
Moreover, it is preferable to use a non-breathable material as the sheet body 50 from the viewpoint of improving sound insulation. From the viewpoint of improving sound insulation, the specific gravity of the sheet body 50 is preferably 0.9 or more, more preferably 1.4 or more. Similarly, the basis weight of the sheet body 50 is preferably 1000 g/m ² or more, more preferably 1500 g/m ² or more. When the basis weight of the sheet body 50 is 2000 g/m ² or more, the sound insulation can be improved more efficiently. In particular, when the specific gravity of the sheet body 50 is 1.4 or more and the basis weight is 2000 g/m ² or more, it is preferable because the sound loss transmission effect can be significantly increased from the low frequency range. Note that the low frequency range referred to here generally refers to a range of 200 Hz to 400 Hz. The same applies to the following description.

Next, a method of manufacturing a sound insulation panel will be described with reference to FIG.
The process of manufacturing the sound insulation panel of the present embodiment includes a process of manufacturing a resin structure 10 having a plurality of communication holes 15 formed in the upper surface 10a, and a process of bonding a sheet body 50 to the upper surface 10a of the resin structure 10. Consists of First, the process of manufacturing the resin structure 10 will be described.

As shown in FIG. 3A, the first sheet material 100 is formed by molding one thermoplastic resin sheet into a predetermined shape. In the first sheet material 100 , strip-shaped flat areas 110 and swollen areas 120 are alternately arranged in the longitudinal direction (X direction) of the first sheet material 100 . In the bulging region 120 , a first bulging portion 121 having a downward groove shape in cross section and having an upper surface and a pair of side surfaces is formed over the entirety of the extending direction (Y direction) of the bulging region 120 . The angle between the upper surface and the side surface of the first bulging portion 121 is preferably 90 degrees. Moreover, the width of the first bulging portion 121 (the length of the upper surface in the short direction) is equal to the width of the planar region 110, and the bulging height of the first bulging portion 121 (the length of the side surface in the short direction) ) is set to be twice as long.

In the bulging region 120 , a plurality of second bulging portions 122 each having a trapezoidal cross-sectional shape obtained by bisected a regular hexagon along the longest diagonal line are arranged so as to be perpendicular to the first bulging portions 121 . formed. The bulging height of the second bulging portion 122 is set to be equal to the bulging height of the first bulging portion 121 . Also, the interval between adjacent second bulging portions 122 is equal to the width of the upper surfaces of the second bulging portions 122 .

The first swelling portion 121 and the second swelling portion 122 are formed by partially swelling the sheet upward using the plasticity of the sheet. Also, the first sheet material 100 can be formed from one sheet by a well-known forming method such as a vacuum forming method or a compression forming method.

As shown in FIGS. 3A and 3B, the core layer 20 is formed by folding the first sheet material 100 configured as described above along the boundary lines P and Q. As shown in FIGS. Specifically, the first sheet material 100 is valley-folded along the boundary line P between the plane region 110 and the bulging region 120, and is folded along the boundary line Q between the top surface and the side surface of the first bulging portion 121. Fold and compress in the X direction. Then, as shown in FIGS. 3B and 3C, the top surface and the side surface of the first bulging portion 121 are folded over, and the end surface of the second bulging portion 122 and the planar region 110 are folded over, thereby forming a single A prismatic partition 130 extending in the Y direction is formed for one bulging region 120 . The core layer 20 in the form of a hollow plate is formed by continuously forming such division bodies 130 in the X direction. In this embodiment, the direction in which the first sheet member 100 is compressed for folding is the direction in which the cells S are arranged side by side (the X direction).

When the first sheet material 100 is compressed as described above, the upper wall portion 21 of the core layer 20 is formed by the upper surface and the side surface of the first bulging portion 121, and the end surface and the plane surface of the second bulging portion 122 are formed. The region 110 forms the lower wall portion 22 of the core layer 20 . In addition, as shown in FIG. 3C, a portion of the upper wall portion 21 where the upper surface and the side surface of the first bulging portion 121 are folded to form a two-layer structure, and a second bulging portion of the lower wall portion 22 A portion where the end surface of 122 and the planar region 110 are folded to form a two-layer structure becomes an overlapping portion 131 .

In addition, the hexagonal prism-shaped regions partitioned by folding the second bulging portion 122 become the second cells S2, and the hexagonal prism-shaped regions partitioned and formed between the pair of adjacent partitions 130 are the second cells S2. 1 cell S1. In the present embodiment, the upper surface and the side surface of the second bulging portion 122 constitute the side wall portion 23 of the second cell S2, and the side surface of the second bulging portion 122 and the second bulging portion 122 in the bulging region 120 The planar portion located therebetween constitutes the side wall portion 23 of the first cell S1. A side wall portion 23 having a two-layer structure is formed by the contact portion between the upper surfaces of the second bulging portion 122 and the contact portion between the planar portions of the bulging region 120 . The upper portion of the first cell S1 is defined by the pair of overlapping portions 131, and the lower portion of the second cell S2 is defined by the pair of overlapping portions 131. As shown in FIG. It is preferable that the first sheet material 100 be heated and softened before performing such a folding process.

A second sheet member made of a thermoplastic resin is joined to the upper surface and the lower surface of the core layer 20 obtained in this manner by thermal welding. The second sheet material joined to the upper surface of the core layer 20 becomes the skin layer 30 and closes the upper portion of the side wall portion 23 together with the upper wall portion 21 of the core layer 20 . The second sheet material joined to the lower surface of the core layer 20 becomes the skin layer 40 and closes the lower portion of the side wall portion 23 together with the lower wall portion 22 of the core layer 20 .

When the second sheet material (skin layers 30 and 40) is heat-sealed to the core layer 20, the two-layer upper wall portion 21 (superposed portion 131) of the first cell S1 is heat-sealed to each other. . Similarly, the lower wall portion 22 (overlapping portion 131) of the two-layer structure in the second cell S2 is thermally welded to each other.

Through the above process, a resin structure in which a large number of the first cells S1 or the second cells S2 are arranged in rows in the X direction, and a large number of the first cells S1 and the second cells S2 are arranged alternately in the Y direction. A body 10 is obtained.

Next, a large number of communication holes 15 are formed in one blocking wall (upper surface 10 a ) of the resin structure 10 . The communication hole 15 is formed by penetrating the upper surface 10a of the resin structure 10 with a penetrating member 60 such as a drill, a needle, or a punch. As shown in FIG. 3D, a plurality of penetrating members 60 are arranged at substantially the same intervals as the intervals between the centers of adjacent cells S. As shown in FIG. The resin structure 10 is arranged and fixed on the lower side of the plurality of penetrating members 60, and the penetrating members 60 are moved downward. In this manner, one communication hole 15 is formed in each of the upper surfaces 10a of the resin structure 10 at approximately the center of each cell S. As shown in FIG. Through the above steps, resin structure 10 having a plurality of communication holes 15 formed in upper surface 10a is manufactured.

Next, a process of manufacturing a sound insulation panel by joining the sheet body 50 to the upper surface 10a (first closing wall) of the resin structure 10 in which the communication hole 15 is formed will be described.
The sheet body 50 is set to have substantially the same shape and size as the upper surface 10 a of the resin structure 10 . The sheet bodies 50 are aligned and laminated so as to cover the entire upper surface 10a of the resin structure 10 in which the communication holes 15 are formed. Subsequently, using a tucker, the sheet body 50 is joined to the resin structure 10 with rivets 70 at a plurality of points along the entire periphery of the sheet body 50 . As a result, a sound insulation panel as shown in FIG. 1 is obtained. In addition, in the case of joining by Tacker, the rivet 70 may overlap the position where the communication hole 15 is formed, but joining at a plurality of locations does not pose a particular problem in joining strength.

Next, the operation of the sound insulation panel of the above embodiment will be described together with its effects.
(1) In the above embodiment, the sheet body 50 is laminated on the upper surface 10a of the resin structure 10 in which the communication holes 15 are formed. Therefore, the sound transmission loss effect is improved, and the sound insulation is improved as compared with the case of the resin structure 10 alone.

In general, the sound transmission loss effect of a wall made of the same material is proportional to the logarithm of the product of the mass per unit area of the wall and the sound frequency. In the sound insulation panel of the above embodiment, the sound insulation is improved more than the sound transmission loss effect due to the increased mass of the sheet body 50 . This is considered to be due to film vibration of the sheet body 50 between itself and the upper surface 10a in which the communication holes 15 are formed.

(2) In the above embodiment, the sheet body 50 is partially joined to the peripheral portion of the upper surface 10 a of the resin structure 10 . Therefore, the sound transmission loss effect due to film vibration of the sheet body 50 can be favorably exhibited while suppressing the displacement of the sheet body 50 .

(3) In the above embodiment, the communication hole 15 is formed in each of the plurality of cells S forming the resin structure 10 . Therefore, the entire sheet body 50 joined to the upper surface 10a of the resin structure 10 is likely to vibrate. A sound transmission loss effect can be achieved over the entire sound insulation panel.

(4) In the above embodiment, the resin structure 10 is formed in a hollow plate shape having a plurality of cells S, and each cell S is formed with a communication hole 15 . Therefore, sound pressure enters the internal space of each cell S through the communication hole 15, and the sound pressure in the internal space can be effectively reduced. That is, each cell S of the resin structure 10 can function as a so-called "Helmholtz resonator". The function of each cell S as a "Helmholtz resonator" promotes the vibration of the sheet body 50, improving the sound transmission loss effect of the entire sound insulation panel.

The above-described embodiment may be modified as follows, or may be applied in combination with the following modified examples.
- In the above embodiment, the plurality of communication holes 15 are formed only in the upper surface 10a of the resin structure 10, but the plurality of communication holes 15 may be formed in both the upper surface 10a and the lower surface of the resin structure 10. In this case, the communication hole 15 may be formed in both the upper closing wall and the lower closing wall in one cell S, or may be formed in only one of them.

In the above embodiment, a plurality of communication holes 15 are formed only in the upper surface 10a of the resin structure 10, and the sheet body 50 is laminated only on the upper surface 10a in which the communication holes 15 are formed. However, the present invention is not limited to this. When a plurality of communication holes 15 are formed on both the upper surface 10a and the lower surface of the resin structure 10, the sheet body 50 may be laminated on either surface, or the sheet bodies 50 may be laminated on both surfaces. . When the sheet bodies 50 are laminated on both surfaces, the entire resin structure 10 may be wrapped with the sheet bodies 50 .

- In the above-described embodiment, one communication hole 15 is formed substantially in the central portion of each cell S, but the formation position and number of the communication holes 15 are not limited to this. Further, in the above embodiment, the communication holes 15 are formed regularly throughout the resin structure 10, but the communication holes 15 may be formed irregularly. For example, one communicating hole 15 may be formed at a different location in each cell S, or a plurality of communicating holes may be formed. In addition, cells S in which communication holes 15 are formed and cells S in which communication holes 15 are not formed are mixed, or communication holes 15 are localized in a partial region of the upper surface 10 a or the lower surface of the resin structure 10 . You may

- In the above-described embodiment, the sheet body 50 is joined at a plurality of points along the entire periphery of the upper surface 10a of the resin structure 10, but the number of joints and the number of joints is not limited to this. The four corners of the upper surface 10a of the resin structure 10 may be joined, or the joints may be provided in the inner portion of the upper surface 10a. In short, it is sufficient that the entire sheet body 50 is not bonded to the entire upper surface 10a of the resin structure 10 and adhered thereto.

- In the above-described embodiment, the sheet body 50 is joined to the peripheral portion of the upper surface 10a of the resin structure 10 by the Tucker rivets 70, but the joining method is not limited to this. You may adhere with a double-sided tape, an adhesive agent, or the like. Alternatively, a pair of outer frames having a shape along the peripheral portions of the resin structure 10 and the sheet body 50 may be created, and the resin structure 10 and the sheet body 50 may be sandwiched between the pair of outer frames. The peripheral portions of the body 10 and the sheet body 50 may be sandwiched between a plurality of frames. Alternatively, a lattice-shaped frame formed by combining thin rods may be placed on the sheet body 50 and joined together with the sheet body 50 to the resin structure 10 .

- In the above-described embodiment, the sheet body 50 is directly laminated and joined to the upper surface 10a of the resin structure 10, but the present invention is not limited to this. A nonwoven fabric or the like may be laminated on the upper surface 10a of the resin structure 10 and the sheet body 50 may be bonded thereon, or a space may be formed between the upper surface 10a of the resin structure 10 and the sheet body 50. The sheet bodies 50 may be laminated and joined together.

- Although the upper surface 10a and the lower surface of the resin structure 10 are formed in a rectangular shape in the above-described embodiment, the shape is not limited to this. It may be a polygonal shape such as a triangular shape or a pentagonal shape, a circular shape such as a perfect circular shape or an elliptical shape, or an irregular shape.

- In the above-described embodiment, the sheet body 50 is formed to have substantially the same size and shape as the upper surface 10a of the resin structure 10, but the present invention is not limited to this. It may be larger or smaller than upper surface 10 a of resin structure 10 . Also, the shape of the sheet body 50 may be different from that of the upper surface 10 a of the resin structure 10 . Therefore, the size and shape may not cover the entire upper surface 10a of the resin structure 10 .

- In the above-described embodiment, the sheet body 50 is formed to have substantially the same size as the upper surface 10a of the resin structure 10, and one sheet body 50 is laminated on the upper surface 10a, but the present invention is not limited to this. Two sheets formed in half the size of the upper surface 10 a may be arranged and laminated, or a plurality of sheet bodies 50 may be arranged and laminated to cover the upper surface 10 a of the resin structure 10 .

- When forming the sheet|seat body 50 with a synthetic resin material, you may use what added various functional resins in the synthetic resin material. For example, flame retardancy can be enhanced by adding a flame retardant resin to a thermoplastic resin. It is also possible to increase the specific gravity by mixing talc, inorganic materials, or the like.

- The material of the core layer 20 and the skin layers 30 and 40 is not limited as long as it is a synthetic resin material. Also, various functional resins may be added in the same manner as the sheet body 50 . Even if a part of resin structure 10 contains a material other than synthetic resin, it can be said to be resin structure 10 if most of the material is made of synthetic resin.

- The resin structure 10 is not limited to forming the core layer 20 by folding and molding one first sheet material 100, and the core layer may be formed using a plurality of first sheet materials. For example, the core layer may be formed by bending a band-shaped first sheet material at predetermined intervals and arranging a plurality of these first sheet materials in parallel. In the case of this modification, the bent portion of each first sheet member constitutes the side wall portion of the cell.

In the above-described embodiment, the resin structure 10 has a structure in which a plurality of cells S are arranged in parallel by folding a sheet material, but the structure is not limited to this. A hollow plate having a harmonica-shaped cross section formed by extrusion may be used.

- The shape of the cell S is not particularly limited to a hexagonal prism shape. For example, it may have a cylindrical shape, or may have a polygonal prism shape such as a quadrangular prism shape or an octagonal prism shape. Further, the shape of the cells S may be, for example, a frustum shape or a shape in which the top surfaces of the frustum shapes are butted against each other. That is, it may have any shape as long as it has a columnar shape as a whole. Furthermore, the cells S having different shapes may be mixed in the core layer 20, or the cells S may not be adjacent to each other, and a space (gap) may be generated between the cells S. When there is a space (gap) between the cells S, the communication hole 15 is formed not only in a portion that communicates the inside and outside of the cell S, but also in the space between the cells S. It may be formed in the space between them.

In the above-described embodiment, the resin structure 10 is configured such that the communication holes 15 are formed after the skin layers 30 and 40 are laminated on the core layer 20 formed by folding a sheet material, but the present invention is not limited to this. . For example, after the core layer 20 is formed by extrusion molding, skin layers 30 and 40 having a plurality of communication holes 15 formed in advance may be laminated on the core layer 20 .

- The skin layers 30 and 40 are not limited to being joined to the core layer 20 by thermal welding. Alternatively, an adhesive layer made of, for example, a thermoplastic resin may be interposed between the core layer 20 and the skin layers 30 and 40, and the skin layers 30 and 40 may be joined to the core layer 20 by the adhesive strength of this adhesive layer. .

- In the above embodiment, the direction in which the core layer 20 is folded and compressed (the X direction) has been described as the direction in which the cells S are arranged side by side, but this is merely an example. For example, in FIG. 2(a), adjacent cells S share one side of the hexagon even in directions inclined by 30° and 60° with respect to the X direction, and are arranged side by side. I can say. Also, in cases other than the honeycomb structure, even if one side of the polygon is not shared, or if there is some deviation, if the cells form a row as a whole, it can be said that the cells are arranged side by side.

- As a sound insulation panel, the surface of the sheet body 50 may be further laminated with a wound cloth, paper, metal sheet, or the like. Alternatively, the sound insulation panel may be wrapped with cloth, paper, metal sheet, or the like.

Next, a test of the sound transmission loss effect of the sound insulation panel of the present invention will be described.
[Test 1]
In Test 1, the effect of sound transmission loss was evaluated by bonding the sheet body 50 to the surface of the resin structure 10 on which the communication holes 15 were formed.

The sound transmission loss was measured according to JIS-A1416. The same applies to the measurement of sound transmission loss in Tests 2 to 7 below.
Specifically, a sound insulation panel as a test sample was placed between two reverberation rooms (a sound source room and a sound receiving room) (partition opening), and the sound transmission loss was measured to evaluate sound insulation. Random noise was output from the sound source room side, and the average sound pressure level of the sound that was sufficiently diffused in the sound source room and the average sound pressure level of the sound that was transmitted through the specimen and radiated to the sound receiving room side and diffused were measured. In addition, the reverberation time of the sound receiving room was measured, and the sound transmission loss R (dB) was calculated by the following formulas (1) and (2).

A=0.16V/T (1)
R= _L1 - _L2 + _10log10S /A (2)
L ₁ ; Indoor average sound pressure level (dB) in the sound source room
L ₂ ; Indoor average sound pressure level (dB) in the sound receiving room
S ; area of test specimen with a width equal to open test opening (m ² )
A ; Equivalent sound absorption area of sound receiving room (m ² )
V ; Volume of sound receiving room (m ³ )
T ; Reverberation time of sound receiving room (sec)
FIG. 4 shows a schematic diagram of the arrangement of the sound insulation panels. Each of the resin structures 10 constituting the sound insulation panel had a thickness of 30 mm and had a communicating hole 15 with a diameter of 1.0 mm formed only on one surface. In Condition 1A (FIG. 4A), only the resin structure 10 was placed between the sound source room and the sound receiving room such that the communication hole 15 faced the sound source side. Condition 1B (FIG. 4(b)) is a sound insulation panel in which a sheet body 50 having the same shape is joined to the periphery of the surface of the resin structure 10 where the communication holes 15 are formed, and the sheet body 50 faces the sound source side. placed like this. In condition 1C (FIG. 4(c)), the same sound insulation panel as in condition 1B was placed so that the sheet body 50 faced the sound receiving side. Condition 1D (FIG. 4(d)) is a sound insulation panel in which a sheet body 50 having the same shape is joined to the peripheral portion of the surface of the resin structure 10 on which the communication hole 15 is not formed, and the sheet body 50 faces the sound receiving side. placed facing the direction. The joined sheet bodies 50 are all vinyl chloride sheets and have a thickness of 1.2 mm. Table 1 shows the configuration and arrangement of each sound insulation panel. In Table 1, the lamination side of the sheet body 50 and the closed side refer to the side of the resin structure 10 on which the communication holes 15 are not formed.

The following results were obtained from Test 1. From the results of Condition 1A and Condition 1D, the sheet body 50 bonded to the surface of the resin structure 10 on which the communicating hole 15 is not formed has a slightly higher acoustic loss transmission over the entire frequency range than the resin structure 10 alone. Improved effectiveness. Under condition 1D, it is considered that the sound loss transmission effect is slightly improved due to the influence of the increased mass of the sheet body 50 . On the other hand, from the results of Condition 1A and Condition 1B, Condition 1B showed a significant increase in the sound loss transmission effect from the low frequency region. Similar results were also obtained under condition 1C.

From these results, it can be seen that by bonding the sheet body 50 to the surface of the resin structure 10 on which the communication holes 15 are formed, the sound insulation is improved more than the sound transmission loss effect due to the increase in the mass of the sheet body 50. rice field. In addition, in the case where the sheet body 50 is joined to the surface of the resin structure 10 on which the communicating holes 15 are formed, the sheet body 50 is installed on the sound source room side and the sound receiving room side. It has been found that a certain degree of sound transmission loss effect can be obtained.

[Test 2]
In Test 2, regarding the resin structure 10 constituting the sound insulation panel, the hollow volume of the cells S formed in the resin structure 10 and the diameter of the communication holes 15 formed in the resin structure 10 were evaluated for the sound transmission loss effect. .

As a result, the larger the hollow volume of the cells S formed in the resin structure 10, the greater the sound loss transmission effect from the low frequency region. The hollow volume of the cell S was preferably 1000 mm ³ or more, more preferably 2000 mm ³ or more. When it was 3000 mm ³ or more, the sound insulation could be improved more efficiently. In particular, when the hollow volume of the cell S was 3000 mm ³ or more, a remarkable increase in the sound loss transmission effect was observed from the low frequency region. This effect was the same when the sheet body 50 (communication hole 15) was arranged on the sound source side and when it was arranged on the sound receiving side.

Also, the smaller the diameter of the communication hole 15 formed in the resin structure 10, the greater the sound loss transmission effect from the low frequency region. The diameter of the cell S was preferably 0.3-3.0 mm, more preferably 0.75-2.0 mm.

[Test 3]
In Test 3, the sound transmission loss effect was evaluated using a sound insulation panel in which communication holes 15 were formed on both sides of the resin structure 10 constituting the sound insulation panel. FIG. 5 shows a schematic diagram of the arrangement of the sound insulation panels.

The same resin structure 10 and sheet body 50 that constitute the sound insulation panel are used in FIGS. 5(a) to 5(c). FIG. 5(a) shows a sound insulation structure in which only the resin structure 10 is arranged between the sound source room and the sound reception room, and FIG. The panel is arranged with the sheet body 50 facing the sound receiving side, and FIG.

As a result, by laminating the sheet body 50 on one side of the resin structure 10 having the communicating holes 15 formed on both sides, the acoustic loss effect is increased, and by laminating the sheet body 50 on both sides, Furthermore, the sound transmission loss effect is increased. In addition, the sound transmission loss effect from the low frequency range increased in the case where the sheet bodies 50 were laminated on both sides, rather than in the case where the sheet bodies 50 were laminated only on one side.

[Test 4]
In Test 4, the sheet body 50 constituting the sound insulation panel was evaluated for the sound transmission loss effect due to the difference in basis weight. Using the same resin structure 10 constituting the sound insulation panel, sheet bodies 50 having different basis weights were laminated.

As a result, the larger the basis weight of the sheet body 50, the greater the sound transmission loss effect from the low frequency range. From the standpoint of increasing the sound transmission loss effect and keeping the mass of the sound insulation panel as a whole within a suitable range, the basis weight of the sheet body 50 is preferably 1000 g/m ² or more, more preferably 1500 g/m ² or more. 1, more preferably 2000 g/m ² . Moreover, from the viewpoint of suitable film vibration of the sheet body 50, the Young's modulus of the sheet body 50 is preferably 50 MPa or more, more preferably 90 MPa or more. In particular, when the basis weight of the sheet body was 2000 g/m ² or more, or when the Young's modulus was 90 MPa or more, the sound loss transmission effect was remarkably increased from the low frequency region.

[Test 5]
In test 5, the sound transmission loss effect of the bonding method of the sheet body 50 to the resin structure 10 was evaluated.

As a result, when the sheet body 50 was partially joined to the resin structure 10, the sound transmission loss effect increased more than when the whole was joined. It was found that the acoustic effect loss effect can be increased by setting the joint area of the sheet body 50 to be small so that the sheet body 50 causes film vibration on the resin structure 10 .

S... Cell, S1... First cell, S2... Second cell, 10... Resin structure, 10a... Upper surface, 15... Communication hole, 20... Core layer, 21... Upper wall (closed wall), 22... Lower wall Part (blocking wall) 23 Side wall 30 Skin layer (blocking wall) 40 Skin layer (blocking wall) 50 Sheet body 60 Penetrating member.

Claims (3)

A sound insulation panel comprising a hollow plate-shaped resin structure in which a plurality of column-shaped cells are arranged side by side, and a sheet body,
The resin structure includes a side wall section that divides the cell into a columnar shape, and a pair of blocking walls that block upper and lower portions of the side wall section. A first closing wall formed with a communication hole that communicates with the
The communication hole is formed at one or a plurality of different locations in each cell,
A sound insulation panel, wherein the sheet body is laminated on at least one outer surface of a hollow plate-shaped resin structure in which a plurality of columnar cells are arranged side by side. The sound insulation panel according to claim 1, wherein the communication holes are irregularly formed in the first blocking wall. The sound insulation panel according to claim 1, wherein the sheet body has a basis weight of 1000 g/ ^m2 or more and a specific gravity of 0.9 or more.

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