JP2011026815A - Sound absorption panel - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a light-weighted sound absorption panel capable of enhancing a sound absorption rate of about 500 Hz or less of low-frequency range, capable of thinning a thickness, capable of generating hardly end face separation, and capable of attaching-fixing a required part by a nail/screw tightening. <P>SOLUTION: A gas impermeable face bar 31 is arranged on at least one face of a plate-like honeycomb core 11 with opened both faces, an outer circumference of the honeycomb core 11 is surrounded by a frame-like member 21 comprising a cellular body of closed cell structure, at least one face of the gas impermeable face bar 31 is fixed onto the frame-like member 21, and is not fixed to the honeycomb core 11, and at least one part of the frame-like member 21 is constituted of the cellular body of closed cell structure having 0.3-0.8 g/cm<SP>3</SP>of density. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a sound absorbing panel in which a non-breathable face material is laminated on at least a sound absorbing surface of a honeycomb core having both sides opened.

  Honeycomb cores in which the planar shape of cells (chambers) surrounded by partition walls are triangular, quadrangular, hexagonal (honeycomb), octagonal, or circular are used as panel structures because they are lightweight and rigid. It is also known to have sound absorption characteristics (rectifying effect). By arranging the porous sound-absorbing material directly on the front surface of this honeycomb core, the high-frequency sound-absorbing property of the porous sound-absorbing material can be improved to the middle frequency range by the rectification effect and the back air layer effect of the honeycomb core. Has been proposed (Patent Documents 1 and 2). However, depending on this structure, there is a problem that if the honeycomb core has a thickness of 50 mm or more, the sound absorption improvement effect cannot be obtained when the frequency is in a low frequency range of 500 Hz or less.

  In addition, a sound absorbing panel obtained by bonding and integrating a plate-like body and a honeycomb core has been proposed (Patent Documents 3 and 4). However, since this structure is inferior in performance as a sound absorbing panel, it is mainly used as a sound insulating material.

  There has also been proposed a structure in which an attachment portion is attached in a frame shape around a plate-like body via a vibration damping member (damping material), and the frame is fixed to a rigid plate member (Patent Document 5). However, this structure has a problem that good sound-absorbing property cannot be obtained in a low frequency range of 500 Hz or less, and the thickness becomes large.

Furthermore, a sound-absorbing panel with a face material bonded to the surface (opening surface) of the honeycomb core is a nail for the purpose of end face peeling (peeling at the end of the face material) and mounting the panel to a fixed wall surface.・ There is also a problem with screwing.
Regarding end face peeling, the manufacturing end face (horizontal face) of the honeycomb core is not smooth, and the bonding between the opening face of the honeycomb core and the face material becomes line adhesion, so that the strength retention becomes insufficient and the face material End peeling (end face peeling) is likely to occur.
Therefore, there is a structure in which a wooden frame is provided around the honeycomb core to strengthen the fixation of the face material to make it difficult to peel off the face material, and the side surface (the end) of the panel is smooth or curved (Patent Document 6). 7). However, since the wooden frame has water absorbency and hygroscopicity, there is a problem of warping or twisting.

  On the other hand, with regard to nails and screwing, the honeycomb core has a structure having a plurality of cells (openings and chambers surrounded by partition walls), so when nailing and screwing, the nails and screws that pierce the face material are cells. It is in a free state at the (opening) part, and it is difficult to firmly fix it. Therefore, nails and screws are attached to the piece of wood (Patent Documents 6 and 7). However, there are problems such as loss of waterproofness at the pierced portion of the nail and screw, and an increase in weight due to use of the piece of wood. Depending on the material such as the particle board piece, there is a problem that the strength is insufficient at the nail / screwed portion. In Patent Document 4, it is also proposed to use a non-combustible material that does not change due to water absorption and to be filled with the non-combustible material to enable nailing and screwing. Since the force is not sufficient and the incombustible material is expensive, there is a problem that it is expensive for an application that does not require incombustibility. In addition, special nails and screw fasteners are provided on a part of the honeycomb core (Patent Document 8). However, in this case, the manufacturing process is complicated, and there is anxiety about the holding property of the nail and screw fastener to the honeycomb core. For this reason, the current situation is that the metal frame or metal fitting is sandwiched between the outer periphery.

JP 2005-247235 A JP 2005-17636 A JP-A-8-151704 JP 2005-254478 A JP 2005-134653 A Japanese Patent Laid-Open No. 5-124164 JP-A-7-68975 JP 2009-6947 A

  The present invention has been made in view of the above points, and has good sound absorption in a low frequency range of 500 Hz or less, can be made difficult to cause end face peeling, and further, panel without impairing lightness. It is an object of the present invention to provide a sound absorbing panel that can be easily attached by nails or screwing without attaching a metal frame or metal fittings to the outer periphery.

  The invention according to claim 1 is a sound-absorbing panel in which a non-breathable face member is disposed on at least one side of a plate-shaped honeycomb core having both sides opened, and the outer periphery of the honeycomb core is made of a foam having a closed cell structure. The non-breathable face material is fixed to the frame-shaped member, and at least the one-side non-breathable face material is unfixed to the honeycomb core.

  A second aspect of the present invention is directed to the first aspect, wherein the honeycomb core is formed into a plurality of layers, and the non-breathable face material is disposed between the honeycomb cores and at least one outer surface of the honeycomb core. The frame-shaped member is provided on the outer periphery of the core, and the non-breathable face material is fixed to the frame-shaped member. At least the face material on the outer surface of the honeycomb core on one side is in contact with the honeycomb core. It is characterized by being non-fixed.

According to a third aspect of the present invention, in the first or second aspect, at least a part of the frame-shaped member is formed of a foam having a closed cell structure with a density of 0.3 to 0.8 g / cm ³ .

  According to the first aspect of the present invention, in the sound-absorbing panel in which the non-breathable face material is arranged on at least one side of the plate-shaped honeycomb core having both sides opened, the outer periphery of the honeycomb core is made of a foam having a closed cell structure. The non-breathable face material is fixed to the frame-shaped member surrounded by a ring-shaped member, and at least the non-breathable face material on one side is not fixed to the honeycomb core, so that the frequency is around 500 Hz. The sound absorption rate can be increased in the following low frequency range, and the thickness of the sound absorption panel can be reduced. Moreover, since the face material is fixed to the frame-shaped member made of a foam having a closed cell structure surrounding the outer periphery of the honeycomb core, end face peeling can be prevented. Moreover, since the foam of the closed cell structure which comprises a frame-shaped member has a low density compared with a wooden frame, the lightweight property which is the characteristic of a honeycomb core is not impaired. Further, the closed-cell structure foam constituting the frame-shaped member is prevented from being twisted or deformed due to water absorption of the frame-shaped portion because the closed-cell structure prevents moisture from being impregnated.

  According to the invention of claim 2, the honeycomb core is formed into a plurality of layers, the non-breathable face material is disposed between the honeycomb cores and at least the outer surface of the honeycomb core on one side, and the outer periphery of each honeycomb core is disposed. Each of the frame-shaped members is provided, and the non-breathable face material is fixed to the frame-shaped member, and at least the face material on the outer surface of the honeycomb core on one side is not fixed to the honeycomb core. Therefore, the effect of improving the sound absorption rate in the low frequency range of around 500 Hz or less, the effect of preventing the end face peeling, the light weight effect, the twisting due to the water absorption of the frame-like part, and the effect of preventing the deformation are obtained as in the case of claim 1. Furthermore, the effect of improving the sound absorption rate can be obtained even in a high frequency range higher than 500 Hz.

According to invention of Claim 3, since at least one part of a frame-shaped member consists of a foam of the closed cell structure of density 0.3-0.8 g / cm < ³ >, this high density (0.3-0.8 g / Cm ³ ), the nail / screw holding force is increased in the portion composed of the foam having a closed cell structure, and the nail / screw fastening becomes possible. In addition, the foam having a closed cell structure having a high density (0.3 to 0.8 g / cm ³ ) has a lower density than a wooden frame, and thus does not impair the light weight characteristic of the honeycomb core. Further, since the closed cell structure foam with a high density (0.3 to 0.8 g / cm ³ ) capable of being nail-screwed can be prevented from being impregnated with water, the nail / screw portion Therefore, there is no risk of twisting or deformation due to water absorption.

It is a top view which notches and shows a part of sound-absorbing panel which concerns on 1st Embodiment. It is 2-2 expanded sectional drawing of FIG. It is a top view of the state which removed the face material in FIG. It is a top view which shows the example of a frame-shaped member. It is a partial sectional view of a sound absorption panel concerning a 2nd embodiment. It is a figure which shows the time of the assembly of the frame-shaped member at the time of sound absorption panel preparation of Example 1. FIG. It is a graph which shows the reverberation room sound absorption rate measurement result of Examples 1-3 and Comparative Examples 1-3. It is a graph which shows the reverberation room sound absorption rate measurement result of Example 1, 4, 5 and the comparative example 4. FIG. It is a sketch of the factory which measured the noise level. It is a graph which shows the measurement result of a noise level. It is a table | surface which shows the reduction effect of a noise level.

  The sound absorbing panel of the present invention will be described below with reference to the drawings. The sound absorbing panel 10 of the first embodiment shown in FIGS. 1 to 3 has a non-breathable face material 31 disposed on at least one side of a plate-like honeycomb core 11 having both sides opened, and surrounds the outer periphery of the honeycomb core 11. The face material 31 is fixed to a frame-like member 21 made of a foam having a closed cell structure. In the illustrated example, non-breathable face materials 31 are arranged on both surfaces (opening surfaces on both sides) of the honeycomb core 11. One surface of the sound absorbing panel 10 is a sound absorbing surface (a surface directed toward the sound source side), and the opposite surface is a back surface. One side of the honeycomb core 11 where the face material is indispensable is a sound absorbing surface. In the present embodiment, in the case of distinguishing the sound absorbing surface side surface material from the back surface surface material of the non-breathable surface material 31 provided on both surfaces of the honeycomb core 11, the sound absorbing surface side non-breathable surface material is 310. And the non-breathable face material on the opposite back side is 311.

  The honeycomb core 11 has a plurality of cells (chambers) 15 partitioned by partition walls 13, and the cells 15 are open at both ends in the height direction (that is, the thickness direction of the honeycomb core). The honeycomb core 11 is not limited to a hexagonal (honeycomb shape) cell planar shape as in the present embodiment. For example, the honeycomb core 11 is a polygon such as a triangle, a quadrangle, a pentagon, an octagon, or a flute (wave shape). ), Or a circular shape. In particular, from the viewpoint of the strength of the honeycomb core and the ease of manufacturing, the planar shape of the cell is preferably a hexagonal shape (honeycomb), a flute shape, or a circular shape.

  Examples of the material of the honeycomb core 11 include paper, metal, resin, ceramic, and the like, but particularly inexpensive and lightweight paper and resin are preferable. When nonflammability is required, nonflammable paper such as ceramic or aluminum can be suitably used. In addition, the cell size of the honeycomb core 11 is not particularly limited, but if it is too small, the weight of the honeycomb core increases and the sound absorbing panel 10 becomes heavy. Since it becomes a cause, the range of 5-50 mm is preferable. In addition, the height (thickness) of the honeycomb core 11 is too heavy if it is too low, and if it is too high, the strength of the honeycomb core 11 (base material 11) is reduced. The planar dimension of the honeycomb core 11 is preferably 100 mm square or more from the viewpoint of securing a preferable range of the non-fixed portion in the sound absorbing surface side surface material 310 described later.

  The frame-shaped member 21 is formed of a foam having a closed cell structure, surrounds the entire outer periphery of the honeycomb core 11, and is fixed to a later-described face material 31 by adhesion or the like. Examples of the foam having a closed cell structure include a polyethylene resin, a polypropylene resin, a polystyrene resin, a fluorine polyolefin resin, and a polyurethane resin. The thickness (height) of the frame-shaped member 21 is the same as the thickness (height) of the honeycomb core 11. The width is preferably 5 to 30 mm. If the width is too narrow, adhesion between the honeycomb core 11 and the face material 31 described later becomes insufficient, and sufficient panel strength cannot be obtained. On the other hand, when the width is too wide, the weight of the sound absorbing panel 10 is increased. The frame-shaped member 21 is not limited to a series of frame shapes formed by punching or the like, and may be a frame shape formed by joining a plurality of closed-cell foams. In the present embodiment, four foams having a closed cell structure are formed into a frame shape by bonding. FIG. 4 shows another example of the case where the frame-shaped member 21 is formed of a foam having a plurality of closed cell structures. 4 (A) and 4 (B) are a plurality of prismatic foams made into a frame shape by bonding (including fixing such as fusion), and (C) and (D) are fitting and bonding. It is made into a frame shape by using together. A frame shape may be formed only by fitting (not shown). Further, the frame-shaped member 21 may be foamed on the outer periphery of the honeycomb core 11 and processed into a predetermined shape and size. Further, the frame-like member 21 may be subjected to a water-repellent coating process on the surface of a foam having a closed cell structure, or may be laminated with a moisture-proof layer (non-breathable / water vapor impermeable film).

The density of the closed cell structure foam constituting the frame member 21 is 0.05 to 0.3 g / cm ³ when the nail and screwing are not performed at the frame member 21 portion. Is more preferable, and 0.1 to 0.2 g / cm ³ is more preferable. If the density is too low, the sound absorbing panel 10 becomes too soft and the edge of the sound absorbing panel 10 has low strength, while if the density is too high, the sound absorbing panel 10 becomes heavy. In this case, the preferred foaming ratio of the foam having the closed cell structure is 4 to 25 times, and the 25% compression hardness (JIS K6767) of the foam having the closed cell structure is that of the sound absorbing panel 10. From the viewpoint of edge strength, 0.15 MPa or more is preferable. As a particularly preferred specific example of the foam having the closed cell structure in the case where nail and screwing are not performed, polyethylene foam can be mentioned.

On the other hand, when the frame-shaped member 21 can be nail-screwed, the closed-cell structure foam constituting the frame-shaped member 21 has a high density of 0.3 to 0.8 g / cm ³ . A foam is preferred. If the density is too low, nails and screws are difficult to stay, while if the density is too high, the sound absorbing panel 10 becomes heavy. In this case, the preferred foaming ratio of the foam having a closed cell structure is 1.3 to 4 times. Further, as a particularly preferable specific example of the foam having the closed cell structure in the case of performing nailing and screwing, a polystyrene foam can be exemplified. Further, when only a part of the frame-shaped member 21 is a nail / screw-fastenable part, the closed cell structure foam of the nail / screw-fastenable part has a density of 0.3 to 0.8 g / cm ^3, the foam of closed cell structure of the other portions may be density 0.05 to 0.3 g / cm ^3. Further, if necessary, the honeycomb core 11 is divided into a plurality of parts, and a high density foam having a density of 0.3 to 0.8 g / cm ³ is provided as an intermediate material at the boundary, and a nail / screw is provided at the center of the face material. It may be possible to fasten. That is, the honeycomb core is composed of a plurality of honeycomb cores parallel to the face material, and a foam (intermediate body) having a closed cell structure with a density of 0.3 to 0.8 g / cm ³ is disposed between the honeycomb cores. May be.

  The four corners of the frame member 21 (corresponding to the four corners of the lightweight honeycomb core panel) may be chamfered. As the molding method of the lip (outside lateral surface) 41 of the frame-shaped member 21, vacuum molding, post foam, direct post foam, soft foam, soft laminate, edge banding (straight, round), transfer, bag pasting , J cut, V cut, driving, direct printing, painting, resin filling, and the like.

  The face material 31 is made of a non-breathable sheet material. Examples of the non-breathable sheet material include non-porous resin, rubber / elastomer, metal, and inorganic material. Specifically, polypropylene, polyethylene, polystyrene, styrene rubber, silicon rubber, polycarbonate, ABS resin, polyacrylonitrile, polymethyl methacrylate, fluororesin, melamine resin, polyester resin, diallyl phthalate resin and other resin sheets, aluminum, iron In addition, a metal sheet such as stainless steel, a ceramic sheet, non-combustible paper, or the like may be used alone or in a laminated form.

  The face material 31 has a size that can cover the honeycomb core of the base material 11 and the outer frame member 21. The face material 310 on the sound absorbing surface side is not fixed to the honeycomb core 11, and only the edge of the face material 310 is fixed to the surface of the frame-shaped member 21 by bonding or the like. The portion of the sound absorbing surface side surface material 310 that is not fixed to the honeycomb core 11 is preferably 100 mm square (100 m × 100 mm square) or more, and more preferably 150 mm square or more. If even one side of the outer periphery of the non-fixed portion is smaller than 100 mm, the sound absorption effect due to resonance cannot be sufficiently obtained, and not only the sound absorption range is shifted to the high frequency range, but also the sound absorption rate is somewhat lowered. If the surface material 310 on the sound absorbing surface side is fixed to the honeycomb core, the sound absorption range is not only shifted to the high frequency region but also the sound absorption rate is somewhat reduced, even if the same size, for example, 150 mm square is fixed only to the frame material. Therefore, no face material is attached to the honeycomb core of the sound absorbing surface. The face material 311 on the back surface side opposite to the sound absorbing surface side may be fixed not only to the frame-shaped member 21 but also to the honeycomb core 11 by bonding or the like. If the face material 311 on the back surface side is fixed to the honeycomb core 11 as described above, the strength of the sound absorbing panel 10 can be improved.

Further, for the surface material 310 on the sound absorbing surface side, if the surface density (surface weight) is too low, the peak frequency at which the sound absorption coefficient reaches a peak shifts to the high frequency side, and the sound absorption coefficient decreases. On the other hand, if the surface density is too high, the sound absorption coefficient is lowered although the peak frequency is shifted to the low frequency side. Therefore, a preferable surface density of the face material 310 is 0.05 to 2.0 kg / m ² . The surface density is defined as a unit representing the weight of an object per unit area, and is obtained by multiplying the density (g / cm ³ ) of the object by the thickness (cm). The unit is kg / m ² , g / cm ² or the like.

  Note that the foam 41 of the frame-shaped member 21 may be exposed as it is in the mouth 41 of the frame-shaped member 21. In that case, the foam of the frame-shaped member 21 may be at the same position as the edge of the face member 31, or the foam of the frame-shaped member 21 protrudes from the edge of the face member 31. Good.

  Further, the lip 41 of the frame-shaped member 21 may be attached with a lip tape or a lip member such as resin or metal fitting. The lip member has a shape that can cover the lip 41 of the frame-shaped member 21 such as a U-shaped cross section or an L-shaped cross section. When attaching the end member to the end 41 of the frame member 21, the edge of the face material 31 may be sandwiched between the end member and the frame member 21. Furthermore, the non-breathable sheet material on the surface of the face material can be folded and bonded between the back surface or the face material on the front surface and the frame member.

  The adhesive used for fixing the honeycomb core 11, the frame-shaped member 21, the face material 31, the end member, and the like is not particularly limited. Examples include aqueous emulsion systems such as vinyl acetate emulsion and aqueous vinyl urethane, solvent systems such as general resins, synthetic rubbers and urethane resins, and inorganic solvent resin systems such as hot melt adhesives such as urethane resins, epoxy resins and polyester systems. However, in order to improve water resistance, solvent-free resin-based materials such as the solvent-based and hot-melt adhesives are preferable. For fixing, in addition to bonding with an adhesive, pressure-sensitive adhesive, adhesive such as double-sided adhesive tape, welding, fusion (such as heat, high-frequency or ultrasonic fusion), and pressure bonding can be used. Any one or a plurality of methods are selected according to the material of the adherend.

  The sound-absorbing panel of the present invention is not limited to the one-layer (single-stage) honeycomb core, and the honeycomb core is composed of a plurality of layers (multi-stage). Alternatively, a non-breathable face material may be provided, a frame-like member may be provided on the outer periphery of each honeycomb core, and the face material on one side (sound absorbing side) may be fixed only to the frame-like member.

  The sound absorbing panel 10A of the second embodiment shown in FIG. 5 is an example in which the honeycomb core has two layers. In this sound absorbing panel 10A, the non-breathable face materials 31A, 32A, 33A are disposed between the honeycomb cores 11A, 12A and on the outer surfaces of the honeycomb cores 11A, 12A on both sides, and the outer periphery of each honeycomb core 11A, 12A. Are provided with frame-like members 21A and 22A made of the foam of the closed cell structure, respectively, and the edges of the non-breathable face materials 31A, 32A and 33A are fixed to the frame-like members 21A and 22A, respectively, The face material 31A disposed on the outer surface of the honeycomb core 11A on the sound absorbing side is not fixed to the honeycomb core 11A. The other face materials 32A and 33A may be either non-fixed or fixed to the corresponding honeycomb core. If the other face materials 32A and 33A are fixed to the corresponding honeycomb core (for example, the face material 32A is fixed to at least one of the honeycomb core 11A and the honeycomb core 12A, and the other face material 33A is fixed to the honeycomb core 12A). The strength of the sound absorbing panel 10A can be increased, which is more preferable. Reference numerals 41A and 42A denote a butt. The height of the honeycomb core does not have to be the same in all layers, and each layer may be different.

Example 1
As shown in FIG. 6, on a work board 61 of 1000 × 700 mm, a polyethylene foam manufactured by Inoac Corporation, product name: PE Lite · A12 (density 0.12 g / cm ³ , 25% compression hardness 0.25 MPa). Adhere four prisms 62, 63 with width 30mm, height 45mm, length 910mm and square pillars 64, 65 with the same width, height and length of 550mm from the same polyethylene foam. A frame-shaped member having a length of 910 mm, a width of 610 mm, and a thickness (height) of 45 mm was formed. Next, using a roll coater, melted hot-melt adhesive: a moisture-reactive urethane-based hot-melt adhesive manufactured by Dainippon Ink Industries, Ltd., product name: FH-300 was applied to the upper surface of the frame-like member, and the wood material sheet: Nelson Pine Made by company, product name: MDF (1 mm thickness, 0.75 g / cm ³ ), a face material having a plane size of 910 mm × 610 mm was put on and bonded by pressure bonding. After cooling, this is turned over and the bonded face material is used as the lower surface, and a honeycomb core: a paper honeycomb core (cell diameter 12 mm) manufactured by Nippon Daiscore Co., Ltd. is accommodated in a length of 850 mm × width of 550 mm × height of 45 mm. did. The hot melt adhesive was again applied to the upper surfaces of the frame-shaped member and the honeycomb core by a roll coater, and the face material was covered and pressure bonded.

The panel intermediate thus obtained was chamfered and cut to 900 mm × 600 mm, and further melted on one side of the face material: moisture reaction type urethane hot melt adhesive made by Dainippon Ink & Chemicals, Inc. Agent, product name: FH-300 was applied with a roll coater, and a polypropylene sheet with a decorative print (0.18 mm thickness) manufactured by Toppan Corp. was pressure-bonded to the coated surface. After cooling, the polypropylene sheet was turned upside down, and the polypropylene sheet was used as the lower surface. The hot melt adhesive melted in the upper surface material: a moisture-reactive urethane hot melt adhesive manufactured by Dainippon Ink Industries, Ltd., product name: FH-300 as a roll coater A polypropylene sheet with a decorative print made by Toppan (0.18 mm thickness) was pressure-bonded to the coated surface, and a sound-absorbing panel having a lateral surface attached to a bag was produced. Two sound absorbing panels were produced and the weights were measured. The measurement result was 2.25 kg on average, which was light. Further, the sound absorbing surface was not inferior to the back surface in which the face material was fixed on the entire surface, such as appearance and strength, although the honeycomb core and the face material were not fixed. The two sound absorbing panels were arranged to be 1200 mm × 900 mm, the sound absorbing surface on the non-fixed side of the face material was turned up, and the reverberation chamber sound absorption rate was measured based on JIS A 1409. However, a reverberation chamber volume of 36 m ³ was used. As shown in FIG. 7, the reverberation chamber sound absorption coefficient showed a sharp sound absorption peak centered at a frequency of 250 Hz.

Example 2
The same as in Example 1, except that the frame-shaped member was polystyrene foam manufactured by Inoac Corporation, product name: Durawood PS (density 0.5 g / cm ³ , height 25 mm), and the honeycomb core height was 25 mm. Thus, a sound absorbing panel was obtained. The weight of the sound absorbing panel was an average of 2.45 kg. In addition, as shown in FIG. 7, the measurement result of the reverberation chamber sound absorption coefficient showed a sharp sound absorption peak centered at a frequency of 400 Hz.

Comparative example 1
In Example 2, a sound absorbing panel was obtained in the same manner except that the face material was bonded to the frame member and the honeycomb core on both sides of the panel. As shown in FIG. 7, the measurement result of the reverberation chamber sound absorption rate in this sound absorption panel was such that the sound absorption rate was low and the center frequency was greatly shifted to the high frequency side.

Comparative example 2
In Example 2, the frame-shaped member is not used, and the surface material and the honeycomb core on the sound absorbing surface side are bonded to the outer periphery of the honeycomb core and three stripes (30 mm width at 112.5 mm intervals) set inside thereof. went. For this adhesion, the hot melt adhesive used in Example 2 was used. As shown in FIG. 7, the measurement result of the reverberation chamber sound absorption rate in this sound absorption panel was such that the center frequency of the sound absorption rate shifted to a high frequency and the sound absorption rate was low. Further, there is a problem that the outer periphery of the sound absorbing panel is soft and easily deformed.

Example 3
In Example 1, for the frame-shaped member, a product made by Inoac Corporation, product name: PE Lite · A8 (density 0.06 g / cm ³ , 25% compression hardness 0.09 MPa), a prismatic material having a width of 30 mm and a height of 18 mm is used. The honeycomb core uses a paper honeycomb core / flute shape (cell diameter 10 mm, height 18 mm) manufactured by Nihon Daiscore Co., Ltd. The melamine decorative sheet manufactured by Ibiden Co., Ltd., product name: IB-7121 (0.8 mm thickness) A sound-absorbing panel was produced in the same manner as in Example 1 except that Kiuchi tape: Pattyfuri Kogyo ABS (0.45 mm thickness) was affixed to the lateral surface (the face of the mouth) of the frame-shaped member. The weight of the sound absorbing panel was 1.55 kg on average. As a result of measuring the sound absorption coefficient of the reverberation chamber for this sound absorbing panel, a sharp sound absorption peak centered around a frequency of 500 Hz was obtained as shown in FIG.

  Further, in Example 3, two pieces having a size of 300 × 150 mm were produced in the same manner, and the following water resistance test method was performed. (1) After 24 hours of water immersion, (2) After changing to 60 ° C for 24 hours and after 24 hours of water immersion, change the thickness between the face materials with calipers for a total of 6 points in the middle of each corner and 300 mm width. It was measured. When the change before and after the test is + 1% or more, it is regarded as swelling due to water immersion. As for the measurement results, the expansion coefficient was small at all six points, and no water was observed, and the water resistance was good. (1) Average 0.12%, (2) Average 0.05%

Comparative example 3
A sound-absorbing panel was produced in the same manner as in Example 3 except that Particle Board: manufactured by Shin-Akigi Industry Co., Ltd., product name: U-18 (density 0.68 g / cm ³ , height 18 mm) was used as the frame member. The weight of the sound absorbing panel was 2.35 kg, which was heavier than that of Example 3. Moreover, the reverberation chamber sound absorption rate measurement result of this sound absorption panel showed the same tendency as Example 3 as shown in FIG. Further, in the water resistance test method, (1) After 24-hour immersion: 3-point immersion was confirmed (4.2, 3.6, 6.3%). (2) After standing at 60 ° C. for 24 hours and then immersed for 24 hours: Three-point immersion was confirmed (7.5%, 5.3%, 2.9%), and there was a problem with water resistance.

Example 4
In Example 1, a panel intermediate of 910 × 610 mm was obtained in the same manner as in Example 1 except that the height of the prismatic material of the frame member and the honeycomb core was 15 mm. Next, another frame-like member is formed on the work wood board 61 of 1000 × 700 mm by placing the prismatic material having a height of 30 mm so as to be the same size as the frame-like member of the panel intermediate. After the hot melt adhesive was applied to the shaped member, the back surface of the 15 mm high panel intermediate was attached. After cooling, it is turned over and a 30 mm high honeycomb core is accommodated in a 30 mm high frame member, a hot melt adhesive is applied, and a face material is attached to the frame member and the honeycomb core. In the same manner as above, a multi-layer structure (sound absorbing surface to face material / honeycomb core with a height of 15 mm // face material / honeycomb core with a height of 30 mm // face material; ) Sound absorbing panel (900 × 600 × 45 mm). The sound absorbing panel weighed 2.73 kg. Further, as a result of measuring the reverberation chamber sound absorption coefficient, as shown in FIG. 8, it has a sharp sound absorption main peak centered around the frequency of 250 Hz and a sub peak near 630 Hz.

Example 5
In Example 1, a low-density foam of a frame-shaped member, manufactured by Inoac Corporation, product name: PE Light A12, each of the upper and lower portions of 910 mm in length, each 50 mm high-density foam: manufactured by Inoac Corporation, product name: Durawood PS (specific gravity 0.5g / cm ³ )
Replaced by a prismatic material with a width of 30 mm and a height of 45 mm, and the back material was a 15 mm thick wood material sheet as a sound insulating material: Product name: MDF (1 mm thickness, 0.75 g / cm ³ ) made by Nelson Pine Produced two sound-absorbing panels in the same manner as in Example 1. As a result of measuring the standing sound absorption rate by arranging two sheets in the reverberation chamber, the sound absorption peak was almost the same as in Example 1, as shown in FIG.

<Results of on-site evaluation>
A dust collector and a wood crusher are placed in the equipment installation space (2500 mm x 6100 mm) provided in one corner of the room shown in the floor plan of Fig. 9, and at the measurement point of the outdoor factory gate when the dust collector and the wood crusher are in operation. In the factory where the noise level is 61.0 dBA and 250 Hz: 55.3 dBA, the sound absorbing panels of Examples and Comparative Examples were attached to the wall surface around the equipment as follows, and the noise level was measured. The main cause of the high noise level was the dust collector, and it was found that a sharp noise peak was generated particularly at 250 Hz. The noise level was measured based on the equivalent noise level (LAeq) based on Environmental Agency Notification No. 64 “Environmental Standards for Noise”.

Comparative example A
On one side of the wall in the three directions around the device (5 steps, height of about 4000 mm to the ceiling, up to about 3000 mm in height), urethane foam manufactured by INOAC CORPORATION, product name: Calm Flex F2, thickness 50 mm (in the graph of FIG. 8) Comparative Example 4) was affixed with a double-sided tape, and a PVC curtain having a thickness of 2 mm was installed at the boundary (6100 mm) between the device installation space and other space. However, as shown in the graph of FIG. 10 and the table of FIG. 11, the noise level measurement results did not change from before the implementation of the countermeasures for both all-pass and 250 Hz.

Example A
Compared to Comparative Example A, the second and third steps on the wall surface in the three directions around the device were replaced with the sound absorbing panel of Example 1. As a result, as shown in the graph of FIG. 10 and the table of FIG. 11, there was a reduction effect of about 4 dB at 250 Hz and about 2 dB at the all pass.

Example B
Compared to Comparative Example A, the second and fourth steps of the wall surface in the three directions around the device are replaced with the sound absorbing panel of Example 1, and the third step is replaced with the two-layered sound absorbing panel of Example 4, and the device Replace the vinyl chloride resin curtain for 2400mm at the boundary between the installation space and other space (6100mm), and attach the wood screws to the four ends of the sound absorbing panel of Example 5 so that the sound absorbing surface is on the inside. It was fixed and walled. As a result, as shown in the graph of FIG. 10 and the table of FIG. 11, there was a reduction effect of about 6 dB at 250 Hz and about 3 dB at the all pass. In addition, since the sound absorbing panel could not be arranged on the straight line of the measurement point, the reduction of the noise level at the measurement point is considered to be a reduction of the reflected sound of the sound absorbing panel, and the larger example B is reflected. It can be seen that the sound reduction effect was high.

  In addition, although the wood screw slightly wobbles at the four ends of the sound absorbing panels of Examples 1 and 4, it was difficult to fix them to function as walls. However, in the sound absorbing panel of Example 5, the inner surface of the frame-shaped member was a high-density foam. As a result, it became a strong wood screw holding force, and it was possible to make a solid wall while being fixed with a connecting bracket.

  Thus, the sound-absorbing panel of the present invention can exhibit a high sound-absorbing rate in a low frequency region of around 500 Hz or less, and is thin. If necessary, it is possible to deal with a wide range of frequencies by arranging different thicknesses and face material thicknesses, forming multiple layers, or attaching a porous sound absorbing material to the front surface. Moreover, since the face material is fixed to the frame-shaped member made of a foam having a closed cell structure surrounding the outer periphery of the honeycomb core, end face peeling can be prevented. Moreover, since the foam of the closed cell structure which comprises a frame-shaped member has a low density compared with a wooden frame, the lightweight property which is the characteristic of a honeycomb core is not impaired. Further, the closed-cell structure foam constituting the frame-shaped member is prevented from being twisted or deformed due to water absorption of the frame-shaped portion because the closed-cell structure prevents moisture from being impregnated.

Furthermore, the sound-absorbing panel of the present invention can be nail-screwed at a portion of the frame-shaped member by providing a foam having a closed cell structure with a density of 0.3 to 0.8 g / cm ^{3 on} at least a part of the frame-shaped member. . Therefore, since it is possible to directly nail and screw without attaching an outer metal frame or the like, it is possible to mount lightly, easily and inexpensively. Since it is lightweight, it can be attached and fixed with adhesives, double-sided tapes, hook-and-loop fasteners, screw fasteners, etc. for thin and small-sized products.

  The sound-absorbing panel of the present invention takes advantage of the above and satisfies non-combustible and flame-retardant properties with non-combustible paper and aluminum materials. For example, noise countermeasures such as fans for construction machines, various motors such as dust collectors and air conditioners in factories Countermeasures against mechanical noise, electrical equipment noise, railway / shinkansen decks, pantograph noise, building walls / ceiling / floor sound insulation, office / toilet partition walls, road / airport noise barriers It can be suitably used as such.

10, 10A Sound absorbing panel 11, 11A, 12A Honeycomb core 21, 21A, 22A Frame member 31, 31A, 32A, 33A Non-breathable face material 41, 41A, 42A Wood end

Claims (3)

In the sound-absorbing panel in which a non-breathable face material is arranged on at least one side of a plate-shaped honeycomb core having both sides opened,
An outer periphery of the honeycomb core is surrounded by a frame-shaped member made of a foam having a closed cell structure, and the non-breathable face material is fixed to the frame-shaped member,
The sound-absorbing panel, wherein at least the one-side non-breathable face member is not fixed to the honeycomb core. The honeycomb core is a multilayer, and the non-breathable face material is disposed between the honeycomb cores and at least one outer surface of the honeycomb core,
The outer periphery of each honeycomb core is provided with the frame member, and the non-breathable face material is fixed to the frame member.
The sound absorbing panel according to claim 1, wherein at least the face material on the outer surface of the honeycomb core on one side is not fixed to the honeycomb core. The sound-absorbing panel according to claim 1 or 2, wherein at least a part of the frame-shaped member is formed of a foam having a closed cell structure with a density of 0.3 to 0.8 g / cm ³ .

Images