JP2008111218A - Electromagnetic wave/sonic wave-absorbing yarn, electromagnetic wave/sonic wave-absorbing fabric, electromagnetic wave/sonic wave-absorbing sheet, electromagnetic wave/sonic wave-absorbing plate, electromagnetic wave/sonic wave-absorbing structural body and electromagnetic wave-shielding yarn - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an electromagnetic/sonic wave-absorbing sheet equipped with an excellent electromagnetic wave-absorbing characteristics and sonic wave-absorbing characteristics jointly and further having an extremely light weight and thin thickness, and also translucency by which another side can be seen. <P>SOLUTION: This electromagnetic wave/sonic wave-absorbing yarn 3 having a structure of having a short whisker type carbon fiber-projecting parts 2A from a chain-stitched part of the transparent polyester fiber 1 and carbon fiber 2 is prepared by while knitting each of the multiple numbers of transparent polyester fibers 1 and carbon fibers 2 by a chain stitch, knitting the carbon fiber 2 by omitting one piece of the transparent polyester fibers 1 by every 2 to 5 times, then cutting the carbon fiber 2 along the transparent polyester fiber 1. By weaving a coarse fabric by using such the electromagnetic wave/sonic wave-absorbing yarn, it becomes the electromagnetic wave/sonic wave-absorbing fabric 5 having the high electromagnetic/sonic wave-absorbing function, and by fusing with nipping such the electromagnetic wave/sonic wave-absorbing fabric 5 with 2 pieces of transparent vinyl sheets, it becomes the electromagnetic wave/sonic wave-absorbing sheet having also translucency. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  INDUSTRIAL APPLICABILITY The present invention can be used as an excellent electromagnetic wave and sound wave absorber, and has an electromagnetic wave and sound wave absorbing yarn, an electromagnetic wave and sound wave absorbing fabric, an electromagnetic wave and sound wave absorbing sheet, and an electromagnetic wave and sound wave absorbing sheet, as necessary. The present invention relates to an electromagnetic wave shielding yarn capable of shielding an electromagnetic wave with a plate, an electromagnetic wave / sound absorbing structure, and a similar structure.

  In recent years, with the development of IT (information technology), IT and OA devices such as personal computers (hereinafter referred to as “personal computers”) have rapidly spread, and even in normal home and work environments, The effect of electromagnetic waves radiated from IT equipment / OA equipment on the human body has become a problem. Therefore, in Patent Document 1, for the purpose of applying the above equipment to an electromagnetic wave shielding cabinet or the like, a woven fabric composed of a composite elastic yarn in which metal fibers are spirally wound around an elastic fiber is thermoplastically synthesized. An idea of a synthetic resin plate for electromagnetic wave shielding sandwiched between resin sheets is disclosed.

  In Patent Document 2, in order to shield electromagnetic waves in a wider range, a blended yarn of an aluminum fiber obtained by finely cutting an aluminum foil into staple fibers and a normal spinnable fiber is used. The present invention discloses an idea of a curtain for electromagnetic wave shielding formed by a woven fabric woven using a woven fabric.

  Furthermore, in the invention described in Patent Document 3, in order to sew electromagnetic shielding work clothes and the like for the purpose of more reliably protecting the human body from electromagnetic waves, the conductive metal wire and the twisted yarn or filament yarn are drawn in parallel. A core yarn is formed in a uniform manner, and a twisted yarn or a filament yarn is Z-twisted and S-twisted around the core yarn to prevent the conductive metal wire from being exposed, thereby forming a composite yarn for electromagnetic wave shielding and weaving.

  On the other hand, prevention of noise pollution to private houses along highways and railway lines is also an important issue. For this reason, various soundproof structures, sound absorbing structures, soundproof walls, and the like have been developed.

  For example, in Patent Document 4, in a porous soundproof structure configured by disposing an exterior plate and an interior plate having a large number of through holes so as to face each other, the interior plate has a top located on the exterior plate side. The patent invention of the porous soundproof structure in which the convex part is formed and the top part of the convex part is joined to the exterior board via the damping member which attenuates vibration is disclosed. Thus, it is said that sufficient soundproof performance is exhibited not only for the resonance frequency in the general formula of the Helmholtz resonance principle but also for noise in a wide frequency band.

  In Patent Document 5, a transparent plate is provided with a large number of pores to form a porous plate, and the surface impedance of the porous plate with respect to a frequency intended for sound absorption is a product of the density of air and the speed of sound. The invention of a sound-absorbing structure in which the aperture ratio of pores to the surface of a porous plate is determined so as to approach a fixed impedance is disclosed. Thus, it is possible to obtain a sound-absorbing material that can have sufficient transparency and is excellent in terms of rigidity and the like.

  Further, in Patent Document 6, a translucent sound absorbing material in which a perforated plate having an aperture ratio of 40% or more is provided by providing openings having a hole diameter of 3 to 50 mm on both sides or one side of a translucent film-like material; A patented invention of a translucent soundproof board comprising a translucent soundproof board and a panel frame member that holds these at regular intervals is disclosed. As a result, a light-transmitting soundproof board having light-transmitting properties and see-through properties and having sound absorbing properties and sound insulating properties is obtained.

Patent Document 7 discloses an invention of a radio wave acoustic wave absorber formed by laminating a radio wave reflector, a sound absorbing unit, a radio wave absorbing unit, and a plate-shaped radio wave absorbing unit protecting unit made of a dielectric. By using the radio wave absorber having such a configuration, it has a function of absorbing radio waves and sound waves coming from the radio wave absorber protection part side, and can be used in the field, which was difficult with conventional radio wave absorbers. It can be installed on roads.
No. 3-40595 No. 3-36538 JP 2004-11033 A Japanese Patent No. 3661779 JP 2003-41528 A Japanese Patent No. 3625392 JP 2004-3259 A

  However, in the synthetic resin plate for electromagnetic wave shielding described in Patent Document 1, a woven fabric composed of metal fibers is sandwiched between thermoplastic synthetic resin sheets, and the metal material is not exposed on the surface. . As a result, the electromagnetic wave shielding performance is not as large as 57 dB at a frequency of 30 MHz and 42 dB at 1000 MHz (1 GHz). Further, in the curtain for electromagnetic wave shielding described in Patent Document 2, since the surface exposure ratio of the aluminum fiber is small, the electromagnetic wave shielding performance remains at 30 to 50 dB with respect to the electromagnetic wave having a frequency of 10 to 500 MHz.

  Further, in the composite yarn for electromagnetic wave shielding and knitting described in Patent Document 3, since the metal wire is not exposed because importance is placed on the comfort, no specific measurement data is described. However, the electromagnetic shielding performance is considered to be even smaller.

  Furthermore, although the electromagnetic wave shielding performance to some extent is obtained in the devices or inventions described in Patent Documents 1 to 3, the soundproofing effect and the sound absorbing effect are hardly provided. On the other hand, in the inventions described in Patent Documents 4 to 6, the soundproofing effect and sound absorbing effect are excellent, but the electromagnetic wave shielding performance is not at all. Thus, the devices or inventions described in Patent Documents 1 to 6 do not have both electromagnetic wave absorption characteristics and sound wave absorption characteristics.

  On the other hand, Patent Document 7 describes an invention of a radio wave absorber having both radio wave absorption characteristics and sound wave absorption characteristics. However, a metal plate is used as the radio wave reflector constituting the radio wave absorber, the sound absorbing part includes a sound absorbing material made of glass wool or synthetic fiber, and the radio wave absorbing part is made of a conductive foam having open cells. Therefore, the radio wave absorber is heavy and thick as a whole, and it is not easy to mount it on the inner wall of the tunnel, and a lighter and thinner radio wave absorber has been desired.

  In addition, since the radio wave absorber having such a configuration blocks the light beam and the other side is not visible, when used as a road accessory, it obstructs the view of the driver and passengers of a vehicle such as an automobile and feels obstruction. give. Furthermore, in an ETC (Electronic Toll Collection) system provided at a toll booth on an expressway, etc., when used for electromagnetically blocking between the gates of adjacent ETC systems, the passing situation of vehicles at adjacent gates There was a problem that could not be seen.

  Therefore, the present invention combines an excellent electromagnetic wave absorption property and a sound wave absorption property, and is also extremely light and thin, and has an electromagnetic wave / sonic wave absorption sheet and an electromagnetic wave / sonic wave absorption plate having translucency so that the other side can be seen if necessary, An object of the present invention is to provide an electromagnetic wave / sound absorbing structure, an electromagnetic wave / sound absorbing yarn for manufacturing them, an electromagnetic wave / sound absorbing fabric, and an electromagnetic wave shielding yarn capable of shielding electromagnetic waves with a similar structure.

  The electromagnetic wave / sound absorbing yarn according to the invention of claim 1 is made of a conductive material applied to a number of short carbon fibers, a short metal wire or a base material over the entire length of a normal spun fiber braided. One end or the central part of the coated and cut thinly and cut shortly, when the usual spinnable fiber is knitted by chain knitting, is simultaneously knitted or twisted twice to ten times, and fixed. One or both ends of a plurality of short carbon fibers or short metal wires or substrates coated with a conductive material, cut into pieces and cut into short pieces, projecting from the one in which the usual spinnable fiber is knitted. is there.

  Here, “ordinary spinnable fiber” includes cotton, silk, hemp, wool, nylon, vinylon, polyester fiber, acrylic fiber, vinylidene chloride fiber, organic fiber such as acetate and rayon, and inorganic fiber such as glass fiber. Alternatively, these fibers can be mixed. Examples of the “base material” include paper, cloth, and plastic film, and examples of the “conductive material” include metals such as gold, silver, and copper, and carbon.

  The electromagnetic wave / acoustic absorption yarn according to the invention of claim 2 is obtained by coating a plurality of ordinary spinnable fibers with a gap between them and coating a carbon fiber, a metal wire or a base material with a conductive material, When the carbon fiber, the metal wire, or the base material is coated with a conductive material and cut into thin pieces every 2 to 10 times when knitting with chain knitting, Furthermore, after repeatedly knitting to move to the next adjacent one, the carbon fiber or the metal wire or the base along the normal spinnable fiber between the plurality of normal spinnable fibers. It is formed by coating a material with a conductive material and cutting it into pieces.

  The electromagnetic wave / acoustic wave absorbing yarn according to the invention of claim 3 is formed by kneading and spinning a short carbon fiber or carbon powder or a short metal wire or metal powder in an organic synthetic resin, rubber or elastomer.

  Here, examples of the “organic synthetic resin” include thermoplastic resins such as polyethylene, polypropylene, acrylic resin, and vinyl chloride resin, and thermosetting resins such as phenol resin and epoxy resin. “Elastomer” in the broad sense means “highly elastic polymer” and includes natural rubber and synthetic rubber (edited by Saburo Nagakura et al., “Iwanami Rikagaku Dictionary, 5th Edition”, page 153, published.・ Iwanami Shoten Co., Ltd., issue date, February 20, 1998), here, it means a narrowly defined elastomer that does not contain rubber.

  The electromagnetic wave / acoustic wave absorbing yarn according to a fourth aspect of the present invention is the thin film according to any one of the first to third aspects, wherein the short carbon fiber, the short metal wire or the base material is coated with a conductive material. The length of the short cut or the carbon fiber or the metal wire or the base material coated with a conductive material and cut into a thin piece, the short carbon fiber or the short metal wire or the base material is conductive. The length of the material that has been coated, cut into pieces, and cut short is set in accordance with the wavelength of the electromagnetic wave to be absorbed.

  The electromagnetic wave / sound absorbing yarn according to the invention of claim 5 is organic over the entire length after the glass fiber is wound over the entire length of the electromagnetic wave / sound absorbing yarn according to any one of claims 1 to 4. A synthetic resin, rubber or elastomer is coated.

  Here, examples of the “organic synthetic resin” include thermoplastic resins such as polyethylene, polypropylene, acrylic resin, and vinyl chloride resin, and thermosetting resins such as phenol resin and epoxy resin. The term “elastomer” refers to a “highly elastic polymer substance” in a broad sense, and includes natural rubber and synthetic rubber, but here, it means a narrowly defined elastomer that does not contain rubber.

  The electromagnetic wave / sound absorbing yarn according to the invention of claim 6 is formed by coating a fluororesin over the entire length of the electromagnetic wave / sound absorbing yarn according to any one of claims 1 to 4. Here, as a method of coating the fluororesin, there are a method of spraying a liquid fluororesin, a method of immersing in a fluororesin solution, and a method of baking a gaseous fluororesin.

  An electromagnetic wave / sound absorption fabric according to the invention of claim 7 is formed by weaving the electromagnetic wave / sound absorption yarn according to any one of claims 1 to 6.

  The electromagnetic wave / sound absorbing fabric according to the invention of claim 8 is formed by mixing and weaving the electromagnetic wave / sound absorbing yarn according to any one of claims 1 to 6 and normal spinnable fibers. It is.

  The electromagnetic wave / sound absorbing fabric according to the invention of claim 9 is the structure of claim 7 or claim 8, wherein the size of the weave of the electromagnetic wave / sound absorbing yarn in the electromagnetic wave / sound absorbing fabric is the wavelength of the electromagnetic wave to be absorbed. It is set according to.

  The electromagnetic wave / sound absorbing fabric according to claim 10 is the electromagnetic wave / sound absorbing fabric according to any one of claims 7 to 9, wherein the electromagnetic wave / sound absorbing fabric is any one of claims 1 to 4. An electromagnetic wave / sound absorbing fabric made by weaving an electromagnetic wave / sound absorbing yarn is coated on the entire front and back surfaces with a fluororesin.

  The electromagnetic wave / sound absorbing sheet according to the invention of claim 11 is the electromagnetic wave / sound absorbing sheet according to any one of claims 7 to 9, wherein the electromagnetic wave / sound absorbing fabric is any one of claims 1 to 4. One or two or more layers of electromagnetic wave / sound absorbing fabrics made by weaving electromagnetic wave / sound absorbing yarns, sandwiched between two thin organic synthetic resin sheets, rubber sheets or elastomer sheets and heat-pressed into a sheet shape It is.

  The electromagnetic wave / sound absorbing sheet according to the invention of claim 12 is the electromagnetic wave / sound absorbing fabric according to any one of claims 7 to 9, among the electromagnetic wave / sound absorbing fabric according to any one of claims 7 to 9. In the electromagnetic wave / acoustic absorption fabric formed by weaving the electromagnetic wave / acoustic absorption yarns, those having different textures of the electromagnetic wave / acoustic absorption yarns or short carbon fibers or short metal wires in the used electromagnetic wave / acoustic absorption yarns or A base material is coated with a conductive material, cut into small pieces, and cut into short pieces, but two or more pieces of different lengths are stacked and sandwiched between two thin organic synthetic resin sheets, rubber sheets, or elastomer sheets, and heat-pressed It is a sheet.

  The electromagnetic wave / sound absorbing sheet according to the invention of claim 13 is the electromagnetic wave / sound absorbing sheet according to any one of claims 7 to 9, wherein the electromagnetic wave / sound absorbing sheet is any one of claims 1 to 4. One or two or more electromagnetic wave / sound absorbing fabrics formed by weaving the electromagnetic wave / sound absorbing yarns of a plurality of layers, and a large number of through-holes having a hole diameter in the range of 100 nm to 1 mm are in the range of 5% to 30% in the aperture ratio. A thin organic synthetic resin sheet, a rubber sheet, or an elastomer sheet that is perforated inside is sandwiched and bonded.

  The electromagnetic wave / sound absorbing plate according to the invention of claim 14 has a different texture of the electromagnetic wave / sound absorbing yarns of the electromagnetic wave / sound absorbing fabric according to any one of claims 7 to 10 or Organic synthesis with a predetermined thickness between short carbon fibers or short metal wires or conductive materials coated on conductive materials and cut into short pieces of different lengths. Two or more sheets sandwiched between resin plates, rubber plates, or elastomer plates are bonded or thermocompression bonded into a plate shape.

  The electromagnetic wave / acoustic wave absorbing sheet or electromagnetic wave / acoustic wave absorbing plate according to the invention of claim 15 is the structure according to any one of claims 11 to 14, wherein the electromagnetic wave / acoustic wave absorbing fabric has a texture of 1 mm or more and 200 mm or less. The two thin organic synthetic resin sheets or rubber sheets or elastomer sheets, or the organic synthetic resin plate, rubber plate or elastomer plate having the predetermined thickness are transparent.

  An electromagnetic wave / sound absorption structure according to the invention of claim 16 is formed by stretching the electromagnetic wave / sound absorption yarn according to any one of claims 1 to 6 parallel to each other at a predetermined interval on a frame. An electromagnetic wave according to any one of Claims 1 to 6, wherein the electromagnetic wave / sound absorbing yarn stretched over each other with a dielectric sheet sandwiched between two sheets is vertically stacked, or the electromagnetic wave according to any one of claims 1 to 6・ Sound absorption yarns are stretched across the frame vertically and horizontally.

  The electromagnetic wave / sound absorbing structure according to claim 17 is the electromagnetic wave / sound absorbing structure according to claim 5 or 6 of the electromagnetic wave / sound absorbing fabric according to any one of claims 7 to 9. An electromagnetic wave / sound absorbing fabric woven by absorbing yarn, the electromagnetic wave / sound absorbing fabric according to claim 10, or the electromagnetic wave / sound absorbing structure according to claim 16, facing a metal net at a predetermined interval. And both are fixed to the frame.

  The electromagnetic wave / sound absorption structure according to the invention of claim 18 is a structure in which a thin metal plate or a metal net is fixed to a wall surface to be installed, and a metal channel material having a predetermined channel interval is used. The electromagnetic wave / sound absorbing fabric according to claim 5 or claim 6 or the electromagnetic wave / sound absorbing fabric according to claim 10 formed by weaving the electromagnetic wave / sound absorbing yarn according to claim 5 or 6 among the electromagnetic wave / sound absorbing fabric according to claim 9. A sound absorbing fabric or an electromagnetic wave / sound absorbing structure according to claim 16 is attached.

  The electromagnetic wave / sound absorption structure according to the invention of claim 19 is formed by applying the electromagnetic wave / sound absorption yarn according to claim 5 or 6 at a predetermined pitch on the outer peripheral surface of a plastic pipe having a predetermined inner diameter. Wound and fixed in the S direction, and supported by a cap fixed to both ends of the plastic pipe along the center line of the plastic pipe with a metal rod or metal pipe inside the plastic pipe It will be.

  An electromagnetic wave / sound absorbing structure according to the invention of claim 20 is formed by arranging a plurality of the electromagnetic wave / sound absorbing structures according to claim 19 in parallel at a predetermined interval.

  The electromagnetic wave shielding yarn according to the invention of claim 21 is obtained by coating a conductive material on a number of short carbon fibers or short metal wires or base materials over the entire length of a normal spun fiber knitted by chain knitting. When one end or the center of the thinly cut and short cut is knitted or twisted twice or 10 times at the same time when the usual spinnable fiber is knitted by chain knitting, the above-mentioned many One end or both ends of a short carbon fiber, a short metal wire, or a base material coated with a conductive material, cut into pieces, and cut into short pieces protrude from the braided normal spinn fiber.

  Here, “ordinary spinnable fiber” includes cotton, silk, hemp, wool, nylon, vinylon, polyester fiber, acrylic fiber, vinylidene chloride fiber, organic fiber such as acetate and rayon, and inorganic fiber such as glass fiber. Alternatively, these fibers can be mixed. Examples of the “base material” include paper, cloth, and plastic film, and examples of the “conductive material” include metals such as gold, silver, and copper, and carbon.

  The electromagnetic shielding yarn according to the invention of claim 22 is formed by a plurality of ordinary spinnable fibers spaced apart from each other and coated with a conductive material on a carbon fiber, a metal wire or a base material, and a chain braid. When the knitted fabric is knitted, the carbon fiber, the metal wire, or the base material coated with a conductive material and cut into pieces every two to ten times, or adjacent one of the normal spinnable fibers, or further After repeatedly knitting to move to the next adjacent one, the carbon fiber or the metal wire or the base material along the normal spinnable fiber between the plurality of normal spinnable fibers. This is formed by coating a conductive material and cutting it into thin pieces.

  The electromagnetic shielding yarn according to the invention of claim 23 is formed by kneading and spinning a short carbon fiber or carbon powder or a short metal wire or metal powder in an organic synthetic resin, rubber or elastomer.

  Here, examples of the “organic synthetic resin” include thermoplastic resins such as polyethylene, polypropylene, acrylic resin, and vinyl chloride resin, and thermosetting resins such as phenol resin and epoxy resin. The term “elastomer” refers to a “highly elastic polymer substance” in a broad sense, and includes natural rubber and synthetic rubber, but here, it means a narrowly defined elastomer that does not contain rubber.

  The electromagnetic shielding yarn according to the invention of claim 24 is an organic synthetic resin or rubber over the entire length of the electromagnetic shielding yarn according to any one of claims 21 to 23 after the glass fiber is wound over the entire length. Or an elastomer is coated.

  Here, examples of the “organic synthetic resin” include thermoplastic resins such as polyethylene, polypropylene, acrylic resin, and vinyl chloride resin, and thermosetting resins such as phenol resin and epoxy resin. The term “elastomer” refers to a “highly elastic polymer substance” in a broad sense, and includes natural rubber and synthetic rubber, but here, it means a narrowly defined elastomer that does not contain rubber.

  The electromagnetic shielding yarn according to the invention of claim 25 is formed by coating a fluororesin over the entire length of the electromagnetic shielding yarn according to any one of claims 21 to 23. Here, as a method of coating the fluororesin, there are a method of spraying a liquid fluororesin, a method of immersing in a fluororesin solution, and a method of baking a gaseous fluororesin.

  The electromagnetic wave / sound absorbing yarn according to the invention of claim 1 is made of a conductive material applied to a number of short carbon fibers, a short metal wire or a base material over the entire length of a normal spun fiber braided. One end or the central part of the coated and cut thinly and cut shortly, when the usual spinnable fiber is knitted by chain knitting, is simultaneously knitted or twisted twice to ten times, and fixed. One or both ends of a plurality of short carbon fibers or short metal wires or substrates coated with a conductive material, cut into pieces and cut into short pieces, projecting from the one in which the usual spinnable fiber is knitted. is there.

  Here, “ordinary spinnable fiber” includes cotton, silk, hemp, wool, nylon, vinylon, polyester fiber, acrylic fiber, vinylidene chloride fiber, organic fiber such as acetate and rayon, and inorganic fiber such as glass fiber. Alternatively, these fibers can be mixed. Examples of the “base material” include paper, cloth, and plastic film, and examples of the “conductive material” include metals such as gold, silver, and copper, and carbon.

  As a result, short carbon fibers or short metal wires or base materials coated with a conductive material and chopped into short pieces are entangled with ordinary knitted fibers that are knitted, and the tip is entangled with ordinary spinning fibers. Protrusively from bearded fibers. This beard-like projecting portion is a carbon fiber or metal wire or base material coated with a conductive material, cut into pieces and cut short, and has conductivity, so that the short carbon fiber or short metal wire or base material has An electromagnetic wave having a frequency corresponding to the length of the conductive material coated, cut into pieces, and cut short can be strongly absorbed. Accordingly, if a woven fabric having a coarse texture is woven using such an electromagnetic wave / sound absorbing yarn so that the beard-like protruding portions do not continuously contact, an electromagnetic wave absorbing fabric having a high electromagnetic wave absorbing ability is obtained.

  Here, in order to obtain an electromagnetic wave-absorbing fabric having a high electromagnetic wave absorbing capability, it is preferable that the beard-like protruding portion protrudes along a normal spinnable fiber.

  In addition, the beard-like protruding portion is a carbon fiber or metal wire or base material coated with a conductive material, cut into pieces and cut into short pieces, and has rigidity so that it can disperse air and dissipate sound waves. Therefore, it also functions as a sound-absorbing yarn. If a coarsely woven fabric is woven using such a sound absorbing yarn, a sound absorbing fabric with a high sound absorbing ability is obtained.

  In this way, by providing a large number of beard-like protrusions of conductive material on ordinary spinnable fibers, it has exactly the same ability as ordinary spinnable fibers while having greater electromagnetic wave and sound wave absorption performance. It becomes an electromagnetic wave / sound absorbing yarn that can be woven with a loom.

  The electromagnetic wave / acoustic absorption yarn according to the invention of claim 2 is obtained by coating a plurality of ordinary spinnable fibers with a gap between them and coating a carbon fiber, a metal wire or a base material with a conductive material, When knitting with chain knitting, carbon fiber or metal wire or base material coated with a conductive material every 2 to 10 times, and then cut into a thin piece of normal spinnable fiber or next to it After knitting repeatedly moving to one, a conductive material is coated on a carbon fiber or metal wire or substrate along a normal spinnable fiber between a plurality of normal spinnable fibers. It is made by cutting a thin piece.

  As a result, a short carbon fiber or a short metal wire or base material cut into a normal spinnable fiber is entangled with a conductive material coated into a thin piece and cut into short pieces. It is possible to easily produce a mixed yarn having a structure projecting like a beard from a conductive fiber. This beard-like protruding portion is made by coating a conductive material on a carbon fiber or metal wire or base material and cutting it into thin pieces, so that it has conductivity, so that the short carbon fiber or short metal wire or base material is conductive. It is possible to strongly absorb electromagnetic waves having a frequency corresponding to the length of a material that has been coated, cut into thin pieces, and cut into short pieces. Accordingly, if a woven fabric having a coarse texture is woven using such an electromagnetic wave / sound absorbing yarn so that the beard-like protruding portions do not continuously contact, an electromagnetic wave absorbing fabric having a high electromagnetic wave absorbing ability is obtained.

  Here, the beard-like protruding portion of the electromagnetic wave / sound absorbing yarn manufactured by such a method protrudes along a normal spinnable fiber, so that an electromagnetic wave absorbing fabric having a high electromagnetic wave absorbing ability is used. Preferred for obtaining.

  In addition, the beard-like projecting portion is a carbon fiber or metal wire or base material coated with a conductive material and cut into thin pieces, and because it has rigidity, it has an action of dispersing sound by dispersing air, Also functions as a sound absorbing yarn. If a coarsely woven fabric is woven using such a sound absorbing yarn, a sound absorbing fabric with a high sound absorbing ability is obtained.

  In this way, ordinary spinnable fibers can be easily provided with a large number of beard-like protruding portions of conductive material, and have a larger electromagnetic wave / sound absorption capability, while being completely different from ordinary spinnable fibers. Similarly, it becomes an electromagnetic wave / sound absorbing yarn that can be woven with a loom.

  The electromagnetic wave / acoustic absorption yarn according to the invention of claim 3 is formed by kneading a short carbon fiber or carbon powder or a short metal wire or metal powder into an organic synthetic resin, rubber or elastomer and spinning. Here, examples of the “organic synthetic resin” include thermoplastic resins such as polyethylene, polypropylene, acrylic resin, and vinyl chloride resin, and thermosetting resins such as phenol resin and epoxy resin. The term “elastomer” refers to a “highly elastic polymer substance” in a broad sense, and includes natural rubber and synthetic rubber, but here, it means a narrowly defined elastomer that does not contain rubber.

  Thus, short carbon fiber, carbon powder, short metal wire, or organic synthetic resin fiber or rubber fiber or elastomer fiber kneaded with metal powder is short carbon fiber, carbon powder, short metal wire having conductivity inside, Or, since it contains metal powder, it exhibits excellent electromagnetic wave absorption characteristics, and depending on the method of use, it also exhibits excellent sound wave absorption characteristics. And since it is an organic synthetic resin fiber, a rubber fiber, or an elastomer fiber, a woven fabric can be woven by a normal method.

  In this way, the electromagnetic wave / sound absorbing yarn can be woven with a loom just like a normal spinable fiber while having a large electromagnetic wave / sound absorbing performance.

  The electromagnetic wave / sound absorbing yarn according to the invention of claim 4 is a short carbon fiber, a short metal wire or a base material coated with a conductive material, cut into pieces and cut into pieces, or a carbon fiber, a metal wire or a base. Try to absorb the length of short carbon fiber or short metal wire or base material coated with conductive material and cut thinly by coating conductive material on the material and cutting it. Set according to the wavelength of the electromagnetic wave.

  As described above, the beard-like projecting portion is obtained by coating a conductive material on a carbon fiber, a metal wire, or a base material, and is thinly cut, so that the short carbon fiber or the short metal wire or base material is conductive. It is possible to strongly absorb an electromagnetic wave having a frequency corresponding to the length of a material that is coated with a conductive material, cut into thin pieces, and cut into short pieces. Therefore, when manufacturing an electromagnetic wave / acoustic absorption yarn, a short carbon fiber, a short metal wire or a substrate is coated with a conductive material in accordance with the wavelength (namely, frequency) of the electromagnetic wave to be absorbed and cut into pieces. By setting the length of the short cut, it is possible to strongly absorb the electromagnetic wave of the target wavelength (frequency), and to obtain an electromagnetic wave / sound absorbing yarn having an excellent electromagnetic wave absorbing ability.

  In this way, by easily providing a large number of beard-like protruding portions of conductive material on ordinary spinnable fibers, it has exactly the same electromagnetic wave and sound wave absorption performance as the usual spinnable fibers. Thus, it becomes an electromagnetic wave / sound absorbing yarn that can be woven with a loom.

  The electromagnetic wave / sound absorbing yarn according to the invention of claim 5 is organic over the entire length after the glass fiber is wound over the entire length of the electromagnetic wave / sound absorbing yarn according to any one of claims 1 to 4. Coated with synthetic resin, rubber or elastomer. Here, examples of the “organic synthetic resin” include thermoplastic resins such as polyethylene, polypropylene, acrylic resin, and vinyl chloride resin, and thermosetting resins such as phenol resin and epoxy resin. The term “elastomer” refers to a “highly elastic polymer substance” in a broad sense, and includes natural rubber and synthetic rubber, but here, it means a narrowly defined elastomer that does not contain rubber.

  The electromagnetic wave / sound absorbing yarn having such a configuration is excellent in water resistance because it is coated with an organic synthetic resin, rubber, or elastomer over the entire length, and the electromagnetic wave / sound absorbing fabric formed by weaving the electromagnetic wave / sound absorbing yarn is sealed. Even if you do not, you can use it outdoors.

  In this way, ordinary spinnable fibers can be easily provided with a large number of beard-like protruding portions of a conductive material and coated with an organic synthetic resin, rubber, or elastomer, thereby providing greater electromagnetic wave and sound wave absorption performance. However, it is excellent in water resistance and becomes an electromagnetic wave / sound absorbing yarn that can be woven with a loom just like a normal spinable fiber.

  The electromagnetic wave / sound absorbing yarn according to the invention of claim 6 is formed by coating a fluororesin over the entire length of the electromagnetic wave / sound absorbing yarn according to any one of claims 1 to 4. Here, as a method of coating the fluororesin, there are a method of spraying a liquid fluororesin, a method of immersing in a fluororesin solution, and a method of baking a gaseous fluororesin.

  The electromagnetic wave / sound absorbing yarn having such a configuration is excellent in water resistance because it is coated with a fluororesin having water repellency over the entire length, and the electromagnetic wave / sound absorbing fabric formed by weaving the electromagnetic wave / sound absorbing yarn is sealed. Even without it, it can be used outdoors as it is.

  In this way, ordinary spinnable fibers can be easily provided with a large number of beard-like protrusions of conductive material and coated with fluororesin, providing superior water resistance while having greater electromagnetic wave and sound wave absorption performance. Thus, the electromagnetic wave / sound absorbing yarn can be woven with a loom just like a normal spinable fiber.

  The electromagnetic wave / sound absorption fabric according to the invention of claim 7 is formed by weaving the electromagnetic wave / sound absorption yarn according to any one of claims 1 to 6.

  As described above, the electromagnetic wave / sound absorbing yarn according to claims 1 to 6 has a beard-like protruding portion coated with a conductive material on a carbon fiber, a metal wire, or a base material, and is finely cut. Because it has electrical conductivity, it can strongly absorb electromagnetic waves having a frequency corresponding to the length of the short metal wire or short carbon fiber or substrate coated with a conductive material and cut into pieces, and has a beard-like shape. Since the projecting part is made of carbon fiber, metal wire or base material coated with a conductive material and cut into thin pieces and has rigidity, it has the effect of dispersing air and dissipating sound waves. Function.

  Therefore, if a woven fabric with a coarse texture is woven using such electromagnetic wave / sound absorbing yarn so that the beard-like protruding portions do not continuously contact, an electromagnetic wave / sound absorbing fabric with high electromagnetic wave absorbing ability and high sound absorbing ability can be obtained. Obtainable. Furthermore, if a coarsely woven fabric is woven using the electromagnetic wave / sound absorbing yarn according to claim 5 or 6, an electromagnetic wave / sound absorbing fabric having water resistance can be obtained.

  In this way, by weaving an electromagnetic wave / sound absorbing yarn in which a large number of beard-like protruding parts of conductive material are provided on an ordinary spinnable fiber, It becomes an electromagnetic wave and sound wave absorbing woven fabric that can be woven with a loom just like the woven fabric.

  The electromagnetic wave / acoustic absorption fabric according to the invention of claim 8 is formed by mixing and mixing the electromagnetic wave / acoustic absorption yarn according to any one of claims 1 to 6 and ordinary spinnable fibers. Even if we mix and weave electromagnetic wave / sound absorbing yarn and normal spinnable fiber, the large electromagnetic wave / sound absorbing performance is not deteriorated. If the fibers are mixed and woven, the cost can be reduced and a light shielding effect can be obtained.

  In this way, a larger electromagnetic wave can be obtained by mixing and weaving an electromagnetic wave / acoustic absorption yarn in which an ordinary spinnable fiber is provided with a number of bearded protruding portions of a conductive material with an ordinary spinnable fiber. It becomes an electromagnetic wave / sound absorption fabric that can be woven with a loom just like a normal fabric while having sound absorption capability.

  In the electromagnetic wave / sound absorbing fabric according to the invention of claim 9, the size of the weave of the electromagnetic wave / sound absorbing yarn in the electromagnetic wave / sound absorbing fabric is set according to the wavelength of the electromagnetic wave to be absorbed.

  As a result of earnest experiment research, the present inventor has found that the peak of the wavelength (that is, frequency) of the electromagnetic wave that can be absorbed changes depending on the size of the weave of the electromagnetic wave / sound absorbing yarn in the electromagnetic wave / sound absorbing fabric. . Therefore, by setting the size of the weave of the electromagnetic wave / acoustic absorption yarn in the electromagnetic wave / acoustic absorption fabric according to the wavelength (frequency) of the electromagnetic wave to be absorbed, the electromagnetic wave having the desired wavelength (frequency) can be obtained even by one sheet. An electromagnetic wave / sound absorption fabric that can be strongly absorbed can be obtained.

  In this way, an electromagnetic wave / acoustic absorption yarn in which a number of whisker-like protruding portions of a conductive material are provided on a normal spinable fiber is woven to a size corresponding to the wavelength of the target electromagnetic wave. Thus, an electromagnetic wave / sound absorbing fabric that can be woven with a loom just like a normal fabric while having a larger electromagnetic wave / sound absorbing capability.

  The electromagnetic wave / sound absorbing fabric according to claim 10 is the electromagnetic wave / sound absorbing fabric according to any one of claims 7 to 9, wherein the electromagnetic wave / sound absorbing fabric is any one of claims 1 to 4. An electromagnetic wave / sound absorbing fabric made by weaving an electromagnetic wave / sound absorbing yarn is coated on the entire front and back surfaces with a fluororesin.

  Among the electromagnetic wave / sound absorbing fabrics according to claim 7 to claim 9, the electromagnetic wave / sound absorbing fabric formed by weaving the electromagnetic wave / sound absorbing yarn according to claim 5 or 6 has water resistance. The electromagnetic wave / sound absorbing fabric formed by weaving the electromagnetic wave / sound absorbing yarn according to any one of claims 1 to 4 does not have water resistance. Therefore, the fluororesin is coated over the entire front and back surfaces of these electromagnetic wave / sound absorbing fabrics to provide water resistance and withstand outdoor use.

  In this way, a large amount of electromagnetic waves / sound waves can be obtained by weaving an electromagnetic wave / sound absorbing yarn in which a number of beard-like protruding parts of a conductive material are easily provided on a normal spinable fiber and coating with a fluororesin. It has excellent water resistance while having absorption performance, and becomes an electromagnetic wave / sound absorption fabric that can be woven with a loom just like ordinary spinnable fibers.

  The electromagnetic wave / sound absorbing sheet according to the invention of claim 11 is the electromagnetic wave / sound absorbing sheet according to any one of claims 7 to 9, wherein the electromagnetic wave / sound absorbing fabric is any one of claims 1 to 4. One or two or more layers of electromagnetic wave / sound absorbing fabrics made by weaving electromagnetic wave / sound absorbing yarns, sandwiched between two thin organic synthetic resin sheets, rubber sheets or elastomer sheets and heat-pressed into a sheet shape It is.

  As a result, the electromagnetic wave / sound absorbing sheet without water resistance is prevented from getting wet with moisture such as rain, and the electromagnetic wave / sound absorbing sheet can be used outdoors. Also, when sandwiching between two thin organic synthetic resin sheets, rubber sheets, or elastomer sheets and thermocompression bonding, in the portion where there is an electromagnetic wave / acoustic absorption yarn underneath, the normal spinning that constitutes the electromagnetic wave / acoustic absorption yarn Since the thin organic synthetic resin sheet or rubber sheet or elastomer sheet does not adhere to the conductive fiber, a minute hole is formed in the thin organic synthetic resin sheet or rubber sheet or elastomer sheet to form an air passageway. Since a large number of holes are formed on the entire surface of the electromagnetic wave / sound absorbing sheet, the electromagnetic wave / sound absorbing performance is not impaired.

  In this way, the electromagnetic wave / sound absorbing sheet can be installed in any place and has excellent electromagnetic wave / sound absorbing performance.

  The electromagnetic wave / sound absorbing sheet according to the invention of claim 12 is the electromagnetic wave / sound absorbing fabric according to any one of claims 7 to 9, among the electromagnetic wave / sound absorbing fabric according to any one of claims 7 to 9. In the electromagnetic wave / acoustic absorption fabric formed by weaving the electromagnetic wave / acoustic absorption yarns, those having different textures of the electromagnetic wave / acoustic absorption yarns or short carbon fibers or short metal wires in the used electromagnetic wave / acoustic absorption yarns or A base material is coated with a conductive material, cut into small pieces, and cut into short pieces, but two or more pieces of different lengths are stacked and sandwiched between two thin organic synthetic resin sheets, rubber sheets, or elastomer sheets, and heat-pressed It is a sheet.

  When the texture of the electromagnetic wave / sound absorbing fabric is different, or when the electromagnetic wave / sound absorbing yarn is used, a short carbon fiber, a short metal wire or a base material is coated with a conductive material and cut into small pieces. When the lengths of the objects are different, the frequency bands showing the greatest electromagnetic wave absorption are different. Therefore, by stacking two or more such electromagnetic wave / sound absorbing fabrics, an electromagnetic wave / sound absorbing sheet having excellent electromagnetic wave absorbing performance over a wider frequency band is obtained.

  And it becomes an electromagnetic wave and a sound wave absorption sheet which can prevent the water-resistant electromagnetic wave and sound wave absorption textiles from getting wet with moisture, such as rain, and can be used outdoors. Also, when sandwiching between two thin organic synthetic resin sheets, rubber sheets, or elastomer sheets and thermocompression bonding, in the portion where there is an electromagnetic wave / acoustic absorption yarn underneath, the normal spinning that constitutes the electromagnetic wave / acoustic absorption yarn Since the thin organic synthetic resin sheet or rubber sheet or elastomer sheet does not adhere to the conductive fiber, minute holes are formed in the thin organic synthetic resin sheet to form air passages, and these fine holes absorb electromagnetic waves and sound waves. Since many sheets are formed on the entire surface of the sheet, the electromagnetic wave and sound wave absorption performance is not impaired.

  In this way, the electromagnetic wave / sound absorbing sheet has excellent electromagnetic wave absorption performance over a wider frequency band and can be installed in any place, and has excellent electromagnetic wave / sound absorption performance.

  The electromagnetic wave / sound absorbing sheet according to the invention of claim 13 is the electromagnetic wave / sound absorbing sheet according to any one of claims 7 to 9, wherein the electromagnetic wave / sound absorbing sheet is any one of claims 1 to 4. One or two or more electromagnetic wave / sound absorbing fabrics formed by weaving the electromagnetic wave / sound absorbing yarns of a plurality of layers, and a large number of through-holes having a hole diameter in the range of 100 nm to 1 mm are in the range of 5% to 30% in the aperture ratio. A thin organic synthetic resin sheet, a rubber sheet, or an elastomer sheet that is perforated inside is sandwiched and bonded.

  If the hole diameter is a through-hole in the range of 100 nm to 1 mm, air passes but moisture does not pass through, so the water-resistant electromagnetic wave and sound-absorbing fabric can absorb moisture such as rain without impairing sound absorption characteristics. It becomes an electromagnetic wave and sound wave absorbing sheet that can be used outdoors by preventing getting wet. If the opening ratio is in the range of 5% to 30%, the two thin organic synthetic resin sheets or rubber sheets or elastomer sheets are not torn, and the organic synthetic resin sheet or rubber is bonded by bonding instead of thermocompression bonding. It is also possible to prevent large holes from opening in the sheet or elastomer sheet.

  In this way, the electromagnetic wave / sound absorbing sheet can be installed in any place and has excellent electromagnetic wave / sound absorbing performance.

  The electromagnetic wave / sound absorbing plate according to the invention of claim 14 has a different texture of the electromagnetic wave / sound absorbing yarns of the electromagnetic wave / sound absorbing fabric according to any one of claims 7 to 10 or Organic synthesis with a predetermined thickness between short carbon fibers or short metal wires or conductive materials coated on conductive materials and cut into short pieces of different lengths. Two or more sheets sandwiched between resin plates, rubber plates, or elastomer plates are bonded or thermocompression bonded into a plate shape.

  As described above, a conductive material is coated on a short carbon fiber, a short metal wire, or a short base material having different textures with an organic synthetic resin plate or a rubber plate or an elastomer plate having a predetermined thickness in between. By overlapping electromagnetic wave / sound absorbing fabrics with different lengths, electromagnetic wave / sound absorbing fabrics with different wavelength peaks of electromagnetic waves to be absorbed can be arranged at predetermined intervals and have strong electromagnetic wave absorbing performance. It becomes.

  That is, when the texture of the electromagnetic wave / sound absorbing fabric is different, or when the electromagnetic wave / sound absorbing yarn is used, a short carbon fiber or a short metal wire or a base material is coated with a conductive material and cut into small pieces. When the lengths of the cut pieces are different, the frequency bands showing the largest electromagnetic wave absorption are different. Therefore, by stacking two or more such electromagnetic wave / sound absorbing fabrics, an electromagnetic wave / sound absorbing plate having excellent electromagnetic wave absorbing performance over a wider frequency band is obtained.

  The inventor has found that the electromagnetic wave / sound absorbing fabric is provided with a predetermined interval to provide a superior electromagnetic wave / sound absorbing performance, and the present invention is completed based on this finding. It is a thing. That is, by sandwiching an organic synthetic resin plate or rubber plate or elastomer plate with a predetermined thickness according to the dielectric constant between them, it is possible to install such electromagnetic wave / sound absorbing fabrics separated by a predetermined interval, which is more excellent. The electromagnetic wave / sound absorbing plate has the electromagnetic wave / sound absorbing performance.

  In this way, the electromagnetic wave / sound absorbing plate has excellent electromagnetic wave absorbing performance over a wider frequency band, and more excellent electromagnetic wave / sound absorbing performance.

  The electromagnetic wave / acoustic wave absorbing sheet or electromagnetic wave / acoustic wave absorbing plate according to the invention of claim 15 is characterized in that the electromagnetic wave / acoustic wave absorbing fabric has a coarse texture of 1 mm to 200 mm, and two thin organic synthetic resin sheets or rubber sheets or elastomer sheets or The organic synthetic resin plate or rubber plate or elastomer plate having a predetermined thickness is transparent.

  As described above, the electromagnetic wave / sound absorbing fabric has a coarse texture of 1 mm to 200 mm and the organic synthetic resin sheet, rubber sheet, elastomer sheet, organic synthetic resin plate, rubber plate, or elastomer plate is transparent. The sound absorbing sheet or electromagnetic wave / sound absorbing plate has translucency so that the other side can be seen. Therefore, it is extremely suitable for applications requiring translucency.

  In this way, an electromagnetic wave / sound absorbing sheet or an electromagnetic wave / sound absorbing plate having excellent electromagnetic wave absorbing performance, excellent sound wave absorbing performance, translucency, and the other side can be seen.

  An electromagnetic wave / sound absorption structure according to the invention of claim 16 is formed by stretching the electromagnetic wave / sound absorption yarn according to any one of claims 1 to 6 parallel to each other at a predetermined interval on a frame. The electromagnetic wave / sound absorbing yarn stretched over each other with a dielectric sheet sandwiched between two sheets is overlapped so as to be vertical, or the electromagnetic wave / sound according to claim 1 is formed. A sound-absorbing yarn is stretched vertically and horizontally on a frame.

  As a result, even without weaving the fabric with a loom, the electromagnetic wave and sound wave absorption having excellent electromagnetic wave and sound wave absorption performance can be achieved by stretching it at a predetermined interval according to the wavelength of the electromagnetic wave to be absorbed. It becomes a structure. Since only the electromagnetic wave / sound absorbing yarn is stretched at a predetermined interval, the electromagnetic wave / sound absorbing structure is excellent in translucency and the other side can be seen well. In addition, the electromagnetic wave / sound absorbing structure obtained by stretching the electromagnetic wave / sound absorbing yarn according to claim 5 or 6 over the frame body is excellent in water resistance, and therefore is suitable for outdoor use.

  In this way, an electromagnetic wave / sound absorption structure having a simple structure and excellent electromagnetic wave absorption performance, having excellent sound wave absorption performance, and having translucency and the other side visible.

  The electromagnetic wave / sound absorbing structure according to claim 17 is the electromagnetic wave / sound absorbing structure according to claim 5 or 6 of the electromagnetic wave / sound absorbing fabric according to any one of claims 7 to 9. An electromagnetic wave / sound absorbing fabric woven by absorbing yarn, the electromagnetic wave / sound absorbing fabric according to claim 10, or the electromagnetic wave / sound absorbing structure according to claim 16, facing a metal net at a predetermined interval. Both are fixed to the frame.

  As a result, the electromagnetic wave incident from the electromagnetic wave / sound absorbing fabric side or the electromagnetic wave / sound absorbing structure side is first partially absorbed by the electromagnetic wave / sound absorbing fabric or electromagnetic wave / sound absorbing structure and reflected by a metal net. And absorbed again when passing through the electromagnetic wave / sound absorbing fabric or the electromagnetic wave / sound absorbing structure. Here, the distance between the metal net and the electromagnetic wave / sound absorbing fabric or the electromagnetic wave / sound absorbing structure is a predetermined interval that matches the wavelength of the electromagnetic wave to be absorbed. The electromagnetic waves reflected by the net cancel each other and can absorb the electromagnetic waves more effectively.

  The electromagnetic wave / sound absorbing structure formed by fixing the metal net and the electromagnetic wave / sound absorbing fabric or the electromagnetic wave / sound absorbing structure to the frame allows air to freely pass therethrough. Excellent sound absorbing characteristics are exhibited by the absorbent fabric or electromagnetic wave / sound absorbing structure. In addition, the electromagnetic wave / sound absorbing structure according to the present invention has translucency so that the other side can be seen. Furthermore, since the electromagnetic wave / acoustic absorption fabric formed by weaving the electromagnetic wave / acoustic absorption yarn according to claim 5 or 6 or the electromagnetic wave / acoustic absorption fabric according to claim 10 is water resistant, Suitable for outdoor use such as shielding.

  In this way, an electromagnetic wave / sound absorbing structure that has excellent electromagnetic wave absorbing performance, has excellent sound wave absorbing performance, has translucency, can be seen from the other side, and is lightweight.

  The electromagnetic wave / sound absorption structure according to the invention of claim 18 is a structure in which a thin metal plate or a metal net is fixed to a wall surface to be installed, and a metal channel material having a predetermined channel interval is used. The electromagnetic wave / sound absorbing fabric according to claim 5 or claim 6 or the electromagnetic wave / sound absorbing fabric according to claim 10 formed by weaving the electromagnetic wave / sound absorbing yarn according to claim 5 or 6 among the electromagnetic wave / sound absorbing fabric according to claim 9. A sound absorbing fabric or an electromagnetic wave / sound absorbing structure according to claim 16 is attached.

  As a result, the electromagnetic wave incident from the electromagnetic wave / sound absorbing fabric side or the electromagnetic wave / sound absorbing structure side is first partially absorbed by the electromagnetic wave / sound absorbing fabric or the electromagnetic wave / sound absorbing structure, and is made of a thin metal plate or metal Reflected by the net and absorbed again when passing through the electromagnetic wave / sound absorbing fabric or the electromagnetic wave / sound absorbing structure. Here, the distance between the thin metal plate or the metal net and the electromagnetic wave / sound absorbing fabric or the electromagnetic wave / sound absorbing structure is a predetermined distance according to the wavelength of the electromagnetic wave to be absorbed by the metal channel material. Therefore, the incident electromagnetic wave and the electromagnetic wave reflected by the thin metal plate or metal net cancel each other, and the electromagnetic wave can be absorbed more effectively.

  There is a predetermined gap between the thin metal plate or metal net fixed to the wall and the electromagnetic wave / sound absorbing fabric or electromagnetic wave / sound absorbing structure so that air can freely pass therethrough. Therefore, an excellent sound absorption characteristic is exhibited by the electromagnetic wave / sound absorbing fabric or the electromagnetic wave / sound absorbing structure. Furthermore, the electromagnetic wave / sound absorbing fabric woven with the electromagnetic wave / sound absorbing yarn according to claim 5 or claim 6 or the electromagnetic wave / sound absorbing fabric according to claim 10 has water resistance, so that it can be used outdoors such as an inner wall of a tunnel. Suitable for use in

  The electromagnetic wave / sound absorption structure according to the invention of claim 19 is formed by applying the electromagnetic wave / sound absorption yarn according to claim 5 or 6 at a predetermined pitch on the outer peripheral surface of a plastic pipe having a predetermined inner diameter. It is wound and fixed in the S direction, and a metal rod or metal pipe is supported inside a plastic pipe by a cap fixed to both ends of the plastic pipe along the center line of the plastic pipe.

  The electromagnetic wave incident on the electromagnetic wave / sound absorbing structure having such a structure is first partially absorbed by the electromagnetic wave / sound absorbing thread on the outer peripheral surface of the plastic pipe and reflected by a metal rod or pipe inside the plastic pipe. Then, it is absorbed again by the electromagnetic wave / sound absorbing yarn on the outer peripheral surface. Accordingly, electromagnetic waves incident from any direction with respect to the electromagnetic wave / sound absorbing structure can be strongly absorbed. And since a sound wave is absorbed by the electromagnetic wave and sound wave absorption thread | yarn of the outer peripheral surface of a plastic pipe, the outstanding electromagnetic wave and sound wave absorption performance are shown.

  Let's absorb the predetermined inner diameter of the plastic pipe (more precisely, the distance from the inner metal rod or pipe surface to the electromagnetic wave / acoustic absorption yarn on the outer surface) and the predetermined pitch around which the electromagnetic wave / acoustic absorption yarn is wound. By setting according to the wavelength of the electromagnetic wave, it is possible to efficiently absorb the electromagnetic wave of the target wavelength. Further, if a transparent pipe is used as the plastic pipe, an electromagnetic wave / sound absorbing structure having translucency can be obtained.

  In this way, an electromagnetic wave / sound absorbing structure having excellent electromagnetic wave / sound absorbing performance and capable of particularly strongly absorbing an electromagnetic wave with a predetermined wavelength is obtained.

  An electromagnetic wave / sound absorbing structure according to the invention of claim 20 is formed by arranging a plurality of the electromagnetic wave / sound absorbing structures according to claim 19 in parallel at a predetermined interval.

  As a result, electromagnetic waves / sound waves can be absorbed over a wide area, and a stronger electromagnetic wave absorbing ability can be exhibited by corresponding to the wavelength of the electromagnetic waves to be absorbed at a predetermined interval. In addition, since the electromagnetic wave / sound absorption structure according to claim 19 is disposed at a predetermined interval, the other side can be seen even when a transparent plastic pipe is not used. .

  In this way, an electromagnetic wave / sound absorbing structure having excellent electromagnetic wave / sound absorbing performance and capable of particularly strongly absorbing an electromagnetic wave with a predetermined wavelength is obtained.

  The electromagnetic wave shielding yarn according to the invention of claim 21 is obtained by coating a conductive material on a number of short carbon fibers or short metal wires or base materials over the entire length of a normal spun fiber knitted by chain knitting. When one end or the center part of the thinly cut and short cut is knitted or twisted twice or every 10 times at the same time when the usual spinnable fiber is knitted by chain knitting, it is fixed in a number of short One end or both ends of a carbon fiber, a short metal wire or a base material coated with a conductive material, cut into pieces and cut short, protrudes from a knitted ordinary spinn fiber.

  Here, “ordinary spinnable fiber” includes cotton, silk, hemp, wool, nylon, vinylon, polyester fiber, acrylic fiber, vinylidene chloride fiber, organic fiber such as acetate and rayon, and inorganic fiber such as glass fiber. Alternatively, these fibers can be mixed. Examples of the “base material” include paper, cloth, and plastic film, and examples of the “conductive material” include metals such as gold, silver, and copper, and carbon.

  That is, the electromagnetic shielding yarn according to the invention of claim 21 has the same configuration as the electromagnetic wave / acoustic absorption yarn of the invention of claim 1. As a result, short carbon fibers or short metal wires or base materials coated with a conductive material and chopped into short pieces are entangled with ordinary knitted fibers that are knitted, and the tip is entangled with ordinary spinning fibers. Protrusively from bearded fibers. This beard-like projecting part is a carbon fiber or metal wire or base material coated with a conductive material, cut into pieces and cut short, and has conductivity, so it is wound around the object to be shielded at a predetermined pitch Therefore, the electromagnetic wave can be shielded by the beard-like protruding portion having conductivity.

  If a woven fabric is woven using such an electromagnetic shielding yarn, an electromagnetic shielding fabric having a high electromagnetic shielding ability is obtained. In this way, by providing a large number of bearded protrusions of conductive material on ordinary spinnable fibers, the loom can be used in a loom just like normal spinnable fibers while having greater electromagnetic shielding performance. It becomes an electromagnetic shielding yarn that can be woven.

  The electromagnetic shielding yarn according to the invention of claim 22 is formed by a plurality of ordinary spinnable fibers spaced apart from each other and coated with a conductive material on a carbon fiber, a metal wire or a base material, and a chain braid. When knitting, a carbon fiber, a metal wire or a base material coated with a conductive material every 2 to 10 times is cut into fine pieces, one adjacent normal spinning fiber, or one next After repeatedly knitting to move to a carbon fiber or metal wire or substrate along the normal spinnable fiber between multiple normal spinnable fibers, the conductive material is coated and thinly cut It is made by cutting what is done.

  That is, the electromagnetic wave shielding yarn according to the invention of claim 22 has the same configuration as the electromagnetic wave / acoustic absorption yarn according to the invention of claim 2. As a result, a short carbon fiber or a short metal wire or base material cut into a normal spinnable fiber is entangled with a conductive material coated into a thin piece and cut into short pieces. It is possible to easily produce a mixed yarn having a structure projecting like a beard from a conductive fiber. This beard-like protruding portion is a conductive material coated on a carbon fiber or metal wire or base material and cut into thin pieces, and has conductivity, so by winding it around a target to be shielded against electromagnetic waves at a predetermined pitch, The electromagnetic wave can be shielded by the beard-like protruding portion having conductivity.

  If a woven fabric is woven using such an electromagnetic shielding yarn, an electromagnetic shielding fabric having a high electromagnetic shielding ability is obtained. In this way, by providing a large number of bearded protrusions of conductive material on ordinary spinnable fibers, the loom can be used in a loom just like normal spinnable fibers while having greater electromagnetic shielding performance. It becomes an electromagnetic shielding yarn that can be woven.

  The electromagnetic shielding yarn according to the invention of claim 23 is formed by kneading and spinning a short carbon fiber or carbon powder or a short metal wire or metal powder into an organic synthetic resin, rubber or elastomer. Here, examples of the “organic synthetic resin” include thermoplastic resins such as polyethylene, polypropylene, acrylic resin, and vinyl chloride resin, and thermosetting resins such as phenol resin and epoxy resin. The term “elastomer” refers to a “highly elastic polymer substance” in a broad sense, and includes natural rubber and synthetic rubber, but here, it means a narrowly defined elastomer that does not contain rubber.

  That is, the electromagnetic shielding yarn according to the invention of claim 23 has the same configuration as the electromagnetic wave / acoustic absorption yarn of the invention of claim 3. Thus, short carbon fiber, carbon powder, short metal wire, or organic synthetic resin fiber or rubber fiber or elastomer fiber kneaded with metal powder is short carbon fiber, carbon powder, short metal wire having conductivity inside, Or, because it includes metal powder, it exhibits excellent electromagnetic shielding properties. And since it is an organic synthetic resin fiber, a rubber fiber, or an elastomer fiber, a woven fabric can be woven by a normal method.

  If a woven fabric is woven using such an electromagnetic shielding yarn, an electromagnetic shielding fabric having a high electromagnetic shielding ability is obtained. In this way, it becomes an electromagnetic wave shielding yarn that can be woven with a loom just like ordinary spinnable fibers while having a larger electromagnetic wave shielding performance.

  The electromagnetic shielding yarn according to the invention of claim 24 is an organic synthetic resin or rubber over the entire length of the electromagnetic shielding yarn according to any one of claims 21 to 23 after the glass fiber is wound over the entire length. Or an elastomer is coated. Here, examples of the “organic synthetic resin” include thermoplastic resins such as polyethylene, polypropylene, acrylic resin, and vinyl chloride resin, and thermosetting resins such as phenol resin and epoxy resin. The term “elastomer” refers to a “highly elastic polymer substance” in a broad sense, and includes natural rubber and synthetic rubber, but here, it means a narrowly defined elastomer that does not contain rubber.

  That is, the electromagnetic wave shielding yarn according to the invention of claim 24 has the same configuration as the electromagnetic wave / sound absorbing yarn according to the invention of claim 5. The electromagnetic shielding yarn having such a configuration is excellent in water resistance because it is coated with an organic synthetic resin, rubber, or elastomer over the entire length, and the electromagnetic shielding fabric formed by weaving the electromagnetic shielding yarn and the electromagnetic shielding yarn does not seal. However, it can be used outdoors as it is.

  In this way, ordinary spinnable fibers can be easily provided with many conductive beard-like protruding portions and coated with an organic synthetic resin, rubber, or elastomer, thereby providing water resistance while having greater electromagnetic shielding performance. It becomes an electromagnetic shielding yarn that is excellent in properties and can be woven with a loom just like ordinary spinnable fibers.

  The electromagnetic shielding yarn according to the invention of claim 25 is formed by coating a fluororesin over the entire length of the electromagnetic shielding yarn according to any one of claims 21 to 23. Here, as a method of coating the fluororesin, there are a method of spraying a liquid fluororesin, a method of immersing in a fluororesin solution, and a method of baking a gaseous fluororesin.

  That is, the electromagnetic shielding yarn according to the invention of claim 25 has the same configuration as the electromagnetic wave / acoustic absorption yarn of the invention of claim 6. The electromagnetic shielding yarn having such a configuration is excellent in water resistance because it is coated with a fluororesin having water repellency over the entire length, and the electromagnetic shielding fabric formed by weaving the electromagnetic shielding yarn and the electromagnetic shielding yarn does not seal. Can also be used outdoors.

  In this way, by providing a large number of beard-like protruding portions of conductive material to ordinary spinnable fibers and coating with fluororesin, it has excellent water resistance while having greater electromagnetic shielding performance. It becomes an electromagnetic shielding yarn that can be woven with a loom just like the spinnable fiber.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
Note that, in the second and subsequent embodiments, the same symbols and the same reference numerals as those in the first embodiment are parts that have the same or corresponding functions as those in the first embodiment, and therefore, duplicate description is omitted here.

Embodiment 1
First, Embodiment 1 of the present invention will be described with reference to FIGS.

  FIG. 1 is an explanatory view showing a process of manufacturing an electromagnetic wave / sound absorbing yarn according to Embodiment 1 of the present invention. FIG. 2 (a) is a partially enlarged view showing the structure of the electromagnetic wave / sound absorbing yarn according to the first embodiment of the present invention, and FIG. 2 (b) shows the structure of the electromagnetic wave / sound absorbing fabric according to the first embodiment of the present invention. It is a perspective view. FIG. 3 is a graph showing the electromagnetic wave absorption characteristics of the electromagnetic wave / sound absorbing fabric according to the first embodiment of the present invention. FIG. 4A is a perspective view showing a method of manufacturing the electromagnetic wave / sound absorbing sheet according to the first embodiment of the present invention, and FIG. 4B shows the structure of the electromagnetic wave / sound absorbing sheet according to the first embodiment of the present invention. It is a perspective view.

  As shown in FIG. 1, the electromagnetic wave / sound absorbing yarn according to the first embodiment is knitted by chain stitching a plurality of transparent polyester fibers 1 and carbon fibers 2 as ordinary spinnable fibers. A production method is employed in which the carbon fiber 2 is continuously knitted by passing one transparent polyester fiber 1 every 2 to 5 chain stitches. In this way, after repeatedly knitting the transparent polyester fiber 1 once every two to five times, the carbon fiber 2 is cut along the transparent polyester fiber 1 between the transparent polyester fibers 1.

  As a result, as shown in FIG. 2 (a), an electromagnetic wave / sonic wave having a structure in which a short carbon fiber beard-like protruding portion 2A is formed on a chain of transparent polyester fiber 1 and carbon fiber 2 sewn. The absorbent yarn 3 can be easily produced. Since the beard-like protruding portion 2A is a carbon fiber and has electrical conductivity, electromagnetic waves having a frequency corresponding to the length of the entire short carbon fiber including the protruding portion 2A of the carbon fiber can be strongly absorbed.

  Further, since the protruding portion 2A of the carbon fiber has rigidity, it has an action of dispersing air and dissipating sound waves, and therefore functions as a sound absorbing yarn. Accordingly, if a woven fabric is woven using the electromagnetic wave / sound absorbing yarn 3, an electromagnetic wave / sound absorbing fabric having a high electromagnetic wave / sound absorbing ability is obtained.

  In the first embodiment, as shown in FIG. 2 (b), an electromagnetic wave / sound absorbing fabric 5 having a coarse texture of about 10 mm is woven using the electromagnetic wave / sound absorbing yarn 3. Thus, the electromagnetic wave / sound absorbing fabric 5 can be seen through the other side while having strong electromagnetic wave / sound absorbing performance.

  Next, the electromagnetic wave absorption characteristics of the electromagnetic wave / sound absorbing fabric 5 will be described with reference to FIG. As shown in FIG. 3, in the electromagnetic wave absorption characteristic measurement test in the first embodiment, the incident angle of the radio wave is 90 degrees, that is, perpendicular to the sample surface. In the metal reflector, the radio wave is totally reflected in any frequency band ranging from 1.0 GHz to 15.0 GHz, which is the measurement range, so that the radio wave absorption is approximately 0 dB (decibel).

  Here, when an styrene foam plate having a thickness of 10 mm was placed on a metal reflector and a large number of carbon fibers cut into a length of 20 mm were dispersed on the metal reflector, an electromagnetic wave absorption characteristic measurement test was performed. As shown in FIG. 2, the radio wave absorption characteristics having a large peak in the vicinity of 5.8 GHz, which is the frequency of the radio wave used in the ETC system.

  As a result, it has been found that a carbon fiber having a length of 20 mm is effective for absorbing a radio wave having a frequency of 5.8 GHz. Therefore, the carbon fiber of the electromagnetic wave / sound absorbing yarn 3 constituting the electromagnetic wave / sound absorbing fabric 5 is used. When the electromagnetic wave / sound absorbing fabric 5 was woven with the length of the entire short carbon fiber including the protruding portion 2A of about 20 mm, and an electromagnetic wave absorption characteristic measurement test was conducted, as shown in FIG. 3, it was about 5.8 GHz. An electromagnetic wave absorption characteristic of 20 dB was shown.

  Accordingly, the electromagnetic wave / sound absorbing fabric 5 formed by weaving the electromagnetic wave / sound absorbing yarn 3 having a short carbon fiber length of about 20 mm is excellent in the ability to absorb radio waves in a frequency band centered on 5.8 GHz. It has been found.

  Next, an electromagnetic wave / sound absorbing sheet manufactured using the electromagnetic wave / sound absorbing fabric 5 will be described with reference to FIG.

  As shown in FIG. 4 (a), in the first embodiment, the top and bottom of the electromagnetic wave / sound absorbing fabric 5 have a large number of pores in the range of 500 nm to 1 μm on the transparent whole surface as a thin organic synthetic resin sheet. A vinyl sheet 6 (thickness of about 0.1 mm) with a through hole of 20% is sandwiched between them, and the upper and lower vinyl sheets 6 are adhered to the electromagnetic wave / sound absorbing fabric 5 using a weather-resistant adhesive. Yes. In this way, as shown in FIG. 3B, the electromagnetic wave / sonic wave absorbing sheet 8 according to the first embodiment is obtained.

  Here, the electromagnetic wave / sound absorbing fabric 5 uses the electromagnetic wave / sound absorbing yarn 3 having a structure in which the short carbon fiber 2A is entangled with the transparent polyester fiber 1 and has a coarse texture of about 10 mm. See through. Furthermore, since a thin organic synthetic resin sheet sandwiching the upper and lower sides is made of a transparent vinyl sheet 6 having a large number of through holes in the range of 500 nm to 1 μm on the entire surface, air may pass therethrough. It is possible to exhibit a sound wave absorbing effect and has translucency.

  In this way, the electromagnetic wave / sound absorbing sheet 8 can be seen through the other side while having an excellent electromagnetic wave / sound absorbing effect. Therefore, the electromagnetic wave / sound absorption sheet is particularly suitable for electromagnetic wave / sound absorption applications that need to be transparent or translucent.

  In the first embodiment, the electromagnetic wave / sound absorbing yarn 3 having a structure in which a short carbon fiber 2A is wound around a transparent polyester fiber 1 as a normal spinnable fiber has been described. However, the present invention is limited to the short carbon fiber 2A. Rather than electromagnetic wires and sound-absorbing yarns with a structure in which short metal wires such as copper wires and stainless steel wires are wound, and substrates such as paper, cloth, and plastic films, metals such as gold, silver, copper, and carbon An electromagnetic wave / acoustic absorption yarn having a structure in which a conductive material is coated, cut into thin pieces, and shortly cut is wound.

  Also, the usual spinnable fiber is not limited to the transparent polyester fiber 1, but other usual spinnable properties such as transparent or opaque synthetic fibers such as transparent nylon fibers and opaque nylon fibers. Fiber can also be used.

  Furthermore, although the transparent vinyl sheet 6 in which a large number of through-holes having a hole diameter in the range of 500 nm to 1 μm are formed on the entire surface as a thin organic synthetic resin sheet with an aperture ratio of 20% is used, the sound absorption characteristic is not required. In some cases, there may be no through-hole, and when there is no requirement for transparency or translucency, other thin organic synthetic resin sheets that are translucent or opaque may be used.

  In addition, the electromagnetic wave / sound absorbing sheet 8 according to the first embodiment includes a weather resistant adhesive sandwiched between a transparent vinyl sheet 6 as a thin organic synthetic resin sheet having a thickness of about 0.1 mm. However, when a large number of through holes are not formed, it can be formed into a sheet by thermocompression bonding.

  Here, normal sound barriers such as highways are made of thick materials that absorb sound or reflect sound waves, so the outside cannot be seen at all, and the driver feels obstruction and passengers Enjoying the scenery was also hindered. However, the sound absorbing sheet 8 according to the first exemplary embodiment of the present invention can be seen through the other side even when one or several sheets are stacked, so that it is not obstructive to enjoy the scenery without giving a feeling of blockage. A soundproof wall can be constructed.

Embodiment 2
Next, a second embodiment of the present invention will be described with reference to FIGS. FIG. 5A is a cross-sectional view showing the structure of an electromagnetic wave / sound absorption plate according to Embodiment 2 of the present invention, and FIG. 5B is a perspective view showing the entire structure. FIG. 6 is a graph showing the electromagnetic wave absorption characteristics of the electromagnetic wave / sound absorbing plate according to the second embodiment of the present invention.

  As shown in FIG. 5A, the electromagnetic wave / sound absorbing plate 10 according to the second embodiment is manufactured using three electromagnetic wave / sound absorbing fabrics 5A, 5B, and 5C having different weave roughness. Has been. The electromagnetic wave / sound absorbing yarn 3 used for weaving the electromagnetic wave / sound absorbing fabric 5A, 5B, 5C is the same electromagnetic wave / sound absorbing yarn 3 as in the first embodiment.

  The electromagnetic wave / acoustic absorption fabric 5A is made by weaving the electromagnetic wave / acoustic absorption yarn 3 into a 40 mm mesh coarse lattice, and the electromagnetic wave / acoustic absorption fabric 5B is an electromagnetic wave / acoustic absorption yarn 3 having a roughness of 30 mm mesh. The electromagnetic wave / sound absorbing fabric 5C is formed by weaving the electromagnetic wave / sound absorbing yarn 3 into a 20 mm mesh coarse lattice.

  As shown in FIG. 5A, a foamed polystyrene plate 11 having a thickness of 10 mm as an organic synthetic resin plate is sandwiched between these three electromagnetic wave / sound absorbing fabrics 5A, 5B, and 5C. ), The electromagnetic wave / sonic wave absorbing plate 10 according to the second embodiment is manufactured by fastening the periphery with a frame 12.

  Next, the electromagnetic wave absorption characteristics of the electromagnetic wave / sonic wave absorbing plate 10 according to the second embodiment having such a configuration will be described with reference to FIG. As shown in FIG. 6, in the electromagnetic wave absorption characteristic measurement test in the second embodiment, the incident angle of radio waves is set to 75 degrees (that is, an angle inclined from 90 degrees to 15 degrees vertically). In the metal reflector, the radio wave is totally reflected in any frequency band, and therefore, the radio wave absorption is approximately 0 dB (decibel).

  On the other hand, when the electromagnetic wave / sound absorbing fabric 3C formed by weaving the electromagnetic wave / sound absorbing yarn 3 in a 20 mm mesh coarse grid is placed on a metal reflector through a 10 mm thick polystyrene plate and measured. As shown in FIG. 6, radio wave absorption of 20 dB or more was observed at a frequency of 5.8 GHz.

  Further, when the electromagnetic wave / sound absorbing plate 10 according to the second embodiment is measured on a metal reflector through a foamed polystyrene plate having a thickness of 10 mm, as shown in FIG. 6, at a frequency of 5.8 GHz. Radio wave absorption near 30 dB was observed at a frequency of 25 dB or more and a frequency of 6.0 GHz.

  These measurement results are summarized in Table 1.

  As shown in Table 1, the electromagnetic wave absorption amount of the electromagnetic wave / acoustic wave absorbing plate 10 at a frequency of 5.8 GHz is a large value of 26.5 dB. In the electromagnetic wave absorption characteristic measurement test in the second embodiment, since the incident angle of radio waves is set to 75 degrees, it has been found that not only vertically incident radio waves but also obliquely incident radio waves are strongly absorbed. Therefore, it can be seen that the electromagnetic wave / acoustic wave absorbing plate 10 according to the second embodiment is extremely effective for electromagnetically blocking between the adjacent gates of the ETC system using the radio wave having a frequency of 5.8 GHz. It was.

Embodiment 3
Next, Embodiment 3 of the present invention will be described with reference to FIGS. 7A is a perspective view showing a construction state of the electromagnetic wave / sound absorbing sheet according to the third embodiment of the present invention on the inner wall of the tunnel, and FIG. 7B is an electromagnetic wave / sound absorbing effect in the tunnel of the electromagnetic wave / sound absorbing sheet. It is explanatory drawing which shows. FIG. 8 is a perspective view showing an example of use of the electromagnetic wave / sound absorbing plate according to the third embodiment of the present invention at a toll gate on an expressway.

  As shown in FIG. 7A, the electromagnetic wave / sound absorbing sheet 8 described in the first embodiment is used as the electromagnetic wave / sound absorbing sheet for construction on the inner wall of the tunnel according to the third embodiment. .

  As described in the first embodiment, the electromagnetic wave / sound absorbing sheet 8 is made by weaving a rough electromagnetic wave / sound absorbing fabric 5 having a texture of about 10 mm using the electromagnetic wave / sound absorbing yarn 3, and 5 is sandwiched between a vinyl sheet 6 in which a large number of through-holes having a hole diameter in the range of 500 nm to 1 μm are formed on a transparent entire surface having a thickness of about 0.1 mm on the upper and lower sides of 5 with a weather-resistant adhesive. The upper and lower vinyl sheets 6 are bonded to the electromagnetic wave / sound absorbing fabric 5 using

  Therefore, the electromagnetic wave / sound absorption sheet 8 has excellent electromagnetic wave absorption performance and sound wave absorption performance, is extremely light and thin, and is very easy to install on the inner wall of the tunnel T.

  Conventionally, in an automobile road tunnel T as shown in FIG. 7 (a), noises such as engine sound and running sound emitted from the automobile V are echoed and amplified on the inner wall of the tunnel T, resulting in greater noise. It was happening. In addition, in the car navigation system (hereinafter referred to as “car navigation”), the radio waves from the satellites are repeatedly reflected on the inner wall of the tunnel T and the road surface, causing irregular reflection noise, so that the car navigation system cannot be used in the tunnel T. There was also a situation of becoming.

  However, by attaching and constructing the electromagnetic wave / sound absorbing sheet 8 on the entire inner wall of the tunnel T, as shown in FIG. 7 (b), the engine sound / running sound, etc. emitted from the automobile V indicated by the solid line arrow, etc. This noise is absorbed by the electromagnetic wave / sonic wave absorbing sheet 8 and does not reverberate, so that a larger noise is not generated. Further, the radio wave from the satellite for car navigation indicated by the broken arrow is not absorbed by the electromagnetic wave / sound absorbing sheet 8 to cause irregular reflection noise, and the car navigation can be used as usual in the tunnel T.

  Next, the electromagnetic wave / sound absorbing plate 15 according to the third embodiment will be described with reference to FIG. The electromagnetic wave / sound absorbing plate 15 according to the third embodiment is the same as the electromagnetic wave / sound absorbing plate 10 according to the second embodiment, except that a transparent acrylic resin plate is used instead of the styrofoam plate 11 as an organic synthetic resin plate. It is.

  In recent years, with the spread of ETC, the number of automobiles V equipped with ETC on-board units has increased, and as shown in FIG. 8, a plurality of ETC gates 16G are provided at a toll gate TG. Yes. Here, an electromagnetic wave shielding plate is provided between the adjacent ETC gates 16G in order to prevent radio wave mixing between the adjacent ETC gates 16G. However, since the conventional electromagnetic wave shielding plate is opaque, the adjacent ETC gates are not provided. There was a problem that it was not possible to confirm the movement of another vehicle V passing through 16G.

  However, the electromagnetic wave / sound absorbing plate 15 according to the third exemplary embodiment has three electromagnetic wave / sound absorbing fabrics 5A having a coarse texture of 40 mm mesh, 30 mm mesh, and 20 mm mesh with a transparent acrylic resin plate interposed therebetween. Since the other side can be seen through because it is composed of 5B and 5C, the movement of the other vehicle V passing through the adjacent ETC gate 16G can be confirmed, and radio wave crossing can be reliably prevented. .

Embodiment 4
Next, a fourth embodiment of the present invention will be described with reference to FIGS.

  FIG. 9A is an enlarged view showing a method for producing an electromagnetic wave / acoustic absorption yarn for forming an electromagnetic wave / acoustic absorption structure according to Embodiment 4 of the present invention, and FIG. It is an enlarged view which shows a state. FIG. 10A is a perspective view showing a method for manufacturing an electromagnetic wave / sound absorbing structure according to Embodiment 4 of the present invention, and FIG. 10B is a perspective view showing a completed state of the electromagnetic wave / sound absorbing structure.

  FIG. 11A is a perspective view showing a method for manufacturing an electromagnetic wave / sound absorbing structure according to a first modification of Embodiment 4 of the present invention, and FIG. 11B is an electromagnetic wave / sound absorbing structure according to the first modification. It is a perspective view which shows the completion state of. FIG. 12A is a perspective view showing a method for manufacturing an electromagnetic wave / sound absorbing structure according to a second modification of Embodiment 4 of the present invention, and FIG. 12B is an electromagnetic wave / sound absorbing structure according to the second modification. It is a perspective view which shows the completion state of. FIG. 13: is a perspective view which shows the usage example in the toll booth of the electromagnetic wave and sound wave absorption structure concerning Embodiment 4 of this invention and the 2nd modification of Embodiment 4 of this invention.

  As shown in FIGS. 9A and 9B, the electromagnetic wave / sound absorbing yarn 9 according to the fourth embodiment is made of glass fiber over the entire length of the electromagnetic wave / sound absorbing yarn 3 according to the first embodiment. After winding 4, polyethylene 7 as an organic synthetic resin is coated over the entire length. As a method for coating polyethylene 7, the total length of electromagnetic wave / sound absorbing yarn 3 shown in FIG. 9A is applied to a solution obtained by dissolving polyethylene 7 in an organic solvent or a melt obtained by heating and melting polyethylene 7. For example, a method in which a glass fiber 4 is wound around the glass fiber 4 is immersed.

  When the method of immersing in a polyethylene solution is employed, the organic solvent is removed by lifting and drying, and when the method of immersing in a polyethylene melt is employed, it is lifted and cooled to obtain FIG. The electromagnetic wave / sound absorption yarn 9 shown in b) can be obtained. Here, as shown in FIG. 9 (a), since the glass fiber 4 is first wound over the entire length of the electromagnetic wave / sound absorbing yarn 3, even if it is immersed in a high-temperature polyethylene melt, it is possible to use it normally. The transparent polyester fiber as the spinning fiber 1 does not melt.

  The electromagnetic wave / sound absorbing yarn 9 having such a structure is excellent in water resistance because it is coated with polyethylene 7 over the entire length, and the electromagnetic wave / sound absorbing fabric formed by weaving the electromagnetic wave / sound absorbing yarn 9 does not seal. Can also be used outdoors. Thus, by coating the electromagnetic wave / sound absorbing yarn 3 provided with many spine-like protruding portions 2A of the carbon fiber 2 on the usual spinnable fiber 1 with the polyethylene 7, it has a larger electromagnetic wave / sound absorbing performance. However, it is excellent in water resistance and can be woven with a loom just like ordinary spinnable fibers.

  Next, a method of manufacturing an electromagnetic wave / sound absorbing structure using the electromagnetic wave / sound absorbing yarn 9 having such a configuration will be described with reference to FIG.

  As shown in FIG. 10 (a), two sheets of electromagnetic wave / acoustic wave absorbing yarns 9 stretched in parallel with an interval of 20 mm are produced on a frame body 17 made of a thin stainless steel pipe. And these two sheets are adhere | attached on both sides of the dielectric material sheet 18 which consists of glass fiber so that the direction of the electromagnetic wave and sound wave absorption thread | yarn 9 stretched on the frame 17 may become perpendicular | vertical mutually.

  The electromagnetic wave / sound absorbing structure thus manufactured is fixed to the upper surface of the frame 24 made of reinforced plastic as shown in FIG. 10 (b), and is used as a metal net shown in FIG. 10 (a). A stainless steel wire mesh 23 is fixed to the bottom surface of the frame body 24. Thereby, as shown in FIG. 10B, the electromagnetic wave / sound absorption structure 20 according to the fourth embodiment is completed.

  The electromagnetic wave / sound absorbing yarn 9 was stretched with an interval of 20 mm in order to absorb the 5.8 GHz radio wave used for the ETC system, and the thickness of the frame 24 was 10 mm, so An interval of about 10 mm is generated between the electromagnetic wave / sound absorption structure and the stainless steel wire mesh 23 on the bottom surface, which is also to absorb the 5.8 GHz radio wave used in the ETC system. The electromagnetic wave / sound absorbing structure 20 manufactured in this way is excellent in water resistance because it uses the electromagnetic wave / sound absorbing yarn 9, and can be used outdoors without any problems.

  Next, the manufacturing method of the electromagnetic wave and sound wave absorption structure concerning the 1st modification of this Embodiment 4 is demonstrated with reference to FIG.

  As shown in FIG. 11 (a), the electromagnetic wave / sound absorbing fabric 21 used in the electromagnetic wave / sound absorbing structure according to the first modification of the fourth embodiment is the same as the electromagnetic wave / sound absorbing fabric according to the first embodiment. The electromagnetic wave / acoustic absorption yarn 22 coated with a fluororesin over the entire length of the acoustic absorption yarn 3 is woven in a lattice shape with an interval of 20 mm. Here, as a method of coating the fluororesin, a method of removing the solvent by immersing the electromagnetic wave / acoustic absorption yarn 3 in the fluororesin solution and then removing the solvent may be used, or a method of baking a gaseous fluororesin may be used. .

  Further, as shown in FIG. 11A, a stainless steel wire net 23 is prepared as a metal net having the same dimensions as the electromagnetic wave / sound absorbing fabric 21. Here, the stainless steel wire mesh 23 is preferably made of a stainless steel wire as thin as possible in order to have excellent translucency when superimposed on the electromagnetic wave / sound absorbing fabric 21 and to make the other side visible. Moreover, since it plays a role of reflecting electromagnetic waves, it is preferable that the mesh of the metal mesh 23 is finer. In the first modification of the fourth embodiment, a stainless steel wire mesh 23 made of a stainless steel wire having a thickness of 0.5 mm and having a mesh size of 2 mm to 3 mm is used.

  As shown in FIG. 11B, the electromagnetic wave / sound absorbing fabric 21 and the stainless steel wire mesh 23 are respectively attached to both sides of a reinforced plastic frame 24, and the thickness (10 mm) of the frame 24 is obtained. It is constituted so as to face each other with a gap of only. As a result, the electromagnetic wave / sound absorption structure 25 according to the first modification of the fourth embodiment is completed.

  The electromagnetic wave / sound absorption structure 25 according to the first modification of the fourth embodiment having such a configuration is mainly used indoors. For example, a thin wooden board can be pasted on the electromagnetic wave / sound absorbing fabric 21 on the upper surface of the electromagnetic wave / sound absorbing structure 25 and applied as a structural material (wall panel) for the wall surface of a house.

  Next, the manufacturing method of the electromagnetic wave and sound wave absorption structure concerning the 2nd modification of this Embodiment 4 is explained with reference to FIG.

  As shown in FIG. 12A, the electromagnetic wave / sound absorbing structure 21A used in the electromagnetic wave / sound absorbing structure according to the second modification of the fourth embodiment is made of the thin stainless steel pipe described above. The above-described electromagnetic wave / sound absorbing yarn 9 is stretched vertically and horizontally at an interval of 20 mm on the frame 17.

  As shown in FIG. 12 (b), the electromagnetic wave / sound absorption structure 21A and the above-described stainless steel wire mesh 23 are attached to both surfaces of the above-mentioned reinforced plastic frame 24, respectively. It is configured to face each other with a gap of 10 mm. Thereby, the electromagnetic wave / sound absorption structure 25A according to the second modification of the fourth embodiment is completed.

  Here, the stainless steel wire mesh 23 is preferably made of a stainless steel wire as thin as possible in order to have excellent translucency when superimposed on the electromagnetic wave / sound absorbing structure 21A and to make the other side visible. . Moreover, since it plays a role of reflecting electromagnetic waves, it is preferable that the mesh of the metal mesh 23 is finer. In the second modification of the fourth embodiment, a stainless steel wire mesh 23 made of a stainless steel wire having a thickness of 0.5 mm and having a mesh size of 2 mm to 3 mm is used.

  In the second modification of the fourth embodiment, the thickness of the frame body 24 is set to 10 mm, which is the same as the reason why the eye of the electromagnetic wave / sound absorbing structure 21A is set to 20 mm, and the ETC system. This is to absorb the 5.8 GHz radio wave used in the above.

  Next, a usage example of the electromagnetic wave / sound absorbing structure 20 according to the fourth embodiment and the electromagnetic wave / sound absorbing structure 25A according to the second modification of the fourth embodiment will be described with reference to FIG. .

  As shown in FIG. 13, two ETC gates 16G are installed next to each other at the toll gate TG on the highway. The electromagnetic wave / sound absorbing structure 25A according to the second modification of the fourth embodiment is installed between the two ETC gates 16G and functions to prevent radio wave crosstalk. As described above, the electromagnetic wave / sound absorption structure 25A is excellent in translucency, and the other side can be seen well, so the driver of the automobile V1 and the driver of the automobile V3 can see each other's movement well, and the ETC gate 16G. You can pass through with confidence.

  Further, as shown in FIG. 13, the electromagnetic wave / sound absorbing structure 20 according to the fourth embodiment is attached obliquely to the roof of the toll gate TG diagonally above the radio wave transmitter of the ETC gate 16G. ing. As a result, the radio wave transmitted from the radio wave transmission unit of the ETC gate 16G reaches only the automobiles V1 and V3 that are about to pass through the ETC gate 16G, and the radio wave that travels backward is absorbed by the electromagnetic wave / acoustic wave absorbing structure 20. Therefore, it is possible to prevent a situation where a cross line occurs between the following automobiles V2, V4 and the automobiles V1, V3.

  In this way, the electromagnetic wave / sound absorbing structure 20 according to the fourth embodiment and the electromagnetic wave / sound absorbing structure 25A according to the second modification of the fourth embodiment ensure crosstalk of radio waves in the ETC gate 16G. Can be prevented.

  The electromagnetic wave / sound absorbing structure 20 is composed of an electromagnetic wave / sound absorbing thread 9 coated with polyethylene 7, a frame 17 made of stainless steel pipe, a stainless steel wire mesh 23, and a frame 24 made of reinforced plastic. Similarly, the electromagnetic wave / sound absorbing structure 25A is composed of an electromagnetic wave / sound absorbing yarn 9 coated with polyethylene 7, a frame 17 made of stainless steel pipe, a stainless steel wire mesh 23, and a frame 24 made of reinforced plastic. Therefore, both have excellent water resistance and can withstand outdoor use.

Embodiment 5
Next, a fifth embodiment of the present invention will be described with reference to FIG. FIG. 14A is a perspective view showing the structure of an electromagnetic wave / sound absorbing structure according to a fifth embodiment of the present invention, and FIG. 14B is a perspective view showing an example of use of the electromagnetic wave / sound absorbing structure at a toll gate on a highway. FIG.

  As shown in FIG. 14 (a), the electromagnetic wave / sound absorbing structure 26 according to the fifth embodiment is provided on the outer peripheral surface of a vinyl chloride pipe 27 as a plastic pipe on the polyethylene 7 according to the fourth embodiment. The electromagnetic wave / acoustic wave absorbing yarn 9 coated with is wound and fixed at a constant pitch P in the Z direction and the S direction, and an aluminum pipe 28 as a metal pipe is passed through the vinyl chloride pipe 27 to pass through the vinyl chloride pipe. By being inserted into caps 29 fitted to both ends of 27, it is supported so as to be positioned along the center line of the vinyl chloride pipe 27.

  Part of the electromagnetic wave incident on the electromagnetic wave / sound absorption structure 26 having such a structure is first absorbed by the electromagnetic wave / sound absorption yarn 9 on the outer peripheral surface of the vinyl chloride pipe 27, and then by the aluminum pipe 28 inside the vinyl chloride pipe 27. It is reflected and again absorbed by the electromagnetic wave / sound absorbing yarn 9 on the outer peripheral surface. As a result, electromagnetic waves incident on the electromagnetic wave / sound absorbing structure 26 from any direction can be strongly absorbed. Since the sound wave is absorbed by the electromagnetic wave / sound absorbing yarn 9 on the outer peripheral surface of the vinyl chloride pipe 27, excellent electromagnetic wave / sound absorbing performance is exhibited.

  The inner diameter of the vinyl chloride pipe 27 (more precisely, the distance from the surface of the inner aluminum pipe 28 to the electromagnetic wave / sound absorbing yarn 9 on the outer peripheral surface) and the pitch P around which the electromagnetic wave / sound absorbing yarn 9 is wound are the electromagnetic waves to be absorbed. By setting according to the wavelength, it is possible to efficiently absorb the electromagnetic wave having the target wavelength. In the fifth embodiment, the pitch P is set to 20 mm, and the distance from the surface of the aluminum pipe 28 to the electromagnetic wave / sound absorbing yarn 9 on the outer peripheral surface is set to 10 mm.

  Next, a usage example of the electromagnetic wave / sound absorbing structure 26 having such a structure will be described with reference to FIG. As shown in FIG. 14B, two ETC gates 16G are installed adjacent to each other at the toll gate TG on the highway. Between these two ETC gates 16G, an electromagnetic wave according to a modification of the fifth embodiment in which a plurality of electromagnetic wave / sound absorbing structures 26 according to the fifth embodiment are arranged in the horizontal direction at regular intervals. A sound wave absorbing structure 30 is installed and functions to prevent crosstalk of radio waves.

  In the electromagnetic wave / sound absorbing structure 30 according to the modification of the fifth embodiment, a pair of support columns 31 are erected on the bottom plate 32, and a plurality of electromagnetic wave / The sound absorbing structure 26 is supported horizontally at regular intervals in the vertical direction. Since the electromagnetic wave / sound absorbing structure 30 includes a plurality of electromagnetic wave / sound absorbing structures 26, the electromagnetic wave incident from any direction can be strongly absorbed. Since there is a space in the vertical direction, the driver of the automobile V passing through the ETC gate 16G can see the movement of the automobile V passing through the adjacent ETC gate 16G well.

  In the fifth embodiment, an opaque vinyl chloride pipe 27 is used as the plastic pipe constituting the electromagnetic wave / sound absorbing structure 26. However, the plastic pipe is a transparent pipe such as a transparent acrylic resin pipe. By using the thing, the movement of the automobile V passing through the adjacent ETC gate 16G can be seen well.

Embodiment 6
Next, a sixth embodiment of the present invention will be described with reference to FIG. FIG. 15A is a perspective view showing the structure of the electromagnetic wave / sound absorbing structure according to Embodiment 6 of the present invention, and FIG. 15B is an explanation showing the electromagnetic wave / sound absorbing effect in the tunnel of the electromagnetic wave / sound absorbing structure. FIG.

  As shown in FIG. 15 (a), the electromagnetic wave / sound absorbing structure 35 according to the sixth embodiment has a metal wire mesh 23 made of stainless steel as a metal mesh on the inner wall surface of a tunnel T as a wall surface to be installed. The electromagnetic wave / acoustic wave absorbing yarn 9 is vertically and horizontally spaced 20 mm apart from the frame 17 made of a thin stainless steel pipe as described above through the metal channel member 36 having a predetermined channel interval. A stretched electromagnetic wave / sound absorption structure 21A is attached.

  As a result, the electromagnetic wave incident from the electromagnetic wave / sound absorbing structure 21A side is first partially absorbed by the electromagnetic wave / sound absorbing structure 21A, reflected by the stainless steel wire mesh 23, and again reflected by the electromagnetic wave / sound absorbing structure 21A. Absorbed when passing through.

  Here, since the interval between the stainless steel wire mesh 23 and the electromagnetic wave / sound absorbing structure 21A is a predetermined interval that matches the wavelength of the electromagnetic wave to be absorbed by the metal channel member 36, the incident electromagnetic wave And the electromagnetic waves reflected by the stainless steel wire mesh 23 cancel each other, so that the electromagnetic waves can be absorbed more effectively.

  There is a predetermined gap between the stainless steel wire mesh 23 fixed to the wall surface and the electromagnetic wave / sound absorbing structure 21A, and air can freely pass therethrough. Excellent sound absorption characteristics are exhibited by 21A. Furthermore, as described above, the electromagnetic wave / sound absorbing structure 21A has water resistance and is suitable for use on the inner wall of the tunnel.

  Conventionally, in an automobile road tunnel T as shown in FIG. 15 (b), noises such as engine sound and running sound emitted from the automobile V are echoed and amplified on the inner wall of the tunnel T, and more noise is generated. It was happening. As for the car navigation system, there is a situation in which the car navigation system becomes unusable in the tunnel T due to irregular reflection noise caused by the radio waves from the satellite being repeatedly reflected on the inner wall of the tunnel T and the road surface.

  However, by attaching and constructing the electromagnetic wave / sound absorbing structure 35 over the entire inner wall of the tunnel T, as shown in FIG. 15B, the engine sound / running sound emitted from the automobile V indicated by the solid line arrow. Such noise is not absorbed by the electromagnetic wave / sonic wave absorbing structure 35 and does not reverberate, and thus no larger noise is generated. In addition, radio waves from a satellite for car navigation indicated by broken arrows are not absorbed by the electromagnetic wave / sound absorbing structure 35 to cause irregular reflection noise, and the car navigation can be used as usual in the tunnel T. .

Embodiment 7
Next, a seventh embodiment of the present invention will be described with reference to FIG. FIG. 16 is a graph showing the electromagnetic wave absorption characteristics of the electromagnetic wave / sound absorbing yarn according to the seventh embodiment of the present invention. In Embodiment 7, as shown in FIGS. 9A and 9B, the glass fiber 4 is wound around the electromagnetic wave / sound absorbing yarn 3, and the organic synthetic resin 7 is further coated thereon. If the entire length of the short carbon fiber including the protruding portion 2A of the carbon fiber is made almost uniform in the electromagnetic wave / sound absorption yarn 9 to be generated, the frequency band indicating the electromagnetic wave / sound absorption performance becomes very narrow. Since there is a problem, it shows how to solve it.

  That is, the length of the entire short carbon fiber including the protruding portion 2A of the carbon fiber is not made constant, for example, 25 mm ± (1 mm to 5 mm), that is, a random length within the range of 20 mm to 30 mm. Thus, it is possible to widen the frequency band showing the electromagnetic wave / sound absorption performance. A glass fiber 4 is wound around an electromagnetic wave / sound absorbing yarn 3 having a length of a short carbon fiber including a protruding portion 2A of the carbon fiber and a random length within a range of 20 mm to 30 mm, and an organic synthetic resin is further formed thereon. FIG. 16 shows the result of measuring the electromagnetic wave absorption characteristics of the electromagnetic wave / acoustic absorption yarn 9 produced by coating 7. In addition to the glass fiber 4, other fibers such as an insulating fiber such as cotton may be used as the fiber to be wound.

  As shown in FIG. 16, in the electromagnetic wave absorption characteristic measurement test according to the seventh embodiment, the incident angle of radio waves is 90 degrees, that is, perpendicular to the sample surface. Curves S1 and S2 are the results of measurement at different measurement locations. Although the position of the peak is shifted by changing the measurement location, the frequency band showing the electromagnetic wave absorption characteristics is greatly expanded for both the curves S1 and S2. The curve S3 is measured by pressing the electromagnetic wave / sound absorbing yarn 9 according to the seventh embodiment with a plywood plate so that the peak position does not shift even if the measurement location is changed. Although the peak of electromagnetic wave absorption is low, the frequency band showing the electromagnetic wave absorption characteristics is further expanded.

  Thus, by making the length of the entire short carbon fiber including the protruding portion 2A of the carbon fiber constant, for example, 25 mm ± (1 mm to 5 mm), that is, a random length within a range of 20 mm to 30 mm. By doing so, the frequency band showing the electromagnetic wave / sound absorption performance can be expanded.

Embodiment 8
Next, an eighth embodiment of the present invention will be described with reference to FIG. FIG. 17: is a fragmentary perspective view which shows the state which wound the electromagnetic wave shield thread concerning Embodiment 8 of this invention around the high voltage | pressure electric wire. As shown in FIG. 17, in the eighth embodiment, the electromagnetic wave / sound absorbing yarn 3 manufactured by the same manufacturing method as in the first embodiment is used as the electromagnetic shielding yarn.

The electromagnetic wave can be shielded by winding the electromagnetic wave shielding yarn 3 having the same structure as the electromagnetic wave / acoustic absorption yarn of Embodiment 1 around a target to be electromagnetic wave shielded at a predetermined pitch. As a specific application, for example, when a normal power line is used for communication in high-speed power line communication (PLC), leakage of radio waves from the power line becomes a problem. By winding, it is possible to reliably prevent such leakage of radio waves.
Here, the electromagnetic shield yarn 3 is not different from the electromagnetic wave / acoustic wave absorbing yarn 3 in the basic configuration, and is therefore expressed by the same reference numeral.

  In the eighth embodiment, as shown in FIG. 17, when the high voltage electric wire 40 is used as a PLC communication line by winding the electromagnetic shielding yarn 3 around the high voltage electric wire 40 at a predetermined pitch, the high voltage electric wire 40 is used. It is possible to reliably prevent radio waves from leaking. Here, the power line including the high voltage electric wire 40 is not a flat plate but has a long cylindrical three-dimensional shape. In the case of a flat plate, for example, an electromagnetic wave can be shielded even if a thin metal foil is attached, but in the case of a three-dimensional shape such as a power line, the eighth embodiment is used. The electromagnetic wave cannot be shielded unless a cut conductor such as the electromagnetic wave shielding yarn 3 is arranged.

  In the eighth embodiment, as an electromagnetic wave shielding yarn, the carbon fiber 2 is used every 2 to 5 times when the polyester fiber 1 as a normal spinnable fiber is knitted with a carbon fiber 2 and a chain braid at intervals. Although the example which used the electromagnetic wave shielding thread | yarn 3 which cut | disconnects the carbon fiber 2 between the several polyester fibers 1 after having repeatedly knitted moving to the adjacent one of the polyester fiber 1 was demonstrated, In addition to this, various electromagnetic shielding yarns can be used.

  For example, a short carbon fiber or carbon powder or a short metal wire or metal powder is kneaded and spun into an organic synthetic resin or rubber or elastomer, and after the glass fiber is wound over the entire length of the electromagnetic shielding yarn 3, For example, those obtained by coating organic synthetic resin or rubber or elastomer over the entire length, those obtained by coating fluororesin over the entire length of the electromagnetic wave shielding yarn 3, and the like. That is, the above-described electromagnetic wave / sound absorbing yarns 9 and 22 can also be used as electromagnetic shielding yarns as they are.

  In each of the above-described embodiments, a plurality of transparent polyester fibers 1 and carbon fibers 2 as ordinary spinnable fibers are knitted by chain stitching, and then the carbon fibers 2 are cut and electromagnetic wave / sound absorbing yarns 3 and Although the example which forms the electromagnetic wave shielding thread | yarn 3 was demonstrated, in addition to this as an ordinary spinnable fiber, opaque polyester fiber, cotton, silk, hemp, wool, nylon, vinylon, acrylic fiber, vinylidene chloride fiber, Organic fibers such as acetate and rayon, inorganic fibers such as glass fibers, or these fibers can be mixed.

  In addition to carbon fibers, metal wires such as copper wire, plated copper wire, and stainless wire can also be used. Here, the thickness of the metal wire is preferably in the range of 30 μm to 120 μm. Furthermore, a base material such as paper, cloth, or plastic film may be coated with a metal such as gold, silver, copper, or a conductive material such as carbon, cut into small pieces, and cut into short pieces.

  In addition to these, the electromagnetic wave / acoustic absorption yarn and the electromagnetic wave shielding yarn are made by kneading a short carbon fiber or carbon powder or a short metal wire or metal powder into an organic synthetic resin, rubber or elastomer and spinning them. It can also be used.

  Furthermore, in each of the above-described embodiments, the electromagnetic wave / sound absorbing sheet 8, 3 is formed by sandwiching an electromagnetic wave / sound absorbing fabric between two transparent thin organic synthetic resin sheets and a vinyl sheet 6 having a thickness of about 0.1 mm. Electromagnetic wave / sound absorbing plate 10 having a thickness of 10 mm as an organic synthetic resin plate and electromagnetic wave having a transparent acrylic resin plate sandwiched between two electromagnetic wave / sound absorbing fabrics 5A, 5B, 5C -The sound wave absorbing plate 15 and the like have been described, but as the electromagnetic wave / sound absorbing sheet, the electromagnetic wave / sound absorbing plate, the electromagnetic wave / sound absorbing structure, a thin rubber sheet or an elastomer sheet sandwiched between them, Two or more sheets with a predetermined thickness of rubber plate or elastomer plate sandwiched between them, etc. Can be used took also various configurations in addition.

  For example, the electromagnetic wave / sound absorbing fabric is sandwiched between two transparent thin rubber sheets or elastomer sheets and bonded, or two or more laminated with a predetermined thickness rubber plate or elastomer plate between them, Two or more sheets of electromagnetic waves / sound absorbing fabrics, and two or more sheets of electromagnetic waves / sound absorbing fabrics with different textures are stacked on each other and sandwiched between two thin organic synthetic resin sheets. An electromagnetic wave / sound absorbing sheet sandwiched between two thin organic synthetic resin sheets, or two organic synthetic resin plates with multiple through holes perforated on one or more layers of one or more electromagnetic wave / sound absorbing fabrics. Two sheets of electromagnetic waves / sound absorbing plates sandwiched between them, two or more sheets of different weaves of electromagnetic waves / sound absorbing fabrics, with many through holes drilled on the entire surface Electromagnetic-wave-absorbing plate formed by interposing an organic synthetic resin plates, and the like.

  Electromagnetic wave / acoustic absorption yarn, electromagnetic wave / acoustic absorption fabric, electromagnetic wave / acoustic absorption sheet, electromagnetic wave / acoustic absorption plate, electromagnetic wave / acoustic absorption structure and other parts of electromagnetic shielding yarn, configuration, shape, quantity, material, thickness, The thickness, size, connection relationship, and the like are not limited to the above embodiments.

FIG. 1 is an explanatory view showing a process of manufacturing an electromagnetic wave / sound absorbing yarn according to Embodiment 1 of the present invention. FIG. 2 (a) is a partially enlarged view showing the structure of the electromagnetic wave / sound absorbing yarn according to the first embodiment of the present invention, and FIG. 2 (b) shows the structure of the electromagnetic wave / sound absorbing fabric according to the first embodiment of the present invention. It is a perspective view. FIG. 3 is a graph showing the electromagnetic wave absorption characteristics of the electromagnetic wave / sound absorbing fabric according to the first embodiment of the present invention. FIG. 4A is a perspective view showing a method of manufacturing the electromagnetic wave / sound absorbing sheet according to the first embodiment of the present invention, and FIG. 4B shows the structure of the electromagnetic wave / sound absorbing sheet according to the first embodiment of the present invention. It is a perspective view. FIG. 5A is a cross-sectional view showing the structure of an electromagnetic wave / acoustic wave absorbing plate according to Embodiment 2 of the present invention, and FIG. 5B is a perspective view showing the entire structure. FIG. 6 is a graph showing the electromagnetic wave absorption characteristics of the electromagnetic wave / sound absorbing plate according to the second embodiment of the present invention. 7A is a perspective view showing a construction state of the electromagnetic wave / sound absorbing sheet according to the third embodiment of the present invention on the inner wall of the tunnel, and FIG. 7B is an electromagnetic wave / sound absorbing effect in the tunnel of the electromagnetic wave / sound absorbing sheet. It is explanatory drawing which shows. FIG. 8 is a perspective view showing an example of use of the electromagnetic wave / sound absorbing plate according to the third embodiment of the present invention at a toll gate on an expressway. FIG. 9A is an enlarged view showing a method for producing an electromagnetic wave / acoustic absorption yarn for forming an electromagnetic wave / acoustic absorption structure according to Embodiment 4 of the present invention, and FIG. It is an enlarged view which shows a state. FIG. 10A is a perspective view showing a method for manufacturing an electromagnetic wave / sound absorbing structure according to Embodiment 4 of the present invention, and FIG. 10B is a perspective view showing a completed state of the electromagnetic wave / sound absorbing structure. FIG. 11A is a perspective view showing a method of manufacturing an electromagnetic wave / sound absorbing structure according to a first modification of Embodiment 4 of the present invention, and FIG. 11B is an electromagnetic wave / sound absorbing structure according to the first modification. It is a perspective view which shows the completion state of. FIG. 12A is a perspective view showing a method for manufacturing an electromagnetic wave / sound absorbing structure according to a second modification of Embodiment 4 of the present invention, and FIG. 12B is an electromagnetic wave / sound absorbing structure according to the second modification. It is a perspective view which shows the completion state of. FIG. 13: is a perspective view which shows the usage example in the toll booth of the electromagnetic wave and sound wave absorption structure concerning Embodiment 4 of this invention and the 2nd modification of Embodiment 4 of this invention. FIG. 14A is a perspective view showing the structure of an electromagnetic wave / sound absorbing structure according to a fifth embodiment of the present invention, and FIG. 14B is a perspective view showing an example of use of the electromagnetic wave / sound absorbing structure at a toll gate on a highway. FIG. FIG. 15A is a perspective view showing the structure of the electromagnetic wave / sound absorbing structure according to Embodiment 6 of the present invention, and FIG. 15B is an explanation showing the electromagnetic wave / sound absorbing effect in the tunnel of the electromagnetic wave / sound absorbing structure. FIG. FIG. 16 is a graph showing the electromagnetic wave absorption characteristics of the electromagnetic wave / sound absorbing yarn according to the seventh embodiment of the present invention. FIG. 17: is a fragmentary perspective view which shows the state which wound the electromagnetic wave shield thread concerning Embodiment 8 of this invention around the high voltage electric wire.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Spinnable fiber 2 Carbon fiber 2A Protruding part 3 Electromagnetic wave / acoustic absorption yarn, electromagnetic wave shielding yarn 4 Glass fiber 5, 5A, 5B, 5C, 21 Electromagnetic wave / acoustic absorption fabric 6 Organic synthetic resin sheet 7 Organic synthetic resin 8 Electromagnetic wave / Sound wave absorbing sheet 9, 22 Electromagnetic wave / sound absorbing yarn 10 Electromagnetic wave / sound absorbing plate 11 Organic synthetic resin plate 20, 21A, 25, 25A, 26, 30, 35 Electromagnetic wave / sound absorbing structure 23 Metal net 24 Frame 27 Plastic pipe 28 Metal pipe 29 Cap 36 Channel material 40 High-voltage electric wire

Claims (25)

  One end or the center of a short piece of ordinary spinnable fiber woven by chain knitting, coated with a conductive material on a number of short carbon fibers or short metal wires or substrates, cut into small pieces When knitting the usual spinnable fiber with chain knitting, the portion is knitted or twisted at the same time every 2 to 10 times, and fixed to the multiple short carbon fibers or short metal wires or substrates. An electromagnetic wave / sound absorbing yarn characterized in that one end or both ends of a conductive material coated, cut into thin pieces, and cut into short portions protrude from the braided ordinary spinnable fiber.   When a plurality of normal spinnable fibers are spaced apart from each other and coated with a conductive material on a carbon fiber or metal wire or base material and cut into a thin piece, and knitting with chain stitch every 2 to 10 times The carbon fiber or the metal wire or the base material coated with a conductive material and cut into pieces is repeatedly knitted by moving it to one adjacent one of the normal spinnable fibers or further to the next adjacent one. After that, the carbon fiber or the metal wire or the base material is coated with a conductive material along the normal spinnable fiber between the plurality of normal spinnable fibers and cut into pieces. An electromagnetic wave / sound absorption yarn characterized by being cut.   An electromagnetic wave / sound absorbing yarn obtained by kneading and spinning a short carbon fiber or carbon powder or a short metal wire or metal powder in an organic synthetic resin, rubber or elastomer.   The short carbon fiber or short metal wire or base material is coated with a conductive material, cut into pieces and cut short, or the carbon fiber or metal wire or base material is coated with a conductive material and thinned. The length of the short carbon fiber or short metal wire or base material that is cut from the cut material, coated with a conductive material, cut into small pieces, and cut short is set according to the wavelength of the electromagnetic wave to be absorbed. The electromagnetic wave / acoustic wave absorbing yarn according to claim 1, wherein   A glass fiber is wound over the entire length of the electromagnetic wave / sound absorbing yarn according to any one of claims 1 to 4, and then coated with an organic synthetic resin, rubber, or elastomer over the entire length. Electromagnetic wave / sound absorbing yarn.   An electromagnetic wave / sound absorbing yarn comprising a fluororesin coated over the entire length of the electromagnetic wave / sound absorbing yarn according to any one of claims 1 to 4.   An electromagnetic wave / sound absorption fabric, wherein the electromagnetic wave / sound absorption yarn according to any one of claims 1 to 6 is woven.   An electromagnetic wave / sound absorbing fabric comprising the electromagnetic wave / sound absorbing yarn according to any one of claims 1 to 6 and a normal spinnable fiber.   9. The electromagnetic wave / sound absorbing fabric according to claim 7, wherein the size of the weave of the electromagnetic wave / sound absorbing yarn in the electromagnetic wave / sound absorbing fabric is set according to the wavelength of the electromagnetic wave to be absorbed. .   The electromagnetic wave and sound wave absorption formed by weaving the electromagnetic wave and sound wave absorbing yarn according to any one of claims 1 to 4 among the electromagnetic wave and sound wave absorbing fabric according to any one of claims 7 to 9. An electromagnetic wave / sound absorbing fabric characterized in that the entire surface of the fabric is coated with a fluororesin.   The electromagnetic wave and sound wave absorption formed by weaving the electromagnetic wave and sound wave absorbing yarn according to any one of claims 1 to 4 among the electromagnetic wave and sound wave absorbing fabric according to any one of claims 7 to 9. An electromagnetic wave / sound absorbing sheet characterized in that one or two or more woven fabrics are stacked and sandwiched between two thin organic synthetic resin sheets, rubber sheets or elastomer sheets and heat-pressed to form a sheet.   The electromagnetic wave and sound wave absorption formed by weaving the electromagnetic wave and sound wave absorbing yarn according to any one of claims 1 to 4 among the electromagnetic wave and sound wave absorbing fabric according to any one of claims 7 to 9. Coated with a conductive material on a short carbon fiber or a short metal wire or base material of the electromagnetic wave / sound absorbing yarn having different textures from each other in a woven fabric, or cut into fine pieces Electromagnetic wave / sound absorption sheet characterized in that two or more sheets of different lengths cut shortly are stacked and sandwiched between two thin organic synthetic resin sheets, rubber sheets or elastomer sheets and heat-pressed into a sheet shape .   The electromagnetic wave and sound wave absorption formed by weaving the electromagnetic wave and sound wave absorbing yarn according to any one of claims 1 to 4 among the electromagnetic wave and sound wave absorbing fabric according to any one of claims 7 to 9. Two thin organic synthetic resin sheets in which one or two or more woven fabrics are stacked and a large number of through-holes having a hole diameter in the range of 100 nm to 1 mm are drilled in the range of 5% to 30%. Alternatively, an electromagnetic wave / sound absorption sheet characterized by being sandwiched and adhered by a rubber sheet or an elastomer sheet.   The electromagnetic wave / sound absorbing fabric according to any one of claims 7 to 10 having a different texture of the electromagnetic wave / sound absorbing yarn or short carbon fibers in the used electromagnetic wave / sound absorbing yarn or Two or more sheets of a short metal wire or base material coated with a conductive material, cut into thin pieces and cut in short lengths, with an organic synthetic resin plate, rubber plate or elastomer plate with a predetermined thickness in between An electromagnetic wave / sound absorption plate characterized by being laminated and bonded or heat-pressed into a plate shape.   The electromagnetic wave / sound absorbing fabric has a coarse texture of 1 mm to 200 mm, and the two thin organic synthetic resin sheets or rubber sheets or elastomer sheets, or the organic synthetic resin plate or rubber plate or elastomer plate of the predetermined thickness are transparent. The electromagnetic wave / sound absorbing sheet or electromagnetic wave / sound absorbing plate according to claim 11, wherein the electromagnetic wave / sound absorbing sheet is provided.   An electromagnetic wave / acoustic wave absorbing yarn according to any one of claims 1 to 6 is stretched with a dielectric sheet sandwiched between two sheets, which are stretched in parallel to each other at a predetermined interval. The passed electromagnetic wave / sound absorbing yarn is stacked so as to be vertical, or the electromagnetic wave / sound absorbing yarn according to any one of claims 1 to 6 is stretched vertically and horizontally on a frame. An electromagnetic wave / sound absorption structure characterized by the above.   An electromagnetic wave / sound absorbing fabric formed by weaving the electromagnetic wave / sound absorbing yarn according to claim 5 or 6 among the electromagnetic wave / sound absorbing fabric according to claim 7, or claim 10. The electromagnetic wave / sound absorbing fabric according to claim 16 or the electromagnetic wave / sound absorbing structure according to claim 16, wherein a metal net is opposed to each other at a predetermined interval, and both are fixed to a frame. Electromagnetic wave / sound absorption structure.   The electromagnetic wave / sound absorbing fabric according to any one of claims 7 to 9, wherein a thin metal plate or a metal net is fixed to a wall surface to be installed, and a metal channel material having a predetermined channel interval is used. The electromagnetic wave / acoustic absorption fabric according to claim 10, the electromagnetic wave / acoustic absorption fabric according to claim 10, or the electromagnetic wave / acoustic absorption structure according to claim 16. An electromagnetic wave / sound absorption structure characterized by attaching a body.   The electromagnetic wave / acoustic wave absorbing yarn according to claim 5 or 6 is wound around the outer peripheral surface of a plastic pipe having a predetermined inner diameter in a Z direction and an S direction at a predetermined pitch, and is fixed inside the plastic pipe. An electromagnetic wave / sound absorbing structure comprising a metal rod or a metal pipe supported by caps fixed to both ends of the plastic pipe along a center line of the plastic pipe.   An electromagnetic wave / sound absorbing structure comprising a plurality of the electromagnetic wave / sound absorbing structures according to claim 19 arranged in parallel at a predetermined interval.   One end or the center of a short piece of ordinary spinnable fiber woven by chain knitting, coated with a conductive material on a number of short carbon fibers or short metal wires or substrates, cut into small pieces When knitting the usual spinnable fiber with chain knitting, the portion is knitted or twisted at the same time every 2 to 10 times, and fixed to the multiple short carbon fibers or short metal wires or substrates. An electromagnetic wave shielding yarn, characterized in that one end or both ends of a material cut with a conductive material, cut into thin pieces, and cut into short portions protrude from a braided piece of the usual spinnable fiber.   When a plurality of normal spinnable fibers are spaced apart from each other and coated with a conductive material on a carbon fiber or metal wire or base material and cut into a thin piece, and knitting with chain stitch every 2 to 10 times The carbon fiber or the metal wire or the base material coated with a conductive material and cut into pieces is repeatedly knitted by moving it to one adjacent one of the normal spinnable fibers or further to the next adjacent one. After that, the carbon fiber or the metal wire or the base material is coated with a conductive material along the normal spinnable fiber between the plurality of normal spinnable fibers and cut into pieces. An electromagnetic shielding yarn characterized by being cut.   An electromagnetic wave shielding yarn obtained by kneading and spinning a short carbon fiber or carbon powder or a short metal wire or metal powder in an organic synthetic resin, rubber or elastomer.   24. A glass fiber is wound over the entire length of the electromagnetic shielding yarn according to any one of claims 21 to 23, and then coated with an organic synthetic resin, rubber, or elastomer over the entire length. Electromagnetic shielding yarn.   24. An electromagnetic wave shielding yarn obtained by coating a fluororesin over the entire length of the electromagnetic wave shielding yarn according to any one of claims 21 to 23.

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