JPH0770855B2 - Method for forming electromagnetic wave shielding wall covering material on wall surface - Google Patents

Description

The present invention relates to a method for forming an electromagnetic wave shielding wall covering material on a wall surface.

More specifically, the present invention relates to a method for forming a wall covering material on a wall surface, which has excellent shielding properties against electromagnetic waves and has a sufficiently beautiful appearance and durability in practical use.

[Conventional technology]

With the recent development and spread of electronic devices, there is a need for a wall covering material that can protect these devices from the adverse effects of static electricity and / or electromagnetic waves, and that has a sufficiently beautiful appearance and durability in practical use. Came. Conventionally, in order to protect electronic equipment from static electricity, a conductive material containing a carbon powder or fiber, or a conductive material containing a metal foil or powder has been used. The material is not always sufficiently effective to comprehensively protect various electronic devices from electromagnetic waves at the same time, and as a wall covering material, its appearance, The durability was not satisfactory.

Therefore, it has been attempted to form a so-called shielded room in which the entire room containing electronic devices is shielded by electromagnetic waves, and it is suitable for practical use. However, a method for forming a wall covering material that can sufficiently cope with such an attempt has not been provided yet.

[Problems to be Solved by the Invention]

INDUSTRIAL APPLICABILITY The present invention utilizes an amorphous metal thin film to have a sufficient shielding and protection effect against both static electricity and electromagnetic waves, satisfy the requirements for appearance, and have sufficient durability for practical use. It is an object of the present invention to provide a method for easily forming a material on a wall surface to meet various requirements.

[Means and Actions for Solving the Problems]

A method of forming an electromagnetic wave shielding wall covering material on a wall surface of the present invention comprises a plurality of amorphous metal thin film thin sheets arranged in parallel with each other and electromagnetically bonded to each other on a wall foundation surface. Two or more of the amorphous metal thin film-containing core layers having the amorphous metal thin film and the flexible resin coating layer that covers at least one surface of the amorphous metal thin film are attached in parallel to each other, at this time, A series of amorphous metals formed by exposing the edges of the amorphous metal thin films adjacent to each other of the two or more amorphous metal thin film-containing core layers and electromagnetically bonding them to each other. And applying a wallpaper sheet on the thin film-containing core layer.

The wall covering material formed by the method of the present invention includes the core layer containing the amorphous metal thin film and the wallpaper layer as described above.

The amorphous metal thin film contained in the core layer is a magnetic substance and can exhibit an excellent electromagnetic wave shielding property against a magnetic field. An amorphous metal thin film is effective when particularly high magnetic field shielding properties are required.

Attempts have recently been made to utilize amorphous metals in various applications based on their properties. Generally, amorphous metal is supplied as a ribbon-shaped material with a width of 2.54 to 10.16 cm, and it is expected that a width of 20.32 cm will be supplied in the near future. It was considered to be almost impossible to use as a covering sheet material.

In the method of the present invention, the amorphous metal material is used as a sheet having a desired width. Conventionally, it was considered almost impossible to use the ribbon-shaped or small (narrow) width material as described above for a wall covering material requiring a wide width of 100 to 300 cm. In the method of the present invention, a plurality of amorphous metal thin film narrow sheets are arranged in parallel to form a wide sheet-like body for use.

When a conductive metal is plated on at least one surface of the amorphous metal thin film, the obtained core layer has the electric field shielding property of the plating layer added to the magnetic field shielding property of the amorphous metal thin film, and the core layer as a whole has a low frequency. It is possible to show an excellent shielding effect against a wide range of electromagnetic waves from high to high frequencies. The conductive metal plating layer also has the effect of improving the solder adhesion of the amorphous metal thin film.

Regarding the type of amorphous metal used in the method of the present invention, there is no particular limitation as long as it has an effect of protecting electronic devices from static electricity and electromagnetic waves, and it can be generally selected from commercially available materials. Is preferably selected from amorphous alloys containing iron as a main component and adding at least one selected from boron, silicon, carbon, nickel, cobalt, molybdenum, and the like. For example, Allied's product name METGLAS
NO.2605SC (Fe: 81%, B: 13.5%, Si: 3.5%, C: 2% amorphous alloy), No.2605S-2 (Fe: 78%, B: 13%, Si: 9%
No.2605-CO (Fe: 87 parts, B: 14)
Part, Si: 1 part, Co: 18 parts amorphous alloy), No. 2826-
MB (Fe: 40%, Ni: 38%, Mo: 4%, B: 18% amorphous alloy) and the like can be used.

In addition, the amorphous metal thin film may be formed using amorphous metal powder. Alternatively, fine wires made of amorphous metal may be used as a knitted woven or non-woven sheet, which may be used as an amorphous metal sheet.

The above-mentioned amorphous metal is a magnetic substance and has an excellent shield effect against a magnetic field.

Further, the amorphous metal thin film may be a perforated thin film within a range that does not substantially affect the electromagnetic raw shielding property.

The above-mentioned effect of protecting the electronic device means an effect that the electromagnetic wave energy is absorbed or reflected by the electromagnetic wave shield means so that the electronic device is not affected by the electromagnetic wave energy. The degree of electromagnetic wave energy attenuation by the electromagnetic wave shield means is expressed in a unit decibel (dB), and as the electromagnetic wave shield material has a larger value, the attenuation effect is larger, which is preferable.

In the wall covering material formed by the method of the present invention, its electromagnetic wave shielding effect depends substantially on the shielding effect of the amorphous metal thin film contained therein, and is generally 10 dB.
It is preferably at least 30 dB, more preferably at least 30 dB, even more preferably at least 60 dB.

In the method of the present invention, the amorphous metal thin film layer is 100
It preferably has a thickness of less than or equal to μm, more preferably 1 to 50 μm, and even more preferably 5 to 30 μm.

The conductive metal plating layer contained in the core layer containing the amorphous metal thin film preferably has a thickness of 0.1 μm or more, more preferably about 0.1 to 5 μm.

When the thickness of the amorphous metal thin film layer is more than 100 μm, its rigidity becomes excessive, it is hard to be deformed, drapability becomes insufficient, and a sharp cut surface may be formed, which may be dangerous in operation. In addition, a rust preventive agent on the surface of the amorphous metal thin film or the metal plated amorphous metal thin film,
Other thin protective films may be formed.

Since these amorphous metal materials are supplied in the form of ribbons or narrow width sheets as described above, in order to use them in the method of the present invention, a plurality of ribbon-shaped or narrow width sheet-shaped amorphous metal thin films are required. The materials are arranged in parallel with each other, and their opposite side edges are overlapped and brought into contact with each other, or bonded by solder or a conductive adhesive (adhesive) to obtain a sheet-like body having a desired width. .

At this time, when joining the narrow sheets, it is preferable to devise to minimize the formation of protrusions by the joints. Also, the protrusions are absorbed as much as possible by the wall base surface and the wallpaper layer to finish a flat wall. It is preferable that the surface is formed.

For this reason, the core layer containing an amorphous metal thin film includes an amorphous metal thin film (including a metal-plated one).
And a flexible resin coating layer covering at least one surface thereof, thereby absorbing the irregularities of the amorphous metal thin film layer and flattening it.

Such flexible resins include natural rubber; neoprene rubber, chloroprene rubber, silicone rubber, hypalon and other synthetic rubbers; and PVC resin, ethylene-vinyl acetate copolymer (EVA) resin, polyacrylic resin, silicone resin, polyurethane. Resin, polyethylene (PE)
Resin, polypropylene (PP) resin, polyester resin,
Fluorine-containing resins and other synthetic resins can be used. The flexible resin layer made of such a material has a sufficient thickness to impart desired flatness to the resulting wall covering material, as well as desired waterproofness, flame retardancy and mechanical strength. For example, it has a thickness of 0.05 mm or more, preferably 0.05 to 1.0 mm.

These flexible resin layers may be formed of a film or solution of a rubber or resin as described above, a solution, a paste, a straight line, or the like by a known method, for example, a method such as topping, calendering, coating, or dipping. It can be formed on the surface of the layer. These rubbers or resins include plasticizers, stabilizers, colorants,
An ultraviolet absorber or the like and another function-imparting agent such as a flameproofing agent or a flame retardant may be contained.

Conventionally, it is known that a resin layer having a thickness of about 1 to 10 μm is formed on the surface of a metal foil for the purpose of rust prevention and corrosion prevention. The flexible resin coating layer is generally formed to a thickness of 30 μm or more, and this thickness is preferably 50 to 5000 μm, more preferably 100 to 3000 μm, still more preferably 200 to 2000 μm.
Is. Therefore, the flexible resin coating layer used in the method of the present invention is clearly different from the conventional rust-preventing and corrosion-preventing coating layer formed on the metal foil. Further, the flexible resin coating layer used in the method of the present invention can exhibit sufficient flexibility in use even if it has the above-mentioned thickness, facilitating the handling of the amorphous metal thin film-containing core layer. To do.

The flexible resin coating layer may be formed on both surfaces of the amorphous metal thin film, and the wallpaper layer may be formed on one of them, or it may be formed only on one surface of the amorphous metal thin film, A wallpaper layer may be formed on it,
Alternatively, it is formed only on one surface of the amorphous metal thin film,
A wallpaper layer may be formed on the other surface.

For the purpose of flattening and reinforcing, a fiber cloth having a proper thickness, for example, a knitted woven fabric, a non-woven fabric, a compressible deformable paper or a composite layer thereof is applied on at least one surface of the amorphous metal thin film. It is preferable to form an amorphous metal thin layer-containing core layer by coating. The core layer containing an amorphous metal thin film may include both the flexible resin coating layer and the fiber cloth layer. The type, thickness, length, or structure of the fibers constituting the fiber cloth layer is not particularly limited, but it is preferably flameproof and waterproof.

The wallpaper layer includes paper, fiber cloth, plastic sheets, and other decorative materials that can be used as wallpaper.

In the method of the present invention, the core layer containing an amorphous metal thin film as described above is formed on the surface of the wall underlayer by using an adhesive or an adhesive, if necessary. This core layer may be preliminarily formed and adhered to the surface of the wall underlayer, or may be formed on the surface of the wall underlayer in a predetermined configuration. Good.

In the method of the present invention, when two or more amorphous metal thin film-containing core layers are arranged in parallel and adhered to the surface of the wall underlayer, the edge portions of the amorphous metal thin films adjacent to each other are exposed, and these are exposed. They are electromagnetically joined to each other. For this purpose, the edge portions may be overlapped and brought into direct contact with each other, or these edge portions may be joined by solder or a conductive adhesive or a pressure-sensitive adhesive. At this time, for example, the resin coating layer and / or the fiber cloth layer in this portion is removed or the amount of the adhesive or the pressure-sensitive adhesive applied is reduced so that a remarkable protrusion is not formed on the wall surface by the joint. It is preferable to take measures such as letting it occur.

Before or after the operation of applying the core layer containing the amorphous metal thin film to the surface of the wall base, a wallpaper sheet is applied using an adhesive or a pressure-sensitive adhesive, if necessary. The wallpaper sheet can be arbitrarily selected from paper, plastic sheet, fiber cloth sheet, decorative material and the like having a desired constitution, thickness, color, pattern and the like. In particular, when a ridge is formed on the wall surface by joining the amorphous metal thin films, it is desirable to select a wallpaper sheet having a configuration, thickness, color and pattern that makes the formation of the ridge inconspicuous.

There is no particular limitation on the type of the adhesive material used in the method of the present invention. Isocyanate-based adhesive materials, epoxy-based adhesive materials, polyacrylic-based adhesive materials, polyurethane-based adhesive materials, polyamide-based adhesive materials, rubber-based (particularly synthetic rubber) materials. system)
Either adhesive material or the like may be used. Also, amino groups, imino groups, ethyleneimine residues, acrylates containing alkylenediamine residues, acrylates containing aziridinyl groups, aminoester-modified vinyl polymers, aromatic epoxy adhesives, amino nitrogen-containing methacrylate polymers, etc. Although it is a preferred adhesive material, other adhesives may be used together.

In the wall covering material formed by the method of the present invention, one or more such as an adhesive for binding each component layer is made conductive or semiconductive in accordance with its use and required performance. Alternatively, it may be insulative. Alternatively, each layer may be provided with different conductivity or insulating property and combined. By doing so, products having various characteristics or performances can be obtained.

According to the method of the present invention, by sticking the core layer and the wallpaper sheet to the wall underlayer surface in order, the problem when directly laminating the finished laminate wallpaper to the wall underlayer surface, that is,
When the laminated laminated product wallpaper is unwound from the roll, the core layer containing the amorphous metal thin film and the wallpaper sheet are not joined to each other unevenly, and wrinkles, floats, waviness, and unevenness are formed on the wallpaper sheet, and the finished wall surface state is poor. This eliminates the problem of becoming flat, uniform, and has a beautiful wall surface finish. Further, since the amorphous metal thin film-containing core layer is relatively expensive, the core layer and the wallpaper sheet are stocked separately, and a combination of these is used to obtain a desired color, pattern, thickness,
The method of the present invention that can be arbitrarily determined according to the material,
It also has the advantage of significantly reducing the stock cost of wall covering materials.

〔Example〕

 The method of the present invention will be further described with reference to examples.

Example 1 Amorphous alloy (Fe: 81%, B: 13.5%, Si: 3.5%, C: 2
%, Trademark: METGLAS No.2605SC, Allied, width 7.62c
m, 25 μm thick ribbon-like body), 1 μm thick on all surfaces
Copper plated. Thirteen sheets of this copper-plated amorphous alloy ribbon were arranged in parallel with each other, and their side edges were soldered to each other to form a wide sheet having a width of about 95 cm.

Apply synthetic rubber adhesive (trademark: SC 12N, made by Sony Chemicals) on both sides of this wide amorphous alloy sheet,
On one side of it, glass fiber gauze (trademark: K-5210, manufactured by Kanebo Glass Fiber Co., Ltd., thickness: 0.12 mm, basis weight: 52 g / m ² , texture: leno weave, warp: (10 + 10) pieces / 25.4 mm, weft: 10 (25.4mm), and a polyvinyl chloride resin film with a thickness of 0.05mm on the other side of the amorphous alloy sheet and the surface of the fiber cloth layer with an adhesive, containing an amorphous metal thin film. A core layer was formed.

The above-mentioned core layer containing an amorphous metal thin film was attached to the entire surface of the base of the wall surface of the shield room using an adhesive. At this time, the polyvinyl chloride resin film layer and the fiber cloth layer were spread over a width of 1.5 cm at the edge portions of two or more amorphous metal thin film-containing core layers arranged in parallel with each other,
Peeling off to expose the amorphous metal thin film, these are
Overlapping each other, the resin film layer and fiber fabric layer present in this polymerized portion were removed.

An arbitrarily selected wallpaper was applied on the applied core layer containing the amorphous metal thin film. At this time, the core layer and the wallpaper were arranged so that the joint portion of the core layer and the joint portion of the wallpaper did not overlap each other.

The wall surface of the obtained shield room had a flat, uniform and beautiful appearance, and exhibited a good electromagnetic wave shielding property.

For comparison, only the wallpaper without using the amorphous metal thin film, or the underlaying of the fiber cloth and polyvinyl chloride film without the amorphous metal thin film, and the wallpaper was pasted on it, the electromagnetic wave shielding property of the wall surface was poor. Met.

Further, a core layer containing an amorphous metal thin film is prepared, a polyvinyl chloride wallpaper is attached to one surface of the core layer, an adhesive is applied to the opposite surface thereof, and a release paper is laminated to obtain a finished wall covering material laminated product. Wound up. The laminated finished product was spread, and the release paper was removed, and the laminated product was attached to the surface of the base of the wall by a conventional method. Each of the obtained wall surfaces showed a good electromagnetic wave shielding property, but wrinkles and curls remained, and wrinkles were seen on the surface of the finished wall covering, and the appearance was slightly inferior to the above.

[Effect]

The wall covering material containing an amorphous metal thin film formed by the method of the present invention is extremely useful for making a wall surface of a shield room or the like an electromagnetic wave shielding property. In particular,
When a plurality of wall covering materials are arranged in parallel and attached to a wide wall surface, by forming the wall covering material on the wall surface by the method of the present invention, electromagnetic bonding of the amorphous metal thin film is facilitated, and It can be completely achieved and the walls of any desired color and pattern can be formed. Furthermore, the amorphous metal thin film is reinforced by a flexible resin coating layer, and if necessary, a fiber cloth layer is also used together to prevent breakage at the time of joining the amorphous metal thin film and to prevent local bulging of the wall surface. It can be reduced or absorbed.

In addition, the wall covering material forming method of the present invention, the amorphous metal thin film-containing core layer and various colors, patterns, thicknesses, various different wallpaper sheets having different materials are separately stocked, and if desired, Since it is possible to combine these arbitrarily,
It has the merit of avoiding dead stock of expensive wall covering material and significantly reducing stock cost. Further, as described above, since the core layer and the wallpaper sheet are separately stocked, the wrinkles and winding curls that occur when the wallpaper and the core layer are laminated and wound in advance are not generated, In addition, it is possible to prevent the formation of corrugation, unevenness and the like accompanying it. Therefore, by the method of the present invention, it is possible to form an electromagnetic wave shielding wall surface which is flat, uniform and has a desired aesthetic appearance.

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁶ Identification code Internal reference number FI Technical indication H05K 9/00 N

Claims (15)

[Claims] 1. An amorphous metal thin film comprising a plurality of narrow sheets of amorphous metal thin films arranged in parallel with each other and electromagnetically bonded to each other on a surface of a wall base, and at least one of the amorphous metal thin films. Two or more amorphous metal thin film-containing core layers each having a flexible resin coating layer covering the surface are attached in parallel to each other, and at this time, 2
A series of amorphous metal thin film containing a series of amorphous metal thin films formed by exposing the edge portions of the amorphous metal thin films adjacent to each other in one or more amorphous metal thin film-containing core layers and electromagnetically bonding them to each other. A method of forming an electromagnetic wave shielding wall covering material on a wall surface, which comprises applying a wallpaper sheet onto the core layer. 2. The method according to claim 1, wherein in the core layer containing an amorphous metal thin film, a conductive metal plating layer is formed on at least one surface of the amorphous metal thin film. 3. The method according to claim 1, wherein the surface of the wall foundation and the core layer containing an amorphous metal thin film are bound by an adhesive or a pressure-sensitive adhesive. 4. The method according to claim 1, wherein the amorphous metal thin film-containing core layer and the wallpaper sheet are bound by an adhesive or a pressure-sensitive adhesive. 5. A plurality of said core layers containing an amorphous metal thin film are bonded and attached in parallel to a wall foundation surface, and when a plurality of said wallpaper sheets are bonded and attached in parallel, said Each of the joint portion of the plurality of core layers and the joint portion of the plurality of wallpaper sheets, so as not to overlap each other,
The method according to claim 4, wherein the core layer and the wallpaper sheet are arranged. 6. The amorphous metal is selected from an amorphous alloy containing Fe as a main component and at least one selected from B, Si, C, Co, Ni and Mo added thereto. The method according to item 1. 7. The method according to claim 1, wherein the plurality of thin amorphous metal thin sheets are bonded to each other at their side edges adjacent to each other. 8. The method according to claim 1, wherein the amorphous metal thin film has a thickness of 100 μm or less. 9. The method according to claim 2, wherein the conductive metal plating layer in the core layer containing an amorphous metal thin film has a thickness of 0.1 μm or more. 10. The flexible resin coating layer comprises natural rubber, synthetic rubber, polyvinyl chloride resin, ethylene-vinyl acetate (EVA) copolymer resin, polyacrylic resin, silicone resin, polyurethane resin, polyethylene resin, polypropylene. The method according to claim 1, comprising at least one selected from a resin, a polyester resin, a polyamide resin, and a fluorine-containing resin. 11. The method according to claim 1, wherein the flexible resin coating layer has a thickness of 30 μm or more. 12. The method according to claim 1, wherein in the core layer containing an amorphous metal thin film, both surfaces of the amorphous metal thin film are covered with the flexible resin layer. 13. A sticking of the core layer containing an amorphous metal thin film, wherein one surface of the amorphous metal thin film is stuck to the surface of the wall base through the flexible resin coating layer, and the other surface is stuck. The method according to claim 1, wherein the wallpaper sheet is attached. 14. A sticking of the core layer containing an amorphous metal thin film, wherein the wallpaper sheet is stuck on one surface of the amorphous metal thin film via the flexible resin coating layer.
The method according to claim 1. 15. In the core layer containing an amorphous metal thin film, a fiber cloth layer is directly or indirectly arranged on at least one surface of the amorphous metal thin film.
The method according to claim 1.