JP7418923B2 - Electromagnetic shielding material and method for manufacturing electromagnetic shielding material - Google Patents

Description

The present disclosure relates to an electromagnetic shielding material including a metal sprayed layer and a method for manufacturing the same.

BACKGROUND ART Conventionally, there is an electromagnetic wave shielding material in which a metal sprayed layer is laminated by metal spraying on a sheet-like base material made of resin or the like (see, for example, Patent Document 1).

JP-A-6-326492 (paragraphs [0004], [0008], Figure 1, etc.)

It is desired that the above-mentioned electromagnetic shielding material suppress the falling off of metal particles constituting the metal sprayed layer.

The invention of claim 1 made to solve the above problem includes: a sheet-like base material; a metal sprayed layer laminated on the sheet-like base material; The present invention is an electromagnetic shielding material having a first viscoelastic layer that is laminated and inserted between metal particles constituting the metal sprayed layer.

The invention according to claim 2 is the electromagnetic shielding material according to claim 1, wherein the first viscoelastic layer is the outermost layer of the electromagnetic shielding material and is made of a self-adhesive adhesive material.

The invention according to claim 3 is the electromagnetic shielding material according to claim 1 or 2, wherein the first viscoelastic layer contains powder of a conductive material.

The invention according to claim 4 is the electromagnetic shielding material according to claim 3, wherein the first viscoelastic layer is the outermost layer of the electromagnetic shielding material.

The invention according to claim 5 is the electromagnetic shielding material according to any one of claims 1 to 4, wherein the first viscoelastic layer contains powder of a magnetic material.

The invention according to claim 6 has a second viscoelastic layer disposed between the sheet-like base material and the metal sprayed layer and inserted between metal particles constituting the metal sprayed layer. 6. The electromagnetic shielding material according to any one of claims 1 to 5.

The invention according to claim 7 is the electromagnetic shielding material according to claim 6, wherein the first viscoelastic layer and the second viscoelastic layer are made of materials that adhere to each other.

The invention according to claim 8 is the electromagnetic wave shielding material according to claim 6 or 7, wherein the second viscoelastic layer contains powder of a conductive material.

The invention according to claim 9 is the electromagnetic wave shielding material according to any one of claims 6 to 8, wherein the second viscoelastic layer contains powder of a magnetic material.

The invention according to claim 10 is the electromagnetic wave shielding material according to any one of claims 1 to 9, wherein the sheet-like base material is made of a foamed sheet.

An eleventh aspect of the invention is the electromagnetic shielding material according to the tenth aspect, wherein a protective layer is laminated on the sheet-like base material from a side opposite to the first viscoelastic layer.

The twelfth aspect of the invention is the production of an electromagnetic shielding material, in which a first viscoelastic layer is laminated on the metal sprayed layer by applying a fluid adhesive to the metal sprayed layer laminated on the sheet-like base material. It's a method.

The thirteenth aspect of the invention is that the metal sprayed layer is directly laminated on the second viscoelastic layer laminated on the sheet-like base material, and when the metal sprayed layer is laminated, the heat of the sprayed metal is 13. The method of manufacturing an electromagnetic shielding material according to claim 12, wherein the second viscoelastic layer is softened.

The fourteenth aspect of the invention includes winding up a laminated sheet in which the metal sprayed layer is laminated on the sheet-like base material with a take-up roller, and the winding of the laminated sheet is carried out on the metal sprayed layer. 14. The method of manufacturing an electromagnetic shielding material according to claim 12 or 13, which is carried out after forming the first viscoelastic layer.

In the electromagnetic shielding material of the first aspect and the electromagnetic shielding material manufactured by the manufacturing method of the twelfth aspect, the first viscoelastic layer makes it possible to suppress falling off of the metal particles constituting the metal sprayed layer. Further, even if the electromagnetic shielding material is bent, the provision of the first viscoelastic layer makes it possible to suppress the occurrence of cracks in the metal sprayed layer. When the first viscoelastic layer is formed by applying a fluid adhesive material to the metal sprayed layer as in the invention of claim 12, the first viscoelastic layer is formed in the gaps between the metal particles constituting the metal sprayed layer. It becomes easy to penetrate the adhesive material of the viscoelastic layer.

If the first viscoelastic layer is the outermost layer of the electromagnetic shielding material and the first viscoelastic layer is made of an adhesive material, the electromagnetic shielding material can be attached to the adherend by the first viscoelastic layer. If the first viscoelastic layer as the outermost layer of the electromagnetic shielding material is self-adhesive (invention of claim 2), the first viscoelastic layers can be bonded together by bending or rolling the electromagnetic shielding material. The electromagnetic wave shielding material becomes easier to handle because the first viscoelastic layer and the first viscoelastic layer are less likely to stick to a material made of a different material than the first viscoelastic layer.

In the third aspect of the invention, since the first viscoelastic layer contains powder of a conductive material, it is possible to enhance the electromagnetic shielding effect of the electromagnetic shielding material. Moreover, in the invention of claim 4, since the first viscoelastic layer is the outermost layer of the electromagnetic wave shielding material, the first viscoelastic layer including the conductive material can be easily grounded (earthed).

In the fifth aspect of the invention, since the first viscoelastic layer contains powder of a magnetic material, it is possible to enhance the electromagnetic shielding effect of the electromagnetic shielding material.

In the invention of claim 6, the second viscoelastic layer is arranged between the sheet-like base material and the metal spray layer. The metal sprayed layer is directly laminated on the second viscoelastic layer, and the second viscoelastic layer is inserted between the metal particles forming the metal sprayed layer. Further, in the thirteenth aspect of the invention, since the second viscoelastic layer is softened by the heat of the sprayed metal, metal particles can be embedded in the second viscoelastic layer. According to the invention of claims 6 and 13, the adhesion between the metal sprayed layer and the second viscoelastic layer is improved by the anchoring effect, and the metal sprayed layer does not peel off or cracks occur in the metal sprayed layer. suppressed. Moreover, since the metal spray layer is in close contact with the first and second viscoelastic layers from both sides, no matter which side the electromagnetic wave shielding material is bent, the metal spray layer will crack. can be suppressed from occurring.

In the seventh aspect of the invention, the first viscoelastic layer and the second viscoelastic layer are made of materials that adhere to each other. Therefore, when the gaps between the metal particles of the metal sprayed layer are connected throughout the thickness direction of the metal sprayed layer, the first viscoelastic layer and the second viscoelastic layer can be made to stick together through the gap. This makes it possible to strengthen the adhesion between the first viscoelastic layer and the second viscoelastic layer and the metal sprayed layer, further suppressing part of the metal sprayed layer from falling off or peeling off. becomes possible.

When the electromagnetic wave shielding material is provided with a second viscoelastic layer, the second viscoelastic layer may contain powder or granules of a conductive material (invention of claim 8), or the second viscoelastic layer may contain powder or granules of a conductive material. The elastic layer may contain powder of a magnetic material (invention of claim 9). According to these configurations, it is possible to enhance the electromagnetic shielding effect of the electromagnetic shielding material.

In the tenth aspect of the invention, since the sheet-like base material is made of a foamed sheet, the flexibility of the electromagnetic shielding material can be improved. When the sheet-like base material is made of a foamed sheet, if a protective layer is laminated on the sheet-like base material from the side opposite to the first viscoelastic layer as in the invention of claim 11, damage to the sheet-like base material can be prevented. becomes possible.

In the fourteenth aspect of the invention, a laminated sheet in which a metal sprayed layer is laminated on a sheet-like base material is wound up with a winding roller. The laminated sheet is then wound up after the first viscoelastic layer is laminated on the metal sprayed layer. This makes it possible to prevent metal particles of the metal sprayed layer from falling off and cracks from forming in the metal sprayed layer when winding up the laminated sheet.

(A) Side sectional view of the electromagnetic shielding material according to an embodiment of the present disclosure, (B) Enlarged side sectional view of the metal sprayed layer Side view of a feed line used for manufacturing electromagnetic shielding material (A) Side sectional view of electromagnetic shielding material according to other embodiments, (B) Enlarged side sectional view of metal sprayed layer Graph of transmission attenuation rate of electromagnetic shielding material of each example

As shown in FIG. 1(A), the electromagnetic shielding material 10 of this embodiment has a laminated structure including a sheet-like base material 11. As shown in FIG. The sheet-like base material 11 is made of a foam sheet. Examples of the resin constituting the foam sheet include polyolefin resins (polyethylene resins, polypropylene resins, etc.), polyurethane resins, acrylic resins, and blends thereof. The foamed sheet constituting the sheet-like base material 11 may have an open-cell structure or a closed-cell structure, but an open-cell structure is preferable from the viewpoint of flexibility of the sheet-like base material 11. In this embodiment, the sheet-like base material 11 and the electromagnetic shielding material 10 are flexible.

A protective layer 41 is laminated on one of the front and back surfaces of the sheet-like base material 11 . Examples of the material constituting the protective layer 41 include non-foamed film and paper. Examples of materials for such a film include polyolefin resins and polyolefin thermoplastic elastomers. In this embodiment, the protective layer 41 can prevent damage from one side of the sheet-like base material 11.

An inner viscoelastic layer is laminated on the other surface of the sheet-like base material 11. The inner viscoelastic layer is made of a viscoelastic material such as an adhesive material, an elastomer (rubber or thermoplastic elastomer), or a gel material. Note that the adhesive material herein also includes one having self-adhesiveness (self-adhesiveness). Here, self-adhesiveness (self-adhesiveness) means that objects made of the same type of material stick to each other (i.e., they stick together), but they are difficult to adhere to (i.e., they do not stick easily) to items made of different materials. ) means a property.

In this embodiment, an inner adhesive layer 32 is provided as the inner viscoelastic layer, and this inner adhesive layer 32 is made of a self-adhesive adhesive (self-adhesive adhesive). Note that the adhesive material constituting the inner adhesive layer 32 (inner viscoelastic layer) does not have to be self-adhesive, and can be adhesive not only to objects made of the same type of material but also to items made of different materials. It may also be a material that has the property of being easily adhesive (normal adhesive material). The melting point of the adhesive material constituting the inner adhesive layer 32 is preferably 70 to 120°C, more preferably 70 to 100°C.

Examples of the material for the self-adhesive adhesive constituting the inner adhesive layer 32 include natural rubber latex mixed with an adhesion aid. Examples of this adhesion aid (tackifier) include tackifiers (terpene resins, rosin ester resins, petroleum resins, etc.), antioxidants (phenolic antioxidants, etc.), and organic solvents such as toluene. , etc. Further, it is preferable that a polyolefin emulsion is added to the adhesive material constituting the inner adhesive layer 32. A polyolefin emulsion is one in which polyolefin resin particles are dispersed in water using an emulsifier or a dispersant. By using the aqueous dispersion, the thickness of the inner adhesive layer 32 can be reduced, and the flexibility of the electromagnetic shielding material 10 can be increased. The polyolefin emulsion may be produced by various known production methods, or a commercially available product may be used. Known manufacturing methods include, for example, emulsion polymerization in the presence of an emulsifier in an aqueous medium, and a method of stirring and mixing a molten resin and an aqueous medium in the presence of shearing force.

The inner adhesive layer 32 (inner viscoelastic layer) may contain a conductive material or a magnetic material. According to these configurations, it is possible to enhance the electromagnetic shielding effect of the electromagnetic shielding material 10. For example, these conductive materials and magnetic materials may be in the form of granules and dispersed in the adhesive material of the inner adhesive layer 32. Examples of the shape of this powder or granular material include spherical shape (for example, true spherical shape, etc.), flat shape, and the like.

Examples of the conductive material include metal materials (for example, copper, nickel, aluminum, silver, gold, iron, etc.), carbon materials (for example, conductive carbon black), conductive polymers, ion conductive materials, and the like.

The magnetic material may be a soft magnetic material or a hard magnetic material, and examples thereof include iron, ferrite, silicon steel, permalloy, sendust, permendur, and the like. Examples of ferrite include spinel ferrite (e.g. manganese ferrite, nickel ferrite, copper ferrite, zinc ferrite, cobalt ferrite, etc.), hexagonal ferrite (e.g. barium ferrite, strontium ferrite, etc.), garnet ferrite (e.g. Yttrium iron garnet ferrite), etc.

As shown in FIG. 1(A), the metal sprayed layer 21 is directly laminated on the inner adhesive layer 32 from the side opposite to the sheet-like base material 11. The metal spray layer 21 is formed by spraying metal onto the inner adhesive layer 32 on the sheet-like base material 11 . The basis weight of the metal sprayed layer 21 is preferably 90 g/m ² or more from the viewpoint of shielding performance of the electromagnetic shielding material 10, and 280 g/m ² or less from the viewpoint of flexibility of the electromagnetic shielding material 10. is preferred.

In metal spraying, a large number of metal particles 22 are made to collide with the inner adhesive layer 32 on the sheet-like base material 11 . The metal spray layer 21 is formed by depositing flattened metal particles 22 (see FIG. 1(B)). The metal to be sprayed is, for example, zinc, aluminum, copper, or an alloy of these metals (for example, an alloy of zinc and aluminum).

As shown in FIG. 1(B), a part of the inner adhesive layer 32 enters the inside of the metal spray layer 21, and in the part of the metal spray layer 21 on the sheet-like base material 11 side, the metal particles 22 It's getting into the gap between them. Therefore, due to the anchoring effect, the adhesion between the inner adhesive layer 32 and the metal sprayed layer 21 is increased, the peeling of the metal particles 22 is suppressed, and when the electromagnetic shielding material 10 is bent and deformed, This makes it possible to suppress the occurrence of cracks.

As shown in FIG. 1(A), an outer viscoelastic layer is directly laminated on the metal sprayed layer 21 from the side opposite to the sheet-like base material 11. The outer viscoelastic layer is made of a viscoelastic material such as an adhesive material (for example, a self-adhesive adhesive material, etc.), an elastomer (rubber or thermoplastic elastomer), or a gel material. In this embodiment, an outer adhesive layer 31 is provided as the outer viscoelastic layer, and the outer adhesive layer 31 is the outermost layer of the electromagnetic shielding material 10. Furthermore, in the present embodiment, the outer adhesive layer 31 is made of a self-adhesive adhesive material that has self-adhesive properties, but it may be made of a normal adhesive material instead of the self-adhesive material. As the material of the adhesive constituting the outer adhesive layer 31, those exemplified above as the material of the inner adhesive layer 32 can be used. In this embodiment, the outer adhesive layer 31 and the inner adhesive layer 32 are made of materials that adhere to each other, and specifically, are made of the same self-adhesive adhesive.

As shown in FIG. 1(B), a part of the outer adhesive layer 31 enters the inside of the metal sprayed layer 21, and in the part of the metal sprayed layer 21 on the side opposite to the sheet-like base material 11, It has entered the gaps between the particles 22. Therefore, the adhesion between the outer adhesive layer 31 and the metal sprayed layer 21 is improved. In the electromagnetic shielding material 10, the outer adhesive layer 31 prevents the metal particles 22 from falling off, and also suppresses the occurrence of cracks between the metal particles 22 when the electromagnetic shielding material 10 is bent and deformed. .

The outer adhesive layer 31 (outer viscoelastic layer) may contain a conductive material or a magnetic material. According to these configurations, it is possible to enhance the electromagnetic shielding effect of the electromagnetic shielding material 10. For example, these conductive materials and magnetic materials may be in the form of granules and dispersed in the adhesive material of the outer adhesive layer 31. Examples of the shape of this powder or granular material include spherical shape (for example, true spherical shape, etc.), flat shape, and the like. As the conductive material and magnetic material contained in the outer adhesive layer 31, those listed above as the conductive material and magnetic material contained in the inner adhesive layer 32 can be used.

When the outer adhesive layer 31 or the inner adhesive layer 32 contains a conductive material, the content thereof is preferably 10 to 20% by weight, more preferably 10 to 15% by weight. The surface resistance value (resistance value between two points 1 cm apart on the surface) of the outer adhesive layer 31 and the inner adhesive layer 32 containing a conductive material is preferably 10 to the fourth power Ω or less. Further, when the outer adhesive layer 31 or the inner adhesive layer 32 contains a magnetic material, the content thereof is preferably 10 to 20% by weight, more preferably 10 to 15% by weight.

Note that the conductive material may be contained in only one of the outer adhesive layer 31 and the inner adhesive layer 32, or may be contained in both. Further, the magnetic material may be contained in only one of the outer adhesive layer 31 and the inner adhesive layer 32, or may be contained in both. Alternatively, only one of the outer adhesive layer 31 and the inner adhesive layer 32 may contain a conductive material, and only the other may contain a magnetic material.

The electromagnetic shielding material 10 of this embodiment is manufactured, for example, as follows. First, a sheet-like base material 11 made of a foam sheet is prepared.

Next, a protective layer 41 is formed on the sheet-like base material 11 by laminating a resin film on one of the front and back surfaces of the sheet-like base material 11 . Note that the resin film can be laminated onto the sheet-like base material 11 by direct lamination, extrusion lamination, or the like.

Next, the inner adhesive layer 32, the metal spray layer 21, and the outer adhesive layer 31 are laminated in this order on the sheet-like base material 11. FIG. 2 shows an example of a feeding line 60 in which this lamination process is performed while feeding the sheet-like base material 11. The feeding line 60 is provided with a metal spraying device 63, a coating device 64, and a drying oven 65 in this order from the upstream side. In the feeding line 60, the elongated sheet-like base material 11 is fed out by a delivery roller 61, subjected to a lamination process, and then wound up by a take-up roller 62.

In the lamination process, first, the other surface of the sheet-like base material 11 (the upper surface of the sheet-like base material 11 fed out in FIG. 2) is coated with a self-adhesive coating using an unillustrated coating device (for example, a roll coater, a sprayer, etc.). An adhesive having the following properties is applied. When this adhesive material dries, an inner adhesive layer 32 is formed on the sheet-like base material 11. The adhesive material constituting the inner adhesive layer 32 can be manufactured, for example, by charging an adhesive agent, etc. into a homomixer tank, then rotating the homomixer tank forward and backward for a predetermined period of time, and then This is done by blending natural rubber latex with an adhesion aid. Note that the adhesive material of the inner adhesive layer 32 may contain a conductive material or a magnetic material.

Next, the metal spraying device 63 sprays metal onto the inner adhesive layer 32 laminated on the sheet-like base material 11 . As a result, the metal sprayed layer 21 is formed on the inner adhesive layer 32. At this time, of the metal particles 22 of the metal spray layer 21 , the metal particles 22 on the inner adhesive layer 32 side are embedded in the inner adhesive layer 32 . That is, the adhesive of the inner adhesive layer 32 enters into the gaps between the metal particles 22. Thereby, the adhesion between the metal sprayed layer 21 and the inner adhesive layer 32 is improved due to the anchoring effect. Here, in this embodiment, the adhesive material of the inner adhesive layer 32 is softened by the heat of the sprayed metal, so that the metal particles 22 are easily embedded in the inner adhesive layer 32. Note that if the thermal spraying temperature of the metal is set to be higher than the melting point of the material of the inner adhesive layer 32, the inner adhesive layer 32 will be softened by the heat of the sprayed metal, making it easier to embed the metal particles in the inner adhesive layer 32. Become.

As metal spraying, flame spraying using combustion gas as a heat source, arc spraying using electricity as a heat source, high-speed flame spraying, plasma spraying, RF plasma spraying, explosive spraying, wire bomb irradiation, etc. can be used. . Among these, arc spraying is preferable because the formation speed of the metal sprayed layer 21 is fast and the basis weight of the metal sprayed layer 21 can be controlled with high precision.

Next, the coating device 64 coats the metal sprayed layer 21 with a self-adhesive adhesive 31A. In this embodiment, since the adhesive material 31A has fluidity, the adhesive material 31A soaks into the gaps between the metal particles 22 of the metal sprayed layer 21. It is preferable that the adhesive material 31A is liquid. In the example of FIG. 2, the coating device 64 is a roll coater. Specifically, this roll coater includes a coating roll 64A and a doctor roll 64B, which are provided facing the metal sprayed layer 21. The adhesive material 31A is supplied between the coating roll 64A and the doctor roll 64B, and the adhesive material 31A is applied onto the metal sprayed layer 21 by the coating roll 64A coming into contact with the metal sprayed layer 21. Note that the coating device 64 may be a sprayer. Further, the adhesive material 31A may contain a conductive material or a magnetic material.

Next, the adhesive material 31A on the metal spray layer 21 is dried in the drying oven 65. Then, an outer adhesive layer 31 is formed on the metal sprayed layer 21. In this embodiment, the outer adhesive layer 31 is formed by applying the fluid adhesive material 31A to the metal spray layer 21, so that the outer adhesive layer 31 is formed in the gaps between the metal particles 22 constituting the metal spray layer 21. It becomes easy to penetrate the adhesive material of the material layer 31. Moreover, in this embodiment, since the adhesive material 31A permeates into the metal sprayed layer 21, it becomes possible to strengthen the bond between the metal particles 22 by the outer adhesive material layer 31.

Thereafter, the laminated sheet 30S in which the metal sprayed layer 21 is laminated on the sheet-like base material 11 is wound up by the winding roller 62. In this embodiment, the laminated sheet 30S is rolled up after the outer adhesive layer 31 covering the metal sprayed layer 21 is formed, so that when the laminated sheet 30S is rolled up, the metal particles 22 of the metal sprayed layer 21 are rolled up. It becomes possible to suppress falling off and generation of cracks in the metal sprayed layer 21. In addition, since the outer adhesive layer 31 has self-adhesive properties, it is difficult to adhere to materials made of a material different from the outer adhesive layer 31, and the workability of winding the laminated sheet 30S by the winding roller 62 is improved. Become.

The laminated sheet 30S is appropriately cut to a desired size. Through the above steps, the electromagnetic shielding material 10 is completed. Note that the protective layer 41 may be laminated onto the sheet-like base material 11 after the inner adhesive layer 32, the metal sprayed layer 21, and the outer adhesive layer 31 are laminated on the sheet-like base material 11.

In the electromagnetic shielding material 10 of this embodiment, a metal sprayed layer 21 is laminated on a sheet-like base material 11. Then, an outer adhesive layer 31 is directly laminated on the metal sprayed layer 21 from the side opposite to the sheet-like base material 11 . In the electromagnetic shielding material 10, the outer adhesive layer 31 is inserted between the metal particles constituting the metal spray layer 21, so the outer adhesive layer 31 prevents the metal particles 22 constituting the metal spray layer 21 from falling off. It is possible to suppress it. Moreover, since the layer laminated directly on the metal sprayed layer 21 is made of an adhesive material, even if the electromagnetic shielding material 10 is deformed (for example, rolled up), the adhesion with the metal sprayed layer 21 can be maintained. It becomes possible to further suppress falling of the metal particles 22 by maintaining the metal particles 22. Further, by providing the outer adhesive layer 31, it is possible to suppress the generation of cracks in the metal sprayed layer 21 when the electromagnetic shielding material 10 is bent.

In this embodiment, since the outer adhesive layer 31 is disposed as the outermost layer of the electromagnetic shielding material 10, the electromagnetic shielding material 10 can be attached to an adherend using the outer adhesive layer 31. For example, the electromagnetic shielding material 10 can be wrapped around cables and the like like adhesive tape to bind the cables and the like. Furthermore, since the outermost adhesive layer 31 of the electromagnetic shielding material 10 has self-adhesive properties, the outer adhesive layers 31 can be bonded together by bending or rolling the electromagnetic shielding material 10. Since the outer adhesive layer 31 is less likely to stick to a material made of a different material than the outer adhesive layer 31, the electromagnetic shielding material 10 becomes easier to handle. In addition, when the outer adhesive layer 31 contains a conductive material, by making the outer adhesive layer 31 the outermost layer of the electromagnetic shielding material 10, the ground (ground) of the outer adhesive layer 31 containing the conductive material can be used. ) Connection becomes easy. In this case, for example, the electromagnetic shielding material 10 may be attached directly to a conductor serving as a ground with the outer adhesive layer 31 attached, or the electromagnetic shielding material 10 may be attached to a metal wire connected to the ground with the outer adhesive layer 31 attached. It may be rolled up so that 31 is inside and brought into contact.

Furthermore, in this embodiment, the metal sprayed layer 21 is in close contact with the outer adhesive layer 31 and the inner adhesive layer 32 from both sides, so no matter which side the electromagnetic wave shielding material 10 is bent, the metal The generation of cracks in the sprayed layer 21 can be suppressed.

Further, in this embodiment, the outer adhesive layer 31 and the inner adhesive layer 32 are made of materials that adhere to each other. Specifically, the outer adhesive layer 31 and the inner adhesive layer 32 are made of the same material and have self-adhesive properties. Therefore, when the gaps between the metal particles 22 of the metal sprayed layer 21 are connected to the entire thickness direction of the metal sprayed layer 21, it is possible to adhere the outer adhesive layer 31 and the inner adhesive layer 32 through the gap. becomes. This strengthens the adhesion between the outer adhesive layer 31 and the inner adhesive layer 32 and the metal sprayed layer 21, making it possible to further prevent part of the metal sprayed layer 21 from falling off.

In this embodiment, the outer adhesive layer 31 (outer viscoelastic layer) and the inner adhesive layer 32 (inner viscoelastic layer) are the "first viscoelastic layer" and the "second viscoelastic layer" described in the claims, respectively. corresponds to "elastic layer".

Hereinafter, the above-mentioned embodiment will be described in more detail with reference to Examples, but the electromagnetic wave shielding material of the present disclosure is not limited to the following Examples.

1. Configuration of electromagnetic shielding material <Example 1>
Sheet-like base material 11; product name “FOLEC LZ2000” manufactured by INOAC Corporation, thickness 0.9 mm
Inner adhesive layer 32; manufactured by INOAC Corporation, product name: “INOTACK Low Temperature Grade”, basis weight: 20 g/m ²
Metal sprayed layer 21; zinc, area weight: 250 g/m ²
Outer adhesive layer 31: manufactured by INOAC Corporation, product name “INOTACK Shield Grade”, basis weight: 100 g/m ²
Magnetic material; manufactured by Powder Tech Co., Ltd., trade name "M03S" (true spherical Mn-based phyllite). The magnetic material was added to the outer adhesive layer 31 at a content of 15% by weight.

<Example 2>
Example 2 differs from Example 1 only in the outer adhesive layer 31, and in that the outer adhesive layer 31 does not contain a magnetic material.

2. Evaluation method <Transmission attenuation rate>
Regarding the electromagnetic shielding materials of Examples 1 and 2, the transmission attenuation rate (Rtp) was determined in accordance with IEC62333-2, and the electromagnetic shielding properties were evaluated based on this.

3. Evaluation Results As shown in Figure 4, in Example 1 in which the outer adhesive layer 31 contained magnetic powder, the transmission attenuation rate was much higher than in Example 2 in which magnetic powder was not contained. It was found that electromagnetic wave shielding properties can be greatly improved. Furthermore, in Examples 1 and 2, it was confirmed that the outer adhesive layer 31 could prevent the metal particles 22 of the metal sprayed layer 21 from falling off.

[Other embodiments]
(1) Like the electromagnetic shielding material 10V shown in FIGS. 3(A) and 3(B), the inner adhesive layer 32 may not be provided, and the metal sprayed layer 21 It may be directly laminated.

(2) In the above embodiment, the outer adhesive layer 31 has self-adhesion and is difficult to adhere to a material different from the outer adhesive layer 31; It may also have the property of easily adhering to materials made of different materials. Thereby, for example, the electromagnetic shielding material 10 can be rolled up and wound around a cable or the like, and the outer adhesive layer 31 can be bonded to the protective layer 41.

(3) The adhesive materials forming the outer adhesive layer 31 and the inner adhesive layer 32 may be different. In this case, it is preferable that the outer adhesive layer 31 and the inner adhesive layer 32 are made of materials that adhere to each other. Note that, for example, the outer adhesive layer 31 may be made of a self-adhesive adhesive, and the inner adhesive layer 32 may be made of a normal adhesive material.

(4) As shown in FIG. 3(A), the protective layer 41 may not be provided.

(5) The metal spray layer 21 and the outer adhesive layer 31 may be laminated on both the front and back sides of the sheet-like base material 11. In this case, the inner adhesive layer 32 may not be provided, may be provided only on one of the front and back sides of the sheet-like base material 11, or on both the front and back sides of the sheet-like base material 11. may be provided.

(6) In the above embodiment, the outer adhesive layer 31 constitutes the outermost layer of the electromagnetic shielding material 10, but the outer adhesive layer 31 has one or more layers ( For example, layers made of resin films may be laminated.

(7) In the above embodiment, the sheet-like base material 11 is made of a foamed sheet, but it may be made of a non-foamed sheet (for example, a resin sheet, a rubber sheet, etc.). Moreover, the sheet-like base material 11 may have a structure in which a plurality of sheets are laminated. Moreover, the sheet-like base material 11 does not need to be flexible.

(8) In the above embodiment, a viscoelastic layer made of a viscoelastic body such as an elastomer (rubber or thermoplastic elastomer) or a gel body is provided in place of the outer adhesive layer 31 or the inner adhesive layer 32, The viscoelastic layer may be inserted between the metal particles 22 of the metal sprayed layer 21. By using such a viscoelastic body, the electromagnetic wave shielding material 10 can be easily deformed (for example, rolled up, etc.), and even when the electromagnetic wave shielding material 10 is deformed, the relationship between the metal sprayed layer 21 and the metal sprayed layer 21 is maintained. It becomes possible to maintain adhesion and suppress falling off of the metal particles 22. Note that this viscoelastic layer may contain powder or granule of a conductive material or powder or granule of a magnetic material.

10 Electromagnetic wave shielding material 11 Sheet-like base material 21 Metal sprayed layer 22 Metal particles 31 Outer adhesive layer (first viscoelastic layer)
32 Inner adhesive layer (second viscoelastic layer)
41 Protective layer

Claims (14)

A sheet-like base material,
a metal sprayed layer laminated on the sheet-like base material;
An electromagnetic wave shielding material, comprising: a first viscoelastic layer that is laminated on the metal sprayed layer from the side opposite to the sheet-like base material and that is inserted between metal particles constituting the metal sprayed layer. The electromagnetic shielding material according to claim 1, wherein the first viscoelastic layer is the outermost layer of the electromagnetic shielding material and is made of a self-adhesive adhesive. The electromagnetic wave shielding material according to claim 1 or 2, wherein the first viscoelastic layer contains powder of a conductive material. The electromagnetic shielding material according to claim 3, wherein the first viscoelastic layer is the outermost layer of the electromagnetic shielding material. The electromagnetic shielding material according to any one of claims 1 to 4, wherein the first viscoelastic layer contains powder of a magnetic material. Any one of claims 1 to 5, further comprising a second viscoelastic layer disposed between the sheet-like base material and the metal sprayed layer and inserted between metal particles constituting the metal sprayed layer. An electromagnetic shielding material according to claim 1. The electromagnetic wave shielding material according to claim 6, wherein the first viscoelastic layer and the second viscoelastic layer are made of materials that adhere to each other. The electromagnetic wave shielding material according to claim 6 or 7, wherein the second viscoelastic layer contains powder of a conductive material. The electromagnetic shielding material according to any one of claims 6 to 8, wherein the second viscoelastic layer contains powder of a magnetic material. The electromagnetic shielding material according to any one of claims 1 to 9, wherein the sheet-like base material is a foamed sheet. The electromagnetic wave shielding material according to claim 10, wherein a protective layer is laminated on the sheet-like base material from the side opposite to the first viscoelastic layer. A method for manufacturing an electromagnetic shielding material, which comprises laminating a first viscoelastic layer on the sprayed metal layer by applying a fluid adhesive to the sprayed metal layer laminated on a sheet-like base material. Laminating the metal sprayed layer directly on the second viscoelastic layer laminated on the sheet-like base material,
13. The method for manufacturing an electromagnetic shielding material according to claim 12, wherein when laminating the metal sprayed layer, the second viscoelastic layer is softened by the heat of the sprayed metal. Winding up a laminated sheet in which the metal sprayed layer is laminated on the sheet-like base material with a winding roller,
The method for manufacturing an electromagnetic shielding material according to claim 12 or 13, wherein the laminated sheet is wound up after the first viscoelastic layer is formed on the metal sprayed layer.

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