JP3001248B2 - Conductive fiber sheet and method for producing the same - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a conductive fiber sheet that can be used as an electromagnetic wave shielding material or a radio wave reflecting material, and particularly to a conductive fiber sheet suitable as a gasket.

[Related Art] In recent years, the spread of various electronic devices has been remarkable. However, with the widespread use of various electronic devices, the problem of electromagnetic interference, which has not been a problem so far, has been highlighted. The problem of the electromagnetic wave disturbance is that the function of the electronic device is obstructed by an electromagnetic wave generated from various electronic devices, an electromagnetic wave in the natural world, or the like.

As a solution to the problem of such electromagnetic interference,
To prevent electromagnetic waves from leaking from the electronic device or to prevent electromagnetic waves from entering from outside, form a metal conductive layer on the surface inside the electronic device case, or mix a conductive filler inside the electronic device case. Alternatively, a method of attaching a conductive sheet to the surface inside the electronic device case has been adopted.

However, even if the electromagnetic waves are shielded by the above-described method, the electromagnetic waves leak or intrude from a gap formed in a joint portion of the case of the electronic device, a joint portion, or the like. Various proposals have been made for shielding.

For example, JP-A-61-14948 and JP-A-63-199639 propose a conductive elastic body in which a conductive fiber sheet and conductive particles are mixed in an elastic polymer material.
However, although the elastic body itself has some flexibility, the inner conductive fiber sheet hardly expands, so the conductive elastic body hardly expands as a whole,
Because there is no flexibility, if you try to fill the gap in the electronic device case and stretch it forcibly to fit it, the metal plated on the surface of the conductive fiber will peel off, and the conductivity will be lost, so it is called electromagnetic wave shielding The original performance was lost.

In addition, Japanese Patent Application Laid-Open No. 62-251130 discloses that a knitted fabric is made from conductive fibers having conductivity by metal plating or the like and having crimping, and then impregnated with a hot-melt resin solution. The conductive film obtained by drying is used for shielding electromagnetic waves. However, since this film is made from knitted conductive fibers with a crimp and is immersed in a hot-melt resin solution, the film has some degree of elongation in the transverse direction, but has little elasticity in the thickness direction of the film. Because of this, the adhesiveness to the electronic device case is poor, and since the fibers are woven, voids are formed in the knitted fabric when stretched, and have little effect on short-wavelength electromagnetic waves. Met. In addition, the step of knitting the conductive fiber is complicated, and the plated metal may be peeled off at the knitting stage.

[Problems to be Solved by the Invention] The present invention provides a conductive fiber sheet having an electromagnetic wave shielding property, particularly an electromagnetic wave shielding property in a gap such as a joint portion or a joint portion of an electronic device case, and a method of manufacturing the conductive fiber sheet. Aim.

[Means for Solving the Problems] The present invention is a conductive fiber sheet in which an elastic material is attached to a part or all of voids of a conductive nonwoven fabric mainly composed of highly crimped fibers.

If the high crimped fiber is a latently crimped fiber, it has excellent adhesion to the electronic case.

In addition, a nonwoven fabric obtained by performing an entanglement treatment on a fiber web mainly composed of a high crimped fiber is subjected to conductive processing, then impregnated with an elastic material solution, and dried to obtain a conductive fiber exhibiting excellent adhesion. A sheet is obtained.

[Operation] The conductive fiber sheet of the present invention has the following features, since the elastic material is attached to a part or all of the voids of the conductive nonwoven fabric mainly composed of high crimped fibers.

First, since the nonwoven fabric of the present invention has been subjected to conductive processing, the nonwoven fabric itself has conductivity, and as a result, has high electromagnetic wave shielding performance.

Secondly, since the nonwoven fabric of the present invention is mainly composed of high crimped fibers, even when the nonwoven fabric is stretched, only the crimps of the high crimped fibers are stretched, and it has excellent elongation. The conductivity of the fiber is not reduced because the fiber itself is stretched and the metal such as plating is peeled and the conductivity is not reduced.In the present invention, only the crimp of the fiber is stretched, and the fiber itself is not stretched, so the conductivity is reduced. do not do.

Third, in the conductive fiber sheet of the present invention, the elastic material is present inside the voids of the nonwoven fabric. However, since the elastic material mainly fixes the intersections of the fibers, it not only imparts strength to the nonwoven fabric, In addition, it also provides elasticity in the thickness direction of the conductive fiber sheet. As a result, it is easy to adhere to the gap in the electronic device case, and the electromagnetic wave does not leak or enter.

Fourth, non-woven fabrics are not woven or knitted, can be easily manufactured from a fiber web, and even when stretched, there are many fibers and they do not create a large space, so that the wavelength is short. Does not leak or penetrate electromagnetic waves.

Fifth, when the nonwoven fabric of the conductive fiber sheet of the present invention is obtained by performing an entanglement treatment such as needle punching or hydroentanglement, the fiber orientation tends to be in the thickness direction of the nonwoven fabric, and the high crimped fiber Because the crimping also has the function of a spring, the synergistic effect with the elasticity of the elastic material
It has excellent elasticity and excellent adhesion to an electronic device case.

Sixth, in the present invention, if the nonwoven fabric is impregnated with the elastic material solution, the elastic material mainly adheres only to the intersections of the constituent fibers and does not completely cover the nonwoven fabric surface, which hinders the conductivity of the conductive fiber sheet. Never.

Hereinafter, the conductive fiber sheet of the present invention will be described in more detail.

Highly crimped fibers of the present invention, even if the conductive fiber sheet is stretched,
Since only the crimp of the high crimped fiber elongates and the fiber itself does not elongate, there is an effect that the metal does not peel off and does not affect the conductivity.

The high crimped fiber of the present invention can be preferably used even if it is a high crimped fiber that has already been revealed or a fiber having a potentially high crimp (hereinafter, simply referred to as “potentially crimped fiber”). . In the former case, the crimps have already become apparent, so that the dimensional stability is excellent. In addition to being difficult to form, it has excellent carding properties.

The high crimped fiber referred to in the present invention is a fiber having a number of crimps of 20 to 90 pieces / inch at the stage when the crimps become apparent.

Spiral fibers are preferably used as these highly crimped fibers because of their excellent stretchability. Examples of the fiber having the spiral structure include a composite fiber in which crimp is actualized or latent, a single component in which crimp is actualized with a specific heat history, or a latent fiber. . Among them, a composite fiber such as a side-by-side type made of a high-melting polyester and a low-melting polyester is preferable because it has a large number of crimps and exhibits excellent elasticity.

Highly crimped fibers as described above are 60% of the fibers constituting the nonwoven fabric.
If the content is less than 60% by weight, the elasticity is extremely poor, and the adhesion to the electronic device case deteriorates.

The fibers other than the high crimped fibers are not particularly limited, and general synthetic fibers such as nylon fibers, polyester fibers, and acrylic fibers may be used.

The fiber web is obtained by passing the fiber mainly composed of the high crimped fiber as described above through a carding machine or the like. Since the fiber orientation of the fiber web obtained by passing through the card machine is substantially unidirectional, it is easy to expand and contract in one direction, which is the fiber orientation direction, but how it works when actually used Since it is not clear, it is preferable that the fibers are oriented non-directionally. In order to orient the fibers in such a non-directional manner, for example, a substantially unidirectional fiber web obtained through a carding machine is supplied by a cross layer in a direction perpendicular to the flow direction of the conveyor, and the end of the conveyor is fed. If it is folded back at the edge and crossed by reciprocating at both ends of the conveyor, a nonwoven fabric that can expand and contract in multiple directions can be obtained.

A nonwoven fabric is obtained by entanglement treatment of the fiber web thus obtained. The entanglement treatment in the present invention is a mechanical entanglement method such as a needle punching method and a water entanglement method, and is a preferable method because it does not hinder the elasticity of the nonwoven fabric. In addition, bonding by a binder, even by a bonding method by heat fusion, if it is bonded in a point-like manner so as not to hinder the extensibility of the high crimped fiber, a binder, a nonwoven fabric is formed by heat fusion. Is also good.

This combining process has an important meaning in the present invention. That is, since the entanglement process described above acts at right angles to the horizontal direction of the fiber web, the fibers of the fiber web are oriented in the thickness direction. This means that the elasticity due to the fiber crimping can also act when it is brought into close contact with the electronic device case, and the present invention uses a high crimped fiber, so it exhibits spring-like elasticity. I do.

The method for producing a nonwoven fabric of the present invention differs depending on whether the crimp of the high crimped fiber used is actualized or latent. In other words, when crimping is actualized, a nonwoven fabric can be obtained only by performing the entanglement process, but when latently crimped fibers are used, the crimping is realized after conducting conductive processing. In this case, the conductivity of the fiber becomes poor due to, for example, the metal adhering to the fiber surface being peeled off. Therefore, it is necessary to apply a conductive process after the crimping of the latently crimped fiber becomes apparent.

As described above, by performing the conductive processing on the nonwoven fabric in which the fiber crimps have already become apparent, conductivity is imparted, and as a result, a sheet having excellent electromagnetic wave shielding properties can be obtained.

For such conductive processing, any method can be used as long as a metal layer is formed on the fiber surface and has conductivity, such as commonly used electroless plating, metal deposition, sputtering, or application of conductive paint. Can be.

By impregnating the nonwoven fabric thus subjected to the conductive processing with the elastic material solution, a conductive fiber sheet having the elastic material adhered to the voids of the nonwoven fabric can be obtained. When the nonwoven fabric is impregnated with the elastic material solution as described above, the elastic material mainly adheres to the fiber intersections, so that the strength of the nonwoven fabric is improved, and the elasticity of the entire nonwoven fabric is imparted.

Silicone rubber, natural rubber, SBR, chloroprene rubber, NBR,
Normally used materials such as butyl rubber, nitrile rubber, polysulfide, urethane rubber, acrylic rubber, chlorosulfonated polyethylene, and polyvinyl chloride may be used.

By impregnating the nonwoven fabric with a solution containing such an elastic material, the elastic material mainly adheres to the fiber intersections, but if a large amount or the viscosity of the solution is high, the voids will be filled. It is necessary that the surface is not completely covered by the elastic material. If the surface of the non-woven fabric is completely covered with the elastic material, the conductivity is deteriorated and the electromagnetic wave shielding performance is deteriorated, which is not preferable.

In addition, such an elastic material may be made conductive by mixing carbon black, graphite, silver, iron, nickel, etc. as in the past, but if the mixing amount is increased, the elasticity of the elastic material decreases. Therefore, it is necessary to appropriately select the mixing amount.

After being impregnated in this manner, the elastic material is fixed in the voids of the nonwoven fabric by drying. The drying method is not particularly limited, and may be performed by a tunnel furnace, a ventilation dryer, a heat cylinder, infrared rays, or the like.

Examples will be described below, but the present invention is not limited to the following examples.

[Examples] (Examples) Latent crimped fibers of side-by-side composite type (polyester C-81, 2 denier x 51 mm, manufactured by Unitika Ltd.) 10
After carding 0%, a fiber web with fibers oriented crosswise by a cross layer was obtained. The obtained fiber web was needled at a needle density of 60 needles / cm ² to entangle the fibers to obtain a nonwoven fabric. Then, the non-woven fabric was subjected to a heat treatment to develop the crimp of the latently crimped fiber, thereby obtaining a non-woven fabric having a basis weight of 100 g / m ² . The number of crimps of the latent crimped fiber was 10 to 20 pieces / inch before the onset of crimping, and was 50 to 80 pieces / inch after the onset of crimping.

The thus obtained nonwoven fabric electroless plating of a conventional method, the copper was 25 g / m ² coating, a further nickel thereon
The nonwoven fabric was subjected to conductive processing by coating with 5 g / m ² .

Next, the nonwoven fabric subjected to the conductive processing is impregnated with a latex emulsion having a solid content ratio of a mixture of SBR and NBR of 20% by weight, and then passed through a tunnel furnace to obtain a basis weight.
A conductive fiber sheet of 260 g / m ² was obtained.

SBR and NBR of the conductive fiber sheet thus obtained
The mixture adhered mainly to the fiber intersections inside the conductive fiber sheet.

(Comparative Example) Instead of the latently crimped fiber of the example, 100% of an acrylic-PVC fiber (Kanecaron, trade name of Kanegafuchi Chemical Industry Co., Ltd., 5 denier × 51 mm) having a crimp number of 7 to 10 pieces / inch instead of 100%. A conductive fiber sheet having a basis weight of 260 g / m ² was obtained in exactly the same manner as in the example except that it was used.

(Electrical conductivity test) The elongation of the conductive fiber sheets of Examples and Comparative Examples was 0, 20,
The surface resistance when changing to 40, 60, 80, 100, 120 and 150% was measured.

The results are shown in Table 1. From this table, it can be seen that the conductive fiber sheet of the present invention is excellent in extensibility, and does not decrease in surface resistance even when extended, and has excellent electromagnetic wave shielding performance.

(Adhesion Test) As shown in FIG. 1, a laminate of the conductive fiber sheet 1 of the example and the comparative example and a stainless steel mesh 14 of 14 mesh was sandwiched between gold deposition electrodes 3 and the load 5 was changed. Then, the resistance in the thickness direction of the conductive fiber sheet 1 was measured.

The results are shown in Table 2. From this table, it is found that the conductive fiber sheet 1 of the present invention has an elastic material and elasticity of high crimped fiber,
The conductive fiber sheet of the comparative example is deformed along the uneven stainless steel mesh shape and has a constant resistance regardless of the load 5 because the contact area with the electrode is increased. However, the fiber itself does not have elasticity, so it cannot be deformed along the uneven stainless steel mesh shape, and unless a high load is applied, the volume resistance is high and the electromagnetic wave shielding performance is poor. Understand.

[Effects of the Invention] Since the conductive fiber sheet of the present invention has a nonwoven fabric mainly composed of highly crimped fibers subjected to conductive processing, the nonwoven fabric itself has conductivity and has not only high electromagnetic wave shielding performance but also stretching. In this case, the fiber itself does not stretch, and the crimp of the fiber is stretched, so that the conductivity is hardly reduced.

In the conductive fiber sheet of the present invention, since the elastic material is present inside the voids of the nonwoven fabric and provides elasticity in the thickness direction of the conductive fiber sheet, the conductive fiber sheet adheres to the gap of the electronic device case and leaks or intrudes electromagnetic waves. There is no.

Further, the nonwoven fabric can be manufactured from fibers, and even when stretched, since many fibers are present, the nonwoven fabric is excellent in shielding electromagnetic waves having a short wavelength.

If the nonwoven fabric of the conductive fiber sheet of the present invention is produced by entanglement, the high crimped fibers are easily oriented in the thickness direction, and the crimps of the high crimped fibers also have the function of a spring,
Since it shows excellent elasticity, it has excellent adhesion to electronic device cases.

In the conductive fiber sheet of the present invention, if the nonwoven fabric is impregnated with the elastic material solution, the elastic material mainly adheres to the intersections of the constituent fibers, and thus does not hinder the conductivity of the conductive fiber sheet.

As described above, since the conductive fiber sheet of the present invention has excellent elongation while maintaining excellent electromagnetic wave shielding performance, it can be used as a gasket material, an electromagnetic wave shielding material, and a radio wave reflecting material.

[Brief description of the drawings]

 FIG. 1 is a cross-sectional view of an adhesion tester. 1... Conductive fiber sheet 2... Stainless steel mesh 3... Gold vapor deposition electrode 4... Resistance meter 5.

Continuation of front page (58) Field surveyed (Int.Cl. ⁷ , DB name) D06M 11/00-11/84

Claims (3)

(57) [Claims] An elastic material adheres to a part or all of the voids of a conductively processed non-woven fabric mainly composed of highly crimped fibers having a number of crimps of 20 to 90 pieces / inch after being revealed. A conductive fiber sheet characterized by the above-mentioned. 2. The conductive fiber sheet according to claim 1, wherein the highly crimped fiber is a latently crimped fiber. 3. A nonwoven fabric obtained by performing an entanglement treatment on a fiber web mainly composed of high crimped fibers, and then subjecting the nonwoven fabric to a conductive process,
A method for producing a conductive fiber sheet, comprising impregnating an elastic material solution and drying.