JPH11354981A - Electromagnetic wave shielding sheet - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an expanding/contracting electromagnetic wave shielding sheet. SOLUTION: A woven or knitted cloth 2 applied with a conductive film 3 exhibits flexibility and expands/contracts through deformation of texture or stitch 6. The conductive film 3 is a metallic film formed on the surface of a yarn forming the texture or stitch and follows up deformation thereof. Consequently, a sheet 1 expands/contracts arbitrarily with the conductive film 3 being fixed thereto through deformation of the texture or stitch 6 of the cloth 2.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electromagnetic wave shielding sheet used for electromagnetic sealing of various electronic devices.

[0002]

2. Description of the Related Art Conventionally, as a measure against electromagnetic wave shielding of electronic equipment, a metal film is formed on the inside of a housing of the electronic equipment by using a method such as chemical plating, vacuum deposition, or sputtering, or by applying a conductive paint. It was responded by that. However, when these methods are used, the adhesion between the metal film to be applied and the housing is poor, so that a decrease in productivity cannot be avoided, and the application of a very thick metal film cannot be expected. Japanese Patent No. 916000 (Prior Art 1) uses a combination of a synthetic resin housing for an electronic device and a molded body of a thin conductive material conforming to the inner surface or outer surface shape, and combines the two to form a screw. Attempts to stop, heat stake, or bond with adhesives have been proposed.

In Japanese Patent Publication No. Hei 6-34475 (Prior art 2), a laminated plate of a thermoplastic synthetic resin and a metal exhibiting superplasticity at a molding temperature of the thermoplastic synthetic resin is used. An attempt to form a housing or a member thereof by plastic working is introduced.

[0004]

However, in the prior art 1, a molded body of a conductive material which is to be a metal film and a casing is compared with a casing made of a synthetic resin plated with metal or vacuum-deposited. The effect that the adhesiveness of the film can be improved is emphasized. However, when the combination of the housing and the molded body is used, the step of shaping the molded body in a step separate from the molding of the synthetic resin housing, and the assembly step of combining and integrating the housing and the molded body are performed. This necessitates an increase in the number of steps in the manufacturing process. In this regard, according to the preceding example 2, it is advantageous in that a casing having excellent electromagnetic wave shielding properties can be manufactured in one process.

However, as the "metal exhibiting superplasticity at the molding temperature of the resin" used in the preceding example 2, for example, S
When an n-Pb-based alloy is used, the
Even if it can show an elongation of 200% or more when heated to ° C., it is hard at room temperature, and therefore, if the processing speed is too high, the metal in the laminate cannot follow this and breaks. The problem arises.

Incidentally, although not intended to seal electromagnetic waves, a plastic fiber obtained by combining a matrix having a fine equiaxed grain structure made of a superplastic metallic material with high-strength fibers of carbon fibers and whiskers. Reinforced metals are described in JP-B-56-13780. According to this metal, the effect that it can be easily processed into a desired shape under a superplastic structure is emphasized, but the meaning that it can be easily processed into a desired shape does not necessarily mean that any shape can be formed at room temperature. It does not mean that it can be molded and processed, let alone arbitrarily by sticking along the surface shape of the article, covering the surface along the complex shape of the article, winding it without gaps It cannot be attached.

An object of the present invention is to provide an electromagnetic wave shielding sheet which can be arbitrarily deformed and attached to electronic equipment.

[0008]

In order to achieve the above object, an electromagnetic wave shielding sheet according to the present invention is an electromagnetic wave shielding sheet having a conductive film on a fabric, wherein the fabric is woven or knitted. , Flexible,
The elasticity is exhibited by the deformation of the weave or stitch, and the conductive film is a metal film formed on the surface of the yarn forming the weave or stitch, and follows the deformation of the weave or stitch. is there.

[0009] The fabric is knitted in a knitted structure of a warp knit or a weft knit.

[0010] The yarn on which the conductive film is formed has flexibility.

The weave or stitch of the fabric in which the conductive film is formed on the yarn has a self-restoring property after deformation.

The yarn of the fabric is a false twist yarn or an elastic yarn.

The conductive film is a metal film formed by plating a fabric.

Further, the conductive film is formed by applying a conductive paint.

Further, the yarns forming the texture or stitch approach or touch each other due to the deformation of the texture or stitch,
The surface resistance of the conductive film decreases.

[0016]

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective view showing an embodiment of an electromagnetic wave shielding sheet according to the present invention.

Referring to FIG. 1, an electromagnetic wave shielding sheet 1 according to the present invention is obtained by attaching a conductive film 3 to a cloth 2. The fabric 2 is a woven or knitted fabric, has flexibility, and develops elasticity by deformation of a woven or knitted texture or stitch. A typical fiber structure from which elasticity can be obtained by such a weave or stitch deformation is a knit. The knitted fabric is formed by connecting the stitches formed by the yarn in the warp (warp) or weft (weft) direction to form a cloth, and is classified into a warp knit and a weft knit according to the knitting direction.

The weft knit is formed by forming a large number of stitches using one thread and sequentially connecting them to form a cloth. Knitting, rubber knitting, pearl knitting, and many other changing structures. In the warp knitting, a number of warp yarns are arranged in the same manner as in the manufacture of a woven fabric, and a knitted stitch is formed with each of the yarns to form a cloth. In the warp knitting, the shape of the stitch differs depending on the direction of the warp yarn applied to the knitting yarn. The knitted fabric is referred to as an open stitch or a closed stitch, respectively. News agency
51, pp. 918-919).

In FIG. 2, the stitch 6 of the weft knit and the warp knit is composed of the wale 4 and the course 5, and the elongation of the knitting structure is the stitch, that is, the wale 4 and the course 5
And 10 to 100% elasticity is obtained in at least one of the vertical direction and the horizontal direction. The knitted fabric is effective for use in the fabric of the electromagnetic wave sheet of the present invention because it produces elasticity in one direction due to the deformation of the stitch 6, but the fabric suitable for the sheet of the present invention is not necessarily limited to the knitted fabric. If the structure is such that the elasticity is generated by deformation of the weave, such as a rough woven fabric, the woven fabric can be applied to the fabric of the electromagnetic wave shielding sheet.

As shown in FIG. 3, the conductive film 3 is a metal film made of a conductive material adhered to the thread 7 of the weaving and knitting structure. Such a conductive film 3 can be formed by chemical plating (electroless plating), a combination of chemical plating and electrolytic plating, or by vacuum deposition, ion plating, sputtering, or even applying a conductive paint. it can.

In general, when a fabric formed by forming a conductive film formed of a metal plating such as copper or nickel into a non-stretchable woven yarn is pulled by force, the conductive film on the surface of the yarn is cracked, Peels off from the yarn, and the desired electromagnetic wave shielding performance cannot be obtained. Further, in a sheet in which a conductive film is formed by plating a metal such as copper or nickel on a fabric woven with elastic yarn such as rubber,
When the sheet is pulled, the yarn is stretched but the conductive film is not stretched, so that the conductive film is cracked or peeled off from the yarn, so that the electromagnetic shielding property is significantly reduced.

However, in the present invention, when the sheet is pulled in one direction, the yarns do not expand and contract, but the textures or stitches are deformed and the entire sheet is elongated in the direction in which the sheet is pulled. There is no large relative displacement between the conductive film and the yarn, so that the conductive film 3 is not cracked or peeled off from the yarn.

In the present invention, the elasticity obtained on the fabric 2 after the formation of the conductive film 3 is due to the deformation of the texture or stitch of the fabric. It is necessary that the film has flexibility even after the conductive film is formed. The reason is that the deformation of the weave or stitch is considered to be caused by the flexibility of the yarn.

The expansion and contraction of the fabric is caused by the property of returning to the original state after the deformation of the weave or stitch. Therefore, after the texture or stitch is deformed by receiving external force,
When external force is removed, it is necessary to have a force that returns to the original state, that is, possesses self-recovery. For this purpose,
As long as elastic yarns, false twist yarns, curl yarns, etc. are used, the fabric can be stretched by using the self-restoring properties of the yarn's bending, weave and stitches,
At least one direction of elasticity can be obtained.

Further, in the present invention, when the sheet is pulled in one direction, (texture or) of the fabric as shown in FIG.
The shape of the stitch 6 is deformed and the yarns 7 forming the (stitch) or the stitches 6 are close to each other or come into contact with each other, so that the density of the stitch or stitch is increased, so that the electric resistance of the sheet is increased. As a result, the electromagnetic wave shielding performance can be maintained even after the sheet is extended.

Actually, a copper-nickel plated sheet was stretched in several stages on a weft knit (circular knit) cloth of 75D polyester yarn-36 filaments, and the electromagnetic wave shielding performance was measured using the KEC method. Table 1 shows the measurement results.

[0027]

[Table 1]

As is clear from Table 1, the shielding performance of the electromagnetic wave shielding sheet according to the present invention hardly deteriorated even if it was stretched. Moreover, the sheet surface resistance value of the sheet was lower when the sheet was stretched than before the sheet was stretched. This is thought to be due to the fact that, as described above, the contact between the yarn forming the stitch and the yarn became stronger due to the elongation of the sheet, and that the curled yarn became straight and the distance between the yarns became shorter. Can be

The electromagnetic wave shielding sheet 1 according to the present invention comprises:
As shown in FIG. 5, it is set in the molding die 8 along the mold surface 8a, the undiluted thermoplastic synthetic resin solution is injected into the cavity 9, and the whole surface of the molded product 10 is adhered as an electromagnetic wave seal. It can be integrally mounted according to the surface shape.

The electromagnetic wave shielding sheet 1 according to the present invention comprises:
Because it is flexible and stretchable,
It adapts well to curved surfaces and other irregular shapes, does not wrinkle, and does not break. In addition, the electromagnetic wave shielding sheet laminated on the thermoplastic resin sheet can be shaped to any shape by hot press molding or vacuum forming, and the sheet can be freely shaped to follow the shape or shape of the molded body,
The seat surface will not be torn due to excessive force.

Furthermore, the present invention can be applied to an electromagnetic wave shielding tape, since the sheet has elasticity, even if the outer shape of the article to which the sheet is to be attached or the article has a complicated shape, In the same manner as a bandage wound around a wound on an arm or foot, it can be attached while being wound around the peripheral surface of the article without any gap.

[0032]

As described above, according to the present invention, in addition to being able to be used alone as a flexible electromagnetic wave shielding sheet, the lining and outer lining of a shield box of an electronic device using a hot press molding or vacuum molding method. Or as a shielding tape for bonding the surface of an article or for covering an article. Further, the electromagnetic wave shielding sheet of the present invention can be used as a lining of PVC leather, capron, or rubberized cloth. The sheet of the present invention has an effect that it can be widely used for various uses, for example, the article can have an electromagnetic wave shielding function while retaining the inherent flexibility of the article.

[Brief description of the drawings]

FIG. 1 is a diagram showing one embodiment of the present invention.

FIGS. 2 (a) and 2 (b) are views showing a configuration of a side knitting and a vertical knitting.

FIG. 3 is an enlarged view of a yarn on which a conductive film is formed.

FIG. 4 is a diagram showing a state when a stitch is deformed.

FIG. 5 is a view showing an example of mounting the electromagnetic wave shielding sheet of the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Electromagnetic wave shielding sheet 2 Cloth 3 Conductive film 4 Wale 5 Course 6 Stitch 7 Thread 8a Mold surface 8 Mold 9 Cavity 10 Molded object

Claims (8)

[Claims] 1. An electromagnetic wave shielding sheet having a conductive film on a fabric, wherein the fabric is woven or knitted, has flexibility, and exhibits elasticity by deformation of a weave or stitch shape. The conductive film is a metal film formed on the surface of the yarn forming the weave or stitch, and follows the deformation of the weave or stitch. 2. The electromagnetic wave shielding sheet according to claim 1, wherein the fabric is knitted in a knitted structure of a warp knit or a weft knit. 3. The electromagnetic wave shielding sheet according to claim 1, wherein the yarn on which the conductive film is formed has flexibility. 4. The electromagnetic wave shielding sheet according to claim 1, wherein the weave or stitch of the fabric in which the conductive film is formed on the yarn has a self-restoring property after deformation. 5. The electromagnetic wave shielding sheet according to claim 1, wherein the yarn of the fabric is a false twist yarn or an elastic yarn. 6. The electromagnetic wave shielding sheet according to claim 1, wherein the conductive film is a metal film formed by plating a cloth. 7. The electromagnetic wave shielding sheet according to claim 1, wherein the conductive film is formed by applying a conductive paint. 8. The method according to claim 1, wherein the yarns forming the texture or stitch approach or contact each other due to the deformation of the texture or stitch, and the surface resistance of the conductive film decreases. The described electromagnetic wave shielding sheet.