JP2008093093A - Electromagnetic wave shielding sheet and electromagnetic wave shielding clothes - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an electromagnetic wave shielding sheet 3 and an electromagnetic wave shielding apron 1 which block electromagnetic waves, especially a magnetic field. <P>SOLUTION: The electromagnetic wave shielding sheet includes a copper layer 5 made of a copper material and working as an electromagnetic wave absorbing layer that absorbs a magnetic field G2 and an aluminum layer 7 made of an aluminum material and working as an electromagnetic wave shielding layer that blocks the magnetic field G2. The electromagnetic wave shielding sheet that shields the magnetic field G2 and protects the human body from the magnetic field G2 is formed by arranging the aluminum layer 7 nearer to the human body than to the copper layer 5. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an electromagnetic wave shielding sheet and an electromagnetic wave shielding garment that protect an object to be protected from electromagnetic waves, for example.

  In modern society, radio waves from mobile phones and televisions are known to fly in the atmosphere, and this radio wave affects the human body and precision equipment. In recent years, IH (Induction Heating) cooking heaters that perform electromagnetic induction heating by generating a magnetic field have been provided, and it is also known that this magnetic field affects the human body and precision equipment.

  Such radio waves and magnetic fields may cause the operation of a cardiac pacemaker, which is a precision machine, to become unstable. For this reason, a user who uses a cardiac pacemaker needs clothes that protect the cardiac pacemaker from radio waves and magnetic fields.

  On the other hand, for example, an electromagnetic shielding material for cardiac pacemakers has been proposed as a means for blocking radio waves (see Patent Document 1). This electromagnetic shielding material for cardiac pacemakers is said to be able to block electromagnetic waves in the radio wave region by using a conductive material as a material.

  Further, for example, electromagnetic wave shield clothing has been proposed as a means for blocking electromagnetic waves (see Patent Document 2). The electromagnetic wave shielding clothing is said to be able to block electromagnetic waves by applying copper or copper-tin alloy plating to the lining of the apron.

  However, although these shielding materials are effective against radio waves, they have not been able to effectively block the magnetic field. For this reason, it was not possible to protect the cardiac pacemaker from the magnetic field emitted by an IH cooking heater or the like.

JP 2001-204828 A JP-A-8-116191

  An object of this invention is to provide the electromagnetic wave shielding sheet which can interrupt | block especially the magnetic field in electromagnetic waves, and electromagnetic wave shielding clothing in view of the problem mentioned above.

  This invention is an electromagnetic wave shielding sheet that blocks electromagnetic waves and protects the object to be protected from electromagnetic waves, and is formed of a copper material or an iron material to absorb electromagnetic waves, and is formed of an aluminum material to block electromagnetic waves. An electromagnetic wave shielding sheet comprising an electromagnetic wave shielding layer, wherein the electromagnetic wave shielding layer is disposed closer to the protection target side than the electromagnetic wave absorbing layer.

  According to the present invention, particularly a magnetic field in electromagnetic waves can be blocked. In particular, when a user who uses a cardiac pacemaker uses it, the user's human body can be reliably protected from a magnetic field emitted from an IH cooking heater or the like.

An embodiment of the present invention will be described below with reference to the drawings.
FIG. 1 shows a front view of an electromagnetic wave shield apron 1 using an electromagnetic wave shield sheet 3, and FIG. 2 shows a cross-sectional view of an electromagnetic wave shield cloth 2 using the electromagnetic wave shield sheet 3.
As shown in the front view of FIG. 1, the electromagnetic wave shielding apron 1 is configured to have such a size that the front surface of the user M can be covered from the lower neck to the thigh by the electromagnetic wave shielding cloth 2. For this reason, when the user M wears the electromagnetic wave shield apron 1, the entire front surface of the cardiac pacemaker P is covered with the electromagnetic wave shield apron 1 as viewed from the front.

  As shown in the cross-sectional view of FIG. 2, the electromagnetic shielding cloth 2 is configured by the cloth layers 4 and 9 being superposed on the front and back of the electromagnetic shielding sheet 3 formed in a sheet shape with a constant thickness.

The cloth layer 4 is made of an appropriate fiber material such as chemical fiber or natural fiber.
Chemical fibers include recycled fiber (rayon, cupra, etc.), semi-synthetic fiber (acetate, promix, etc.), synthetic fiber (nylon, aramid, vinylon, pyrinidene, polyvinyl chloride, polyester, acrylic, polyethylene, polypropylene, polyurethane, Fiber materials such as polyclar) or inorganic fibers (glass, carbon fiber, metal fiber, etc.) can be used.
As natural fibers, fiber materials such as plant fibers (cotton, hemp, etc.) or animal fibers (wool, Angola, cashmere, mohair, camel, alpaca, silk, etc.) can be used.

  The electromagnetic wave shielding sheet 3 is configured by superposing a copper layer 5, a carbon layer 6, an aluminum layer 7, and a carbon layer 8 in order from the front side (the left side in FIG. 2) that is the outside of the human body.

The copper layer 5 is a sheet-like layer formed of a copper material, and is formed with a thickness of about 35 microns. The copper layer 5 can be made of other materials, but is preferably made of a material that absorbs a magnetic field, a material that passes a magnetic field, or a material that attracts a magnet. Examples of such materials include iron materials, nickel materials, and zinc materials in addition to copper materials. In this embodiment, by using a copper material, the manufacturing cost is reduced by suppressing the cost compared to using other materials.
The thickness of the copper layer 5 may be 10 microns or more, and more preferably 20 microns or more. In this embodiment, the thickness is about 35 microns in order to achieve both the reliability of the electromagnetic wave shielding function and the flexibility for use in clothes.

Each of the carbon layers 6 and 8 is a layer composed of a carbon sheet formed into a sheet shape from a carbon material, and is formed to have an appropriate thickness. In this embodiment, it is formed thinner than the thickness of the aluminum layer 7.
The carbon layers 6 and 8 can be made of other materials, but are preferably made of an insulating material having a property of releasing magnetism to form an insulating layer. In the present embodiment, carbon is used as a material that emits magnetism. The carbon layers 6 and 8 block the charging, magnetism, and electric field of the copper layer 5 and the aluminum layer 7 and absorb electromagnetic waves.

  The aluminum layer 7 is a sheet-like layer having a constant thickness formed of an aluminum material. In this embodiment, the thickness is about 7 microns. The aluminum layer 7 is preferably made of a material that reflects a magnetic field, a material that does not pass a magnetic field, or a material that does not attract a magnet. In this embodiment, it is made of an aluminum material that has a property of discharging without being charged and that can be formed lightweight.

  With the above configuration, the electromagnetic wave shielding sheet 3 can block both an electric field and a magnetic field. For this reason, it is possible to block radio waves such as 800 MHz, 1.5 GHz, 1.7 GHz, and 2 GHz emitted by the mobile phone and a magnetic field having a frequency of 20 kHz to 90 kHz emitted by the IH cooking heater.

  Moreover, the electromagnetic wave shield apron 1 comprised with the electromagnetic wave shield sheet 3 can prevent that a radio wave and a magnetic field exert an influence on the human body of the user who wears clothes. Therefore, when the user M using the cardiac pacemaker P wears the electromagnetic wave shield apron 1, it is possible to prevent the operation of the cardiac pacemaker P from becoming unstable due to radio waves or magnetic fields.

  The electromagnetic wave shielding sheet 3 used in this example can obtain sufficient shielding characteristics as shown in (A) of the explanatory diagram of FIG. 3 when the shielding characteristics of the electric field are measured by the KEC method.

  In addition, when the shielding property with respect to the magnetic field is measured by the KEC method, the electromagnetic shielding sheet 3 can obtain a sufficient shielding property as shown in (B) of the explanatory diagram of FIG.

  Further, as shown in FIG. 4A, the IC cooking heater 30 emits a magnetic field G1 during use. The above-described electromagnetic wave shield apron 1 can reliably protect the cardiac pacemaker P from this magnetic field G1. Can do.

  That is, since the copper layer 5 in the electromagnetic wave shielding sheet 3 used for the electromagnetic wave shielding apron 1 allows the magnetic field G2 to pass through the copper layer 5, the magnetic field G2 is applied as shown in FIG. It can function as a magnetic absorption layer by sucking. Due to the magnetic field absorption effect of the copper layer 5, the direction of the lines of magnetic force changes as shown in the magnetic field G2, and it prevents the electromagnetic wave shielding sheet 3 from going around to the back side as shown in the magnetic field G1 in an empty state. it can.

  Thus, the human body can be protected from radio waves and magnetic fields by the electromagnetic wave shield apron 1 using the electromagnetic wave shield sheet 3. In particular, the IH cooking heater 30 that emits a strong magnetic field can be blocked so that the magnetic field G2 emitted by the IH cooking heater 30 does not reach the human body side.

  Further, by preventing the magnetic field G2 from flowing from the side to the back of the electromagnetic wave shield apron 1 by the magnetic field absorption function of the copper layer 5, it is possible to mainly cover the entire front, back, left and right of the human body, such as a shirt. The electromagnetic shield apron 1 existing only on the front surface of the human body can prevent the magnetic field G2 from the front from wrapping around and reach the human body, and can prevent the magnetic field G2 from adversely affecting the cardiac pacemaker P.

  Further, since the aluminum layer 7 is disposed on the back side of the copper layer 5, the aluminum layer 7 can reliably block the magnetic field G2 from passing to the human body side. In particular, since the carbon layer 6 serving as an insulating layer is sandwiched between the copper layer 5 and the aluminum layer 7, both the magnetic field absorbing function by the copper layer 5 and the magnetic field blocking function by the aluminum layer 7 can be effectively exhibited. And can effectively block the magnetic field.

  Moreover, the thickness of the copper layer 5 is set to about 35 microns, the thickness of the aluminum layer 7 is set to about 7 microns, and the thickness of the carbon layers 6 and 8 is further reduced to obtain sufficient electromagnetic wave shielding performance. Thus, the flexibility of the electromagnetic wave shielding sheet 3 can be ensured. Therefore, even if the electromagnetic wave shield apron 1 using this electromagnetic wave shield sheet 3 is worn, the user does not feel a sense of stiffness and can use it comfortably.

  In this embodiment, the electromagnetic wave shield apron 1 having the outer shape is formed. However, appropriate clothes such as an upper garment, a pant, a skirt, a muffler, a glove, and an undergarment can be formed using the electromagnetic wave shield sheet 3. .

  The copper layer 5 is formed of a copper material, but may be formed of an iron material to be an iron layer, may be formed of a nickel material to be a nickel layer, or may be formed of a zinc material to be a zinc layer. In this case, the thickness of the iron layer, nickel layer, or zinc layer may be 10 microns or more, preferably 20 microns or more, and more preferably about 35 microns. Even in this case, the magnetic field G2 can be absorbed by the iron layer, the nickel layer, or the zinc layer, and the wraparound of the magnetic field G2 can be prevented.

  Moreover, although the carbon layers 6 and 8 were formed with the carbon material, you may form not only this but with another insulating member. Even in this case, the magnetic field absorption performance of the copper layer 5 (or iron layer) and the magnetic field interruption performance of the aluminum layer 7 can be effectively exhibited.

  The electromagnetic wave shielding sheet 3 may be processed to ensure air permeability and flexibility. For example, as shown in the perspective view of FIG. 5, a plurality of holes 11 may be provided to form an electromagnetic wave shielding sheet 3a having good air permeability. In this case, the diameter of the hole 11 may be 1.5 mm or less, and is preferably about 1 mm. What is necessary is just to make the thickness and material of each layer which comprise the electromagnetic wave shield sheet 3a the same as embodiment mentioned above.

  Thereby, the air permeability can be improved, and the flexibility can be improved and the feeling of stiffness can be eliminated compared to the case where there is no hole 11. Therefore, a feeling of wearing can be made favorable from both air permeability and flexibility. In addition, even when a plurality of minute holes 11 are formed in this way, electromagnetic waves can be sufficiently blocked.

  Further, as shown in the perspective view of FIG. 6, a plurality of dimples (dents) 13 may be provided to form an uneven electromagnetic wave shield sheet 3b. In this case, the dimple 13 may be formed such that the copper layer 5 side is concave and the aluminum layer 7 side is convex, or the copper layer 5 side is convex and the aluminum layer 7 side is concave. What is necessary is just to make the thickness and material of each layer which comprise the electromagnetic wave shield sheet 3a the same as embodiment mentioned above. Thereby, a softness | flexibility can be improved rather than the electromagnetic wave shield sheet 3 without an unevenness | corrugation, and a feeling of wear can be made favorable. In addition, the presence of the dimple 13 reduces the space between close contact with the human body, and the wearing feeling can be improved from this point.

In correspondence between the configuration of the present invention and the above-described embodiment,
The electromagnetic wave shielding garment of this invention corresponds to the electromagnetic wave shielding apron 1 of the embodiment,
Similarly,
The fabric corresponds to the fabric layers 4 and 9,
The electromagnetic wave absorbing layer corresponds to the copper layer 5,
The electromagnetic wave shielding layer corresponds to the aluminum layer 7,
The present invention is not limited only to the configuration of the above-described embodiment, and many embodiments can be obtained.

The front view of an electromagnetic wave shield apron. Sectional drawing of electromagnetic shielding cloth. Explanatory drawing of the interruption | blocking performance with respect to the electric field and magnetic field of an electromagnetic wave shield sheet. Explanatory drawing of the magnetic field rounding prevention effect. The perspective view of the electromagnetic wave shield sheet of another Example. The perspective view of the electromagnetic wave shield sheet of another Example.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Electromagnetic shielding apron, 3, 3a, 3b ... Electromagnetic shielding sheet, 4, 9 ... Cloth layer, 5 ... Copper layer, 7 ... Aluminum layer, G1, G2 ... Magnetic field

Claims (4)

An electromagnetic wave shielding sheet that blocks electromagnetic waves and protects an object to be protected from electromagnetic waves, and is formed of a copper material or an iron material to absorb electromagnetic waves,
With an electromagnetic wave blocking layer that blocks electromagnetic waves formed of an aluminum material,
An electromagnetic wave shielding sheet in which the electromagnetic wave shielding layer is disposed closer to the protection target than the electromagnetic wave absorbing layer. The electromagnetic wave shielding sheet according to claim 1, wherein the electromagnetic wave absorbing layer is formed to a thickness of 10 microns or more. The electromagnetic wave shielding sheet according to claim 1 or 2, wherein the electromagnetic wave shielding layer is formed to a thickness of about 7 microns or more. An electromagnetic wave shielding garment formed by superposing and arranging the electromagnetic wave shielding sheet according to claim 1, 2 or 3 on a cloth.

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