KR20010093434A - Electromagnetic shielding device including a pin pointed metal sheet and soft-ferrite alloy oxides - Google Patents

Abstract

PURPOSE: An electromagnetic wave attenuation device is provided to attenuate intensity of the electromagnetic wave by shielding the electromagnetic wave radiating directly from the electromagnetic wave source to a user, and forming an induced magnetic field in surface direction of the device. CONSTITUTION: An electromagnetic wave attenuation device(10) comprises a pair of metal foils(12,14) having a plurality of through holes(12a,14a); an electromagnetic wave absorbing layer(16) inserted between metal foils, and which is made up of a soft magnetic material alloy oxide constituting a conductive polymer base; and a pair of insulation coating layers(18,20) coating outer surfaces of metal foils, respectively. Each of metal foils has a thickness of 10 to 200 μm, and is made up of such metals as copper, nickel, iron or alloy thereof manufactured by an electro-plating or cold rolling method.

Description

Electromagnetic shielding device including a pin pointed metal sheet and soft-ferrite alloy oxides

The present invention relates to an apparatus for attenuating the intensity by shielding or absorbing electromagnetic waves traveling from one point of space to another.

Conventional methods of attenuating radial electromagnetic waves traveling through space include two methods of shielding and absorption.

The shielding of electromagnetic waves refers to blocking the progress of electromagnetic waves by blocking them using a metal plate or a metal mesh net having excellent electrical conductivity. When the traveling electromagnetic wave is shielded with a metal plate or the like, most of the electromagnetic waves are reflected from the surface of the metal and scattered to another place. When the thickness of the plate is thin, some of the electromagnetic waves are transmitted to continue in the advancing direction. At this time, the minute eddy current induced by the electromagnetic waves propagating on the surface of the metal is generated. Absorption of electromagnetic waves refers to absorption of a part of electromagnetic waves by using a powder of a soft magnetic material easily magnetized by electromagnetic waves traveling through a space, a sintered body or an enclosure such as an electric dipole powder or a liquid which may have a magnetic moment, and the like.

Examples of shielding include electroless copper or nickel plating on the inner surfaces of steel cases and plastic cases of electronic devices such as computers, and the use of copper mesh as a coating material for coaxial wires. .

Examples of absorption include the impregnation of soft magnetic powder in a non-conductive polymer such as electromagnetic wave absorbing paint, and the soft magnetic powder is magnetized by electromagnetic waves, which weakens the strength of electromagnetic waves as much as the energy is used to magnetize or vibrate them. It is mentioned to absorb the.

In this conventional method, these materials had to have sufficient thickness in order to block or absorb electromagnetic waves. Especially, the shielding effect using thin metal plate is not electrically grounded, and the shielding effect is greatly reduced when insulated. Although it is shielded from linear radiation, conduction by refraction does not shield, and thus it is insufficient for use in portable electronic devices.

A wireless communication device such as a portable mobile communication device is a device that communicates by generating and radiating electromagnetic waves for communication, and partially shields only microwaves generated inside the device except for major sources such as antennas for communication. have.

As a method for reducing the user's exposure to electromagnetic waves by improving this, a method of shielding or absorbing electromagnetic waves radiated into a space on the user's side from an external source such as an inside of a communication device or an antenna should be provided and attenuated. . In this case, the shielding material is located only on one side of the user from the source of the device, and can prevent the progress of electromagnetic waves radiating linearly from the source to the user, but does not prevent the progress of electromagnetic waves due to refraction due to the characteristics of the electromagnetic waves.

Therefore, in order to reduce the exposure of the electromagnetic waves of the user more efficiently from the electromagnetic waves generated by the electromagnetic wave source used in close contact with the human body such as a portable mobile communication device, the intensity is attenuated by shielding or absorbing the electromagnetic wave linearly traveling from the source to the user side. At the same time, these shielding materials must be bypassed to reduce the scattering of electromagnetic waves that are refracted from the source to the user.

In the present invention, the electromagnetic wave generated in an environment in which it is difficult to use a thick metal plate or a grounded metal plate as a shielding material as described above, that is, a portable mobile communication device or other electronic device, is radiated and conducted to the user side using the device. The present invention relates to a device for shielding or absorbing an object, and to providing a device for effectively shielding or absorbing electromagnetic waves even when not electrically grounded.

1 is a laminated cross-sectional view of an electromagnetic wave damping apparatus using a microperforated metal sheet and a soft magnetic alloy oxide according to the present invention.

Figure 2 is a graph measuring the degree of electromagnetic wave attenuation of the electromagnetic wave damping device according to the present invention.

Figure 3 is a conceptual diagram for explaining the principle that the eddy current is induced by the electromagnetic wave on the microperforated metal sheet used in the present invention.

Figure 4 is a cross-sectional view of the electromagnetic wave damping device showing another embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

10: electromagnetic wave damping device 12, 14: metal sheet

12a, 14a: Multiple through holes 16: Electromagnetic wave absorber layer

18, 20: insulation coating layer

The present invention provides a composite material for shielding the electromagnetic wave propagating from the source of the electromagnetic wave to the user side to shield the electromagnetic wave radiated linearly and at the same time to form a planar induction magnetic field of the material by the soft magnetic alloy powder contained in the composite material It is to provide a device for attenuating the intensity of electromagnetic waves that are refracted by reaching the user side.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

(Example 1)

As shown in FIG. 1, the electromagnetic wave attenuation device 10 of the first embodiment includes a pair of metal thin plates 12 and 14 and a pair of metal thin plates, respectively, having a plurality of minute through holes 12a and 14a. A pair of insulating coating layers each covering the outer surface of the pair of thin metal plates 12 and 14 and the electromagnetic wave absorber layer 16 of the soft magnetic material interposed between the conductive polymer matrix and 18, 20). The metal thin plates 12 and 14 have a thickness of 10 to 200 μm, and are made of thin plates of copper, nickel, iron, or alloys of these metals produced by electroplating and cold rolling. The metal thin plates 12 and 14 having the through holes 12a and 14a are nickel thin plates having a thickness of 20 μm. The metal thin plates 12 and 14 have a plurality of circular through holes 12a and 14a regularly arranged in the horizontal and vertical directions, and the circular through holes have a diameter of 20 to 500 μm, The ratio between the long axis and the short axis is within 1.2, and the distance between the nearest through hole centers is 1.5 to 20 times the diameter of the circular through hole, and the distance between the centers in the same plate of the metal sheet is within 2 times the deviation of the through hole. Has In the first embodiment, circular holes having a diameter of 50 µm are arranged in the metal thin plates 12 and 14 at 135 meshes (135 holes per 1 inch length) in the horizontal direction and the vertical direction. In addition, the electromagnetic wave absorber layer 16 has a thin plate-like soft magnetic alloy having a side of 10 to 300 μm and a thickness of about 10 μm or less in a conductive polymer having a thickness of about 30 μm between the pair of metal thin plates 12 and 14. Oxides are made by combining. The electromagnetic wave attenuation device 10 has a function of shielding and absorbing radiation of linear electromagnetic waves, and simultaneously attenuating electromagnetic waves that are refracted and proceed to the user side.

In order to provide an electrically insulated device in the environment of use, a pair of insulating coating layers 18, 20 are arranged on each outer surface of the pair of thin metal plates 12,14. The insulating coating layers 18 and 20 are preferably insulating polymer layers, each having a thickness of about 40 mu m.

Fig. 2 shows the electromagnetic wave shielding characteristics of the device provided by Embodiment 1 of the invention, specifically the characteristics of the device manufactured according to the above-described standard. The measurement measured the degree of shielding the linear propagation of electromagnetic waves, varying the frequency from 30 MHz (Mega Hertz) to 1000 MHz. According to this experiment, the device of the present invention is characterized by having a very constant shielding degree without changing according to the frequency change compared to other conventional materials, and as shown in FIG. Attenuation effect of about dB, that is, attenuation of the intensity of the initial electromagnetic wave to about 0.8 × 10 ^-6 was obtained.

Hereinafter, the electromagnetic shielding effect of the electromagnetic wave damping device provided by the first embodiment in comparison with the conventional electromagnetic shielding material.

In order to shield electromagnetic waves that radiate linearly from the source of electromagnetic waves to the user side, conventionally, a metal plate having good electrical conductivity or a metal mesh having a net shape is used. In the present Example 1, it has a metal plate shape macroscopically, but microscopically, a metal material having excellent electrical conductivity in which a plurality of fine through holes penetrated in the thickness direction is arranged as a rule is used as a shielding material.

In the case of shielding electromagnetic radiation that radiates linearly using a thin sheet of metal, electromagnetic waves are mostly reflected from the surface of the thin metal sheet and thus do not penetrate, and surface eddy currents induced by the electromagnetic field are generated on the surface of the thin metal sheet. At this time, when the circular through holes 12a and 14a having a diameter of 20 to 500 µm are regularly drilled on the surfaces of the metal thin plates 12 and 14, the metal thin plates 12 and 14 are formed. At the same time, a portion of the through-holes and through-holes of the thin metal plate is reflected, while at the same time, a portion of the through-holes and the through-holes is thinly penetrated through the metal surface of the through-holes as shown in FIG. It is well known that In addition, some of the electromagnetic waves passing through the through-holes lose their energy due to the phase difference attenuation caused by the multiple-generation source having each through-hole as the secondary source.

Apparatus for absorbing and removing electromagnetic waves by using powder of soft magnetic material is based on the progression of electromagnetic waves to lose energy while magnetizing the magnetic material. It is bent in the direction of the magnetic field formed by the aggregate of to show the result of changing the direction according to the strength of the magnetic field.

In Example 1, a composite material obtained by adhering a powder of a soft magnetic alloy magnetized by absorbing a part of electromagnetic waves to a surface of a finely perforated thin plate is applied so that electromagnetic waves traveling through a space are first finely perforated. Secondly, the surface of the magnetic material is reflected from the surface of the thin metal plate, and secondly, a part of the energy of the electromagnetic wave is absorbed by the energy that magnetizes the soft magnetic material, and thirdly, the magnetic surface is refracted from the source to the user by the magnetized direction. The curvature in the direction parallel to the direction to prevent progression to the user side, and the fourth component to be magnetized according to the magnetic component and magnetic wave propagation direction to magnetize the soft magnetic material by eddy currents formed independently on the surface of the finely perforated metal sheet. Softening due to the increase of magnetic domain deflection in the magnetic body due to the difference in the magnetization direction of the liver It provides a way to increase the damping effect by increasing the energy to magnetize the adult.

(Example 2)

As shown in FIG. 4, the electromagnetic wave damping device 40 of the second embodiment has a metal thin plate 42 having a plurality of minute through holes 42a and a conductive polymer matrix arranged on the surface of the metal thin plate 42. It includes a metal oxide 44 of the soft magnetic material incorporated in. Here, the through hole 32a is a circular hole having a diameter of 20 to 500 μm, and a plurality of through holes 42a are regularly or irregularly drilled in the metal thin plate 42, and are preferably regularly drilled.

The electromagnetic wave attenuation device 40 has a function of shielding and absorbing the radiation of linear electromagnetic waves and simultaneously attenuating electromagnetic waves that are refracted and proceed to the user side. In order to provide an electrically insulated device in the use environment, a pair of insulating coating layers 46 and 48 are arranged around each outer surface of the metal thin plate 42 and the electromagnetic wave absorber layer 44.

Also in Embodiment 2, an electromagnetic wave attenuation device having a function of shielding and absorbing electromagnetic waves can be provided on a principle similar to that of Embodiment 1. FIG.

(Example 3)

In Example 3, instead of the conductive polymer matrix having the soft magnetic alloy oxide in Examples 1 and 2, an alloy oxide having a constant composition is used. The alloy oxide is preferably an oxide of (iron-chromium-nickel-manganese). The other components are the same as in the first and second embodiments.

(Example 4)

In Embodiment 4, in Embodiments 1, 2, and 3, elements other than the external insulating coating layer are repeatedly formed two to four times, and the upper and lower insulating coating layers are covered on the outside.

According to the present invention, there is provided a electromagnetic wave damping device comprising a finely penetrated metal sheet and soft magnetic alloy oxide powder, or a metal oxide having a certain chemical composition, which is described by the above four mechanisms, and moves in close contact with the human body. In electronic devices such as communication devices, electromagnetic waves radiating linearly from the source of electromagnetic waves to the user side can be shielded, and at the same time, the strength of electromagnetic waves that are refracted and reach the user side can be attenuated by forming a field induction magnetic field.

Claims (10)

Metal foil having a plurality of fine through holes; And an electromagnetic wave absorber layer in close contact with the surface of the metal thin plate, the electromagnetic wave absorber layer including a conductive polymer matrix in which a soft magnetic alloy oxide and the soft magnetic alloy oxide powder are combined. The electromagnetic wave damping device according to claim 1, wherein an insulating coating layer is additionally arranged on outer surfaces of the thin metal plate and the electromagnetic wave absorber layer. 2. The shielding and absorbing function of electromagnetic waves according to claim 1, wherein the metal sheet has a thickness of 10 to 200 µm and is a sheet of copper, nickel, iron, or an alloy of these metals produced by electroplating and cold rolling. Electromagnetic wave damping device having a. According to claim 3, wherein the metal sheet is a plurality of circular through holes are arranged regularly arranged in the horizontal and vertical direction, the circular through holes have a diameter of 20 to 500㎛, the long axis of the circular through holes The ratio of the short axis is within 1.2, and the distance between the centers of the nearest through holes is 1.5 to 20 times the diameter of the circular through holes, and the distance between the centers in the same plate of the metal sheet is less than twice the through holes. Electromagnetic wave damping device having a function of shielding and absorbing electromagnetic waves, characterized in that the deviation. Electromagnetic wave damping device having a function of shielding and absorbing electromagnetic waves comprising a micro-perforated metal sheet and an electromagnetic wave absorber layer in close contact with the surface of the metal sheet and made of a composition of an alloy oxide having a constant alloy composition. It has a function of shielding and absorbing electromagnetic waves, including an electromagnetic wave absorber layer comprising a microperforated metal sheet, an alloy oxide having a constant alloy composition and an electrically conductive polymer base in which the alloy oxide is bonded to the surface of the metal sheet. Electromagnetic attenuation device. The electromagnetic wave attenuation apparatus having a shielding and absorption function of electromagnetic waves according to claim 5 or 6, wherein the alloy oxide is an oxide of (iron-chromium-nickel-manganese). 7. The shielding and absorption function of electromagnetic waves according to claim 1, 5 or 6, wherein the microperforated metal sheet and the electromagnetic wave absorber layer are repeatedly laminated two to four times, respectively. Having electromagnetic wave damping device. 7. The shielding and absorption function of electromagnetic waves according to claim 1, 5 or 6, further comprising an electrically insulating layer on each of the outer surfaces of the microperforated metal sheet and the electromagnetic wave absorber layer. Electromagnetic wave damping device having a. An electromagnetic wave absorber layer comprising a conductive polymer matrix in which a soft magnetic alloy oxide and the soft magnetic alloy oxide powder are combined; And a pair of metal thin plates having a plurality of fine through-holes in close contact with upper and lower surfaces of the electromagnetic wave absorber layer.