TW201711853A - Anti-electromagnetic film - Google Patents

Abstract

The invention relates to an anti-electromagnetic film. Primarily, a film is combined with an electromagnetic protective layer and a heat insulating layer sequentially. Thereby when the invention is implemented, the anti-electromagnetic film is adhered to a window of a building or an automobile, and illumination and radiant heat energy of sunlight can be blocked outside the building or the automobile by the heat insulating layer. Furthermore, electromagnetic wave of sunlight passes through the heat insulating layer can be blocked and absorbed by the electromagnetic protective layer. Accordingly, it can efficiently prevent electromagnetic wave of sunlight from entering into a building or an automobile through a window to cause damage to human bodies indoors or in the automobile.

Description

Anti-electromagnetic wave film

The invention relates to an anti-electromagnetic wave film, in particular to an anti-electromagnetic wave film which can block sunlight light and radiant heat energy and block and absorb solar electromagnetic waves.

According to the paper, the insulation paper is widely used in windows such as automobiles and buildings. The main purpose of the insulation paper is to block the sunlight and radiant heat from entering the building or the car to reduce the room temperature or the temperature inside the vehicle. The discomfort caused by the glare of the sun.

The main function of the existing heat insulation paper is only to block the sunlight and the radiant heat energy effect; however, the ultraviolet light and the visible light in the sunlight contain electromagnetic waves harmful to the human body, such as: the electromagnetic wave wavelength of visible light is about 0.4 to 0.76 μm, and the ultraviolet light The electromagnetic wave has a wavelength of about 0.2 to 0.4 μm. The shorter the electromagnetic wave of the shorter wavelength, the higher the electromagnetic wave energy level, and the higher the damage and destructiveness to the human cells. Even if the existing thermal insulation paper can block the sunlight and radiant heat, However, it does not prevent the electromagnetic waves contained in the sunlight from penetrating the insulation paper and entering the building or the car through windows such as buildings or cars, causing damage to people indoors or inside the car.

According to medical reports, long-term exposure to higher than the standard value of electromagnetic waves, it is easy to feel physical fatigue, eye fatigue, shoulder pain, headache, etc., and even more can cause immune function decline, leukemia, tumors, etc., therefore, how to block The electromagnetic waves contained in the sunlight, which cause damage to people indoors or in the car by means of windows of buildings or automobiles, are an important issue in the lives of modern people.

The reason is that the present inventors have in view of the fact that the existing heat insulating paper only has the effect of blocking the sunlight and the radiant heat energy, but cannot block the electromagnetic waves contained in the sunlight from penetrating through the heat insulating paper, and entering the room or the interior of the building or the window of the automobile. The lack of harm to the human body is based on its many years of manufacturing and design experience and knowledge in related fields, and through various ingenuity, research and development of the present invention.

The invention relates to an anti-electromagnetic wave film, the main purpose of which is to provide an anti-electromagnetic wave film which can block sunlight light and radiant heat energy and block and absorb solar electromagnetic waves.

In order to achieve the above-mentioned object, the present inventors have developed the following anti-electromagnetic wave film based on the "anti-electromagnetic particle material" patent of the above-mentioned publication No. I401701, which is mainly provided with a film material and is used in the film material. An electromagnetic wave protection layer is combined thereon; wherein:

The film is selected from the group consisting of polyethylene terephthalate, polycarbonate, polymethyl methacrylate and polyethylene naphthenate; at least one polymer;

The electromagnetic wave protection layer comprises an irregular shaped electrical conductor, a particulate electromagnetic wave absorber and an adhesive. The irregular shaped conductive system is mainly tubular or fibrous, and the irregular shaped electrical conductors are connected to each other to form a tail and a tail. The interlaced network structure, the irregular shape conductive system is mainly one or a combination of a carbon-based material and a conductive-based material, and the particulate electromagnetic wave absorber is mainly a metal oxide powder, a magnetic powder and a natural mineral material. One or a combination thereof, the adhesive is one of a natural resin and a synthetic resin, and the plurality of irregular-shaped conductors, the particulate electromagnetic wave absorber and the adhesive are uniformly mixed to be coated and bonded to the film.

The anti-electromagnetic wave film as described above, wherein the irregular-shaped electric conductor is selected from the group consisting of graphite, carbon nanotubes, carbon spheres, carbon fibers, carbonaceous carbon chips, preparation carbon, activated carbon, bamboo charcoal and conductive metals. One of the filaments or a combination thereof.

The anti-electromagnetic wave film as described above, wherein the material of the particulate electrical conductor is selected from one or a combination of a carbon-based material and a conductive metal material, the carbon-based material comprising conductive carbon, graphite, activated carbon, and charcoal , carbon sixty and bamboo charcoal, and the conductive metal material comprises gold, silver, copper, iron, pig iron, aluminum, nickel, tin, pure bismuth and bismuth iron.

An anti-electromagnetic wave film as described above, wherein the material of the particulate electromagnetic wave absorber is selected from the group consisting of a metal oxide material, a magnetic metal material, a magnetic metal oxide material, and a natural mineral material, or a combination thereof. The metal oxide material comprises alumina, zinc oxide, titanium dioxide, photocatalyst material and iron oxide, and the natural mineral material comprises cement, clay, clay, calcium carbonate and metal ore.

The anti-electromagnetic wave film as described above, wherein the anti-electromagnetic wave film system further comprises a heat insulating layer comprising heat-insulating particles and an adhesive, the heat-insulating particle system being mainly nano-indium tin oxide, composite One or a combination of nano tungsten oxide, nano bismuth tin oxide, nano pentaboride, nano carbon black and lithium tin fluoride oxide, the adhesive is one of natural resin and synthetic resin The plurality of insulating particles are uniformly mixed with the adhesive to be coated and bonded to the electromagnetic wave protection layer.

Therefore, when the anti-electromagnetic wave film of the present invention is adhered to a building or a window of a vehicle, the heat-insulating layer can block the sunlight and the radiant heat energy, and penetrate the heat insulation. The layer of solar electromagnetic waves can be further blocked and absorbed by the electromagnetic wave protection layer, thereby achieving damage to the indoor or car body caused by electromagnetic waves that effectively prevent sunlight from entering the building or the car through the window.

In order to make the technical means of the present invention and the effects thereof can be more completely and clearly disclosed, the following is a detailed description. Please refer to the disclosed drawings and drawings:

First, referring to the first figure, the anti-electromagnetic wave film (A) of the present invention is mainly provided with a film material (1), and an electromagnetic wave protection layer (2) is sequentially bonded to the film material (1). And insulation (3); where:

The film (1) is selected from the group consisting of polyethylene terephthalate [PET], polycarbonate [PC], polymethyl methacrylate [PMMA], and polyethylene naphthenate [PEN] And at least one polymer of the group;

The electromagnetic wave shielding layer (2) comprises an irregular shaped electrical conductor (21), a particulate electromagnetic wave absorber (22) and an adhesive (23), and the plurality of irregular shaped electrical conductors (21) are mainly tubular or fibrous. Equipotentially, and interconnecting the plurality of irregular shaped electrical conductors (21) with each other to form an interlaced mesh structure to increase the conductive path, improve its conductivity, and block and shield electromagnetic waves, etc., and the irregularity The shape conductor (21) may be selected from carbon materials such as graphite, carbon nanotubes, carbon spheres, carbon fiber materials, and fibrous nano carbon chips, prepared carbon, activated carbon, and bamboo charcoal. Or one of or a combination of various conductive materials such as a conductive wire; and the particulate electromagnetic wave absorber (22) is a medium having a high electromagnetic wave reflection loss rate, mainly absorbing electromagnetic waves and causing electromagnetic waves to shuttle therebetween Produces phenomena such as impedance, magnetism, resonance, dielectric loss, etc., and converts electromagnetic wave energy into heat energy, and the particulate electromagnetic wave absorber ( 2) The material selected may be a metal oxide powder such as alumina, zinc oxide, copper oxide, titanium dioxide, triiron tetroxide, photocatalyst material or metal oxide material such as iron oxide, or magnetic powder, for example: Magnetic metal powder [eg bismuth, bismuth alloy, etc.], and magnetic metal oxide materials [eg ferrite magnets], or natural mineral materials such as cement powder, clay, clay, carbonated Calcium, or one or a combination of metal ores (such as tourmaline, medical stone, quartz, crystal, mica, etc.) containing cerium, iron, aluminum, nickel, carbon, magnesium, manganese, chromium minerals, etc.; The adhesive (23) is one selected from the group consisting of a natural resin and a synthetic resin, and the plurality of irregular-shaped conductors (21) and the particulate electromagnetic wave absorber (22) are uniformly mixed in the adhesive (23) to be coated. Bonded to the membrane (1);

The heat insulating layer (3) comprises heat insulating particles (31) and an adhesive (32), and the heat insulating particles (31) may be nano indium tin oxide [ITO] or composite nano tungsten oxide [WO3] 〕, nano bismuth tin oxide [ATO], nano borohydride lanthanum [LaB6], nano carbon black and lithium fluoride tin oxide [LiFTO], or a combination thereof; another adhesive (32 It is selected from one of a natural resin and a synthetic resin, and the plurality of heat insulating particles (31) and the adhesive (32) are uniformly mixed to be coated and bonded to the electromagnetic wave protective layer (2).

Accordingly, when the application is carried out, the anti-electromagnetic wave film (A) of the present invention can be adhered to the window of a vehicle such as a building (B) or a car (C), as shown in the second and third figures. By the heat insulation layer (3) of the present invention, the sunlight and the radiant heat energy of the sunlight can be blocked to reduce the high temperature of the solar radiant heat and the glare of the sunlight to the building (B) or the automobile (C). The user feels uncomfortable, and when the electromagnetic wave contained in the sunlight passes through the heat insulating layer (3) to the electromagnetic wave protective layer (2), the electromagnetic wave protective layer (2) and the irregularly shaped electric conductor (21) are mutually By connecting the intertwined dense and irregular mesh-shaped conductive channels, the electromagnetic waves of the sunlight can be blocked and shielded. In addition, the solar electromagnetic waves blocked and shielded will form a mesh-like conductive shape in the irregular shaped electrical conductors (21). A phenomenon of reflection, diffraction, and creep between the channels, followed by mixing of the particulate electromagnetic wave absorber (22) interposed between the irregularly shaped conductors (21) The electromagnetic wave reflected, diffracted and crawled between the mesh-shaped conductive channels formed by the irregular-shaped conductor (21) is absorbed, and the electromagnetic wave absorber (22) has a characteristic of high electromagnetic wave reflection loss rate, so that the sun can be made When the electromagnetic electromagnetic wave travels through the particulate electromagnetic wave absorber (22), phenomena such as impedance, magnetism, resonance, and dielectric loss are generated to convert the solar electromagnetic wave energy consumption into heat energy, thereby eliminating the solar electromagnetic wave and preventing the solar electromagnetic wave from passing through. A window of a vehicle such as a building (B) or a car (C) enters an indoor or a car, causing damage to the interior of the user or the body of the user.

Furthermore, as shown in the fourth figure, the present invention may also be composed of an irregular shape conductor (21), a particulate electromagnetic wave absorber (22), and an adhesive (23). Further, a plurality of particulate electrical conductors (24) are further added to the electromagnetic wave shielding layer (2). The plurality of particulate electrical conductors (24) are particles having different diameters, and the particulate electrical conductors (24) may be selected from carbon-based materials, for example, various types. One or a combination of carbonaceous materials such as conductive carbon, graphite, activated carbon, carbonaceous carbon, carbon sixty, bamboo charcoal, carbon nanotubes, carbon fiber, and nanocarbon spheres, It is electrically conductive and is then ground into ultrafine particles to form a conductive particulate structure, or alternatively a conductive metal material such as gold, silver, copper, aluminum, iron, pig iron, nickel, tin, pure tantalum and One of the conductive metals such as ferroniobium or a combination thereof is formed into a granular structure, whereby the irregular-shaped conductor (21) and the particulate conductor (24) are blended and bonded to each other. Configuration, to achieve further increase in conductivity and electromagnetic wave shielding effect. In addition, as shown in the fifth figure, in another embodiment of the present invention, the present invention can also directly replace the irregular shaped electrical conductor (21) with a particulate electrical conductor (24), using a particulate electrical conductor (24). The particles have different diameters, that is, they can shield electromagnetic waves of different wavelengths, so as to effectively block and absorb electromagnetic waves of different wavelengths with the particulate electromagnetic wave absorber (22).

Referring to FIG. 6 again, in accordance with still another embodiment of the present invention, the present invention may also omit the arrangement of the heat insulating layer (3), and is formed on the film material (1) with an electromagnetic wave protection layer (2). ) The anti-electromagnetic wave film (A1), by which, as shown in the seventh and eighth figures, the anti-electromagnetic wave film (A1) can be attached to the mobile phone (D), the notebook computer (E), and the table. On the screen of 3C products such as a computer or tablet, to prevent the mobile phone or tablet from being damaged by the electromagnetic waves emitted during use. Please also refer to the ninth figure, which is another embodiment of the anti-electromagnetic wave film (A2) of the present invention. The present invention can directly add the heat insulating particles (31) into the electromagnetic wave protection layer (2) to The irregular shape conductor (21), the particulate electromagnetic wave absorber (22) and the adhesive (23) constituting the electromagnetic wave protection layer (2) are mixed to achieve electromagnetic insulation (2) having heat insulation for reducing solar radiation heat energy. The effect, or the present invention, may also directly add the heat insulating particles (31) to the irregular shaped electrical conductor (21), the particulate electromagnetic wave absorber (22), the particulate electrical conductor (24), and the electromagnetic wave protective layer (2). The adhesive (23) is mixed with the same, or the heat insulating particles (31) and the particulate conductive body (24) constituting the electromagnetic wave protective layer (2), the particulate electromagnetic wave absorber (22), and the adhesive (23) Mixing, etc., where appropriate changes or modifications are made by those of ordinary skill in the art, and should be considered as not deviating from the anti-electromagnetic wave film of the present invention. Lee category.

As can be seen from the above structures and embodiments, the present invention has the following advantages:

1. The anti-electromagnetic wave film of the present invention is bonded to the film with an electromagnetic wave protection layer and a heat insulating layer, whereby when the invention is adhered to a building or a window of a car, the heat insulating layer can be used for sunlight. The light and radiant heat can be blocked, and the solar electromagnetic wave penetrating through the heat insulation layer can be blocked and absorbed by the electromagnetic wave protection layer. According to this, the electromagnetic wave of sunlight can be effectively prevented from entering the building or the car through the window, and Injury caused by the human body inside or inside the car.

2. The anti-electromagnetic wave film of the present invention can further omit the heat insulating layer to form a film having blocking and absorbing electromagnetic waves, thereby effectively preventing the mobile phone or tablet when applied to a 3C product such as a mobile phone or a tablet computer. It is equal to the damage caused by electromagnetic waves emitted during use.

In summary, the embodiments of the present invention can achieve the expected functions, and the specific structures disclosed therein have not been seen in the same products, nor have they been disclosed before the application, and have fully complied with the provisions of the Patent Law. It is required that if an application for a patent for invention is filed in accordance with the law, and if the application is granted, the patent will be granted.

(1) ‧‧‧membrane

(2) ‧ ‧ electromagnetic wave protection layer

(21)‧‧‧ Irregular shape conductors

(22) ‧‧‧Particle electromagnetic wave absorbers

(23) ‧‧‧Adhesives

(24) ‧‧‧Particle conductors

(3) ‧‧‧Insulation

(31)‧‧‧Insulation particles

(32) ‧‧‧Adhesives

(A) ‧ ‧ anti-electromagnetic film

(A1) ‧ ‧ anti-electromagnetic film

(A2) ‧ ‧ anti-electromagnetic film

(B) ‧ ‧ buildings

(C) ‧ ‧ cars

(D) ‧‧‧Mobile phones

(E)‧‧‧Note Computer

First Figure: Cutaway view of the present invention

Second figure: the state diagram of the invention applied to the window of a building

Third figure: the state diagram of the invention applied to the window of a car

Fourth drawing: a cross-sectional view of a second embodiment of the present invention

Figure 5 is a cross-sectional view showing still another embodiment of the present invention

Figure 6 is a cross-sectional view showing still another embodiment of the present invention

Figure 7: Still another embodiment of the present invention is applied to a mobile phone screen state diagram

Figure 8: Still another embodiment of the present invention is applied to a notebook computer screen state diagram

Ninth view: cross-sectional view of another embodiment of the present invention

(1) ‧‧‧membrane

(2) ‧ ‧ electromagnetic wave protection layer

(21)‧‧‧ Irregular shape conductors

(22) ‧‧‧Particle electromagnetic wave absorbers

(23) ‧‧‧Adhesives

(3) ‧‧‧Insulation

(31)‧‧‧Insulation particles

(32) ‧‧‧Adhesives

(A) ‧ ‧ anti-electromagnetic film

Claims (10)

An anti-electromagnetic wave film is mainly provided with a membrane material, and an electromagnetic wave protection layer is combined on the membrane material; wherein: the membrane material is selected from the group consisting of polyethylene terephthalate, polycarbonate, polymethyl At least one polymer composed of a group consisting of methyl acrylate and polyethylene naphthenate; the electromagnetic wave protection layer comprising an irregular shaped electrical conductor, a particulate electromagnetic wave absorber and an adhesive, the irregularly shaped conductive system is mainly tubular Or fibrous, and the irregularly shaped electrical conductors are connected to each other at the head and tail to form an interwoven network structure, the irregularly shaped conductive system is mainly one or a combination of a carbon-based material and a conductive-based material, and the particulate electromagnetic wave The absorber is mainly one of or a combination of a metal oxide powder, a magnetic powder and a natural mineral material, and the adhesive is one of a natural resin and a synthetic resin, and the plurality of irregular shaped conductors and particles are The electromagnetic wave absorber is uniformly mixed with the adhesive to be coated and bonded to the film. The anti-electromagnetic wave film of claim 1, wherein the electromagnetic wave protection layer further comprises a plurality of particulate electrical conductors, wherein the particulate conductive system is mainly one of a carbon-based material and a conductive-based material or a combination thereof, and The plurality of irregular-shaped conductors, the particulate electromagnetic wave absorber, and the adhesive are uniformly mixed and coated and bonded to the film. An anti-electromagnetic wave film is mainly provided with a membrane material, and an electromagnetic wave protection layer is combined on the membrane material; wherein: the membrane material is selected from the group consisting of polyethylene terephthalate, polycarbonate, polymethyl At least one polymer of a group consisting of methyl acrylate and polyethylene naphthenate; the electromagnetic wave protection layer comprising an irregular shape conductor, a particulate electromagnetic wave absorber, a heat insulating particle and an adhesive, the irregular shape conductive The system is mainly tubular or fibrous, and the irregular shaped electrical conductors are connected to each other to form an interwoven network structure, and the irregular shaped conductive system is mainly one of carbonaceous materials and conductive materials, or a combination thereof. The particulate electromagnetic wave absorber is mainly one of or a combination of a metal oxide powder, a magnetic powder and a natural mineral material, and the heat insulating particle is mainly a nano indium tin oxide, a composite nano tungsten oxide, and a naphthalene. One or a combination of rice bran oxide, nano-barium borohydride, nano-carbon black and lithium tin fluoride oxide, the adhesive is one of natural resin and synthetic resin, A plurality of irregularly shaped conductor, an electromagnetic wave absorber particles, insulating particles are uniformly mixed with the adhesive agent, a coating bonded to the membrane. The anti-electromagnetic wave film according to claim 3, wherein the electromagnetic wave protection layer further comprises a plurality of particulate electrical conductors, wherein the particulate conductive system is mainly one of a carbon-based material and a conductive-based material or a combination thereof, and The plurality of irregular-shaped conductors, the particulate electromagnetic wave absorber, the heat-insulating particles, and the adhesive are uniformly mixed and applied to the film. An anti-electromagnetic wave film is mainly provided with a membrane material, and an electromagnetic wave protection layer is combined on the membrane material; wherein: the membrane material is selected from the group consisting of polyethylene terephthalate, polycarbonate, polymethyl At least one polymer of a group consisting of methyl acrylate or polyethylene naphthenate; the electromagnetic wave protection layer comprising a particulate electrical conductor, a particulate electromagnetic wave absorber and an adhesive, the conductive system of the particulate is mainly a carbon-based material and conductive One or a combination of the materials, the particulate electromagnetic wave absorber is mainly one of or a combination of a metal oxide powder, a magnetic powder and a natural mineral material, and the adhesive is one of a natural resin and a synthetic resin. The plurality of fine particle conductors and the particulate electromagnetic wave absorber are uniformly mixed with the adhesive to be applied and bonded to the film. An anti-electromagnetic wave film is mainly provided with a membrane material, and an electromagnetic wave protection layer is combined on the membrane material; wherein: the membrane material is selected from the group consisting of polyethylene terephthalate, polycarbonate, polymethyl At least one polymer of a group consisting of methyl acrylate or polyethylene naphthenate; the electromagnetic wave protection layer comprising a particulate electrical conductor, a particulate electromagnetic wave absorber, a heat insulating particle and an adhesive, the conductive system of the particle is mainly carbon One or a combination of a material and a conductive material, the particulate electromagnetic wave absorber is mainly one of or a combination of a metal oxide powder, a magnetic powder and a natural mineral material, and the insulating particle system is mainly nano indium. One or a combination of tin oxide, composite nano tungsten oxide, nano bismuth tin oxide, nano lanthanum hexaboride, nano carbon black and lithium tin fluoride oxide, the adhesive is a natural resin and One of the synthetic resins is obtained by uniformly mixing the plurality of fine particle conductors, the particulate electromagnetic wave absorber, and the heat insulating particles with the adhesive to be applied to the film. The anti-electromagnetic wave film of claim 2, 4, 5 or 6 wherein the material of the particulate electrical conductor is selected from one or a combination of a carbon-based material and a conductive metal material, the carbon-based material system The conductive metal material comprises gold, silver, copper, iron, pig iron, aluminum, nickel, tin, pure bismuth and strontium iron, and comprises conductive carbon, graphite, activated carbon, carbon preparation carbon, carbon sixty and bamboo charcoal. The anti-electromagnetic wave film according to any one of claims 1 to 6, wherein the particulate electromagnetic wave absorber is made of a metal oxide material, a magnetic metal material, a magnetic metal oxide material, and One or a combination of natural mineral materials comprising alumina, zinc oxide, titanium dioxide, photocatalyst materials and iron oxides, and the natural mineral material comprises cement, clay, clay, calcium carbonate and metal ore. . The anti-electromagnetic wave film of claim 1, wherein the anti-electromagnetic wave film is further provided with a heat insulating layer comprising heat-insulating particles and an adhesive, the heat-insulating particle system being mainly The adhesive system is one of or a combination of nano indium tin oxide, composite nano tungsten oxide, nano bismuth tin oxide, lanthanum hexaboride, nano carbon black and lithium tin fluoride oxide. It is one of a natural resin and a synthetic resin, and the plurality of heat insulating particles are uniformly mixed with the adhesive to be applied and bonded to the electromagnetic wave protective layer. The anti-electromagnetic wave film according to any one of claims 1 to 4, wherein the irregular-shaped electric conductor is made of a material selected from the group consisting of graphite, carbon nanotubes, carbon spheres, carbon fibers, and carbon carbide. , one of or a combination of carbon, activated carbon, bamboo charcoal and conductive metal wire.