CN200988842Y - Anti-electromagnetic wave radiation leather - Google Patents

Abstract

An anti-electromagnetic wave radiation leather includes a leather body, a layer of conductive film coating is coated on the outer surface of the leather body, and an embossing pattern layer is arranged on the conductive film coating. The utility model utilizes the organic conductive film coating with transparency and good conductivity on the leather surface to improve the surface conductance of the leather material. The leather material contains a large number of polarization mechanisms such as electrons, ion groups, dipoles, and internal interfaces. When the electromagnetic wave irradiates the inside of the leather, it will produce electron displacement polarization, ion displacement polarization, dipole steering polarization, and space charge polarization, making the leather material an electromagnetic wave absorbing layer; pressing a specific pattern on the leather surface to make the incident electromagnetic wave pass through Diffuse reflection occurs when the leather material reflects. Since the leather material is a porous material, compared with ordinary materials, more electromagnetic waves will reach the interior of the leather material, so that the above mechanisms can work simultaneously to achieve the purpose of resisting electromagnetic radiation and protecting human health.

Description

A kind of anti-electromagnetic wave radiation leather

technical field

The utility model relates to an anti-electromagnetic wave radiation leather.

Background technique

With the development of the electronic information industry, the hazards of electromagnetic radiation have attracted widespread attention. Medical research has proved that long-term exposure to high electromagnetic radiation will cause changes in blood, lymph and cell protoplasm, and induce leukemia in children; electromagnetic radiation pollution will affect human circulatory system, immunity, reproduction and metabolism. It can induce cancer and accelerate the proliferation of cancer cells in the human body; affect the human reproductive system, mainly manifested as reduced sperm quality in men, spontaneous abortion and fetal malformation in pregnant women, etc.; affect people's cardiovascular system, manifested as palpitations, insomnia, partial Female menstrual disorder, bradycardia, decreased cardiac blood volume, sinus arrhythmia, leukopenia, decreased immune function, etc. If a patient with a pacemaker is exposed to high-voltage electromagnetic radiation, it will affect cardiac pacing The normal use of the device; because the eyes are sensitive organs of the human body to electromagnetic radiation, excessive electromagnetic radiation pollution will cause vision loss, cataracts, etc. High doses of electromagnetic radiation will also affect and destroy the original bioelectric current and biomagnetic field of the human body , so that the original electromagnetic field in the human body is abnormal. Electromagnetic radiation has become an invisible killer that endangers people's health.

Leather is a very common polymer material, which has the characteristics of light weight, low price, large area, easy processing, and mature production technology. Our research has proved that the resistivity of leather materials is within the range of semiconductors, and it is an organic high-density material. Molecular semiconductor materials. The leather material contains a large amount of electrons, ions, dipoles, internal interfaces, etc. When irradiated by electromagnetic waves, it will produce relaxation polarization loss and resonance absorption, absorb and lose a large amount of electromagnetic waves, and achieve the purpose of protecting against electromagnetic hazards.

Since 1967, when the research team led by chemist Mac Diarmid of the University of Pennsylvania first doped polyacetylene with metal-like conductivity, people's understanding of the structure and properties of conjugated polymers has gradually deepened. Conductive polymer materials have special structures and excellent physical and chemical properties, which make them have attractive application prospects in electromagnetic shielding and other aspects. The utility model uses the conductive polymer as the coating layer, absorbs and consumes a large amount of electromagnetic waves, and realizes three-dimensional protection against electromagnetic hazards.

Contents of the invention

The purpose of this utility model is to provide a light weight, high absorption, large area, low price, high mechanical strength, so that the electromagnetic waves incident into the leather material are absorbed and lost, and a small amount of electromagnetic waves are diffusely reflected by the surface. leather.

In order to achieve the above purpose, the technical solution adopted by the utility model is: comprising a leather body, a layer of conductive film coating is coated on the outer surface of the leather body, and an embossed pattern layer is arranged on the conductive film coating; the conductive film coating The thickness of the layer is polyaniline conductive polymer material on the order of microns.

The utility model utilizes the organic conductive film coating with transparent and good conductivity on the leather surface to improve the surface conductance of the leather material and generate electromagnetic waves to pass through the absorbing layer; a specific pattern can be made on the leather surface so that when the incident electromagnetic wave is reflected by the leather material Produces diffuse reflections. Since the leather material is a porous material, compared with ordinary materials, more electromagnetic waves will reach the interior of the leather material, so that the above mechanisms can work at the same time to achieve the purpose of preventing electromagnetic hazards.

Description of drawings

Fig. 1 is a schematic diagram of the overall structure of the utility model.

Detailed ways

Below in conjunction with accompanying drawing, the utility model is described in further detail.

Referring to Fig. 1, the utility model comprises a leather body 5, and the outer surface of the leather body 5 is coated with a polyaniline conductive polymer material of the order of micron to make a conductive film coating 4, and on the conductive film coating 4 An embossed pattern layer 3 is provided.

The utility model utilizes a transparent conductive film coating 4 with good conductivity on the leather surface to improve the surface conductance of the leather material and produce an infrared penetration layer and a resistive radar wave absorption layer; the conductive film coating 4 is pressed with The embossed pattern 3 makes the incident electromagnetic wave 1 produce diffuse reflection 1 when it is reflected by the leather material. Since the leather material is a porous material, compared with ordinary materials, more electromagnetic waves will reach the interior of the leather material, so that the above mechanisms can work at the same time to achieve the purpose of preventing electromagnetic hazards.

Claims (2)

1. An anti-electromagnetic wave radiation leather, comprising a leather body (5), characterized in that: the outer surface of the leather body (5) is coated with a conductive film coating (4), and the conductive film coating (4) An embossed pattern layer (3) is arranged on it. 2. The anti-electromagnetic wave radiation leather according to claim 1, characterized in that: the thickness of the conductive film coating (4) is polyaniline conductive polymer material on the order of microns.

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