KR101575972B1 - Method and device for making electric mesh heater and electric mesh heater thereof - Google Patents

Abstract

The present invention relates to a method for making an electric mesh heater. The method includes a collection process of twisting wires, a doubling and twisting yarn process of twisting glass yarn, a covering process of coating doubling and twisting yarn, a tension uniformizing process which uniformizes the tension of a collection copper wire and coating yarn, a mixture weaving process which weaves the collection copper wire and the coating yarn, a mixture fabric conduction coating and thermosetting process which performs thermosetting by coating the mixture-weaved fabric with conductive silicon rubber.

Description

TECHNICAL FIELD [0001] The present invention relates to a manufacturing method of a wire mesh, a wire mesh manufacturing apparatus,

The present invention relates to a wire netting type wire netting method in which a conductive silicone rubber is coated on woven fabrics in the form of a web weaving with a glass fiber yarn, Wherein the structure of the glass chamber is formed by a covered yarn in which a polyester fiber yarn is twisted in a glass yarn which is a core yarn and a glass yarn in which the center yarn is a plied yarn The present invention relates to an electric mesh heater.

In the conventional conductive silicone rubber heating element, the silicone rubber is excellent in low-temperature characteristics and heat-resistance characteristics, and a net-like heating element composed of silicone rubber, carbon particles and glass seal is formed.

However, the glass yarn is brittleness, and a plurality of short staples protrude from the surface of the glass yarn to coat the glass yarn with the conductive silicone rubber. Even if the glass yarn is coated with the insulating silicone rubber, Is difficult. This is because the sharp staple fibers protruding from the surface of the glass seal break the electrical insulation. This is because even if the fabric composed of the glass yarn is coated with the conductive silicone rubber to thermally cure, heat shrinkage does not occur due to brittleness of the glass yarn, and the protruding portion of the short fiber remains. In addition, there is a problem that even if the electrically insulating silicone rubber is coated, the coated cross-sectional shape of the glass chamber and the conductive silicone rubber is not uniformly coated.

The present invention relates to a method for improving the bonding strength between a glass chamber and a conductive silicone rubber at a high density by improving the flat shape of the coated cross section of the glass chamber and the conductive silicone rubber as described above to a circular shape, It is an object of the present invention to provide a conductive network in which conductive silicon rubber is coated on a spirally coated covering room in order to solve the problem that short fibers break electrical insulation.

The present invention relates to a wire netting type wire netting method in which a conductive silicone rubber is coated on woven fabrics in the form of a net made of a glass fiber yarn, Wherein the structure of the glass chamber is formed by a covered yarn in which a polyester fiber yarn is twisted in a glass yarn which is a core yarn and a glass yarn in which the center yarn is a plied yarn The present invention also provides a method of manufacturing a prereconnecting network.

Accordingly, the present invention is characterized in that the glass seal structure is constituted by a covered yarn, the protruding portions of the short fibers are removed, and a polyester yarn is twisted around the composite yarn composed of a plurality of strands to form a conductive silicone rubber And thermosetting, the polyester yarn is thermally shrunk to tighten the twist yarn as a center yarn and has the effect of concentrating the cross-sectional shape into a circular shape. The yarns are combined with each other at high density to form a glass yarn and a conductive silicone rubber It is possible to increase the thermal conductivity between the conductive silicone rubber and the conductive silicone rubber, thereby lowering hot spots due to heat storage in the conductive silicone rubber, thereby prolonging the degradation of the silicone rubber. In addition, the coating chamber has an effect of increasing the slip resistance of the slanting and slanting, thereby strengthening the structure of the transferring net. In addition, there is also an effect that the conductive path of the conductive silicone rubber coated on the coating chamber flows in a spiral shape to realize an electromagnetic effect.

1 is a cross-sectional view of a coating chamber structure according to the present invention;
FIG. 2 is a process chart of a manufacturing facility of a wire netting according to the present invention. FIG.
Fig. 3 is a view showing the covering process of the existing yarn.
4 is a view showing a covering process according to the present invention.
5 is a manufacturing process diagram of a wire netting according to the present invention.
Fig. 6 is a weaving view of a transfer nip woven in accordance with the present invention. Fig.
7 is a state diagram showing electron rotation in a conventional crystallized π-bond.

The present invention relates to a method of manufacturing an electric mesh heater, which comprises a collecting process of twisting a plurality of copper wires, a combined twisting process of twisting a plurality of glass yarns, a covering process of covering the combined twisted yarn, A mixed-weaving process of weaving with the collective copper wire and the coating chamber, a mixed-fabric conductive coating and a thermosetting process in which the mixed woven fabric is coated with conductive silicone rubber and thermally cured .

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

FIG. 1 is a cross-sectional view of a coated room structure according to the present invention. In the coated room structure, a glass yarn 11 is wound around a plied yarn, which is piled up with a plurality of strands, To form a closed compartment. The covering yarn is a synthetic fiber, and when the heat shrinkage occurs, it has an effect of tightening the center yarn.

In this embodiment, the glass yarn is a center yarn, which is an 816-tex yarn twisted with a fineness of 136 tex 6 strands made of E-glass type and 9 μm filament, and the covering yarn is made of polyester yarn 75 d / 36 f A bulky DTY (Draw Textured Yarn) is preferred.

The twist number of the combined twist yarns is preferably 90 to 150 turns / m. And when it is less than 90, the bending resistance of the glass yarn having a high brittleness is lowered. When the ratio is more than 150, the surface of the composite yarn has many irregularities, which makes it difficult to form a conductive silicone rubber film. That is, cracks may occur in the conductive film. In addition, since there is little space between the glass fibers, the penetration of the conductive silicone rubber is difficult.

The fineness of the combined yarn is preferably 300 tex or more. And less than 300 can not sufficiently dissipate hot spots generated in the conductive silicone rubber. That is, the thermal conductivity of the glass chamber is 1.2 to 1.35 W / m · K, and the thermal conductivity of the conductive silicone rubber is 0.3 to 0.6 W / m · K, . In addition, twisting the combined twist yarn into a covering yarn is performed by coating conductive silicone rubber on the covering yarn and heat-shrinking the covering yarn during the process of thermosetting so that the fibers of the combined twist yarn are tightly rounded, The thermal conductivity between the glass chambers is increased so that the heat point generated by the conductive silicone rubber is dissipated through the glass chamber. Accordingly, the wire net according to the present invention has the effect of preventing the uniform temperature distribution and the heat deterioration and improving the durability.

Further, the glass seal may be replaced with carbon fiber or include carbon fiber. It is to increase electrical conductivity and thermal conductivity.

The number of twists in the covering chamber is preferably 700 to 2000 times / m. If it is less than 700, it can not cover the short fiber protruding part of the glass yarn, and if it exceeds 2000, it covers the surface of the glass yarn and it becomes difficult to coat the conductive silicone rubber.

One of the objects of the present invention is to cover the glass seal by eliminating the short fiber protrusion of the glass seal so as to improve the electrical insulation of the melt seal. The existing net-shaped heating element has a phenomenon that after the conductive silicone rubber is coated on the short fiber protruding portion, the short-fiber protruding portion is sharp like a spike even when coated with the insulating silicone rubber, and the electrical insulation is broken. Previously, woven glass yarns were burned before coating, but they did not disappear because of the incombustibility of the glass yarns.

FIG. 2 is a process flow diagram of a fabrication facility of a wire netting according to the present invention. FIG. 2 is a schematic view of a manufacturing facility of a wire netting system according to the present invention, (2) for feeding a coated yarn produced through a twisting process and a covering process covering the combined yarn to a mixed weirer, a yarn tension supplying unit (2) for uniformly feeding the tension of the bundle moving line and the covering yarn to the mixing loom (1) comprising an equalizing device (3), a mixing loom (4) weaving with said collective copper wire and a coating chamber, a mixing fabric tensioner (5) for maintaining the tension of the mixing fabric woven through said mixing loom, (6) for coating and thermosetting with rubber, a conductive coating and thermosetting device (6) for transferring and coating the coated mixed fabric, and a coating fabric transferring device And is characterized in that aspiration around this manufacture comprises a tooth (8).

The cover-room supply device includes a hollow 50 of the spindle 49, a twist plate 46, an exit aperture 47, a bobbin holder 44 located on the top of the twist plate, a storage plate 45, a balloon guide 41, And a control unit.

The bobbin holder is a fixing device for supporting the bobbin 43 of the center chamber 42. The bobbin holder is a storage disk fixed to the top of the twisted plate for supplying the center chamber, And the bobbin holder is not rotated even if the twisted plate is rotated by the spindle.

Accordingly, the center chamber is supplied to the balloon guide 41, and the covering chamber is drawn out from the exit port 47 of the twisted plate to form the balloon 48, and the central chamber is supplied to the balloon guide while surrounding the center chamber. The twisted plate is rotated together with the spindle, and the exit port is a hole formed in the outer periphery of the twisted plate.

In one embodiment, the central chamber is a glass chamber. This is because the glass yarn is most preferable as a heating element because it has better heat resistance than ordinary fibers.

3 shows a covering process of an existing yarn in which the spindle 32 is a hollow shaft and the glass yarn 31 is supplied to the center yarn of the covering yarn through the hollow of the spindle and is fed through the covering yarn bobbin 33 And a twisting process is performed to form a closed cell. However, since the glass chamber penetrates into the hollow of the spindle rotating at high speed, there is a problem that the hollow inner wall of the spindle rubs against the glass chamber to form bows and staple fibers are generated. Also, The length of the balloon 34 is not constant and the pitch to be covered is not constant.

4 is a view illustrating a covering process according to the present invention. As a process for solving the above-mentioned problems, a glass seal, which is a center seal at the top of a twisted plate 46, is fed to a center chamber 42 through a balloon guide 41, The coverring chamber is formed by passing through the hollow 50 of the spindle 49 and the exit port 47 of the twisted plate 46 to form a balloon 48 and then twisting through a balloon guide to form a closed chamber do. In the covering chamber, the balloon 48 is formed between the exit port 47 of the twisted plate and the balloon guide 41, so that the pitch at which the balloon 48 is covered is constant. The bobbin holder 44 is a fixing device for supporting the bobbin 43. The storage plate 45 is a disk for storing the center chamber fixed to the upper portion of the twisted plate and the storage plate supports the bobbin holder.

The covering unit according to the present invention is based on the principle of a twister. The twisting disc rotates at a high speed, but the storage plate on the top of the twist plate is fixed, and the glass chamber, . That is, the principle is that the glass chamber is supplied from the upper part, and the covering chamber is exposed through the exit port of the twisted plate from the lower part, and the entire glass bobbin is surrounded and twisted.

The general twisted pair can be classified into the up-twister type, the down-twister type, and the double-twister type according to the principle of the twisted yarn method.

1) Italian Spinner: Spinning a small bobbin (200-500g) using a twisting machine on a spindle in the state of a yarn to insert it into the spindle to pull the yarn out of the bobbin and to become flammable between the flyer and the snail wire. It is.

This method is a type of up-twister type which is twisted while pulling the yarn from the rotating package up to the upper part.

2) Ring spinning machine: A kind of down-twister twisted yarn wound around a bobbin inserted in a spindle.

3) Two for one tweeter: It is a kind of double-twister tweeter, and adopts the most efficient and reasonable tweaking method in terms of twitching principle. The yarn supplied from the bobbin passes through the top guide, exits from the exit port on the spindle, forms a balloon, and the twisting process is performed via a balloon guide, and two twists are obtained by one rotation of the spindle .

FIG. 5 is a view showing a manufacturing process of a wire netting according to the present invention. FIG. 5 is a view showing a manufacturing process of a wire netting according to the present invention, which includes a collecting process of twisting a plurality of copper wires, a combined yarn joining process of twisting a plurality of glass yarns, a covering process of covering the combined yarn, A mixed weaving process of weaving with the collective copper wire and the cover yarn, a mixed fabric conductive coating and a heat curing process of coating the mixed and woven fabric with the conductive silicone rubber and thermally curing the same .

In one embodiment, it is preferable that the copper wire is twisted by gathering 7 wires having a diameter of 0.1 mm. The reason for twisting to 0.1mm and 7 lines is to keep flexibility with the glass yarn in the mixed weaving process.

The tension equalizing step for uniforming the tension of the collective copper wire and the covering yarn is characterized by including a method of pressing the whole copper wire or the entire covering yarn with two rollers coated with rubber and rotating.

In the mixed weaving process of weaving with the collective copper wire and the covering yarn, the collective copper wire is a structure in which the weft and the weft are alternately crossed with each other, and the covering yarn is formed by weaving a single weft yarn with two weft yarns close to each other. do.

The mixed fabric conductive coating and the thermosetting process can be divided into two stages. In the first stage, the conductive coating is coated by the impregnation method, and is dried for about 2.5 minutes in the hot air at 110 DEG C, thermoset for 5 minutes in the hot air at 200 DEG C, In the second step, it is characterized in that it is re-cured for 5 minutes in a 200 ° C hot air.

Fig. 6 is a weaving view of a wire mesh weaving machine according to the present invention. Fig. 6 shows a weaving diagram of the wire mesh network composed of an electrode line 61, a leno slope 62 and a transformer 63, And the leno warp yarns and the weft yarns are covered yarns produced in the above process, and the weft density is 3 blanks / inch, and the weft yarns are formed of the covering yarns. Also, the number of strands of the collective copper wire can be adjusted according to the electric capacity of the electrode wire.

The reason why one of the objects of the present invention is to use the covering yarn is that it is woven in the form of a net so as to increase the slip resistance of the stitches in order to prevent the mesh structure from becoming uneven.

In addition, the coating chamber structure in which the covering chamber is spirally wound in a spiral form is formed by making the cross-sectional shape of the center chamber circular and coating the coating chamber with conductive silicone rubber to thermally cure, thereby causing heat shrinkage in the covering chamber, And the bonding force between the glass chamber and the conductive silicone rubber is formed at a high density.

Accordingly, the present invention is characterized in that the fine yarn of the glass yarn is removed by using the coated yarn, the high density bonding is performed between the glass fibers, and the mixed fabric combined with the collective copper wire and the coated yarn becomes a mesh. That is, the slip resistance of the upper and lower slopes is so large that the upper and lower slopes do not have a bow or skewness.

The cross-sectional shape of the conventional glass chamber coated with the conductive silicone rubber was a flat shape, and it was difficult to form the film with a certain thickness even when the electrically insulating silicone rubber was coated. This is because the thinner side of the impregnation method is smaller in thickness than the larger side.

However, by using a coating chamber in which a covering chamber is spirally twisted in a glass chamber, the coating film is formed to have a uniform thickness when the electrical insulating silicone rubber is coated by changing the sectional shape into a circular shape.

In addition, the series of process of the fabrication process of FIG. 5 requires the separation of the weaving process, the coating process and the thermosetting process, so that the tension of the mixed fabric is lost, And the electrode wire and the weft yarn can not be tightly coupled with each other in the weaving view of the transfer net of Fig. In other words, it can not achieve the purpose of the advance network.

In addition, the covering chamber 12 of Fig. 1 is wound in a spiral coil in the center chamber. Therefore, when the conductive silicone rubber is coated on the coating chamber by the thickness of the covering chamber 12, the conductive path of the conductive silicone rubber flows in the form of a spiral, as when the conductive wire is wound.

The above-mentioned electromagnetic phenomenon is called a coil in which a conductor is wound, and a magnetic flux is generated when a current is passed through the coil, thereby promoting the action of electromagnetic induction or electromagnetic force.

Further, the function is improved by adding a functional filler to the conductive silicone rubber.

That is, when the conductive path of the conductive silicone rubber is coated in the coating chamber by the thickness of the covering chamber, electric current flows to the coil of the helical shape, so that the electromagnetic effect and the functionality of the filler are synthesized.

In one embodiment, conventional electrical energy refers to the energy of electrons flowing into a conductor. Recent research has revealed that electric energy is composed of the flow of rotating electromagnetic waves and the oscillation of electrons. There is a rotating electromagnetic wave that interprets electric energy as a concept different from the conventional electric energy.

A rotating electromagnetic wave is an electromagnetic wave having a constant rotational motion. This rotating electromagnetic wave is generated, for example, in a crystallization? Bond during interatomic bonding. The crystallized π-bond serves to convert heat rays into rotating electromagnetic waves. The crystallized π bonds are, for example, found in the elvan and loess, and these substances are known to emit magnetic waves of a wavelength band beneficial to the human body. Therefore, these materials are applied to steam rooms, beds, elbow pipes, garments and building materials. For example, a garment having a large amount of crystallized π bonds changes harmful rotating electromagnetic waves that touch the surface thereof to harmless rotating electromagnetic waves, thereby eliminating the harmfulness thereof.

In addition, when the crystalline π bond turns a strong visible light into a rotating electromagnetic wave, a strong attractive force is generated, and this attractive force is applied to slow the treatment and growth rate of cancer. The wavelength range of the rotating electromagnetic wave generated in the crystallized π-bond is capable of sterilizing harmful bacteria, and is applied to the sterilization industry such as water pipe production. In addition, it is applied to soap, detergent, shoe soles and cosmetics, and it is believed that the π-bonding of crystallization converts the heat from the human body into a rotating electromagnetic wave which is beneficial to the human body. Such rotating electromagnetic waves are applied to oriental medicine and various medicines, and it is believed to be a source of bio energy or ki in oriental medicine, because it is known to have a beneficial effect on the human body.

In the case of rotating electromagnetic waves generated by a hot wire, the generation rate of the hot-wire rotation electromagnetic wave was measured by measuring the far-infrared ray derived therefrom, or the sterilizing ability thereof was measured (Oh JK, "π-ray physics", 2001, The Ajou University Press, ISBN. -86161-14-1-93420).

Other methods include O-ring testing (fingers force tester), quantum resonance spectrometer, meridian and quantum fractal auto-focusing analyzer. The literature on this is as follows.

- Oh, hee-guk, "Some comments on implosion and Brown gas", J. Mater. Process. Technol., 95 (1999), 8-9;

- Oh, Heung Kuk, "Vortex of electrons π-bonding of atoms and superconduction", J. Mater. Process. Technol., 74 (1-3) (1998) 126-130; And

- Oh, Heung-Kuk, "Some observations on the cavity of cold fusion and the generation of heat", J. Mater. Process. Technol., 94 (1999) 60-65) and

There was also a nuclear magnetic resonance (NMR) method. The literature on this is as follows.

- Oh, Heung Kuk, "Conventional metallic bonding and three-dimensional crystallizing π-bondings", J. Mater. Process. Technol., 94 (1999) 60-65; And

-W.J. Gullick et al., "Three dimensional structure of the transmembrane region of the proto-oncogenic and oncogenic forms of the neu protein", EMBO J. 11 (1) 1992, 43-48.

However, according to the above method, there is a problem that the measured value of the rotating electromagnetic wave is not reproducible or the measuring mechanism becomes somewhat complicated. In addition, the scientific reasons for the lack of reproducibility of the measured values were not properly identified. To solve such a problem, in Korean Patent No. 10-0432982, a rotating electromagnetic wave surrounding the material to be measured is guided to protrude, and a rotating electromagnetic wave protruding at this time is turned into a rectilinear electromagnetic wave. When the amount of the rotating electromagnetic wave is measured, It has been found that data relating to reproducible rotating electromagnetic waves can be calculated. Korean Patent No. 10-0631869 discloses a method of detecting rotation of a rotating body by using the fact that the magnitude of energy is amplified or attenuated when rotating electromagnetic waves meet each other in an electric magnetic field. The properties of the rotating electromagnetic waves can be measured simply and effectively by measuring the properties of the electromagnetic waves.

The properties of rotating electromagnetic waves can be largely divided into characteristics of left-turn positive, left-turn negative, right-turn positive and right-turn negative. Such classification can be classified by a measurement method including the following steps.

The positive or negative of the rotating electromagnetic wave is distinguished by the measuring method disclosed in Korean Patent No. 10-0432982. That is, a substance to be measured for the properties of the rotating electromagnetic wave is placed in water and allowed to stand for a predetermined time, so that the rotating electromagnetic wave emitted from the substance is absorbed by water, and the obtained water is placed between electrodes to which a proper voltage is applied, The discharged light is photographed, the luminosity is displayed in multiples of the resolution, and the relative rotating electromagnetic waves of water are measured through the discharge device to indirectly measure and distinguish. The above-mentioned standing time is not particularly limited, but is preferably about 3 hours. The obtained water is placed between electrodes having a proper voltage applied thereto to be discharged, and the discharged light is photographed to display the luminous intensity in a multiple of the resolution (pixel). The range of the voltage used for discharging is preferably 500 to 2,000 V, but is not limited to this range. The discharge process may be performed using a conventional discharge device. For example, gas dischage visualization (GDV) can be used. In this case, it is preferable that the water is placed on the cathode side of the discharge device, for example, the gas discharge visualization device, and is filled with air or gas between the water and the anode to discharge the water. By placing a water sample on a part of the cathode side and filling an air layer or a gas layer between the water and the anode side, the rotating electromagnetic wave in the water sample is transferred to the air layer or the gas layer, . The unit of the measured data means a multiple of the luminosity resolution of the measurement system used in the above measurement method, and a negative value means that the energy is absorbed. That is, the larger the value of the control group, the larger the emissivity of the energy, and the smaller the value of the control group, the greater the absorption rate of this energy. By the measurement method described above, it is possible to select a substance that emits positive or negative rotational electromagnetic waves.

Whether the rotating electromagnetic wave is turned left or right can be determined by the measuring method disclosed in Korean Patent No. 10-0631869. (1) forming a magnetic field by a permanent magnet or an electromagnet; (2) emitting a rotating electromagnetic wave generated from a substance to be measured for the property of the rotating electromagnetic wave in the magnetic field; (3) measuring the change of the magnetic field by the change of the current; And (4) a rotating electromagnetic wave source to be measured in accordance with a change in current due to the change of the magnetic field, using characteristics of the left-turn electromagnetic wave from the S pole to the N pole and the nature of the right- In order to judge whether the rotating electromagnetic wave radiated from the rotating magnetic field is a right-hand rotating electromagnetic wave or a left-hand rotating electromagnetic wave, considering the positions of the magnetic poles of the S and N poles of the magnetic field in accordance with the increase and decrease of the change of the magnetic field in the magnetic field formed by the permanent magnet or the electromagnet . Using the properties of the left-handed electromagnetic wave proceeding from the S-pole to the N-pole and the nature of the right-handed electromagnetic wave proceeding from the N-pole to the S-pole, whether the material for which the property of the rotating electromagnetic wave is to be measured is a right- Can be selected.

One of the important scientific products that lead modern civilization is electricity and artificial lighting. These artificial lights increase the activity time of human, so they increase the activity and productivity, which has the advantage of further developing the civilization, but it generates harmful electromagnetic waves of cations that are not beneficial to the human body and the surrounding ecosystem. Especially, in cities where the benefits of civilization are as much as the city, and artificial lighting is gorgeous, humans are exposed in the flood of harmful electromagnetic waves such as cations.

In addition, all animals and plants, including humans, have a unique smell. When all plants and animals are rotten or decayed, they smell the stench and pollute the surrounding air environment. Various chemicals cause diseases such as atopy in humans due to their toxicity , Even in the case of this smell and toxicity is a kind of left-handed electromagnetic wave.

Sulfomac is, for example, an electromagnetic wave that is harmful to the human body, caused by water flowing over 10 meters underground.

Accordingly, there is a need to develop a rotary energy technology for converting harmful rotating electromagnetic waves generated in a human peripheral living environment, such as artificial light, smell, and snakes, into rotational electromagnetic waves beneficial to the human body.

The present invention is characterized in that a layered material is added to the conductive silicone rubber to be coated on the coated room. The conductive passage of the conductive silicone rubber is wound in a spiral coil around the composite yarn, and the conductor cross section is a flat rectangular shape. That is, a conductor having a flat rectangular cross section is wound around the combined yarn.

The human body produces various kinds of energy. For example, because it produces electricity, it is used for diagnosis by using electrocardiogram, electromyogram, etc. Also, since the human body generates a magnetic field, it is diagnosed using magnetic resonance imaging (MRI). In addition, quantum physics has been applied to the human body, and it has been assumed that very minute energy exists in the human body called the quantum field and the super quantum field.

Like the principle of Yin and Yang in Oriental medicine, the human body has both sides of particles and waves like the relationship between the front and back of a coin. Thus, the molecules have a dual structure of visible particles and invisible waves. Similarly, cells, tissues, organs, and flesh have a dual structure of visible particles and invisible waves, and viruses, bacteria, Food, pesticides and heavy metals also have a dual structure, visible particles and invisible waves.

Thus, the molecules that constitute the body are composed of particles and waves, and the particles are composed of molecules, particles and waves, the cell structure is composed of particles, The body composed of double structure and organs is composed of double structure of particles and waves, and the mind also has a dual structure of particles and waves. Therefore, in the invisible dimension of the human being, the body and the mind are connected to each other because the vibrating elements that make up the body and the vibrating elements that make up the mind are the same, and the mind is connected to DNA.

The heartbeat is the wave of current flowing through the myocardium. This current is caused by many particles with electricity, such as electrolytes of sodium, potassium, chlorine, calcium and magnesium, entering and exiting the muscle cell membrane and promoting muscle contraction. At the same time, the flow of electricity spreads to surrounding tissues.

Some of the current from the heart is transmitted to the circulatory system. Because the blood flowing through blood vessels has a large amount of salinity, the circulatory system becomes a conductor with excellent conductivity. When blood is transported to each tissue, electricity generated from the heart is delivered to all parts of the body. Electrocardiogram (ECG) can be measured by touching the electrodes on the skin at any part of the body, ie at the toes far from the heart.

Bioelectrons flow along the arteries and veins and through the walls of the capillaries. If the biomechanics of the circulatory system is abnormal, all kinds of illnesses will result. When the problem occurs, it can be treated by restoring the original homeostasis.

When a wound is injured, positive ions are formed at the wound site, and negative ions are generated at the tissues in the vicinity of the wound. As a potential difference is formed, a kind of current flow occurs as ions or charged cells move back and forth. For example, in the case of leukocytes, it has a negative charge, which makes it easy to pull it toward the wound.

In other words, when a human body is damaged, a voltage is formed at the wound site, and positive and negative ions constantly come and go, resulting in electrical equilibrium, which is the healing process.

There are many forms of energy in energy such as electricity, magnetism, heat, light, electromagnetic, kinetic energy, sound, gravity, vibration and elastic energy. However, there is a common basic principle for all of these energies. In general, magnetism is the origin of unpaired electrons around a quantum (+) in a nucleus containing an atom of a ferromagnet . Ultimately, electrons turn around and around the nucleus, which causes magnetic energy to be generated.

Muscles other than the heart can generate electrical energy and record EMG. This corresponds to this electromyogram is the nearest prayer. Every muscle in the body produces magnetic waves every time it contracts, and large muscles produce large energies and small muscles produce small energies.

And energy waves contain important information about life phenomena. In other words, waves include not only the phenomena of life, but also the information of nature, material and even psychology, and the exchange of information through waves is not only between animals and animals, plants and plants, between humans and humans but also between animals and plants, , And between man and the universe. In short, the wave is a common language in which all things in the universe are written together.

Quantum physics has revealed that electrons are both particles and waves. It became possible to express all the materials with a constant wave model as the electromagnetic wave is revealed. As you know, the properties of a particular element are determined by the number of electrons in the atom, and atoms have different wave models depending on the number, rotation speed, and direction of the electrons. Not only electrons, but all particles have the characteristics of multi-wave. Light is the same.

Light and color have the energy to stabilize and harmonize humans, and sometimes excitement and inspiration, because each color has its own wavelength and frequency, affecting the body. In other words, a living body emits a unique energy when it is healthy.

It was first discovered by Eli Cartan, a French mathematician in 1922, that torsion fields were created by rotation that were entirely different from electromagnetic fields or gravitational fields. In comparison with physics, electromagnetic fields are generated from charge, gravitation from mass, and torsion field (or spin field) from rotation.

Each atom has a nucleus and a spin (which means a general rotation, which physically means the rotation of electrons or nuclei) is different, and a specific torsion field is created according to the spin arrangement of the nucleus and electrons. In addition to atomic nuclei and electrons, the direction of the physical rotation of the atoms creates a spiral rotation rather than a simple rotation, creating a specific torsion field with various spatial structures.

For each atom of matter, the nucleus and electron spin and the physical rotation of the atom are polarized, and the torsion fields of atoms are superimposed, so that the whole torsion field of the material is expressed in space. That is, a unique torsion field is formed for each substance.

Also, if the rotation speed of the rotating object and the angular velocity of the spin are constant and do not change, a static torsion field is formed in the space, and a dynamic torsion field is formed if the angular velocity of rotation continuously changes.

In a dynamic torsion field, propagating torsional waves are generated. The static torsional field is so weak that it is almost impossible to measure, but the dynamic torsional field can be measured because it affects the spin of the transmitted object.

Torsion waves have very unique properties. The torsional wave is not absorbed in the surrounding environment but transmitted in a vacuum without medium. And the propagation speed of the torsional wave is comparatively faster than the speed of light.

In particular, when an electromagnetic field is generated, the electromagnetic field and the torsion field proceed together because the effect of the substance on the spin is to some degree.

These tornadoes have long been called Ki, and have been used extensively in real life as well as in medicine.

The torsion field for generating the above-mentioned gas is also referred to as a rotating electromagnetic wave. The rotating electromagnetic wave means a rotation of an electron or a nucleus having various spatial structures as a spiral rotation is generated instead of a simple rotation, A rotating electromagnetic wave is created by the construction of a rotating electromagnetic wave with a small wavelength. The wavelength is quantized from infinitely small to infinitely large. The rotating electromagnetic waves of two rotational directions (negative and positive) And the generated energy in such a state of rotation is combined in a form important for signal transmission and biological movement of life.

In particular, the wavelength of the rotating electromagnetic waves in the water has the effect of sterilizing the harmful bacteria by making the structure of the water group (cluster) dense. And the ionic action, which transfers electrons from one atom to the other, blocks the formation of active oxygen and increases the reducing power.

When such rotating electromagnetic waves penetrate into the human body, the energy that interferes with the meridian flow in the human body is driven to the outside, and the function of continuously activating the immune activity and the biological activity is repeated.

Rotating electromagnetic waves also exist in various shapes and geometric structures. That is, all objects with a geometric shape generate left and right rotating electromagnetic waves according to their geometrical characteristics.

In addition, the rotating electromagnetic waves are generated by rotation or angular motion, and left and right rotating electromagnetic waves exist in accordance with the rotation direction.

It can be used for ceramic, elvan, tourmaline, chuncheon jade, amethyst, layered material, graphite, carbon fiber, but are not limited to, carbon fiber, carbon black, carbon nanotube, graphene, copper, iron, aluminum, silver and plastic. The plastics can be, for example, polyethylene, PVC, polypropylene, saran, polystyrene, polytetrafluoroethylene, PMMA, linear polyester, fluorinated ethylene propylene, polyhexamethylene adipamide, have.

Wherein the material for emitting the rotating electromagnetic wave is a geometric structure in the form of a mesh, a rhombus or a honeycomb, or a material for emitting a rotating electromagnetic wave in a framework of a mesh, a rhombus or a honeycomb.

The layered material in a sequential lamellar structure of covalent bonds and crystallized? Bonds is suitable for generating rotating electromagnetic waves.

FIG. 7 is a state diagram showing an electron rotation in a conventional crystallized π-bonded phase, in which electrons rotate and π-far-infrared rays are generated on the trajectory of a crystallized π-bonded atom (Oh, Heung Kook, "THREE- DIMENSIONAL CRYSTALLIZING Π- FAR INFRARED RAYS AND N-MACHINE ", An International Journal of New Energy System, Vol. 2, No.3 / 4, 1997, pp. 86-93).

A rotating electromagnetic wave which is a technical characteristic of a layered material that efficiently protects a covalent bond layer of two or three or more layers of covalent bonds, which is a π-bond in crystallinity, and efficiently generates an alternating magnetic field is used.

The far infrared ray is an infrared ray having a wavelength of 4 탆 or more, which means that the wavelength of infrared rays is long. Infrared rays are a type of electromagnetic wave that has longer wavelength than the red region of visible light and has a high heat action. It is absorbed by substances not visible, and has strong resonance and resonance action to organic compound molecules. If the wavelength is short, the light is well reflected. If the wavelength is long, the light is absorbed well when it reaches the object. Because of the strong penetration, the human body is also warmed by this infrared ray. These infrared rays help to eliminate germs that cause various kinds of diseases, and they help expand the capillaries to produce blood circulation and cell tissue. In addition, when it comes in contact with moisture and protein molecules that make up the cell, the cells are shaken finely 2,000 times a minute to activate cell tissue, which is effective in preventing various diseases such as aging, promotion of metabolism and chronic fatigue. In addition, it has effects of promoting perspiration, relieving pain, removing heavy metals, sleeping, deodorizing, antibacterial, fungus removal, dehumidification, air purification, etc. It is used in various fields.

The layer structure is a structure in which densely arranged surfaces of atoms bonded strongly by covalent bonding or the like are overlapped in parallel by a weak bonding force such as Van der Waals force. A material having this structure is referred to as a layered material.

The layered material has a strong covalent bond in the xy plane, but a weak bond in the z-axis direction. Typical examples of the layered material include graphite, transition metal chalcogenides, carbon oxides, layered double hydroxides, layered silicates, metal phosphates, and the like.

The transition metal chalcogenide is a layered material such as MX ₂ (M = transition, X = S, Se, or Te), where S is Sulfur, Se is Selenium, Te is Tellurium, to be. The chalcogen compound is a substance having a layer mainly composed of a van der Waals bond of chalcogen. That is, six Xs around M are combined into an octahedral or trigonal prism environment. These polyhedra form a plate-like solid material sharing the edges with each other. In the layer, the transition metals form a bond between the metal and the metal in the neighboring polyhedra, but are connected by a van der Waals bond without strong chemical bonds between the layers.

The layered double hydroxide is a kind of two-dimensional nanostructured clay. The layered double hydroxide is a structure in which a part of divalent cations surrounded by octahedral form of six hydroxyl groups (OH) is replaced with iso-morphous by trivalent cations and the sheet is positively charged to be. The positive charge of the plate is canceled by the negative ions present in the interlayer region. In addition, some hydrogen-bonded water molecules may occupy void spaces in the interlayer. For example, Mg-Fe bi-layer hydroxide, Zn-Al bi-layer hydroxide, Mg-Al bi-layer hydroxide and the like.

The layered silicate mineral is a basic structure composed of a combination of two tetrahedral sheets and one octahedral sheet. These silicate layers have high aspect ratios with lengths of hundreds to thousands of nm and each silicate layer is spaced about 1 nm apart by van der Waals forces It has a layered structure. For example, smectite, montmorillonite, vermiculite, mica, brittle mica, kaolinite, illite, chlorite, and the like .

The metal phosphate is obtained by replacing hydrogen of phosphoric acid (H ₃ PO ₄ ) with a metal element. It is produced from igneous rocks and sedimentary rocks and is also produced as secondary minerals. For example, zirconium phosphate.

The layered material has a high aspect ratio, a high surface area and a unique nanometer size of the layered material with high strength in the polymer matrix, resulting in a charge of 0.1% to 50% by weight of the polymer matrix The functionality of the layered material can be realized.

The silane coupling agent is chemically bonded using a silane coupling agent having two functional groups at both terminals due to the low bonding force between the polar filler and the non-polar silicone rubber. This enhances the bonding strength between the silicone rubber, which is a polymer matrix, and the filler, and improves the tensile strength, tear strength and abrasion resistance.

In addition, the layered material, aluminum hydroxide, is preferably a crystal structure of gibbsite. The gibbsite is a monoclinic system with a stratified structure in the z-axis direction. it can be seen that a twinning laminated structure is formed with respect to the z-axis direction. In other words, the z-axis direction is laminated in the form of different sheets, and the strain energy of the sheet surface forming the twinning is larger than the strain energy between the individual layers.

The anionite powders are characterized by containing tourmaline or monazite components.

The above tourmaline is characterized in that electricity is generated by friction, and both ends are charged positively when heated.

The monazite described above is characterized in that it contains a rare earth material such as cerium to anionize the ambient air.

Anion is a German physicist, Renard falls from the high water in nature, and when water or rocks collide with water, the water molecules are momentarily crushed and droplets are sprayed, and the air around them forms an electric layer The surrounding air layer was found to be the first to report the presence of anions by finding the phenomenon of generating a negative (-) weak anion (Lenard effect). Anions are scientifically called air ions (-) with electrical properties floating in the air and have currents. On the other hand, 70% of the constituents of the body are water, and ions in the water are always negative (-) weak currents and negative ions are positive ions. It is involved in the role of continuously sending about 10 trillion cells constituting the body to the electrical signal necessary for life by the weak current signal system. Utilizing the weak current flowing in the body, the hospital is useful for medical use such as EEG, electrocardiogram, and electromyography. Among these, anion increases the ionization rate of minerals such as calcium, sodium and potassium in the blood, purifies the blood through the progress of alkalization, increases the amount of glue, which is an immune component contained in the serum, But also acts to neutralize harmful cations as well as autonomic nervous system regulation, air purification, dust removal and sterilization.

The advancement network according to the present invention includes anion stone, so that it takes a treatment system that absorbs anions as a whole in a forest bath. Air ions absorbed into the human body through respiration are only 14 to 19%, and the remaining 81 to 86% are absorbed through the mucous membranes of the skin, nose, airways, and bronchi. Therefore, it is more effective to treat anions through the whole body bath than to depend on only the respiratory system.

When a person becomes sick or fatigued, lactic acid is formed in the muscle tissue and the body becomes weak acidity. Anion neutralizes the acidified constitution and restores health.

Accordingly, the electric wire network according to the present invention is characterized in that the conductive silicone rubber, the layered material, and the anion stone are fusion-bonded to each other in a mesh, rhombus or honeycomb structure. And a covering chamber is wound in a spiral shape like a covered chamber.

Fusion is a combination of different things that exerts a new, unified effect.

Further, the conductive silicone rubber is coated on the geometric spiral-shaped coating chamber, and the conductive path flows in the form of a coil, so that the electromagnetic effect and the functional effect of the interlayer material are synthesized.

The nanoparticles of the layered material have a very large sum of surface area per unit mass, which can further maximize the life energy effect as a rotating electromagnetic wave. In addition, an anion, an ultrasonic wave, and a far-infrared ray are fused together with a rotating electromagnetic wave to cultivate a unique rotational energy.

The particle size of the anionic gypsum powder is not limited, but it is characterized in that a formed body of a mesh or rhombic structure is produced. Particularly, it is preferably 50 탆 or less.

The one-layered structure is a conductive layer having a conductive function and an electromagnetic network in which a rotating electromagnetic wave can be radiated, or a rhombus or honeycomb-shaped conductive layer. The conductive silicone rubber Layer structure is formed, and the two-layer structure surrounds the one-layer structure, and an insulating layer is formed so that a rotating electromagnetic wave, a far-infrared ray, and an anion are emitted, and is fusion-bonded to a multi-layer structure. That is, when the conductive silicone rubber layer is formed, an insulating layer is further formed for the purpose of electrical insulation.

If the heat generated by the electric resistance heat is generated in the conductive function described above, the intensity of the rotating electromagnetic wave, the far-infrared ray, and the negative ion radiation is increased and the performance can be maximized.

In addition, the structure of the electric wire net according to the present invention is fusion-bonded to a multilayer structure of a conductive layer and an insulating layer, and is capable of culturing vital energy beneficial to the human body by heat, rotating electromagnetic waves, far infrared rays, and anion fusion.

The method for forming the above-described mesh, rhombus, or honeycomb-shaped conductive layer is not limited. For example, the conductive silicone rubber may be coated on a mesh or rhombus or honeycomb knitted fabric or knitted fabric, Or rhombus, and honeycomb.

Alternatively, the mesh or rhombus, honeycomb shape described above is a sheet behavior. The sheet form refers to a cloth or film shape that is densely woven into a fabric structure.

First, the conductive silicone rubber composition in which the conductive layer is formed is composed of silicone rubber, conductive carbon black, EPM (Ethylene Propylene Copolymer) having a Mooney viscosity (ML _{1 + 4} , 100 ° C) of 10 to 30 and a solvent, Wherein the composition ratio is 8 to 80 parts by weight of conductive carbon black, 0.2 to 20 parts by weight of EPM, and 100 to 900 parts by weight of solvent, relative to 100 parts by weight of silicone rubber, and the viscosity (mPa.s, 25 DEG C) 5,000.

The silicone rubber is a colorless or faint yellow elastic solid which has a slight fluidity even at room temperature and is also referred to as a silicon rubber.

Among the commercially available products, a part of the methyl group (CH ₃ ) is replaced by a phenyl group (-C ₆ H ₅ ) or a vinyl group (-CH ₂ = CH) Some are substituted. Heat resistance is good and rubber elasticity is not lost. For example, there are methyl vinyl silicone rubber, fluoromethyl vinyl silicone rubber, methylphenyl vinyl silicone rubber and the like, and generally have a molecular weight (Mn) of 100,000 to 700,000, preferably 100,000 to 500,000, and a viscosity of 100 To 100,000 cps may be used.

Since the vinyl group in the silicone rubber is more reactive than the methyl group, the vinyl group-containing silicone rubber can be crosslinked at a lower temperature than the silicone rubber having a methyl group. Also, the introduction of a phenyl group improves the flexibility and heat resistance of the molecular chain.

The silicone rubber according to the present invention is an addition reaction type crosslinking system. When a siloxane having an unsaturated bond such as a vinyl group is reacted with a Si-O-type siloxane, a Si-H bond is added to the vinyl group to cause a crosslinking reaction. A compound of platinum or palladium is used.

The vinyl group content of the silicone rubber is 0.1 mol% to 10.0 mol%, preferably 0.2 mol% to 10.0 mol%. When it is less than 0.1, the physical properties of the coating film are poor, and when it is more than 10.0, , But it is uneconomical.

The vinyl group-containing silicone rubber according to the present invention is required by a crosslinking reaction system and requires a vinyl group content in order to impregnate the conductive silicone rubber composition into a net or a rhombus structure frame to dry and crosslink at atmospheric pressure hot air.

That is, only the curing method by the addition reaction by the catalyst can cure the conductive silicone rubber composition.

The methyl-based silicone rubber which is cured by using the organic peroxide is not usually cured because the carbon black, which is conductive particles, is poisoned by the catalyst at ordinary pressure such as atmospheric pressure.

The conductivity of the conductive carbon black is not particularly limited, and it is preferable that the conductive carbon black is a π electron-transportable conductive material of carbon particles as the conductivity imparting agent to the silicone rubber. That is, carbon nanotubes are possible, and carbon black and carbon nanotubes can be mixed.

The carbon nanotube has a very large specific surface area, a length-to-diameter ratio, an excellent elastic strength, an excellent electrical characteristic, and an excellent heat transfer characteristic, so that a safe conductive path as an electric heating body can be secured.

Carbon nanotubes are graphite sheets that are dried in a circular shape with a nano-sized diameter, and are characterized by metallic and semiconductor characteristics depending on the angle and shape of the graphite plate. Nanotubes, double-walled carbon nanotubes, and multi-walled carbon nanotubes. The structure of the carbon nanotubes is classified into an armchair, a zigzag and a chiral type according to the angle at which the graphite plate is rolled up.

The carbon nanotube according to the present invention is preferably a multi-walled carbon nanotube and an armchair structure showing metallicity.

Also graphene is preferred. Graphene is a two - dimensional planar structure in which carbon atoms are connected in a hexagonal honeycomb shape.

The conductive carbon black may be one of graphite, carbon nanotubes, graphene, and carbon short fibers.

The particle size of the graphite is 0.5 탆 to 10 탆, and the specific resistivity of the battery is preferably 0.005 Ω · cm to 0.08 Ω · cm. Outside of the above range, it is inappropriate to maintain electrical stability.

 It is preferable that the length of the short carbon fibers is 50 μm to 10 mm. If the length is less than 50 mu m, the reinforcing effect and the entangling effect of the fibers are not exhibited. If the length is more than 10 mm, the orientation in the longitudinal direction of the extruded conductive yarn is difficult. The short carbon fibers are excellent in that an electrically conductive path is formed.

The conductive carbon black is dispersed in the silicone rubber so that electron conduction is carried out by a tunnel effect between carbon structures (primary aggregates of carbon black).

Specific examples of the conductive carbon black include DENKA black (trade name, manufactured by Nippon Electric Chemical Industry Co., Ltd.) as acetylene black, Continex SCF (trade name, manufactured by Continental Chemical Co., Ltd.), Balkan XC-72 CABOT) and Asahi HS-500 (trade name, manufactured by Asahi Carbon Co., Ltd.). Examples of the conductive channel black include Corax L (trade name, manufactured by Degussa) and the like. In addition, Ketjen Black EC and Ketjen Black EC-600JD (trade names, manufactured by Ketjen Black International), which are types of furnace black, can be used. Of these, acetylene black and ketone black are more preferable.

The capillary force generated by the interfacial tension acting on the portion contacting with the volatile solvent through the drying process of the composition (the conductive particles are slowly evaporated while the conductive particles are moved by the capillary force to crystallize into a dense structure) .

In the conductive silicone rubber composition for forming a uniform electric resistor in the composition, the conductive carbon black and the silicone rubber are mixed with a press kneader, Banbury Mixer, roll mill, screw mixer, Mixing and kneading the resulting mixture in a homogeneous distribution mixing sequence; adding a solvent to the kneaded conductive silicone rubber to form a solution phase; adding EPM to form a chain structure of a continuous conduction path in the solution phase; Solution) in the solution.

The conductive carbon black does not exist in the form of individual spherical particles but exists in the form of primary aggregates, that is, an aggregate (primary structure), in which individual particles are fused to each other. Because the aggregate is unevenly shaped, the aggregate contains an internal void that the polymer can enter during the orientation process.

The temperature coefficient of the conductive silicone rubber is positive (+), and the higher the temperature, the more the volume resistivity increases. This is mainly due to the distance between the carbon chains and the distance between particles due to the thermal expansion of the system.

The reason for the low change in the volume resistivity due to the heat treatment for a long time is that carbon chain growth or approaching distance between particles occurs due to heat deterioration of the conductive silicone rubber. The change in the volume resistivity as compared with other conductive rubbers is due to the excellent heat resistance of the siloxane of the silicone rubber.

Conductive Carbon Black In this silicone rubber mixture, the interaction between the silicone rubber and the conductive carbon black can be summarized as follows.

First, as a mechanical interaction, adhesion between the surface of carbon black and rubber molecules (rubber molecules enter into the void volume of carbon black and occlusion), and second, physical interaction causes adsorption of rubber molecules on active sites of the carbon black surface , And third, the chemical interaction between the element and the functional group of the carbon black surface and the element of the rubber molecule.

And has good conductivity when the chain-like connection of the conductive particles is continuous.

As compared with the three types of carbon black (spherical, spherical, and spherical), fiber-like carbon black is most excellent in electrical conductivity.

The volume resistivity of the conductive carbon black is 0.01 to 0.1? 占 cm m, and the aggregate size of the primary particles is about 10 to 100 占 퐉.

In order to have excellent conductivity, aggregates of adjoining carbon black aggregates need to be within about 5 nm in order for electrons to migrate through the tunnel effect.

The shear force for crushing the secondary agglomerates of the conductive carbon black is preferably in the range of 0.1 to 1.2 kgf / cm 2.

If the shearing force of the pressurized kneader or the Banbury mixer exceeds 1.2 kgf / cm 2, the primary agglomerates are broken up to decrease the number of conductive passages, thereby decreasing the conductivity.

If the shear force is less than 0.1 kgf / cm 2, the secondary aggregate of the carbon black is not crushed and the dispersion-mixing effect can not be exhibited.

The base particles of carbon black are few in number as a single particle and form a structure.

The structure of the carbon black is classified into a primary aggregate in which basic particles are fused to each other and a secondary agglomerate in which primary aggregates are aggregated by Van der Waals force.

That is, the primary aggregate structure of the conductive carbon black takes the shape of a chain forming a conductive path.

The volume resistivity of the conductive silicone rubber obtained through the above process is in the range of 1 to 1000 OMEGA .cm.

When the content of the conductive carbon black exceeds 80 parts by weight, the conductivity is increased but the binder function of the silicone rubber is weak and the mechanical strength is weak. When the content is less than 8 parts by weight, the conductivity required for the conductive silicone rubber can not be obtained.

In order to impregnate the conductive silicone rubber with a structure such as a mesh, rhombus, or honeycomb, a solution dispersion process of the conductive silicone rubber is required.

Since carbon black has a large surface tension, it tends to aggregate if it becomes a fine particle and has a large surface area, and is easily re-aggregated even after crushing and dispersing in mixing.

In the above process, the conductive silicone rubber having a good dispersing / distributing / mixing property is dissolved in toluene as a solvent to disperse the solution. If the solution is left for a certain time, the dispersion stability can not be pursued due to the re-agglomeration of the carbon black.

Therefore, it is possible to lower the surface tension by coating the particle surface of the carbon black with a material having a low surface tension.

That is, when a polymer (such as a silane coupling agent) is grafted on the surface of the conductive carbon black particles, the repulsion between particles increases, and the affinity of the polymer with the medium increases, and the stability upon dispersion and dispersion after mixing can be improved. (Because the polymer covers the surface of the carbon particles).

If the conductive path of the chain in the resistor of the conductive silicone rubber is grafted with the polymer between the conductive particles and the thin film is interposed therebetween, the contact resistance between the conductive particles increases, and the required conductivity can not be obtained.

Ultimately, it is most preferable that the conductive path of the continuous phase is formed only by the carbon black particles.

In addition, with respect to the stabilization of the solution dispersion, there is a tendency to flocculate with the lapse of time.

The present invention aims to solve this trade-off by the polymer solution theory.

The process in which the polymer solution spontaneously takes place should have a negative change in the Gibbs free energy.

The polymer arrangement is highly dependent on the nature of the solvent. In a good solvent, the attractive force acts between the solvent and the polymer to stretch the polymer chain, and the coil becomes uncoiled.

In the process of making the polymer into solution, the solvent penetrates into the polymer, blocking the attraction between the polymer chains, and destroying the cohesive force of the polymer, resulting in a swelling process. The cross-linked polymer has only this swelling process when it comes into contact with the solvent. However, in the next step, the polymer without cross-linking gradually diffuses into the solvent and finally forms a homogeneous solution phase.

In the present invention, a solution of a polymer is prepared by using a solvent which is an EPM polymer and toluene, and a solution of the conductive silicone rubber is dispersed in the polymer solution.

The following represent the main representative properties of EPM, toluene, carbon black and silicone rubber.

)는 10 정도이고,The solubility index of the conductive carbon black (

) Is about 10,

)는 8.9 정도이고, 비중은 0.86 정도이다.Solubility index of toluene (

) Is about 8.9, and specific gravity is about 0.86.

) 7.3 정도이고, 비중은 0.98 정도이다.Solubility index of silicone rubber (

) 7.3, and specific gravity is about 0.98.

)는 7.9 정도이고, 비중은 0.86~0.89 정도로서, 무니 점도(ML₁₊₄, 100℃)는 10~30 가 가장 바람직하다.The EPM (Ethylene Propylene Copolymer) is composed of ethylene and propylene copolymer and has a solubility index

) Is about 7.9, and specific gravity is about 0.86 to 0.89, and the Mooney viscosity (ML _{1 + 4} , 100 ° C) is most preferably from 10 to 30.

Particularly, the reason why EPM is used as a polymer dispersant in the present invention is that the molecular structure is copolymerized with an ethylene group and a propylene group, so that it has a large free volume due to its non-straight structure and is highly swollen to a solvent, Because of its excellent weatherability, ozone resistance and heat resistance.

Therefore, in the present invention, the constitution of the conductive silicone rubber and the EPM dispersant is the best choice as a heating element.

If the Mooney viscosity is more than 30, it is not soluble in a solvent because it has a high molecular weight, and phase separation occurs when mixed with silicon. When the Mooney viscosity is less than 10, polymer chains are short and internal chain spaces are small.

Since the specific gravity and solubility index of toluene and EPM are similar to each other as in the main properties, the polymer solution is well formed.

Since the two properties correspond to a good solvent, the solvent is absorbed and the size of the chain is increased by increasing the contact of the polymer with the solvent. In addition, a sensory force acts between the toluene and the EPM to increase the chain of the polymer and the coil to be in a loose state, thus creating an internal space between the EPM chains.

Therefore, the conductive silicone rubber is dispersed in solution, and the continuous phase of the conductive path is arranged in the inner space between the EPM chains, so that stability after dispersion can be achieved.

In addition, surface functional groups such as carboxyl groups, lactones, phenol, quinone, and active hydrogen present on the surface of carbon black inhibit the crosslinking of addition reaction.

That is, when carbon black and a platinum-based catalyst or a polyorganosiloxane having silicon atom-bonded hydrogen atoms as a curing agent are simultaneously mixed, it is possible to obtain a platinum-based catalyst There is a problem in that it is inactivated.

Accordingly, since the present invention encompasses the carbon black with the polymer solution of the EPM, the catalyst poison can be solved, and the cured product of the conductive silicone rubber can be obtained by evaporating the solvent during the drying of the composition.

Therefore, the present invention is characterized not by forming a film by grafting with an existing polymer but by distilling the solvent of the polymer solution into a dispersion phase by dry evaporation, thereby not affecting the conductivity.

The content of EPM in the solution dispersion is preferably 0.2 to 20 parts by weight based on 100 parts by weight of the silicone rubber. When the amount is less than 0.2 part by weight, the stability of the solution after dispersing the solution and the continuous phase of the conductive path can not be pursued due to the insufficient internal space between the polymer chains. When the amount is more than 20 parts by weight, the stability after dispersion is good but the conductive function and heat resistance are reduced. Phase separation occurs.

The dispersion of the solution causes the impeller of the sawtooth type to rotate at a high speed with a high speed disperser and cause shock and shear action by the sawtooth on the disk-shaped circumference.

)가 바람직하다. 100(

) 미만은 도전성 실리콘 고무의 균질화가 안되며, 300(

) 초과시 과도한 전단력으로 도전성 실리콘 고무의 용액 분산시 비산되고, 또한, 과열이 발생한다.The shear rate in the solution dispersion is preferably in the range of 100 to 300 (m < 2 >

). 100 (

), The conductive silicone rubber can not be homogenized and a conductive silicone rubber having a weight of 300

), It is scattered when the conductive silicone rubber solution is dispersed with an excessive shear force, and overheating occurs.

Since the maximum shear force (kgf / m 2) of the solution dispersion by the sawtooth-disk-shaped impeller can not exceed 5000, the solution dispersion process can safely realize solution dispersion without breaking primary particles of the carbon black.

A solution of the EPM and toluene dissolved in the open drum and a kneaded product of the electrically conductive silicone rubber are mixed and aged or directly dispersed in the solution.

By passing the aging period, it is possible to improve the wetting of the conductive particles and achieve good dispersion. The aging period is preferably about 7 days at an indoor temperature of 20 캜.

Alternatively, the above solution dispersion may be realized by dissolving the EPM and toluene in a sealed mixer at a temperature of 70 to 100 캜 in an atmosphere of the EPM and toluene, and then mixing a kneaded product of the dispersion and mixing of the conductive silicone rubber.

Alternatively, after the kneading of the dispersion mixture in the closed mixer is large, the dispersion of the solution may be performed by adding the EPM and the solvent immediately after the mixing and homogeneous mixing.

If the content of toluene as a solvent is less than 100 parts by weight, there is no flowability in the coating process and impregnation is impossible. If the amount is more than 900 parts by weight, the viscosity of the coating solution tends to be low. .

The solvent is toluene, xylene, hexamethyldisiloxane, and the like. Most preferably toluene.

Accordingly, the conductive silicone rubber composition according to the present invention has a viscosity (mPa.s, 25 ° C) of 10 to 5000. A coating amount of less than 10 is too small, and a coating surface of more than 5000 is poor in smoothness.

The above composition is preferably applied in a coating amount of 60 to 300 g / m 2 per unit area, more preferably 90 to 200 g / m 2, by impregnation with a structure such as a mesh, rhombus or honeycomb.

≪ Example 1 >

A composition composed of 100 g of a silicone rubber (SL7210A / B) manufactured by KCC (manufactured by KCC), 15 g of carbon black such as KETJEN BLACK EC 300J, 2 g of EPM (KEP-020P) manufactured by Kumho Polychem Corporation and 900 g of toluene as a solvent was spray- Dry for a few minutes.

And an electric conductor line serving as an electrode line is alternately arranged on both sides of the fabric or the knitted fabric in order to apply electric energy to the conductive layer. That is, the fabric or the knitted fabric is alternately arranged by 22 stranded copper wires on both sides.

The electric conductor wire is not limited, but is preferably copper, aluminum, stainless steel wire, or the like.

For example, aramid fibers, high-tensile PVA, nylon, polyester fibers, glass fibers, carbon fibers, conductive fibers and the like are preferable. Most preferred is glass fiber.

The silicone rubber has excellent heat resistance and excellent rebound resilience even in a heat environment. Further, the far infrared ray emissivity of the silicone rubber is high.

The above-described conductive fiber is not limited, but is characterized, for example, by coating a conductive composite material on an electrically insulating fiber. The conductive composite material is a composition comprising at least one of silicone rubber, carbon black, carbon nanotube, graphite, graphene, and carbon short fibers. The coating may be impregnated or extruded.

Textile fabrics and knitted fabrics are formed by supporting yarns from one yarn to another by weaving, knitting, or the like. The weaving and knitting methods in which yarns are guided over and adjacent to adjacent yarns are different.

Weaving is a cloth with a warp and weft crossed over one another and a flat body of any width. It is woven by loom and becomes various fabric organization according to the way of crossing warp and weft.

The main motions of the weaving process are shedding motion, which is a process of separating the warp yarn into two layers according to the fabric and forming a tunnel called a shed, And a beating motion that completes the organization of the warp and weft by pushing the weft through the opening to the front of the weaving fabric with the body. In order to continuously weave, the warp yarn is loosened from the oblique beam, and a let-off is performed to feed the weft yarn at a predetermined speed and a predetermined constant tension, and a certain amount of weft yarn is separated from the weft yarn Take-up is needed.

The above-mentioned carbon material turns into a far-infrared ray by the vibration when the rotating electromagnetic wave circulating around the carbon atoms is heated. The far infrared rays having a wavelength of 4 ~ 16 탆 of pure infrared wavelength emitted at this time, (Bio-energy) which vibrates and stores the constituent molecules of the human body in a similar manner, and activates the energy flow of the human body. Further, when the electromagnetic wave touches the carbon material, the carbon material turns it into a sound wave. This sound wave is also called biosonic. The audible frequency of a sound wave which a human can hear is about 20 to 20,000 Hz, the sound wave having a frequency of 20 Hz or less is called a low sound wave, and the sound wave having a frequency of 20,000 Hz or more is called an ultrasonic wave. A sound wave is a phenomenon in which a compressed portion having a relatively high air density formed by the vibration of an object and a lean portion having a low air density are propagated to the outside.

The insulating layer is composed of silicone rubber, aluminum hydroxide, vinyl silane, an anionic powder, and a solvent. The composition ratio of these materials is 50 to 200 parts by weight of aluminum hydroxide, 1 to 10 parts by weight of vinylsilane 0.5 to 10 parts by weight of an anionic stone powder and 100 to 500 parts by weight of a solvent, and the viscosity (mPa.s, 25 DEG C) of the composition is 10 to 5,000.

1 to 10 parts by weight of vinylsilane constituting the composition of the present invention is added to 100 parts by weight of the silicone rubber to improve the mechanical properties, insulation properties and functionality by using aluminum hydroxide and an anionic powder. Particularly, in the composition of the present invention, by using the vinyl silane, the condensation reaction of the hydroxyl group and the hydrolyzable group of vinyl silane existing in the aluminum hydroxide and the anion powder causes the vinyl group to be located on the surface of aluminum hydroxide or the like. Aluminum hydroxide and the like surface-treated with a vinyl group improves the compatibility with the silicone polymer and also participates in a radical reaction to form a silicone rubber phase, thereby improving mechanical properties, insulation properties and functionality.

In the above aluminum hydroxide is more than 220 ℃ begins to occur slowly reaction between 205 to 220 ℃ proceeds the decomposition reaction rapidly, in the process, and suppressing the exothermic reaction to the endothermic reaction wherein the resulting alumina (Al ₂ O ₃ ) Acts as a catalyst and effectively blows off the conductive glass carbon on the surface of the material.

Silica can also be added to the composition of the present invention. It is preferred that the silica serves as a reinforcing filler and is amorphous, using synthetic silica having a specific surface area (BET method) of 50 to 600 m < 2 > / g. Silica surface treated with silane and silazane can be used to reduce the width of the increase in plasticity during storage. If the content of the silica is less than 5 parts by weight, the mechanical properties may be poor. When the amount of the silica is more than 100 parts by weight, it is difficult to mix the silica have.

In the composition of the present invention, aluminum hydroxide is used to improve the insulation properties and functionality of silicone rubber, in particular, to improve flame retardance, resistance to arc and rotational electromagnetic wave, and generally expressed by Al ₂ O ₃ .3H ₂ O or Al (OH ) ₃ . It is preferable to use aluminum hydroxide having a particle diameter of 0.5 to 15 탆 and a specific surface area (BET) of 0.5 to 10 m 2 / g, and aluminum hydroxide is contained in an amount of 50 to 200 parts by weight per 100 parts by weight of the silicone rubber . If the content is less than 50, there is a problem of poor arc resistance. If the content is more than 200 parts by weight, the mechanical properties become weak and the dielectric properties (dielectric constant, dielectric loss tangent) become high.

)가 바람직하다. 100(

) 미만은 수산화알루미늄의 균질화가 안되며, 300(

) 초과시 과도한 전단력으로 수산화알루미늄의 용액 분산시 비산된다.50 kg of aluminum hydroxide (Highlite H42-M, Showa Denko), 0.5 kg of an anionic stone powder, 400 g of vinyltriethoxysilane (VTEO, Degussa) were added to an open drum as an example of surface treatment of aluminum hydroxide and anion powder, 100 kg of toluene is added, and the impeller of the sawtooth type is rotated at a high speed with a high speed disperser, and shock and shear action are caused by the sawtooth on the disk type circumferential circumference. The shearing speed of the surface treatment is preferably in the range of 100 to 300 (m < 2 >

). 100 (

), The aluminum hydroxide is not homogenized, and 300 (

), It is scattered when the solution of aluminum hydroxide is dispersed by excessive shear force.

After the dispersion at the shear rate for 30 minutes, pure water 100 was further added and the dispersion was continued at the above shear rate for 30 minutes. The solution temperature during the surface treatment should not exceed 100 ° C.

If the content of the solvent is less than 100 parts by weight, the coating solution may not be impregnated with the coating solution. If the amount of the solvent is less than 100 parts by weight, the coating solution may not be impregnated. If the amount is more than 500 parts by weight, .

Accordingly, the composition of the insulating layer according to the present invention has a viscosity (mPa.s, 25 ° C) of 10 to 5000. A coating amount of less than 10 is too small, and a coating surface of more than 5000 is poor in smoothness.

The above composition is preferably applied in a coating amount of 60 to 300 g / m 2 per unit area, more preferably 90 to 200 g / m 2, by impregnation with a structure such as a mesh, rhombus or honeycomb.

As a result of measuring the rotating electromagnetic wave (Ki) by manufacturing the electric wire network by the above-mentioned method, the following value is obtained. The mean value of the sample value (5 measurements) minus the mean value of the control group (5 measurements).

① Train left turn + turn right

    Left turn positive + left turn voice

    Right turn positive + right turn voice

    Turn right Turn left + turn

② Voice energy - (4) - Positive energy + (11)

    {(-4) to (+11)}

The types of rotating electromagnetic waves are as follows: 1) The left turn positive rotation electromagnetic wave (pharmacological) is the energy to neutralize the toxic and organic toxic energy to vital energy, 2) the left turn negative electromagnetic wave (toxicity) 3) There are four kinds of rotation rotation electromag- netic wave (pharmacological) which is right rotation spinning electromagnetic wave (toxicity) is organic and snake poison which is representative and 4)

Toxic inorganic matter, organic matter, and natural environment (such as smack, electromagnetic wave, mercury, lead, pesticide, briquetting gas, decaying food, bond, and promoaldehyde) are harmful to our human body.

The non-toxic minerals, organic logistics, natural environment (far infrared rays, visible light, gold, germanium, grain, fruits, fresh food, etc.) have a right turn (positive energy) and benefit our human body.

A rotating electromagnetic wave, also called a tangent field, is a rotation of an electron or a nucleus having various spatial structures as a helical rotation is made, not a simple rotation. A rotating electromagnetic wave having a large wavelength is a rotating electromagnetic wave having a small wavelength The wavelength is quantized into an infinitely large and infinitely large range, and then the two rotating directions (negative and positive) of the rotating electromagnetic waves rotate on each of the orbits, and the energy generated in this rotating state (气) is a form that is important for the signal transmission and biological movement of life.

The anion measurement test was carried out at a measurement distance of 30 cm using a charged particle measuring device at room temperature of 18 ° C, humidity of 32% and number of anions in the air of 104 / cc. The anion released from the measurement object was measured, The displayed value is 220ION / cc.

The far infrared ray emissivity (5 ~ 20㎛) was tested at 70 ℃, and the measurement result of BLACK BODY using FT-IR Spectrometer was 90.5%.

In the Orient, the world of weak energy, which is not seen from the past but plays an important role in the human body, is expressed as ki.

For each atom of matter, a torsion field is created by spinning of nuclei and electrons and physical rotation of atoms. The torsion fields of atoms are superimposed on each other, and the whole torsion field of the material is expressed in space. That is, a unique torsion field is formed for each substance.

Torsion waves have very unique properties. The torsional wave is not absorbed in the surrounding environment but transmitted in a vacuum without medium. And it is estimated that the propagation speed of the torsional wave is comparatively faster than the speed of light.

In the world of torsion wave which is faster than light, various things that can not be explained by the existing laws of physics can be possible.

A torsional wave conveys information that does not carry energy but appears just as an array of spin or rotation. This property is very unusual in physics. However, the measurement of the torsional wave is physically possible because the spin state of the transferred material can be varied even if there is no change in energy.

The influence of the torsional wave can remain in the space as well as the object being transmitted. And water can contain the torsion field of concrete material. Dr.Sport, a world-renowned physicist in Russia, has described the space in which the torn wave propagated and memorized as "physical vacuum." The torsional wave transmitted through the 'physical vacuum' exhibits a holographic characteristic in which the entire information is contained in the part. Actually, a torsion field can contain not only unusual pictures, shapes, spatial arrangements, but also ordinary characters and pictures in various ways. The torsion field contained in these characters or figures can be transferred by copying or scanning, and also by e-mail.

Even when an electromagnetic field is generated, the electromagnetic wave and the torsional wave propagate together because they have some influence on the spin of the material. An existing torsion field may exist regardless of the electromagnetic field. However, there is no electromagnetic field that does not have a torsion field. Thus, the torsional wave can be generated using a special electromagnetic system.

By spinning the water physically, a variety of products have emerged that hold energy in water. In fact, using these devices, tap water turned like a whirlwind, resulting in almost no residual chlorine in the tap water, increased pH, increased dissolved oxygen, improved water taste, and decreased water contamination. Not only that, but also in the long term, it is observed that the rust of the pipe disappears and the contaminants of the water are also purified.

It can purify the air by generating water as well as a whirlwind.

When purifying the air with a vortex, it allows the air to be cleaned without special filters or electrical dust collectors. Not only is the air cleaned, but the smell of stubborn tobacco, the smell of food, the smell of the patient and the smell of the pet have disappeared. The dehumidifying effect is also excellent, and the moisture of the house and the wall and ceiling molds that have caused it are gone. The mop did not smell at all. The towel did not smell without sucking for a long time. It can be interpreted that the energy of the whirlwind provided the environment where the reaction could easily take place.

In the case of a torsion boiler, the temperature of the water increases even though the water passes repeatedly through a special spiral tube structure. Moreover, the torsion energy is transferred to all the space where the water of the boiler passes, and the water can be blocked, and amazing things happen that people become healthy. (Kim Hyun Won, Science of the Invisible World, Professor of Biochemistry, Yonsei University Wonju College of Medicine).

Therefore, when the conductive silicone rubber and the functional filler are additionally coated on the coated room, the function of the functional filler and the conductive path of the conductive silicone rubber are formed in the coil So that they are fused with an electromagnetic effect to exhibit a complex function.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation in the present invention. The invention may be embodied in many other forms. Accordingly, modifications of the embodiments of the present invention will not depart from the scope of the present invention.

1: Collective copper wire feeder
2: Coat yarn feeder
3: Thread tension equalizing device
4: Mixed copper wire and sheath mixed weaving machine
5: Mixed fabric tensioner
6: Mixed textile coating and thermosetting device
7: Coated fabric transfer device
8: Coated fabric tensioning device
11: core yarn
12: Covering yarn
31: glass fiber yarn
32: spindle
33: bobbin
34: balloon
41: Balloon guide
42: core yarn
43: bobbin
44: bobbin holder
45: a reserve disc
46: twisting disc
47: thread outlet
48: Balloon
49: spindle
50: hollow
61: Electrode line
62: slope of leno
63: selvage yarn

Claims (14)

A method of manufacturing an electric mesh heater, the method comprising: a collective copper wire process for collecting a plurality of copper wires twisted together; a combined twisting process for twisting a plurality of glass yarns; a covering process for covering the combined twisted yarn; And a coating and thermosetting step of coating the mixed and woven fabric with a conductive silicone rubber and thermally curing the same, characterized in that it comprises a tension equalizing step for uniforming the tensile strength of the mixed woven fabric A method of manufacturing an aspiration network. The method as claimed in claim 1, wherein the covering step is performed by supplying a covering chamber through the hollow (50) of the spindle (49) and the exit port (47) of the twisted plate (46) The center chamber 42 is supplied from the bobbin 43 to the balloon guide 41. After the covering chamber is pulled out of the exit port of the twisted plate and the outer periphery of the bobbin is rotated to form the balloon 48, And a step of twisting and winding the strand. delete delete delete delete delete BACKGROUND ART [0002] A wire mesh is formed by coating a conductive silicone rubber on woven fabrics in the form of a mesh woven with a glass fiber yarn, a covered yarn is formed by twisting a covering yarn in a glass yarn which is a core yarn, and the glass yarn as the center yarn is formed by an electric mesh heater having a plied yarn ),
The conductive silicone rubber is composed of silicone rubber having a vinyl group content of 0.1 to 10 mol%, conductive carbon black, and EPM (Ethylene Propylene Copolymer) having a Mooney viscosity (ML _{1 + 4} , 100 ° C.) of 10 to 30 Aspire to. delete delete delete delete An apparatus for manufacturing a wire netting, comprising: a collective copper wire feeder (1) for feeding an integrated copper wire produced through a collecting process of twisting a plurality of copper wires to a mixing loom; A yarn tension equalizing device (3) for uniformly feeding the tension of the bundle copper wire and the cover yarn to the mixing loom, a yarn tension adjusting device (5) for maintaining the tension of the mixed fabric woven through the mixed weaving machine, a mixer for coating the mixed and woven fabric with conductive silicone rubber and thermally curing the mixed weaving fabric A fabric coating and thermal hardening device 6, a coating fabric transfer device 7 for transferring and winding the coated mixed fabric, and a coating fabric winding device 8 Manufacturing equipment of the former aspire to a gong. The coating machine according to claim 13, wherein the coating chamber supply device comprises a hollow 50 of the spindle 49, a twist plate 46, an exit port 47, a bobbin holder 44 located above the twist plate, And a balloon guide 41. The bobbin holder is a fixing device for supporting the bobbin 43 of the center chamber 42. The bobbin holder is fixed to the top of the twisted- Wherein the storage plate supports the bobbin holder and the bobbin holder is not rotated even if the twisted plate is rotated by the spindle.

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