KR200406376Y1 - Nano silver contain a wire - Google Patents

Abstract

The present invention relates to the mixing 160 or coating 180 of the silver nano 120 on the material of the wire 100 made of a metal or a synthetic resin material, and more specifically, medical, clothing, semiconductor, food manufacturing, which requires antimicrobial power. By injecting the silver nano 120 into the body or surface of the wire 100 to be used in the surface strength of the wire 100 and the sterilization and antibacterial function, lubricating function and heat resistance and durability and elasticity And it relates to an excellent functional wire 100 having corrosion resistance and chemical resistance.

Wire, sterilization, antibacterial, silver, silver nano, far infrared rays, anion

Description

Nano silver contain a wire}

1 is a perspective view of a wire containing silver nano of the present invention.

2 is a mixed block diagram of a wire containing silver nano of the present invention.

Figure 3 is a block diagram of the wet coating of the wire containing silver nano of the present invention.

4 is a block diagram of a dry coating of a wire containing silver nano of the present invention.

FIG. 5 is a photograph taken at 60,000 times magnification of a cross section of a wire containing silver nano of the present invention.

Figure 6 is a photograph of a magnified 80,000-fold magnification of the side of the wire containing silver nano of the present invention.

7 is a three-dimensional structural diagram of silver nano for explaining the silver nano of the present invention.

Figure 8 is a photograph of the antimicrobial activity of the strain into which the silver nano of the present invention.

9 is Staphylococcus aureus, pneumococci, bacteria in which the silver nano of the present invention is added.

MRSA (Methicillin-Resistant Staphylococcus Aureus) Bacteria Antimicrobial Test Picture.

* Description of the symbols for the main parts of the drawings *

100: wire 120: silver nano

160: Mix 180: Coating

200: deposition, lamination, deposition, thin film, plating, spraying

220: melting 240: melting

260: drying 280: stirring

300: barrel 320: elution

340: molding 360: softening

380: molding module 400: chamber

420: washing step 440: rinsing step

460: polishing step 480: plating tank

500: initial plating 520: nickel plating

540: gas injection process 560: sterilization process

580: silver nanoplate 600: 1st surface finish

620: secondary surface finish 640: finished

The present invention relates to coating (180) or coating (180) the silver nano (120) on a material of the wire 100 made of a metal or a synthetic resin material, and more specifically, medical, semiconductor, clothing, etc. By injecting silver nano into the body or surface of the metal wire 100 used in food manufacturing, the surface strength of the wire 100 is strengthened and sterilized and antibacterial function, lubrication function and heat resistance and durability and elasticity and corrosion resistance And a functional wire 100 having excellent chemical resistance.

Conventional wire 100 is made of metal and synthetic resin, and the metal wire 100 is typically made of stainless steel or titanium, nickel, copper, tin, iron, duralumin, and metal wire such as stainless steel or titanium It is used for orthodontic use of herbal needles or in dentistry, or for fixing bones in surgery, and is widely used in food and beverage, semiconductor manufacturing, and laboratories.

The present invention is made of a metal or a synthetic resin material as described above, the mixture of the silver nano 160 to the body of the wire 100 for the purpose of antibacterial and hygienic use in medical or household goods, industrial sites (160) or of the wire 100 Silver nano-coated 180 on the surface of the body relates to an excellent functional wire 100 having surface strength enhancement and sterilization and antibacterial function, lubricating function and heat resistance and durability and elasticity and corrosion resistance and chemical resistance.

  The wire 100 containing the silver nano 120 of the present application is injected during the manufacture of the wire 100 body without surrounding physical and electrical sterilization, so that the economic and economical antiseptic power is unsurpassed. Since it contains a silver nano to the material of the wire 100 can be continuously obtained excellent advantages as follows.

Silver nano 120 is harmless to the human body and has a sterilization station and antibacterial power several times stronger than chlorine series.

If so, the characteristics of the wire 100 containing silver nano 120 of the present application

 1: Compared to the conventional wire 100, the silver nano 120 mixed 160 or coated 180 wire 100 has a surface strength enhancement and sterilization and antibacterial function, lubrication function and heat resistance and durability and elasticity It has excellent corrosion resistance and chemical resistance, and when it is used in underwear of medical institution or women's bra, it generates healthy negative ion and far infrared rays, which makes blood circulation and endocrine activity active. It blocks more than% and protects skin by antiviral and anti-allergic vitamin B6 and has a soft touch and deodorizing effect.

  2: It reacts sensitively according to the pollution level of the surrounding environment

It binds strongly to bacterial cell membranes and destroys the bacterial cell membranes or disrupts the function of the cells, resulting in continuous antiseptic action.

 Recent research has shown that 650 bacteria and viruses can be sterilized, and the reproductive and anti-bacterial functions are excellent for harmful bacteria, fungi, athlete's foot, and allergic bacteria. Nano 120 catalyzes the conversion of oxygen to free radicals, which prevents the sterilization action and the proliferation of bacteria that grow by sweat and body fluids or secretions secreted by the human body. Blocks the growth of bacteria that occur in the city.

  3: There is an antistatic function. The silver nano 120 has excellent electrical conductivity and plays a big role in preventing static electricity and blocking harmful electromagnetic waves.

  4: The silver nano 120 is very easy to coat 180, mix 120, and the like with a material, and is easily fused with a metal, a synthetic resin, or a fiber.

   5: It also produces a healthy negative ion and has a fast color reaction that changes color depending on the user's health.

   The present invention is intended to complete the excellent wire 100 that can contribute to the improvement of public health by mixing 160 or coating 180 with silver nano 120 material having a superior effect as described above to the wire 100 will be.

The present invention is to solve the conventional problems as described above, the present invention is a silver nano-120 (Nano silver) powder or silver nano-dilution of a different technology from the conventional silver powder and silver ions (120) The silver nano 120 is added in an amount of 0.001 to 20% by weight based on the total weight of the body of the wire 100 made of a metal or a synthetic resin material which is a material of the body of the wire 100, or the wire (in PPM) 100) with respect to the total content of 100) in a unit of PPM between 0.01 and 999 PPM to elute or form (190) or form a coating (180) film of any one of deposition, lamination, thin film, deposition, plating, spraying Surface strength and sterilization and antibacterial function, lubrication function and heat resistance and durability and elasticity and corrosion resistance and chemical resistance with the purpose of manufacturing the excellent functional wire 100.

The present invention, as described above, silver nano 120 powder or silver nano 120 silver (Ag) in which the powder is diluted in wire 100 used in a medical institution, a food company, a laboratory, a garment, a laboratory ) Is a mixture of the solution 120 and the coating 180 more specifically, the wire 100 made of a conventional metal or a synthetic resin material of the silver nano (100) powder made of various silver nano methods or a solution diluted therein 0.001 to 20% by weight relative to the total weight of the wire 100 is mixed 160 in the body of the wire 100 and molded (340) or eluted 320 or silver nano solution in the body of the wire 100 Is mixed or deposited, deposited, thin film, deposited, plated, or sprayed on the surface of the wire 100 in a PPM unit between 0.01 and 999 PPM with respect to the total content of the wire 100 in PPM units. Coating (180) membrane As sex and on the wire (100), characterized in that the body surface to 0.01 to 100㎛ (micro) dry or wet coating 180 has a thickness of a nano-cored wire 100,

The particle size of the silver nano 120 injected into the body of the wire 100 is related to the wire 100 containing silver nano, which is characterized by having a particle size of 0.01 to 100 nm, medical, clothing, household goods, laboratory Wire 100 widely used in laboratories, food manufacturing companies, surface strength strengthening, sterilization and antibacterial function, lubrication function and heat resistance and durability, elasticity and corrosion resistance and chemical resistance, anion and far infrared radiation functional wire The purpose is to produce (100).

 In order to help the understanding of the present invention will be described in detail the silver and silver nano 120 of the material of the present invention as follows.

   Silver, the main component of silver nano, has been recognized as a precious metal of high value from ancient times, and has been the object of extraction. It is not only valued as a currency but also gained attention as an important industrial material in modern industry. It is proportional to the production of gold.

Characteristics of silver: The color of silver is gray for elegant gray-white metals and powders. Specific gravity is 10-12, Mohs hardness is 2.5-3, and melting (80) is 960.5 ℃.

In particular, the melting point of silver is very important for the temperature compensation of high thermometers, which is the standard of scientific and industrial temperature. Silver is the best conductor of metal and is used extensively for mechanical contacts and other electronics.

Silver is optically 90% of visible light, which is one of the best metals such as platinum, and silver does not rust even when left in the air or heated. However, silver reacts with sulfur and hydrogen to make emulsified silver. There is a changing nature.

 In addition, the mechanical properties change according to the amount of impurities (O₂) contained in the silver, and the hardness of the high-purity silver obtained by thermal annealing is Brinell hardness HBS (10/500) 25-27, tensile strength 12-16kgf / mm2. The cast material had a tensile strength of up to about 29 kgf / mm 2, and a recrystallization temperature of 150 ° C.

    In particular, in the case of pure silver, the processed hardened material is softened by recrystallization at normal room temperature and softened softly. The malleability and flexibility are rich after gold.

     The effect of silver has been used as a tool to check the imbalance of the body that one does not feel because the gloss and color change depending on the condition of the body when worn on the body from ancient times. If you are tired or have low rhythm), Dongbobom is effective in the prevention and treatment of mental disorders and women's diseases such as epilepsy and game. If you have it, the five Jang (5 하고) is comfortable, mind and body (stable), the mind and body ((身 身) stable), chasing (邪氣) and the body lightens the body lengthened by the main tree.

      In addition, when the Black Plague prevailed in the Middle Ages, aristocrats and royal families who had many silver utensils or silver utensils were not infected with black plagues. In the place where the royal family and the state guests were served, silver products were used habitually.

Briefly describing the silver nano (Nano silver) extraction method and features in the present invention to help the understanding of the silver nano 160 as follows.

The atomic weight of silver is 107.87 amu and the fact that silver (Ag) is bactericidal has been known for a long time.

Silver nano was first developed by a biotechnology company, a government subsidiary of our country, and was named silver nano as a compound name of the brand name Na no-technology and silver;

  Silver nano 120 is a field of Na no-technology, which is an advanced antimicrobial agent that uses silver's strong antibacterial and bactericidal function and excellent electrical conductivity mechanism. Silver nano is unlikely to be resistant to bacteria, unlike conventional antibiotics. Silver nano has been shown to kill almost all single cell germs on the ground in a short time.

 Currently, a variety of products based on silver nano120 consisting of powders and solutions have been devised and manufactured in real life. This technology, called silver nano, is used to convert silver to nanometers (one billionth of a meter). ) It is a small particle size of 0.000000001m. When one gram of silver is aged, ten particles can be produced.

Therefore, silver silver, which has been aged into ultra-fine particles, is a new concept that is made of excellent properties such as anti-microbial power, deodorization zone, and longer food preservation time.

 Since ancient times, silver has been recognized as a material that not only prevents germs but also disinfects both East and West. Currently, the extraction method of silver nano is used by adding silver (Age 99.9%) to distilled water and generating low current at low temperature. The electrolyzed by using the + and-poles of each molecule to collect the silver (Age 99.9%), and can also be produced by physical methods such as liquid reduction, grinding, etc. In order to obtain a stable silver nano (Nano silver), the conventional electrolytic method may be used a lot. The various well-known manufacturing methods of the silver nano 120 may be described as follows.

The manufacturing method of silver nano 120 is currently being released in a variety of ways, and good methods are being developed and developed one after another. Conventional nano powder manufacturing methods can be divided into gas phase manufacturing method, liquid phase manufacturing method and mechanical manufacturing method. In addition, there are gas condensation and gas reduction methods, and there is also a mechanical grinding method using mechanical force.

The uniformity of the particle size of the prepared powder is good and can produce particles of high purity, and the advantages and disadvantages of preventing the agglomeration of the particles have the disadvantage that the experimental equipment is expensive.

In addition, the manufacturing method using the liquid phase is capable of producing a uniform powder than the manufacturing method using the gas phase, and also has the advantage of manufacturing the powder at a low device cost, but the tendency of aggregation of the individual particles is very strong and the shape of the particles is somewhat irregular The disadvantage is that.

Next, there is a systematic, manufacturing method, there is a problem in the mixing of impurities generated in the manufacturing process and the disadvantages of aggregating phenomenon is severe, while there is an advantage that can easily mix several components.

The present invention does not produce the silver nano 120 according to the manufacturing method of the silver nano 120, but the conventional silver nano 120 produced through the various types of silver nano 120 manufacturing method applied to the present invention wire There is a feature of the present application in making (100).

The silver nano 120 of the present invention is a micro fine particle of silver having a particle size of 0.01 to 100 nm, which directly acts on harmful bacteria, directly dissolves the cell membranes of harmful bacteria and interferes with the electron transfer system of the harmful bacteria, thereby making it safe. Has excellent antibacterial and antibacterial properties (99.9%).

The main antimicrobial mechanism of silver nano 120 is to dissolve harmful bacteria cell membranes and work with enzymes in the cells to block the metabolic function of nutrients, that is, the influx and discharge of nutrients, and to stop the respiratory function and production of harmful bacteria, thus stopping the growth of harmful bacteria. And destroys regenerating ability to kill harmful bacteria.

     In addition, since the silver nano 120 continuously controls the harmful bacteria by releasing antimicrobial activity from the fine particles, the antimicrobial and bactericidal function has excellent sustainability.

Therefore, silver nano is not resistant and silver nano has a surface reaction to have an effect, and kills 99% of all bacteria, and is particularly effective for general E. coli and food poisoning.

   The smaller the nanoparticles, the better the bactericidal and antimicrobial activity. Based on the experimental data so far, Escherichia coli, Staphylococcus aureus, Salmonella, Vibrio bacillus, Heterogeneous bacteria, Pneumococcus, Typhoid bacillus and the most resistant MRSA Resistant Staphylococcus aureus) can be 99.9% antibacterial and sterilized.

     Even if silver exists in an ionic state or a metal state, it can be referred to as colloidal silver if it exists in a colloidal state by a solvent.

In silver nano silver nanoparticles have the best antibacterial activity.

   In addition, unlike the general chemical antimicrobial agent or chlorine disinfectant, silver nano 120 is a pure silver ultra fine particle, and therefore has excellent antibacterial and antibacterial properties (99.9%) even at high temperature. It is reported that fungi cannot live in contact with silver nano120 for more than 5 minutes.

 The present invention is a powder of silver nano (120) form or diluted to the body of the wire 100 made of a metal material used in medical institutions, semiconductor companies, clothing, pharmaceutical companies, laboratories, food manufacturing companies Mixing (160) or coating (180) silver nano (120) solution to strengthen the surface strength and sterilization and antibacterial function, lubrication and heat resistance, durability, elasticity, corrosion resistance, chemical resistance, far infrared rays and anion to wire 100 It relates to an excellent functional wire 100 to be.

Next, a brief description of the wire 100 containing the silver nano120 of the present invention for achieving the above object as follows.

 Hereinafter, with reference to the accompanying drawings a preferred embodiment of the present invention will be briefly described.

1 is a perspective view showing a silver nanowire 100 of the present invention in a perspective view showing a wire 100 made of a conventional metal or synthetic resin material generally used,

FIG. 2 is a mixed block diagram of a metal wire 100 containing silver nanoparticles of the present invention, in which a metal raw material, which is a material of the wire 100, is poured into a vessel 300 and heated to melt 240 or melt 220. And silver powder (120) (Nano silver) form or diluted with the powder

The silver nano 120 solution is added to the forming module 380 after stirring 280, and then the molding 340 is completed, followed by a cooling process 460 through a cooling process 460. With respect to the total weight of the body of the wire 100 made of silver nano 120 (Nano silver) powder or silver nano 120 solution diluted with the powder is added to the wire 100 in 0.001 to 20% by weight The size of the silver nano 120 particles relates to a wire 100 having a particle diameter of 0.01 to 100 nm, and a method of manufacturing the wire 100 of the present invention is to follow a known manufacturing process of the wire 100. will be.

FIG. 3 is a block diagram of the wet coating 180 of the metal wire 100 containing silver nanoparticles of the present invention, and the silver nano120 powder of the present invention or silver nanoparticles diluted with the powder ( 120) the solution is deposited on the surface of the wire 100 to a thickness of 0.01 to 100㎛ (micro) thickness, as a block diagram of the coating 180 process by any one of deposition, deposition, lamination, thin film, plating, spraying 200 This is described as follows.

Coating 180 is generally divided into deposition, thin coating (180) and electroless coating (180), deposition, deposition coating (180) and spray coating (180) is largely divided into silver Electrolytic plating of silver nano 120 is required to coat the outside of the completed wire 640, which requires a solution containing ions and a gold nano ion solution for gold plating. We can use both the wet plating method of plating or the dry plating method using plasma,

 The present invention follows a conventional coating 180 method, and many types and methods of the coating 180 are not able to list all of the preferred embodiments. First, a method of plating silver nano is divided into electroplating and electroless plating. Electrolytic plating uses electric current and electroless plating is literally plated through chemical reactions without using electricity. In other words, plating means that metal ions receive electrons and are reduced to stick to a specific surface. Plating is most commonly plated using electricity from the rectifier.

 However, in places where electricity does not pass, such as synthetic resins, rubber, and silicones, which cannot provide electricity to the substrate, the metal cannot be plated by plating on it. The sieve is plated.

There are two methods of electroless plating, one of which is ① reduction plating ② substitution plating method. The reduction plating method is a plating method in which metal is precipitated through reduction reaction. Activates the substrate surface to "+" state. When controlling, the surfactant component is used.

1) Catalyst: Colloidal component of Palladium is attached to the surface of "+" activated synthetic resin.

2) Accelerator: (Palladium) It removes Sn (Tin) which is contained in Palladium colloid and protects Pd and makes Pd Metal precipitate on the surface of synthetic resin.

3) Electroless chemical plating: copper ions, ethylenethiamine tetraacetic acid (EDTA), sodium hydroxide (NaOH), formaldehyde components, Pd acts as a catalyst when Na OH raises the pH above 11 Formaldehyde undergoes a powerful reducing action, at which time electrons are generated and these electrons flow into the copper ions, whereby copper ions are deposited on the Pd catalyst to be applied.

The second substitution plating is as follows.

Substitution plating method is caused by the difference of oxidation / reduction power. Representative materials of substitution plating are Ni / Au, Ag plating, and Ni is electrodeposited on the metal surface using the same method as electroless chemical copper plating method. Then, when immersed in a solution containing silver ions, the silver ions are inherently stronger than nickel, so the reducing power is much stronger than that of nickel. It is oxidized to become an ion, and silver receives electrons from nickel and is reduced to become electrodeposition.

Next, the electroplating 180, which is electroplating, will be described.

 When the electrode is placed in an aqueous solution containing metal ions and a current is passed through it, the metal ions are discharged and precipitated from the cathode, and a thin film of metal is formed on the surface of the article placed on the cathode.

The purpose of the coating 180 is to beautifully finish the appearance of the article, to increase corrosion resistance, to resist wear and corrosion, and to obtain other necessary surface properties. This is to increase the antibacterial and sterilizing power of the wire 100.

 The general procedure of the electroplating in the present application is to pre-plating nickel (500) with copper on the metal surface of the wire 100 made of a metal and second to the nickel nano (120) coating 180 to coat the coating well This process may be omitted as necessary for plating (520), and finally, the silver nano (120) is coated (180).

 The silver nano 120 is used as a cathode, and the metal to be electrodeposited is used as an anode, and the silver nano 120 is immersed in an electrolyte containing nano silver ions to be electrodeposited. Will stick to the surface of (100).

Looking at the process of coating the nanowires 160 on the wire 100, the washing process 420 and the rinsing process 440 to shake off impurities on the body of the completed wire 640 are carried out. After the polishing process (460) with (麻布) and washed again with clean water (洗滌) and immersed in the plating solution.

In the plating tank 480, the wire 100 is stored in a container for receiving the wire 100 to be coated with silver nano 120 (Nano silver) 180 and connected with the wire 100 on the positive side and the negative pole. The silver nano plate 580 is connected to the side, and the silver nano 120 solution containing silver nano 120 ions is injected and DC electricity is flowed to the + and-poles. 120) (Nano silver) is to be coated (180) and the coated (180) silver nano (120) (Nano silver) wire (100) once again washing process (420) and drying (260) process (260) After going through the drying (260) to complete (640) will be packed.

As described above, an object to be coated 180 is attached to the -pole of the electrode (the wire 100 is attached, and the silver nanoplate 580 is attached to the + pole) so that the positive and negative ions of the silver fall, where the electron is the negative pole of the wire 100. Of course, the aqueous solution contains silver nano (120) (Nano silver) ions-When the electrons come to the pole, the silver nano (120) (Nano silver) ions in the aqueous solution around the wire (100) will stick to In this way, the wire 100 is a nano 120 wet coating (180).

 The thickness of the coating 180 of the silver nano 120 (Nano silver) wet coating 180 is a coating 180 with a thickness of 0.01 μm to 100 μm (micrometer) and it is applied to the entirety of the wire 100 in a weight ratio. In the amount of 0.001 to 20% by weight and the particle size of the silver nano 120 is to be coated 180 with a particle diameter of 0.01 to 100nm.

In addition, the embodiment of the silver nano 120 coating 180 has the characteristics of the present application since it follows the conventional coating 180 method and used the coating 180 material as the aged silver nano 120 material. will be.

FIG. 4 is a block diagram of the dry coating 180 of the wire 100 containing silver nano of the present invention, which is capable of coating 180 all of the wires 100 of metal or synthetic resin material. Looking at the plasma coating 180 of the dry plating method of sputtering, deposition, thin film are as follows.

Plasma is a gaseous state that is separated into electrons with positive charges and positively charged ions at high temperatures, and has a high degree of charge separation but is neutral because of the same number of positive and positive charges.

 Since the long-acting Coulomb force acts between charges, it is characterized by the collective action of the whole moving under the influence of the distant state rather than the local state of the short distance. In 1928, I. Langmuer, USA, first applied the concept of plasma to ionized gases produced during electrical discharges.

  Plasma is derived from the Greek words πλσμα, -ατos, τ, and its original meaning is that it is built and assembled, and as the characteristics of group behavior suggest, it actually deals with plasma. There is a view that Plasma itself is usually behaving arbitrarily rather than easily controlled from the outside, and that the original name is wrong.So, Plasma is the fourth to be followed by solid, liquid, and gas (three states of matter). It is called material state.

As the temperature gradually increases, almost all objects change from solid to liquid and gaseous state, and at tens of thousands of degrees Celsius, the gas is separated into electrons and nuclei and becomes plasma.

Each object that makes up the plasma is electric, so it is very different from the neutral gas, has a high electrical conductivity, and the current is limited to the surface like a metal conductor. When applied, it is easily affected by the force as a charge, but as the charge density increases, the group movement differs from the individual movement, and the self-closing required by nuclear fusion means that the charge follows the magnetic field line. It is used to confine the Plasma to it by properly deforming the magnetic force line and confining it to a place in space.

 In the past, plasma research has been conducted in geophysics and astrophysics related to plasma around the earth and celestial bodies, but recently, the development of electromagnetic fluid dynamics (MHD) using the electrical properties of plasma, ion engines of space travel rockets, Research is underway for nuclear fusion research, and it has been a long time since the Department of Plasma was established in the science and engineering fields of Korean universities.

 As such, the high temperature and active chemical properties of plasma can provide extreme environments that are difficult to obtain by conventional methods and can be used to give new physical and chemical properties different from the body by changing the properties of new materials, metals or polymer surfaces. there is,

Diamond, for example, is an important material not only for jewelry but also for industry because of its high hardness, thermal conductivity, refractive index, and large band gap. Artificial synthesis of diamond was developed by GE company in USA in the 1950s. Although a high temperature and high pressure method has been mainly used, it was found in the early 80s that diamonds could be obtained in a thin film form from methane gas plasma at low pressure in the USSR. Medical Device Coatings 180 New applications are actively being explored.

In addition, the wear-resistant coating 180, the decorative coating 180 of the tool, it can be made by the dry method through the reactive ion plating or sputtering, thin film method used as a diffusion barrier at the contact point in the manufacture of the semiconductor device.

In addition, if the surface of the polymer is treated with nitrogen or oxygen plasma, it can give hydrophilicity or hydrophobicity to the surface of the polymer, or it can improve antistatic, dichroic, deep color, etc. When contacted with a plasma and biased, a nitride or carburized layer is formed on the surface to improve the hardness, wear resistance, and corrosion resistance of the metal.

Some of the effects that can be obtained by the surface coating 180 and the reforming technique using plasma can be obtained by the conventional wet plating or coating 180 method. However, in consideration of environmental pollution, dryness using plasma can be achieved. The method has many advantages, and the application of thermal plasma enables plasma welding, cutting, processing of materials using high temperature of plasma and thermal spraying of plasma, and melting high-melting powder into plasma to solid surface Coating 180 on (coating) is to significantly increase the heat resistance, corrosion resistance, wear resistance and the like.

 In addition, ultra-fine particles can be manufactured and the particles synthesized using high temperature and high activity of thermal plasma are quenched and synthesized into ultra-fine particles to deposit plasma chemically or physically and to produce a functional film using plasma. The high temperature, high activity of the thermal plasma allows the waste to be decomposed and vitrified.

As such, the plasma coating 180 turns the vacuum chamber 400 into a vacuum, injects argon and other inert gas, and then causes electrical discharge, thereby ionizing the gases introduced into the chamber 400. ) The process of colliding with the target (silver nano plate (target)) and the silver nano 120 atoms protruding in the gaseous state to be coated 180 on the plated body (wire 100). The thickness can be controlled.

Next, a brief description of the coating 180 process of the wire 100 using the plasma (Plasma) of the present invention as follows.

 In order to clean the foreign substance on the surface of the completed wire 640, the wire 100 is put into the washing tub, the cleaning solution is injected, and is attached to the inside or outside of the manufacturing process of the wire 100, which is a metal material, using a washing machine. After the washing process (420) for washing the impurities present, the rinsing process (460) and the drying (260) in the dryer to evaporate the moisture and then the wire 100 to the holder (not shown) attached to the chamber After the sterilization process (560) to the outside of the wire 100 into the plasma under the vacuum is put into (400) is to perform the surface processing work silver nano (120).

Next, after the plasma sterilization process (580) and the silver nano (120) primary surface processing (600), the surface adhesion of the wire 100 coated with silver nano 120 (180) and the wire ( Plasma secondary surface processing (620) and reinforcement treatment are performed to increase the strength of 100).

Next, in the plasma coating 180 of the silver nano120 finally by the vacuum macnetron stuffing plasma coating method 180, the thickness of the plasma plating coating 180 of 0.01 μm to 100 μm (micrometer) is preferable. Finished by coating 180 with plasma to a thickness (640) or by applying silver nano 120 material to the metal material of the wire 100 at 0.001 to 20% by weight relative to the total weight of the wire 100. 120 is mixed or coated with a surface of the wire 100 by any one of deposition, lamination, deposition, thin film, plating, spraying 200 to a thickness of 0.01 to 100㎛ (micro) It is also possible to 180.

As a result, the wires 100 mixed with 160 or coated 180 with the silver nano 120 are completed 640 and can be used hygienically and effectively in use.

Next, the cross-section, side and the surface of the silver nano 120 of the present invention are illustrated in the drawings for the understanding of the present invention, respectively, by means of an electron microscope.

FIG. 5 is a photograph taken at 60,000 times magnification of a cross section of the wire 100 containing silver nano of the present invention.

FIG. 6 is a photograph taken at 80,000 times magnification of the side surface of the wire 100 containing silver nano of the present invention.

Figure 7 is a photograph taken by magnification of 50,000 times the surface of the wire 100 containing silver nano of the present invention.

8 is a three-dimensional structural diagram of silver nano for explaining the silver nano of the present invention.

Figure 9 is a photograph of the antimicrobial activity of the strain into which the silver nano of the present invention.

10 is Staphylococcus aureus, pneumococci, bacteria in which the silver nano of the present invention is added.

MRSA (Methicillin-Resistant Staphylococcus Aureus) Bacteria Antimicrobial Test Picture.

In the above, the overall manufacturing process and configuration of the wire 100 for musical instruments of the present invention was examined in detail, and the surface reinforcement, lubrication, heat resistance and durability, elasticity, anion, and far infrared emission of the wire 100 of the present invention were examined. In order to anti-sterilize silver nano 120 is extremely preferred and the amount of the mixture 160 is preferably 0.001 to 20% by weight in each of the wire 100 made of metal.

 At 0.001% by weight or less, the lubricity, heat resistance, durability, elasticity, surface strength strengthening and antiseptic effect are not shown at all. This is because it is practically difficult to manufacture 100).

As described above, the silver nano 120 material having strong antimicrobial sterilization, lubrication, heat resistance, durability, and elasticity is contained in an amount of 0.001 to 20% by weight based on the total weight of the metal or synthetic resin material, which is a raw material of the wire 100. Mixing 160 by one of the preferred weight% and coating 180 at the time of coating 180 is to use the wire 100 to a thickness of 0.01 to 100㎛ on the body surface of the wire 100.

The present invention is a mixture 160 of silver nano 120 (Nano silver) to the wire 100 or deposited, deposited, laminated, thin film, plating sprayed to the outer surface of the wire 100 to a thickness of 0.01 to 100 ㎛ (micro) Coating 180 by any one of the preferred method has a good functional wire 100 having the surface strength of the wire 100 and sterilization and antibacterial function, lubricating function and heat resistance and durability and elasticity and corrosion resistance and chemical resistance It is characteristic in that it is.

The terms or words used in this specification and claims are not to be construed as limiting in their usual or dictionary meanings, and the inventors may appropriately define the concepts of terms in order to best describe their own design. It should be interpreted as meaning and concept corresponding to the technical idea of the present invention on the basis of the principle of the present invention.

Therefore, the embodiments described in the specification and the drawings shown in the drawings are only the most preferred embodiment of the present invention and do not represent all of the technical idea of the present invention, various modifications that can be substituted for them at the time of the present application It should be understood that there may be equivalents and variations.

As described above, the present invention provides silver nano 120 (NANO SILVER) powder or nano silver (Ag) solution diluted with silver nano 120 having many advantages to the metal or synthetic resin material which is a raw material of the wire 100. Mix (160) nano (120) at any constant weight ratio between 0.001 and 20 weight percent Alternatively, the silver nano 120 material may be deposited on the outside of the wire 100 in a thickness of 0.01 to 100 μm (micro), and then coated 180 by any one of the preferred methods of depositing, depositing, laminating, thin film, plating, and spraying 200. Of wire 100

It can have secondary bacterial infection prevention, heat resistance, durability, elasticity, lubrication, anion and far infrared generation effect.

In the above, the embodiments or preferred embodiments of the present invention are easily described, and those skilled in the art to which the present invention pertains can devise the present invention in various ways without departing from the scope and spirit of the present invention described in the claims below. It will be appreciated that modifications and variations are possible.

Claims (4)

In the wire 100 made of metal or synthetic resin material. Silver or aged silver nano (100) powder or solution 0.001 to 20% by weight based on the total weight of the material of the wire 100 is mixed (160) is characterized by having a configuration 340 or eluted (320) Phosphorous silver nanowires. The method of claim 1,  The coating of any one of the silver nano solution on the surface of the wire 100 in the body of the wire 100 in 0.01 to 999 PPM mixed or deposited, laminated, thin film, deposition, plating, spraying A wire containing silver nanos, characterized in that it further comprises that a film is formed. The method according to claim 2, The silver nano (120) powder or silver nano solution containing the dilute silver nano wire, characterized in that the dry or wet coating 180 to a thickness of 0.01 to 100㎛ (micro) on the surface of the body body 100. The method according to claim 1 or 2, Particle size of the silver nano 120 injected into the body of the wire 100 is a wire containing silver nano, characterized in that having a particle size of 0.01 to 100nm.

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