KR200396759Y1 - Nano silver self tableware - Google Patents

Abstract

The present invention relates to a tray that is widely used in large restaurants such as schools, factories, the military, etc., mainly for group meals, a plurality of receiving unit 120 is formed of a plate made of metal or synthetic resin material

 When preparing the main body 200 of the plate 200 made of metal or synthetic resin as a raw material of the plate plate of silver nano powder (Nano silver) or a silver nano solution in which the silver nano powder is dissolved in water The present invention relates to a method of mixing the silver nano 160 powder in a constant weight ratio or coating the inside and the outside of the plate with silver nano powder, which is capable of maintaining a clean plate that is exposed to various germs at all times to be clean and fresh. (160) (Nano silver) relates to a tray containing.

Description

Functional pear plate {Nano silver self tableware}

The present invention relates to a plate, more specifically, the present invention relates to a plate widely used in large restaurants such as schools, factories, the military, mainly for group meals, generally a metal plate such as synthetic resin or stainless steel The plate is manufactured by injection molding or press molding is widely used in large restaurants such as the military, schools, factories, such as a group meal, such a plate is formed a plurality of receiving portion 120 to hold food The edge is planar so that it can be gripped by a line.

Such a tray is to grab food on both sides of the edge with your hand and then move the food to the table while holding food in the container 120 as much as you want.

 In general, the plate is largely the main body 80 and the three to five side dishes 90, one rice space 40, one soup space 110 and the receiving portion 120 and cutlery groove 130 Divided into) and rice, soup stew and side dishes all in one place has the advantage that you can eat free.

The plate is always equipped with water and various foods, and even if you clean it in the kitchen after a meal, you can receive various foods.There is a scent of food and there is a risk of germs or infection in the hot summer season. Because of the greater exposure and the feeding of hundreds of thousands of people, the contaminated food being fed can lead to numerous infections, especially for young children who are less resistant.

The present invention sterilizes germs that may occur in contaminated food or plate by putting or coating silver nano (160) powder on the plate that is widely used in large restaurants such as schools, factories, and the military. The purpose is to create a clean, clean and hygienic group meal environment.

The present invention occupies an important position in the group feeding after mixing silver nano powder, which is a strong antimicrobial bactericidal effect, with 0.01 to 20 parts by weight of silver nano powder based on the material of the plate and the total weight. By inserting silver nano (160) powder into metal or synthetic resin, which is the material of the plate, it is molded, injected or manufactured by adhesive or coating to sterilize with the parasitic bacteria on the plate and neutralizes odors. It is about a silver nano (160) plate that can improve food poisoning or bacterial infections that can occur and improve public health.

An object of the present invention is to solve the above conventional problems,

The silver nano powder with excellent sterilization advantages as described above is mixed with 0.01 to 20 parts by weight of silver nano powder based on the total weight of metal or synthetic resin, which is the raw material of the plate, to prevent the odor of food and breeding of bacteria and microorganisms. It provides a functional plate containing Nano silver powder which can be used hygienically at all times.

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The present invention is a meal plate made of any one of metal and non-metallic synthetic resin, ceramic, silicon, acrylic used in meals, the main body portion 80, side dish portion 90, rice bowl portion 40 and soup ball The body of the culture plate comprises 0.01 to 20 parts by weight of silver nano solution (160) powder or the powder dissolved in water based on the liver portion 110 and the groove 130 of the cutlery and chopsticks based on the total weight of the culture plate. In the mixed 200 or the coating on the surface of the body of the culture plate of the wet or dry coating method of any one of the methods of the coating (180) further comprising the size of the fine particles of the silver nano 160 to the culture plate It has a particle diameter of 0.1 to 300nm and is characterized in that the silver nano (160) powder coating film is formed on the body of the tray to the thickness of 0.0l㎛ ~ 50㎛. It relates to a meal plate 80 consisting of the main body portion 80, the side dish portion 90, the rice bowl portion 40, the soup bowl portion 110, the cutlery and the red hole of the plate 130 of the serving plate It relates to a functional culture plate that puts the silver nano (160) material into the main body 80 of the culture plate to perform sterilization and antibacterial action, the silver nano (160) powder (Nano silver) and colo This month (Colloidal Silver) is a silver nano (160) powder in 0.01 to 20 parts by weight based on the entire metal or non-metallic plate made of a variety of materials such as metal, synthetic resin, rubber, minerals, ceramics, silicon, such as the plate Mixing or coating 180 and the other metals 20 to 99 parts by weight of stainless steel, 10 to 99 parts by weight of iron, 10 to 99 parts by weight of titanium. 0.01 to 10 parts by weight of gold or gold nanoparticles, 0.01 to 10 parts by weight of zinc, 0.01 to 10 parts by weight of platinum or platinum nanoparticles, which may be prepared by feeding into a tray, and the silver nano 160 powder particles The size of the relates to a functional culture plate containing silver nano 160 powder having a particle diameter of 0.1 to 300 nm.

 In order to help the understanding of the silver and silver nano (160) as a component of the present invention in detail as follows.

     Silver, the main ingredient of Nano silver (160), has been recognized as a precious metal of high value from ancient times, and has been the object of extraction. It is not only a value as a currency but also an important industrial material in modern industry. The production of silver is proportional to the production of gold in many ways.

Silver was mined early in Europe's Mediterranean coast, where silver was produced from the Incas and Aztecs before the discovery of the Americas, and then silver from Peru and Bolivia entered Europe and flowed out from 1520 to 1800.

It has grown steadily, but has declined since the discovery of large amounts of silver in the early 19th century.

Currently, the world's major silver producers are Russia (13.8%), Canada (13.5%), Mexico (13%), Peru (13%), United States (11%), Australia (8%), Poland (6%). The country's silver reserves are 17 million tons, and its mining capacity is about 1.2 million tons. As of 2002, silver produced in Korea is about 5,000 kg, which accounts for 1.2% of the total domestic demand. The amount is so small that the rest of the silver is imported from abroad.

Characteristics of silver: The color of silver is gray in the case of elegant gray-white metal or powder, specific gravity is 10-12, Mohs hardness is 2.5-3, and melting (80) point 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 cannot feel because the gloss or color changes depending on the condition of the body when worn on the body from ancient times. This fatigue or low rhythm), Dongbobogam said that it is effective in the prevention and treatment of mental disorders and women's diseases such as epilepsy and game. The five chapters are said to be comfortable, the mind and body are stabilized, and the main body records that the body is lengthened by chasing morale and lightening the body.

      Also, when the Black Plague prevailed in the Middle Ages, nobility of the black aristocrats and royals, who had many silverware and silver utensils, did not have black plague, which released silver to the extent that it was able to sterilize the Black Plague bacteria, making it relatively safe from infectious diseases. In the place where the royal family and the state guests were served, silver products were used habitually.

In order to help the understanding of the silver nano 160, the silver nano 160 (Nano silver) extraction method and features are briefly described in the present invention.

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 160 was first developed by a biotechnology company, a government subsidiary of our country, and was named silver nano 160 as a compound name of the brand name Nano-technology and silver;

  Silver nano 160 is a field of nano-technology, which is an advanced antimicrobial agent that utilizes silver's strong antibacterial and bactericidal function and excellent electrical conductivity mechanism. Silver nano (160) is unlikely to be resistant to bacteria, unlike conventional antibiotics. Silver nano (160) 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 nano (160) consisting of powders and solutions are designed and produced in real life. This technology, called silver nano (160), is used to convert silver to nanometers (1 billion won). It is a small particle size of 1m / min), that is, 0.000000001mm. When one gram of silver is aged, ten particles can be produced.

Therefore, silver nano (160) (Nano silver), which is made of silver in the form of ultra fine particles, is a new concept that is made by using excellent effects such as anti-bacterial power, deodorizing power, and longer food preservation time among many characteristics of silver. .

 Since ancient times, silver has been recognized as a disinfecting substance that not only prevents bacteria but also East and West. Currently, the extraction method of silver (160) is added to distilled water (Age 99.9%). It generates low current at low temperature, electrolyzes compounds containing silver, and conducts electrophoresis using + and-poles of each molecule to collect silver (Age 99.9%). In addition, liquid reduction and grinding It can be manufactured by physical methods such as, and the electrolysis method is used a lot to obtain a stable silver nano (160) (Nano silver).

Silver ions are also used in general sterilization concept machines and disinfectants, and all silver products currently used are silver obtained by decomposition, and the sterilization power of silver varies depending on the product, but can obtain up to 99%.

  Silver nano 160 is a fine particle of 1 ~ 5nm silver, which acts directly on harmful bacteria, directly dissolves harmful cell membranes, and sterilizes by disrupting the electron transfer system of harmful bacteria. 99.9%) (the virus size is about 10 nm).

     The main antibacterial mechanism of silver nano (160) is to dissolve harmful bacteria cell membranes and interact with enzymes in the cells to block the metabolic function of nutrients, that is, the influx and discharge of nutrients, and stop the respiration and production of harmful bacteria And destroys regenerating ability to kill harmful bacteria.

     In addition, since the silver nano 160 controls the harmful bacteria by releasing antimicrobial power continuously from the fine particles, the antimicrobial and bactericidal function is excellent in sustainability.

Therefore, silver nano (160) does not produce resistance and silver nano (160) has a surface reaction is effective and can kill all the germs 99%, especially in the common E. coli or food poisoning equality.

   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 the silver nano (160) (Nano silver), the silver nano (160) powder is minimized the best antibacterial activity.

   In addition, unlike the general chemical antimicrobial agent or chlorine disinfectant, silver nano 160 is an ultrafine particle of pure silver. It is reported that the bacteria can not live in contact with the silver nano 160 for more than 5 minutes.

Hereinafter, with reference to the accompanying drawings to describe the present invention in detail.

Method for producing a culture plate of the present invention is to follow the conventional manufacturing method of the plate and will be described below in detail a preferred embodiment of the present invention with reference to the accompanying drawings.

Figure 1 is a perspective view showing a silver nano (160) plate of the present invention is a diagram showing a plate made of a raw material of a conventional metal or synthetic resin generally used.

Figure 2 is a block diagram showing the manufacturing process of the functional synthetic resin plate of the present invention, Figure 3 is a block diagram showing the manufacturing process of the functional metal plate of the present invention

As shown, the process of injecting the silver nano (160) powder of the present invention into a plate made of synthetic resin, metal raw material is shown in the figure.

First, as shown in Figure 1, the plate of the present invention is composed of a side dish space portion that can put three to five side dishes, and a rice space portion that can put rice and a soup space portion that can put soup .

The main body 200 forms a space part that can hold three to five side dishes side by side on one side, thereby causing malodors and bacteria or food poisoning or acute enteritis caused by food waste on the plate. It is possible to prevent the source of the source to provide a clean, clean and sanitary dish plate.

Referring to the block diagram of the mixing (200) or molding process of the distribution plate made of synthetic resin and metal of the present invention of Figures 2 to 3

 As a block diagram of the mixing 200 process of the mixing plate containing silver nano 160 powder, the silver nano 160 powder or the silver nano powder with respect to the total weight of the serving plate made of metal, resin, ceramic, silicon, acrylic, etc. It relates to the mixing (200) or coating 180 of the silver nano solution dissolved in water in 0.01 to 20 parts by weight.

The material material of the tray is melted or melted (220), and then softened (360). The silver nano (160) powder is added at 0.01 to 20 parts by weight, mixed (200), and stirred to form a module (340). 380) is completed after the finishing process of the polishing process (480) and the back plate through the slow cooling process after the molding (340) will be described in detail as follows.

After removing this substance in a synthetic resin, it is added to the container 300, melted 220, softened 360, and 0.1 to 5 parts by weight of the paint, crosslinking agent and hardener based on the total weight of the tray. A pressure-sensitive adhesive was added and 0.01-20 parts by weight of the silver nano 160 powder and the size of the silver nano 160 powder particles were added to the culture plate material to have a particle size of 0.0 1 to 300 nm, and the curing was aggregated. In order to promote the curing agent or flocculant is added 1 to 5 parts by weight based on the total weight of the culture plate, and in order to give the color of the culture plate is injected into the molding module 380 molded by injection into 0.1 to 5 parts by weight of the pigment or injection or The molding 340 is cooled, dried, and then subjected to a drying 260 process, followed by inspection and packaging and completion, followed by a block diagram illustrating the type and method of the injection molding 340.

1, injection molding 340

 It is suitable for mass production of complex shaped products by the molding method of forming the molding plate 340 by heating and melting 220, injection-filling the cavity of the pre-closed mold, and then solidifying or curing to form a molded product. Molding 340 is a major field of processing.

 The molding materials used for injection molding are thermoplastic resins, which are mainly applied to almost all molding materials such as thermosetting resins, rubbers and foam molding materials, and various kinds of molding materials and mold structures have been developed in consideration of the types of molding materials. .

Molding is a standard type of line screw type injection molding machine which is ① mold, ② injection, ③ holding pressure (this series of processes to prevent backflow of material filled in cavity and extract by cooling is repeated as one cycle). When retreating and injecting by material digestion, the screw advances to extrude the molding material and the molding machine of this type is also used for molding the thermosetting resin.

Compared with the thermoplastic resin, when the mold is heated to cure the resin, the temperature of the heating cylinder is lowered to prevent the resin from solidifying, and thus, the heating method of the cylinder and the shape of the screw are somewhat different.

Next, as a method of determining the injection molding conditions;

1, extrusion

 The silver nano 160 powder was introduced into a thermoplastic material on the surface of various thin layer substrates such as paper, cloth, cellophane, vinyl, film, metal film, and the like by heating and melting 220 using an extruder to make a fluid state. It is a processing method in which it is extruded into a thin film form at the same time and is continuously pressed. Characteristics of the substrate and the thermoplastic plastic

Combinations of features (water resistance, moisture resistance, chemical resistance, flexibility toughness, breathability, heat rod synthesis, etc.) make the packaging volume layer material adaptable to various applications, but the mainstream of the current practical use is low density polyethylene, polypropylene, Vinylene chloride resin and the like.

2, compression-molding

 In the most common molding method of the thermosetting resin, the molding material into which the silver nano 160 is charged is placed in a recessed hole (called a cavity) of a heated mold, and press-molded by the compression molding machine (press).

 The molding material of the tray is heated in the cavity and once flowed, spreads to every corner of the cavity and causes a simultaneous chemical reaction to cure, so after opening the mold after a suitable time (called curing time) You can get the product by finishing, and if you divide the molding process largely, it will be the forming process and finishing process.

The molding process is carried out by ① molding material processing weighing (sometimes, it may be done by using a turret machine) and ② inserting material into the cavity (preheated before)

 ③ Pressurization operation (low pressure pressurization, high pressure pressurization) ④ Curing process ⑤ Remove molded product It is to clean the mold.

Finishing process includes ① flash 뗌 ② gloss, etc., and for molding large and thick products, high frequency preheating is usually performed for efficiency and quality improvement. It should be decided properly. In the case of molding a thick product even in a thermoplastic resin or producing a silicon film, compression molding is performed. In this case, the method is to remove the molded product by cooling the mold after heating and pressing the molding material. In general, the compression molding is characterized by less molding of the dielectric material or molecules compared to injection molding or transfer molding, so that a molded article having less internal stress can be easily obtained.

 3, extrusion-blow molding

 Synthetic resin in which silver nano (160) powder is injected,

It is inserted into one or two or more molds of flies that are continuously melted and extruded into a tube from an extruder by heating and melting (220), and the top and bottom are sealed and then expanded by blowing air into the fly hands from the mandrel. It is a method of making a product of a distributing plate by being in close contact with the inner wall and is the most popular blow molding method.

 4, blow molding

 It is a method of softening 360 by heating in a split mold to inflate a flyson or a sheet into which thermoplastic synthetic resin material and silver nano 160 powder are poured, using air pressure or the like. The thermoplastic synthetic resin molding material, usually called blow molding or blow molding, is extruded or extruded or inserted into a mold for blow molding 340 by preliminarily forming a Parisian or two-sheeted sheet into a tube according to an injection method. After heat softening (360), the air is blown into such a hollow product to be molded (340). There are various forms of blow molding according to the Parisian state molding method and the like, such as injection blow molding, extrusion blow molding, sheet blow method (sheet fly hand method), direct blow molding, blow molding and the like.

5, vacuum forming

 After heat softening (360) the thermoplastic material into which the silver nano (160) powder was put, and put it on the mold, immediately vacuuming the gap between the tongue and the sheet to close the surface of the mold and cooling it to fix the phenomenon of the molded article. On the contrary, when the shape is used to take out the molded product by inhaling the air, it is called the spun-forming foam forming, and when the male type is used, it is called the drape forming.

6. vacuum deposition;

A brief overview of vacuum deposition refers to attaching the vapor to the surface of an object by heating a small piece of metal or nonmetal to which silver nano 160 powder is injected in a vacuum.

That is, a method in which a current is applied to a tungsten coil in which a metal (Al) or chromium (Cr) piece to be attached to the surface (object to be deposited) to be coated in a high vacuum state and a metal (Al) or chromium (Cr) piece to be attached to the surface is heated and attached in a high vacuum state. I use it.

In the vacuum deposition process, the paint used in BASE and TOP is composed of urethane acrylate, monomer, and other additives, and it can represent various types of products depending on whether the paint is glossy or matte.

In addition, dyes can be added during TOP PAINT spraying to represent any color desired.

As a result, the method of forming a drainage plate 340 formed of any one of synthetic resin, rubber, synthetic resin, and acrylic material was examined, and the general coating process of the drainage plate containing silver nano 160 powder of the present invention was carried out. Briefly described as follows.

Pre-treatment step to remove the material of the regular plate, the surface of the plate through the pre-treatment step coating the surface color and then drying (260) it coating (180) and coating 180 through the step The coating process 180 and the process of spray coating 180 by mixing (200) the paint and silver nano (160) material on the surface of the plate to go through the surface resistance coating (180) step to lower the surface resistance from the surface of the plate and this process After passing through a slow cooling process and drying (260) shows the step of completing the step.

The silver nano 160 powder is added in an amount of 0.01 to 20 parts by weight based on the total material weight of the tray, and the other metals are 20 to 99 parts by weight of stainless steel, 10 to 99 parts by weight of iron, and 10 to 10 parts by weight of titanium. Or 99 parts by weight. 0.01 to 10 parts by weight of gold or gold nano, 0.01 to 10 parts by weight of zinc, and 0.01 to 10 parts by weight of platinum or platinum nano may be prepared by feeding into a tray.

4 is a block diagram of a wet plating process of the functional dish plate of the present invention.

In order to coat 180 the inside and the outside of the finished plate, a wet coating method of electroplating silver nano 160 or a dry coating method using plasma may be used, and the present invention follows a conventional coating method. Since there are many types and methods of the coating 180, and all of them cannot be listed, a wet electric coating will be described as an exemplary embodiment.

 Coating 180 or plating is generally divided into electroplating 180 and electroless plating 180, and silver plating requires a solution containing silver ions, and gold plating requires a solution containing gold nano ions. I will.

 When the electrode is placed in a solution containing metal ions and a current is applied, metal ions are discharged and precipitated at the cathode, which is used to form a thin film of metal on the surface of the article placed on the cathode.

The purpose of plating 180 is to beautifully finish the exterior of the article, to increase corrosion resistance, to resist wear and corrosion, and to obtain other necessary surface properties. The purpose is to reduce the pain of the patient during the insertion and insertion of the germ board.

 The general procedure of the electroplating in the present application is to pre-plating nickel (500) and copper plated nickel (160) second to the silver metal (160) plating (180) on the metal surface of the metal plate of the plate (2) This process may be omitted if necessary, and finally, the silver nano 160 powder may be plated 180.

 The silver nano (160) powder is used as the cathode, and the metal to be electrodeposited is used as the anode. The silver nano (160) powder is placed in an electrolyte solution containing nano silver ions to be electrodeposited. It will stick to the surface of this tray.

Looking at the process of plating the silver nano (160) powder on the culture plate 180 through the washing process 420 and rinsing process (440) to shake off impurities in the main body 10 of the finished culture plate plate (마 布) After the furnace polishing process (460) and washed again with clean water (洗滌) to immerse in the plating solution.

In the plating tank 480, the plate is stored in a container containing a plate to be plated with silver nano 160 powder (Nano silver) powder and connected to the plate on the pole side, and solidified silver on the pole side. The nano plate 580 is connected and the silver nano 160 powder solution 160 containing the silver nano 160 powder ions is injected and DC electricity is applied to the + and-poles. 160) (Nano silver) powder to be coated (180) and coated (180) or plated (180) silver nano (160) (Nano silver) plate once again washing process (420) and drying (260) After the process (260) is dried (260) to be completed and packaged.

As described above, an object to be plated 180 is attached to the negative electrode of the battery (a plate is attached, and a silver nano (160) plate 580 is attached to the positive electrode so that the positive and negative ions of the silver fall off, where the electron is the negative electrode). Of course, the aqueous solution contains silver nano (160) (Nano silver) ions-When the electrons come to the pole, the silver nano (160) (Nano silver) ions in the aqueous solution will be attached to the distribution plate around this way, The fermentation plate is a wet plating (180) with nano (160) (Nano silver) powder.

 The coating 180 of the wet plating 180 of the silver nano 160 powder is coated with a thickness of 0.0l μm to 50 μm (micrometer) and the total weight of the plate is weighted. It is added in an amount of 0.01 to 20 parts by weight based on the weight and the size of the injected silver nano 160 powder particles is plated to a particle size of 0.1 to 300nm.

In addition, the embodiment of the silver nano 160 plating 180 is according to the conventional plating 180 or coating method, and the plating 180 material is used as the aged silver nano 160 material, the characteristics of the present application Is there.

Next, FIG. 5 is a block diagram of a plasma coating process of dry plating of a functional draining plate of the present invention, which is a block diagram of a plasma coating 180 process of dry plating of a draining plate, containing silver nano 160 powder of the present invention. The plasma (plasma) of the culture plate and the coating 180 will be described in detail 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.

Plasma is not common in everyday life, but it is common throughout the universe, because 99% of the universe is assumed to be plasma, for example conducting gases, rockets or lightning that carry currents in fluorescent lamps. There are ionized gases mixed in the gas when it hits, aurora borealis in the Arctic, ionosphere in the atmosphere.

 Plasma is present in the van allenic zone, solar winds intermittently pouring from the sun, and the hydrogen gas filling the space between the stars and the surrounding gas and the space between the stars is in the plasma state. .

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, and thus used for semiconductor device, tool coating (180) and optical component coating (180). In addition, new applications are being actively explored for acoustic devices.

In addition, the wear-resistant coating 180, the decorative coating 180 of the tool, it can be made by a dry method through a reactive ion plating or sputtering method used as a diffusion barrier at the contact when manufacturing a 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 plasma materials and thermal spraying, 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 vacuumizes the vacuum chamber 400, 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 (160) plate) and the silver nano (160) atoms stick out in the gaseous state and plated (180) on the plated body (formula plate). To control.

Next, the process of coating the coating plate 180 using the plasma of the present invention (Plasma) briefly described as follows.

 In order to wash the foreign substances on the surface of the finished serving plate, the washing plate is put into the washing tub, the washing liquid is injected, and the washing process is used to wash the impurities in the manufacturing process inside or outside the metal ash serving plate using the washing machine (420). After passing through the rinsing process (460) and passing through the drying (260) in the drying (260) to evaporate the water, the vacuum plate is put into the chamber 400 while attached to the fixing plate (not shown) After the sterilization treatment process 560 inside or outside the serving plate with plasma, the silver nano 160 surface processing is performed.

Next, after the plasma sterilization process (580) and the silver nano (160) primary surface processing (600), the surface adhesion of the plate (180) coated with silver nano (160) and the strength of the plate were improved. Plasma secondary surface processing (620) and strengthening treatment to increase the.

Next, in the plasma plating 180 or the coating 180 of the silver nano 160 powder by the vacuum macnetron stuffing plasma plating 180 method, the plasma plating coating 180 thickness of 0.01 μm to 50 Finished by coating (180) with plasma (Plasma) to a preferred thickness of (μm) or by adding a silver nano (160) powder to the metal material of the distribution plate in 0.01 to 20 parts by weight based on the total weight of the distribution plate and 20 to 99 parts by weight of stainless steel, 10 to 99 parts by weight of iron, 10 to 99 parts by weight of titanium, or 0.01 to 10 parts by weight of gold or gold nano, 0.01 to 10 parts by weight of zinc, platinum or platinum It is also possible to produce silver nano (160) powder into an alloy by mixing (200) or coating (180) silver nano (160 powders) with an alloy of 0.01 to 10 parts by weight of nano. Las forehead will be possible to also be a ceramic coating 180, it is possible to mix 200 and coating 180, the material of the food distribution plate of the non-metal non-metallic synthetic resin, acrylic, silicone, vinyl, ceramic uses.

As a result, a mixed plate 200 or 180 coated with silver nano 160 powder was completed, and after packaging, it was distributed to a military unit or a group lunch place, which can be used hygienically and effectively.

Those skilled in the art should understand that the silver nano 160 powder, coating 180 or plating 180 method follows the conventional mixing 200 mixing, plating, coating 180 process.

This is a mixture (200) of the mixing plate made of synthetic resin, rubber material or

The molding 340 method was described.

The following is a picture taken by the electron microscope of the cross-section, side and surface of the silver nano 160 of the present invention as shown in the figure for the understanding of the present invention and described.

Figure 6 is a photograph taken by magnification 60.000 times with an electron microscope of the functional dish plate of the present invention.

Figure 7 is a photograph taken by magnification 80.000 times the side of the functional dish plate of the present invention.

Figure 8 is a photograph taken by magnification 50.000 times the surface of the functional dish plate of the present invention.

9 is a three-dimensional structure diagram of silver nano for explaining the silver nano of the present invention.

Figure 10 is a photograph of the antimicrobial activity of the strain nanoparticles of the present invention.

11 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.

As described above, silver nano (160) powder is mixed with 200 to 0.01 to 20 parts by weight based on the total weight of the culture plate, plasticized, melted (220), and stirred (280) after the mixing plate. It is completed by injecting the mold 340 into the mold.

In the above, the general configuration of the culture plate of the present invention was examined in detail. For sterilization of the culture plate of the present invention, silver nano (160) powder is extremely preferable, and the amount of the mixed (200) culture is formed of metal, ceramic, and synthetic resin. 0.01-20 weight part is preferable each of the board total weight.

 It is because the antibacterial effect is not sufficiently exhibited at 0.01 parts by weight or less, and at 20 parts by weight or more, the price increase and viscosity are so large that it is practically difficult to manufacture the distribution board of the present invention.

The present invention is mixed (200) or coated 180 with silver nano (160) powder having a strong antimicrobial sterilization and lubrication as any one of the preferred weight of 0.01 to 20 parts by weight of the raw material of the culture plate as described above The silver plated (100) per 100g to the weight of the plate in the PPM unit in a content ratio of 0.01 to 20PPM standard range to more effectively block the reproduction of mold or viral bacteria that breeds in the patient's saliva and external environment You can use the plate.

The present invention adds silver (160) powder (Nano silver) to the serving plate or the coating 180 or mixed (200) on the inside and outside of the serving plate body 10 to the functional dish having a sterilization and antibacterial function of the serving plate It is characterized by having a plate.

Although the present invention has been described with reference to one embodiment shown in the drawings, this is merely exemplary, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom.

An object of the present invention is to solve the conventional problems as described above

Silver, which is a technique different from conventional silver, is a powder in the form of silver nano or

 Made of colloidal silver and synthetic resin or metal

 0.01 to 20 parts by weight or mixed with PPM at a ratio of 0.01 to 20 PPM per 100 g of silver nano (Nano silver) or after completion of extrusion, molding, injection, adhesion and bonding, coating, work Provides antimicrobial plate containing silver nano which has excellent sterilization and antimicrobial ability to keep clean and hygienic use of plate which is easy to produce and propagate bacteria or mold microorganism. Is in.

Although the present invention has been shown and described with respect to certain preferred embodiments, the present invention may be variously modified and changed without departing from the spirit or the field of the present invention provided by the following utility model registration claims. It will be readily apparent to one of ordinary skill in the art.

As described above, silver nano 160 is added in an amount of 0.01 to 20 parts by weight or coated with respect to the total weight of the main body 20 of a plate made of synthetic resin or metal, which is a raw material of the plate, according to the present invention. Pears containing silver nano powder that can sterilize and destroy food poisoning or bacterial infections that can occur by using sterilized and neutralized odors and contaminated germ boards and improve public health. It is about a plate.

The table below shows an example of killing the bacteria after 30 minutes by adding 5 parts by weight of silver nanoparticles to Staphylococcus aureus, pneumococci, bacteria, and MRSA (Methicillin-resistant Staphylococcus aureus) bacteria. It can be seen that there is bactericidal power.

test subject unit Number of strains  5 parts by weight of nano-addition (after 30 minutes have elapsed) Staphylococcus aureus CFU / mL 3.4 X 10 ³ 0 Pneumonia group CFU / mL 3.1 X 10 ³ 0 MRSA (Methicillin Resistant Staphylococcus Aureus) CFU / mL 1.3 X 10 ² 0 bacteria CFU / mL 3.4 X 10 ² 0

  (This test report is the analysis data of Korea Testing Institute)

1 is a perspective view showing a functional tray plate of the present invention.

Figure 2 is a block diagram showing the manufacturing process of the functional synthetic resin tray plate of the present invention.

Figure 3 is a block diagram showing the manufacturing process of the functional metal plate of the present invention.

Figure 4 is a block diagram of the wet plating process of the functional dish plate of the present invention.

Figure 5 is a block diagram of the plasma coating process of dry plating of the functional dish plate of the present invention.

Figure 6 is a photograph taken by magnification 60.000 times with an electron microscope of the functional dish plate of the present invention.

Figure 7 is a photograph taken by magnification 80.000 times the side of the functional dish plate of the present invention.

Figure 8 is a photograph taken by magnification 50.000 times the surface of the functional dish plate of the present invention.

9 is a three-dimensional structure diagram of silver nano for explaining the silver nano of the present invention.

Figure 10 is a photograph of the antimicrobial activity of the strain nanoparticles of the present invention.

11 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 Major Symbols in Drawings *

80: body 90: side dish space

100: rice space department 110: bureau space department

120: receiving unit 130: cutlery home

160: frame part 160: silver nano

170: fragrance 180: coating, plating

200: mixing 220: melting

240: fusion 260: drying

280: stirring 300: canister

320: injection 340: molding

360: softening 380: mold module

400: chamber 420: cleaning process

440: rinse 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: 2nd surface finish

Claims (14)

The main body portion 80, the side dish portion 90, the rice bowl portion 40, the soup bowl portion 110 and the cutlery and chopsticks groove 130 of the serving plate made of a metal or non-metal material used at meal In the configured serving plate, Functional serving plate, characterized in that the mixture of 200 to 0.01 parts by weight of silver nano (160) powder relative to the total weight of the serving plate (200). 0.01 to 20 weight of silver nano solution in which silver nano 160 powder or silver nano powder is dissolved in water based on the total weight of the culture plate in a culture plate made of any one of metal, synthetic resin, ceramic, silicon, and acrylic Further comprising a wet or plasma dry coating (180) on the body surface of the serving plate further functional serving plate. The method according to claim 1 or 2. The size of the silver nanoparticles (160) powder particles introduced into the serving plate has a particle size of 0.1 to 300nm, characterized in that the functional serving plate. The method according to claim 2,  Functional wet plate characterized in that the silver nano (160) powder coating film is formed on the body of the plate to the thickness of 0.0l㎛ ~ 50㎛ by the wet or dry coating method. delete delete delete delete delete delete delete delete delete delete